celinelee/thestack_omp · Datasets at Hugging Face

source stringlengths 3 92	c stringlengths 26 2.25M
ep.c	/-------------------------------------------------------------------- NAS Parallel Benchmarks 3.0 structured OpenMP C versions - EP This benchmark is an OpenMP C version of the NPB EP code. The OpenMP C 2.3 versions are derived by RWCP from the serial Fortran versions in "NPB 2.3-serial" developed by NAS. 3.0 translation is performed by the UVSQ. Permission to use, copy, distribute and modify this software for any purpose with or without fee is hereby granted. This software is provided "as is" without express or implied warranty. Information on OpenMP activities at RWCP is available at: http://pdplab.trc.rwcp.or.jp/pdperf/Omni/ Information on NAS Parallel Benchmarks 2.3 is available at: http://www.nas.nasa.gov/NAS/NPB/ --------------------------------------------------------------------/ /-------------------------------------------------------------------- Author: P. O. Frederickson D. H. Bailey A. C. Woo OpenMP C version: S. Satoh 3.0 structure translation: M. Popov --------------------------------------------------------------------/ #include "../common/npb-C.h" #include "npbparams.h" /* parameters / #define MK 16 #define MM (M - MK) #define NN (1 << MM) #define NK (1 << MK) #define NQ 10 #define EPSILON 1.0e-8 #define A 1220703125.0 #define S 271828183.0 #define TIMERS_ENABLED FALSE / global variables / / common /storage/ / static double x[2NK]; static double q[NQ]; /-------------------------------------------------------------------- program EMBAR c-------------------------------------------------------------------/ /* c This is the serial version of the APP Benchmark 1, c the "embarassingly parallel" benchmark. c c M is the Log_2 of the number of complex pairs of uniform (0, 1) random c numbers. MK is the Log_2 of the size of each batch of uniform random c numbers. MK can be set for convenience on a given system, since it does c not affect the results. / int main(int argc, char argv) { double Mops, t1, t2, t3, t4, x1, x2, sx, sy, tm, an, tt, gc; double dum[3] = { 1.0, 1.0, 1.0 }; int np, ierr, node, no_nodes, i, ik, kk, l, k, nit, ierrcode, no_large_nodes, np_add, k_offset, j; int nthreads = 1; boolean verified; char size[13+1]; / character13 / /* c Because the size of the problem is too large to store in a 32-bit c integer for some classes, we put it into a string (for printing). c Have to strip off the decimal point put in there by the floating c point print statement (internal file) / printf("\n\n NAS Parallel Benchmarks 3.0 structured OpenMP C version" " - EP Benchmark\n"); sprintf(size, "%12.0f", pow(2.0, M+1)); #pragma omp parallel for firstprivate(j ) for (j = 13; j >= 1; j--) { if (size[j] == '.') size[j] = ' '; } printf(" Number of random numbers generated: %13s\n", size); verified = FALSE; / c Compute the number of "batches" of random number pairs generated c per processor. Adjust if the number of processors does not evenly c divide the total number / np = NN; / c Call the random number generator functions and initialize c the x-array to reduce the effects of paging on the timings. c Also, call all mathematical functions that are used. Make c sure these initializations cannot be eliminated as dead code. / vranlc(0, &(dum[0]), dum[1], &(dum[2])); dum[0] = randlc(&(dum[1]), dum[2]); #pragma omp parallel for private(i ) for (i = 0; i < 2NK; i++) x[i] = -1.0e99; Mops = log(sqrt(fabs(max(1.0, 1.0)))); timer_clear(1); timer_clear(2); timer_clear(3); timer_start(1); vranlc(0, &t1, A, x); /* Compute AN = A ^ (2 * NK) (mod 2^46). / t1 = A; for ( i = 1; i <= MK+1; i++) { t2 = randlc(&t1, t1); } an = t1; tt = S; gc = 0.0; sx = 0.0; sy = 0.0; #pragma omp parallel for firstprivate(i ) for ( i = 0; i <= NQ - 1; i++) { q[i] = 0.0; } / c Each instance of this loop may be performed independently. We compute c the k offsets separately to take into account the fact that some nodes c have more numbers to generate than others / k_offset = -1; { double t1, t2, t3, t4, x1, x2; int kk, i, ik, l; double qq[NQ]; / private copy of q[0:NQ-1] / #pragma omp parallel for firstprivate(i ) for (i = 0; i < NQ; i++) qq[i] = 0.0; #pragma omp parallel for reduction(+:sx) reduction(+:sy) for (k = 1; k <= np; k++) { kk = k_offset + k; t1 = S; t2 = an; / Find starting seed t1 for this kk. / for (i = 1; i <= 100; i++) { ik = kk / 2; if (2 ik != kk) t3 = randlc(&t1, t2); if (ik == 0) break; t3 = randlc(&t2, t2); kk = ik; } /* Compute uniform pseudorandom numbers. / if (TIMERS_ENABLED == TRUE) timer_start(3); vranlc(2NK, &t1, A, x-1); if (TIMERS_ENABLED == TRUE) timer_stop(3); /* c Compute Gaussian deviates by acceptance-rejection method and c tally counts in concentric square annuli. This loop is not c vectorizable. / if (TIMERS_ENABLED == TRUE) timer_start(2); for ( i = 0; i < NK; i++) { x1 = 2.0 x[2i] - 1.0; x2 = 2.0 x[2i+1] - 1.0; t1 = pow2(x1) + pow2(x2); if (t1 <= 1.0) { t2 = sqrt(-2.0 log(t1) / t1); t3 = (x1 * t2); /* Xi / t4 = (x2 t2); /* Yi / l = max(fabs(t3), fabs(t4)); qq[l] += 1.0; / counts / sx = sx + t3; / sum of Xi / sy = sy + t4; / sum of Yi / } } if (TIMERS_ENABLED == TRUE) timer_stop(2); } { #pragma omp parallel for firstprivate(i ) for (i = 0; i <= NQ - 1; i++) q[i] += qq[i]; } #if defined(_OPENMP) nthreads = omp_get_num_threads(); #endif / _OPENMP / } / end of parallel region */ #pragma omp parallel for firstprivate(i ) reduction(+:gc) for (i = 0; i <= NQ-1; i++) { gc = gc + q[i]; } timer_stop(1); tm = timer_read(1); nit = 0; if (M == 24) { if((fabs((sx- (-3.247834652034740e3))/sx) <= EPSILON) && (fabs((sy- (-6.958407078382297e3))/sy) <= EPSILON)) { verified = TRUE; } } else if (M == 25) { if ((fabs((sx- (-2.863319731645753e3))/sx) <= EPSILON) && (fabs((sy- (-6.320053679109499e3))/sy) <= EPSILON)) { verified = TRUE; } } else if (M == 28) { if ((fabs((sx- (-4.295875165629892e3))/sx) <= EPSILON) && (fabs((sy- (-1.580732573678431e4))/sy) <= EPSILON)) { verified = TRUE; } } else if (M == 30) { if ((fabs((sx- (4.033815542441498e4))/sx) <= EPSILON) && (fabs((sy- (-2.660669192809235e4))/sy) <= EPSILON)) { verified = TRUE; } } else if (M == 32) { if ((fabs((sx- (4.764367927995374e4))/sx) <= EPSILON) && (fabs((sy- (-8.084072988043731e4))/sy) <= EPSILON)) { verified = TRUE; } } Mops = pow(2.0, M+1)/tm/1000000.0; printf("EP Benchmark Results: \n" "CPU Time = %10.4f\n" "N = 2^%5d\n" "No. Gaussian Pairs = %15.0f\n" "Sums = %25.15e %25.15e\n" "Counts:\n", tm, M, gc, sx, sy); for (i = 0; i <= NQ-1; i++) { printf("%3d %15.0f\n", i, q[i]); } c_print_results("EP", CLASS, M+1, 0, 0, nit, nthreads, tm, Mops, "Random numbers generated", verified, NPBVERSION, COMPILETIME, CS1, CS2, CS3, CS4, CS5, CS6, CS7); if (TIMERS_ENABLED == TRUE) { printf("Total time: %f", timer_read(1)); printf("Gaussian pairs: %f", timer_read(2)); printf("Random numbers: %f", timer_read(3)); } }
target_data_messages.c	// RUN: %clang_cc1 -triple x86_64-apple-macos10.7.0 -verify -fopenmp -ferror-limit 100 -o - %s // RUN: %clang_cc1 -triple x86_64-apple-macos10.7.0 -verify -fopenmp-simd -ferror-limit 100 -o - %s void foo() { } int main(int argc, char **argv) { int a; #pragma omp target data // expected-error {{expected at least one 'map' or 'use_device_ptr' clause for '#pragma omp target data'}} {} L1: foo(); #pragma omp target data map(a) allocate(a) // expected-error {{unexpected OpenMP clause 'allocate' in directive '#pragma omp target data'}} { foo(); goto L1; // expected-error {{use of undeclared label 'L1'}} } goto L2; // expected-error {{use of undeclared label 'L2'}} #pragma omp target data map(a) L2: foo(); #pragma omp target data map(a)(i) // expected-warning {{extra tokens at the end of '#pragma omp target data' are ignored}} { foo(); } #pragma omp target unknown // expected-warning {{extra tokens at the end of '#pragma omp target' are ignored}} { foo(); } return 0; }
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 128 #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->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) (x+4), sizeof(clone_info->dash_pattern)); if (clone_info->dash_pattern == (double ) NULL) ThrowFatalException(ResourceLimitFatalError, "UnableToAllocateDashPattern"); (void) memcpy(clone_info->dash_pattern,draw_info->dash_pattern,(size_t) (x+4)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->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) { 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); } 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 ((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) { mvg_info->extent=(size_t) extent; 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); } 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(CompareSplayTreeString,RelinquishMagickMemory, RelinquishMagickMemory); macro=AcquireString(primitive); token=AcquireString(primitive); extent=strlen(token)+MagickPathExtent; for (q=primitive; q != '\0'; ) { GetNextToken(q,&q,extent,token); if (token == '\0') break; if (LocaleCompare("push",token) == 0) { register const char end, start; GetNextToken(q,&q,extent,token); if (q == '"') { char name[MagickPathExtent]; const char p; ssize_t n; / Named macro (e.g. push graphic-context "wheel"). / GetNextToken(q,&q,extent,token); start=q; end=q; (void) CopyMagickString(name,token,MagickPathExtent); n=1; for (p=q; p != '\0'; ) { GetNextToken(p,&p,extent,token); 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. / 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(status == 0 ? MagickFalse : MagickTrue); } primitive=(char ) NULL; if (draw_info->primitive != '@') primitive=AcquireString(draw_info->primitive); else if ((strlen(draw_info->primitive) > 1) && ((draw_info->primitive+1) != '-')) primitive=FileToString(draw_info->primitive+1,~0UL,exception); if (primitive == (char ) NULL) return(MagickFalse); primitive_extent=(double) strlen(primitive); (void) SetImageArtifact(image,"MVG",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. / GetNextToken(q,&q,MagickPathExtent,keyword); 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); switch (keyword) { case ';': break; case 'a': case 'A': { if (LocaleCompare("affine",keyword) == 0) { GetNextToken(q,&q,extent,token); affine.sx=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); GetNextToken(q,&q,extent,token); if (token == ',') GetNextToken(q,&q,extent,token); affine.rx=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); GetNextToken(q,&q,extent,token); if (token == ',') GetNextToken(q,&q,extent,token); affine.ry=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); GetNextToken(q,&q,extent,token); if (token == ',') GetNextToken(q,&q,extent,token); affine.sy=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); GetNextToken(q,&q,extent,token); if (token == ',') GetNextToken(q,&q,extent,token); affine.tx=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); GetNextToken(q,&q,extent,token); if (token == ',') 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) { 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; GetNextToken(q,&q,extent,token); if (token == '\0') { status=MagickFalse; 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. / 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 (draw_info->compliance != SVGCompliance) status&=DrawClipPath(image,graphic_context[n], graphic_context[n]->clip_mask,exception); } break; } if (LocaleCompare("clip-rule",keyword) == 0) { ssize_t fill_rule; 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; 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. / 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; 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) { GetNextToken(q,&q,extent,token); (void) CloneString(&graphic_context[n]->density,token); break; } if (LocaleCompare("direction",keyword) == 0) { ssize_t direction; 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) { 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) { 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; 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(QuantumRangeopacity); break; } if (LocaleCompare("fill-rule",keyword) == 0) { ssize_t fill_rule; 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) { 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) { GetNextToken(q,&q,extent,token); (void) CloneString(&graphic_context[n]->family,token); break; } if (LocaleCompare("font-size",keyword) == 0) { 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; 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; 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; 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) { GetNextToken(q,&q,extent,token); break; } if (LocaleCompare("gravity",keyword) == 0) { ssize_t gravity; 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; 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) { 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) { 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) { 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) { 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. / 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 (draw_info->compliance != SVGCompliance) status=SetImageMask(image,CompositePixelMask, graphic_context[n]->composite_mask,exception); } break; } break; } case 'o': case 'O': { if (LocaleCompare("offset",keyword) == 0) { GetNextToken(q,&q,extent,token); break; } if (LocaleCompare("opacity",keyword) == 0) { double opacity; 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 != OpaqueAlpha) graphic_context[n]->fill.alpha=graphic_context[n]->fill_alpha; graphic_context[n]->stroke_alpha=opacity; if (graphic_context[n]->stroke_alpha != OpaqueAlpha) graphic_context[n]->stroke.alpha=graphic_context[n]->stroke_alpha; 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) { GetNextToken(q,&q,extent,token); 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) && (draw_info->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) { GetNextToken(q,&q,extent,token); if (LocaleCompare("class",token) == 0) { /* Class context. / for (p=q; q != '\0'; ) { GetNextToken(q,&q,extent,token); if (LocaleCompare(token,"pop") != 0) continue; GetNextToken(q,(const char *) NULL,extent,token); if (LocaleCompare(token,"class") != 0) continue; break; } GetNextToken(q,&q,extent,token); break; } if (LocaleCompare("clip-path",token) == 0) { char name[MaxTextExtent]; const char clip_path; GetNextToken(q,&q,extent,token); (void) FormatLocaleString(name,MaxTextExtent,"%s",token); clip_path=(const char ) GetValueFromSplayTree(macros,name); if (clip_path != (const char ) NULL) (void) SetImageArtifact(image,name,clip_path); 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; GetNextToken(q,&q,extent,token); (void) CopyMagickString(name,token,MagickPathExtent); GetNextToken(q,&q,extent,token); (void) CopyMagickString(type,token,MagickPathExtent); GetNextToken(q,&q,extent,token); segment.x1=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); GetNextToken(q,&q,extent,token); if (token == ',') GetNextToken(q,&q,extent,token); segment.y1=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); GetNextToken(q,&q,extent,token); if (token == ',') GetNextToken(q,&q,extent,token); segment.x2=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); GetNextToken(q,&q,extent,token); if (token == ',') GetNextToken(q,&q,extent,token); segment.y2=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); if (LocaleCompare(type,"radial") == 0) { GetNextToken(q,&q,extent,token); if (token == ',') GetNextToken(q,&q,extent,token); } for (p=q; q != '\0'; ) { GetNextToken(q,&q,extent,token); if (LocaleCompare(token,"pop") != 0) continue; 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); 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 == '"') GetNextToken(q,&q,extent,token); break; } if (LocaleCompare("mask",token) == 0) { GetNextToken(q,&q,extent,token); break; } if (LocaleCompare("pattern",token) == 0) { char key[2MagickPathExtent], name[MagickPathExtent]; RectangleInfo bounds; GetNextToken(q,&q,extent,token); (void) CopyMagickString(name,token,MagickPathExtent); GetNextToken(q,&q,extent,token); bounds.x=(ssize_t) ceil(StringToDouble(token,&next_token)-0.5); if (token == next_token) ThrowPointExpectedException(token,exception); GetNextToken(q,&q,extent,token); if (token == ',') GetNextToken(q,&q,extent,token); bounds.y=(ssize_t) ceil(StringToDouble(token,&next_token)-0.5); if (token == next_token) ThrowPointExpectedException(token,exception); GetNextToken(q,&q,extent,token); if (token == ',') GetNextToken(q,&q,extent,token); bounds.width=(size_t) floor(StringToDouble(token,&next_token)+ 0.5); if (token == next_token) ThrowPointExpectedException(token,exception); GetNextToken(q,&q,extent,token); if (token == ',') 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'; ) { GetNextToken(q,&q,extent,token); if (LocaleCompare(token,"pop") != 0) continue; 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); 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) { 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) { GetNextToken(q,&q,extent,token); affine.sx=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); GetNextToken(q,&q,extent,token); if (token == ',') GetNextToken(q,&q,extent,token); affine.sy=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); break; } if (LocaleCompare("skewX",keyword) == 0) { 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) { 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; } GetNextToken(q,&q,extent,token); status&=QueryColorCompliance(token,AllCompliance,&stop_color, exception); stops[number_stops-1].color=stop_color; 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) { 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) { 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; GetNextToken(r,&r,extent,token); if (token == ',') GetNextToken(r,&r,extent,token); for (x=0; IsPoint(token) != MagickFalse; x++) { GetNextToken(r,&r,extent,token); if (token == ',') GetNextToken(r,&r,extent,token); } graphic_context[n]->dash_pattern=(double ) AcquireQuantumMemory((size_t) (2x+4), 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+4)sizeof(graphic_context[n]->dash_pattern)); for (j=0; j < x; j++) { GetNextToken(q,&q,extent,token); if (token == ',') 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; } GetNextToken(q,&q,extent,token); break; } if (LocaleCompare("stroke-dashoffset",keyword) == 0) { 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; 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; 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) { GetNextToken(q,&q,extent,token); graphic_context[n]->miterlimit=StringToUnsignedLong(token); break; } if (LocaleCompare("stroke-opacity",keyword) == 0) { double opacity; 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(QuantumRangeopacity); break; } if (LocaleCompare("stroke-width",keyword) == 0) { 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; cursor=0.0; break; } if (LocaleCompare("text-align",keyword) == 0) { ssize_t align; 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; 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) { GetNextToken(q,&q,extent,token); graphic_context[n]->text_antialias=StringToLong(token) != 0 ? MagickTrue : MagickFalse; break; } if (LocaleCompare("text-undercolor",keyword) == 0) { GetNextToken(q,&q,extent,token); status&=QueryColorCompliance(token,AllCompliance, &graphic_context[n]->undercolor,exception); break; } if (LocaleCompare("translate",keyword) == 0) { GetNextToken(q,&q,extent,token); affine.tx=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); GetNextToken(q,&q,extent,token); if (token == ',') 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. / 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) { 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); GetNextToken(q,&q,extent,token); if (token == ',') 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); GetNextToken(q,&q,extent,token); if (token == ',') 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); GetNextToken(q,&q,extent,token); if (token == ',') 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) { 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; GetNextToken(q,&q,extent,token); point.x=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); GetNextToken(q,&q,extent,token); if (token == ',') GetNextToken(q,&q,extent,token); point.y=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); GetNextToken(q,(const char *) NULL,extent,token); if (token == ',') 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; 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; if (coordinates > (MaxBezierCoordinates/4)) { (void) ThrowMagickException(exception,GetMagickModule(),DrawError, "TooManyBezierCoordinates","`%s'",token); status=MagickFalse; } break; } default: break; } if (coordinates > MaxBezierCoordinates) { (void) ThrowMagickException(exception,GetMagickModule(), ResourceLimitError,"MemoryAllocationFailed","`%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; } 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 != ',') 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; break; } case ImagePrimitive: { if (primitive_info[j].coordinates != 2) { status=MagickFalse; break; } 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) && (draw_info->compliance != SVGCompliance) && (graphic_context[n]->clip_mask != (char ) NULL) && (LocaleCompare(graphic_context[n]->clip_mask, graphic_context[n-1]->clip_mask) != 0)) 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 void LogPrimitiveInfo(const PrimitiveInfo primitive_info) { const char methods[] = { "point", "replace", "floodfill", "filltoborder", "reset", "?" }; PointInfo p, q, point; 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(primitive_info->point.x-0.5); y=(ssize_t) ceil(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(); if (LocaleNCompare(primitive_info->text,"data:",5) == 0) composite_images=ReadInlineImage(clone_info,primitive_info->text, exception); else { (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; status&=DrawAffineImage(image,composite_image,&affine,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; stroke_polygon=(PrimitiveInfo ) RelinquishMagickMemory(stroke_polygon); 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 ((fabs(radii.x) < MagickEpsilon) \|\| (fabs(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; 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); p=(mvg_info->primitive_info)+mvg_info->offset; mvg_info->offset+=p->coordinates; p+=p->coordinates; } 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(status == 0 ? MagickFalse : 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) quantum) quantum=(size_t) alpha; alpha=fabs(primitive_info[j].point.y-primitive_info[i].point.y); if (alpha > (double) quantum) quantum=(size_t) alpha; } } quantum=(size_t) MagickMin((double) quantum/number_coordinates, (double) BezierQuantum); control_points=quantumnumber_coordinates; if (CheckPrimitiveExtent(mvg_info,control_points+1) == MagickFalse) return(MagickFalse); primitive_info=(mvg_info->primitive_info)+mvg_info->offset; coefficients=(double ) AcquireQuantumMemory((size_t) number_coordinates,sizeof(coefficients)); points=(PointInfo ) AcquireQuantumMemory((size_t) control_points, sizeof(points)); if ((coefficients == (double ) NULL) \|\| (points == (PointInfo ) NULL)) ThrowFatalException(ResourceLimitFatalError,"MemoryAllocationFailed"); /* 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) return(MagickFalse); p+=p->coordinates; } if (TracePoint(p,end) == MagickFalse) 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) \|\| (coordinates > (double) GetMaxMemoryRequest())) { (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 { GetNextToken(p,&p,MagickPathExtent,token); if (token == ',') GetNextToken(p,&p,MagickPathExtent,token); arc.x=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); GetNextToken(p,&p,MagickPathExtent,token); if (token == ',') GetNextToken(p,&p,MagickPathExtent,token); arc.y=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); GetNextToken(p,&p,MagickPathExtent,token); if (token == ',') GetNextToken(p,&p,MagickPathExtent,token); angle=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); GetNextToken(p,&p,MagickPathExtent,token); if (token == ',') GetNextToken(p,&p,MagickPathExtent,token); large_arc=StringToLong(token) != 0 ? MagickTrue : MagickFalse; GetNextToken(p,&p,MagickPathExtent,token); if (token == ',') GetNextToken(p,&p,MagickPathExtent,token); sweep=StringToLong(token) != 0 ? MagickTrue : MagickFalse; if (token == ',') GetNextToken(p,&p,MagickPathExtent,token); GetNextToken(p,&p,MagickPathExtent,token); if (token == ',') GetNextToken(p,&p,MagickPathExtent,token); x=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); GetNextToken(p,&p,MagickPathExtent,token); if (token == ',') 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++) { GetNextToken(p,&p,MagickPathExtent,token); if (token == ',') GetNextToken(p,&p,MagickPathExtent,token); x=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); GetNextToken(p,&p,MagickPathExtent,token); if (token == ',') 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 { GetNextToken(p,&p,MagickPathExtent,token); if (token == ',') 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 { GetNextToken(p,&p,MagickPathExtent,token); if (token == ',') GetNextToken(p,&p,MagickPathExtent,token); x=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); GetNextToken(p,&p,MagickPathExtent,token); if (token == ',') 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 { GetNextToken(p,&p,MagickPathExtent,token); if (token == ',') GetNextToken(p,&p,MagickPathExtent,token); x=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); GetNextToken(p,&p,MagickPathExtent,token); if (token == ',') 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++) { GetNextToken(p,&p,MagickPathExtent,token); if (token == ',') GetNextToken(p,&p,MagickPathExtent,token); x=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); GetNextToken(p,&p,MagickPathExtent,token); if (token == ',') 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++) { GetNextToken(p,&p,MagickPathExtent,token); if (token == ',') GetNextToken(p,&p,MagickPathExtent,token); x=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); GetNextToken(p,&p,MagickPathExtent,token); if (token == ',') 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++) { GetNextToken(p,&p,MagickPathExtent,token); if (token == ',') GetNextToken(p,&p,MagickPathExtent,token); x=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); GetNextToken(p,&p,MagickPathExtent,token); if (token == ',') 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 { GetNextToken(p,&p,MagickPathExtent,token); if (token == ',') 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; if ((fabs(start.x-end.x) < MagickEpsilon) \|\| (fabs(start.y-end.y) < MagickEpsilon)) { primitive_info->coordinates=0; return(MagickTrue); } 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); }
RecordTable.h	/* * Souffle - A Datalog Compiler * Copyright (c) 2020, The Souffle Developers. All rights reserved. * Licensed under the Universal Permissive License v 1.0 as shown at: * - https://opensource.org/licenses/UPL * - <souffle root>/licenses/SOUFFLE-UPL.txt / /*********************************************************************** * * @file RecordTable.h * * Data container implementing a map between records and their references. * Records are separated by arity, i.e., stored in different RecordMaps. * *********************************************************************/ #pragma once #include "CompiledTuple.h" #include "RamTypes.h" #include <cassert> #include <cstddef> #include <limits> #include <memory> #include <unordered_map> #include <utility> #include <vector> namespace souffle { / @brief Bidirectional mappping between records and record references / class RecordMap { /* arity of record / const size_t arity; /* hash function for unordered record map / struct RecordHash { std::size_t operator()(std::vector<RamDomain> record) const { std::size_t seed = 0; std::hash<RamDomain> domainHash; for (RamDomain value : record) { seed ^= domainHash(value) + 0x9e3779b9 + (seed << 6) + (seed >> 2); } return seed; } }; /* map from records to references / // TODO (b-scholz): replace vector<RamDomain> with something more memory-frugal std::unordered_map<std::vector<RamDomain>, RamDomain, RecordHash> recordToIndex; /* array of records; index represents record reference / // TODO (b-scholz): replace vector<RamDomain> with something more memory-frugal std::vector<std::vector<RamDomain>> indexToRecord; public: explicit RecordMap(size_t arity) : arity(arity), indexToRecord(1) {} // note: index 0 element left free /* @brief converts record to a record reference / // TODO (b-scholz): replace vector<RamDomain> with something more memory-frugal RamDomain pack(const std::vector<RamDomain>& vector) { RamDomain index; #pragma omp critical(record_pack) { auto pos = recordToIndex.find(vector); if (pos != recordToIndex.end()) { index = pos->second; } else { #pragma omp critical(record_unpack) { indexToRecord.push_back(vector); index = indexToRecord.size() - 1; recordToIndex[vector] = index; // assert that new index is smaller than the range assert(index != std::numeric_limits<RamDomain>::max()); } } } return index; } /* @brief convert record pointer to a record reference / RamDomain pack(const RamDomain tuple) { // TODO (b-scholz): data is unnecessarily copied // for a successful lookup. To avoid this, we should // compute a hash of the pointer-array and traverse through // the bucket list of the unordered map finding the record. // Note that in case of non-existence, the record still needs to be // copied for the newly created entry but this will be the less // frequent case. std::vector<RamDomain> tmp(arity); for (size_t i = 0; i < arity; i++) { tmp[i] = tuple[i]; } return pack(tmp); } /** @brief convert record reference to a record pointer / const RamDomain unpack(RamDomain index) const { const RamDomain* res; #pragma omp critical(record_unpack) res = indexToRecord[index].data(); return res; } }; class RecordTable { public: RecordTable() = default; virtual ~RecordTable() = default; /** @brief convert record to record reference / RamDomain pack(RamDomain tuple, size_t arity) { return lookupArity(arity).pack(tuple); } /** @brief convert record reference to a record / const RamDomain unpack(RamDomain ref, size_t arity) const { std::unordered_map<size_t, RecordMap>::const_iterator iter; #pragma omp critical(RecordTableGetForArity) { // Find a previously emplaced map iter = maps.find(arity); } assert(iter != maps.end() && "Attempting to unpack record for non-existing arity"); return (iter->second).unpack(ref); } private: /** @brief lookup RecordMap for a given arity; if it does not exist, create new RecordMap / RecordMap& lookupArity(size_t arity) { std::unordered_map<size_t, RecordMap>::iterator mapsIterator; #pragma omp critical(RecordTableGetForArity) { // This will create a new map if it doesn't exist yet. mapsIterator = maps.emplace(arity, arity).first; } return mapsIterator->second; } /* Arity/RecordMap association / std::unordered_map<size_t, RecordMap> maps; }; /* @brief helper to convert tuple to record reference for the synthesiser / template <std::size_t Arity> inline RamDomain pack(RecordTable& recordTab, Tuple<RamDomain, Arity> tuple) { return recordTab.pack(static_cast<RamDomain>(tuple.data), Arity); } } // namespace souffle
data.c	#include "../mesh.h" #include "../params.h" #include "../shared.h" #include "../umesh.h" #include <math.h> #include <stdlib.h> // Checks if two strings match #pragma omp declare target int device_strmatch(const char* str1, const char* str2) { int ii = 0; for (ii = 0; str1[ii] != '\0'; ++ii) { if (str1[ii] != str2[ii]) { return 0; } } return str1[ii] == str2[ii]; } #pragma omp end declare target // Allocates some double precision data size_t allocate_data(double** buf, size_t len) { if(!len) { return 0; } allocate_host_data(buf, len); double* local_buf = buf; #pragma omp target enter data map(to : local_buf[ : len]) #pragma omp target teams distribute parallel for for (size_t ii = 0; ii < len; ++ii) { local_buf[ii] = 0.0; } return sizeof(double) len; } // Allocates some int precision data size_t allocate_int_data(int** buf, size_t len) { if(!len) { return 0; } allocate_host_int_data(buf, len); int* local_buf = buf; #pragma omp target enter data map(to : local_buf[ : len]) #pragma omp target teams distribute parallel for for (size_t ii = 0; ii < len; ++ii) { local_buf[ii] = 0; } return sizeof(int) len; } // Allocates some int precision data size_t allocate_uint64_data(uint64_t** buf, size_t len) { if(!len) { return 0; } allocate_host_uint64_data(buf, len); uint64_t* local_buf = buf; #pragma omp target enter data map(to : local_buf[ : len]) #pragma omp target teams distribute parallel for for (size_t ii = 0; ii < len; ++ii) { local_buf[ii] = 0; } return sizeof(uint64_t) len; } // Allocates a host copy of some buffer void allocate_host_data(double** buf, size_t len) { #ifdef INTEL buf = (double)_mm_malloc(sizeof(double) * len, VEC_ALIGN); #else buf = (double)malloc(sizeof(double) * len); #endif if (buf == NULL) { TERMINATE("Failed to allocate a data array.\n"); } } // Allocates a host copy of some integer buffer void allocate_host_int_data(int* buf, size_t len) { #ifdef INTEL buf = (int)_mm_malloc(sizeof(int) * len, VEC_ALIGN); #else buf = (int)malloc(sizeof(int) * len); #endif if (buf == NULL) { TERMINATE("Failed to allocate a data array.\n"); } } void allocate_host_uint64_data(uint64_t* buf, const size_t len) { #ifdef INTEL buf = (uint64_t)_mm_malloc(sizeof(uint64_t) * len, VEC_ALIGN); #else buf = (uint64_t)malloc(sizeof(uint64_t) * len); #endif if (buf == NULL) { TERMINATE("Failed to allocate a data array.\n"); } } // Allocates a data array void deallocate_data(double buf) { #pragma omp target exit data map(delete : buf) } // Allocates a data array void deallocate_int_data(int* buf) { #pragma omp target exit data map(delete : buf) } // Allocates a data array void deallocate_host_data(double* buf) { #ifdef INTEL _mm_free(buf); #else free(buf); #endif } // Synchronise data void copy_buffer(const size_t len, double src, double dst, int send) { double* local_src = src; if (send == SEND) { #pragma omp target update to(local_src[ : len]) } else { #pragma omp target update from(local_src[ : len]) } dst = src; } // Move a host buffer onto the device void move_host_buffer_to_device(const size_t len, double* src, double** dst) { double* local_src = src; #pragma omp target enter data map(to : local_src[ : len]) dst = src; } // Initialises mesh data in device specific manner void mesh_data_init_2d(const int local_nx, const int local_ny, const int global_nx, const int global_ny, const int pad, const int x_off, const int y_off, const double width, const double height, double edgex, double* edgey, double* edgedx, double* edgedy, double* celldx, double* celldy) { // Simple uniform rectilinear initialisation #pragma omp target teams distribute parallel for for (int ii = 0; ii < local_nx + 1; ++ii) { edgedx[ii] = width / (global_nx); // Note: correcting for padding edgex[ii] = edgedx[ii] * (x_off + ii - pad); } #pragma omp target teams distribute parallel for for (int ii = 0; ii < local_nx; ++ii) { celldx[ii] = width / (global_nx); } #pragma omp target teams distribute parallel for for (int ii = 0; ii < local_ny + 1; ++ii) { edgedy[ii] = height / (global_ny); // Note: correcting for padding edgey[ii] = edgedy[ii] * (y_off + ii - pad); } #pragma omp target teams distribute parallel for for (int ii = 0; ii < local_ny; ++ii) { celldy[ii] = height / (global_ny); } } // Initialises mesh data in device specific manner void mesh_data_init_3d(const int local_nx, const int local_ny, const int local_nz, const int global_nx, const int global_ny, const int global_nz, const int pad, const int x_off, const int y_off, const int z_off, const double width, const double height, const double depth, double* edgex, double* edgey, double* edgez, double* edgedx, double* edgedy, double* edgedz, double* celldx, double* celldy, double* celldz) { // Initialise as in the 2d case mesh_data_init_2d(local_nx, local_ny, global_nx, global_ny, pad, x_off, y_off, width, height, edgex, edgey, edgedx, edgedy, celldx, celldy); // Simple uniform rectilinear initialisation #pragma omp target teams distribute parallel for for (int ii = 0; ii < local_nz + 1; ++ii) { edgedz[ii] = depth / (global_nz); edgez[ii] = edgedz[ii] * (z_off + ii - pad); } #pragma omp target teams distribute parallel for for (int ii = 0; ii < local_nz; ++ii) { celldz[ii] = depth / (global_nz); } } // Initialise state data in device specific manner void set_problem_2d(const int local_nx, const int local_ny, const int pad, const double mesh_width, const double mesh_height, const double* edgex, const double* edgey, const int ndims, const char* problem_def_filename, double* rho, double* e, double* x) { char* keys = (char)malloc(sizeof(char) MAX_KEYS * MAX_STR_LEN); #pragma omp target enter data map(to : keys[ : MAX_KEYS* MAX_STR_LEN]) double* values; allocate_data(&values, MAX_KEYS); int nentries = 0; while (1) { char specifier[MAX_STR_LEN]; sprintf(specifier, "problem_%d", nentries++); int nkeys = 0; if (!get_key_value_parameter(specifier, problem_def_filename, keys, values, &nkeys)) { break; } copy_buffer(MAX_KEYS, &values, &values, SEND); #pragma omp target update to(keys[ : MAX_KEYS* MAX_STR_LEN]) // The last four keys are the bound specification double xpos = values[nkeys - 4] * mesh_width; double ypos = values[nkeys - 3] * mesh_height; double width = values[nkeys - 2] * mesh_width; double height = values[nkeys - 1] * mesh_height; int failed = 0; // Loop through the mesh and set the problem #pragma omp target teams distribute parallel for \ map(tofrom : failed) reduction(+ : failed) for (int ii = pad; ii < local_ny - pad; ++ii) { for (int jj = pad; jj < local_nx - pad; ++jj) { double global_xpos = edgex[jj]; double global_ypos = edgey[ii]; // Check we are in bounds of the problem entry if (global_xpos >= xpos && global_ypos >= ypos && global_xpos < xpos + width && global_ypos < ypos + height) { // The upper bound excludes the bounding box for the entry for (int kk = 0; kk < nkeys - (2 * ndims); ++kk) { const char* key = &keys[kk * MAX_STR_LEN]; if (device_strmatch(key, "density")) { rho[ii * local_nx + jj] = values[kk]; } else if (device_strmatch(key, "energy")) { e[ii * local_nx + jj] = values[kk]; } else if (device_strmatch(key, "temperature")) { x[ii * local_nx + jj] = values[kk]; } else { failed++; } } } } } if (failed) { TERMINATE("Found unrecognised key in %s.\n", problem_def_filename); } } free(keys); deallocate_data(values); } // Initialise state data in device specific manner void set_problem_3d(const int local_nx, const int local_ny, const int local_nz, const int pad, const double mesh_width, const double mesh_height, const double mesh_depth, const double* edgex, const double* edgey, const double* edgez, const int ndims, const char* problem_def_filename, double* rho, double* e, double* x) { char* keys = (char)malloc(sizeof(char) MAX_KEYS * MAX_STR_LEN); #pragma omp target enter data map(to : keys[ : MAX_KEYS* MAX_STR_LEN]) double* values; allocate_data(&values, MAX_KEYS); int nentries = 0; while (1) { char specifier[MAX_STR_LEN]; sprintf(specifier, "problem_%d", nentries++); int nkeys = 0; if (!get_key_value_parameter(specifier, problem_def_filename, keys, values, &nkeys)) { break; } copy_buffer(MAX_KEYS, &values, &values, SEND); #pragma omp target update to(keys[ : MAX_KEYS* MAX_STR_LEN]) // The last four keys are the bound specification double xpos = values[nkeys - 6] * mesh_width; double ypos = values[nkeys - 5] * mesh_height; double zpos = values[nkeys - 4] * mesh_depth; double width = values[nkeys - 3] * mesh_width; double height = values[nkeys - 2] * mesh_height; double depth = values[nkeys - 1] * mesh_depth; int failed = 0; // Loop through the mesh and set the problem #pragma omp target teams distribute parallel for \ map(tofrom: failed) reduction(+: failed) for (int ii = pad; ii < local_nz - pad; ++ii) { for (int jj = pad; jj < local_ny - pad; ++jj) { for (int kk = pad; kk < local_nx - pad; ++kk) { double global_xpos = edgex[kk]; double global_ypos = edgey[jj]; double global_zpos = edgez[ii]; // Check we are in bounds of the problem entry if (global_xpos >= xpos && global_ypos >= ypos && global_zpos >= zpos && global_xpos < xpos + width && global_ypos < ypos + height && global_zpos < zpos + depth) { // The upper bound excludes the bounding box for the entry for (int ee = 0; ee < nkeys - (2 * ndims); ++ee) { const int index = (ii * local_nx * local_ny) + (jj * local_nx) + (kk); const char* key = &keys[ee * MAX_STR_LEN]; if (device_strmatch(key, "density")) { rho[(index)] = values[ee]; } else if (device_strmatch(key, "energy")) { e[(index)] = values[ee]; } else if (device_strmatch(key, "temperature")) { x[(index)] = values[ee]; } else { failed++; } } } } } } if(failed) { TERMINATE("Found unrecognised key in %s.\n", problem_def_filename); } } free(keys); deallocate_data(values); } // Finds the normals for all boundary cells void find_boundary_normals(UnstructuredMesh* umesh, int* boundary_edge_list) { const int nnodes = umesh->nnodes; const int nboundary_nodes = umesh->nboundary_nodes; const int* boundary_index = umesh->boundary_index; const double* nodes_x0 = umesh->nodes_x0; const double* nodes_y0 = umesh->nodes_y0; int* boundary_type = umesh->boundary_type; double* boundary_normal_x = umesh->boundary_normal_x; double* boundary_normal_y = umesh->boundary_normal_y; // Loop through all of the boundary cells and find their normals #pragma omp target teams distribute parallel for for (int nn = 0; nn < nnodes; ++nn) { const int bi = boundary_index[(nn)]; if (bi == IS_INTERIOR) { continue; } double normal_x = 0.0; double normal_y = 0.0; for (int bb1 = 0; bb1 < nboundary_nodes; ++bb1) { const int node0 = boundary_edge_list[bb1 * 2]; const int node1 = boundary_edge_list[bb1 * 2 + 1]; if (node0 == nn \|\| node1 == nn) { const double node0_x = nodes_x0[(node0)]; const double node0_y = nodes_y0[(node0)]; const double node1_x = nodes_x0[(node1)]; const double node1_y = nodes_y0[(node1)]; normal_x += node0_y - node1_y; normal_y += -(node0_x - node1_x); } } // We are fixed if we are one of the four corners if ((nodes_x0[(nn)] == 0.0 \|\| nodes_x0[(nn)] == 1.0) && (nodes_y0[(nn)] == 0.0 \|\| nodes_y0[(nn)] == 1.0)) { boundary_type[(bi)] = IS_CORNER; } else { boundary_type[(bi)] = IS_BOUNDARY; } const double normal_mag = sqrt(normal_x * normal_x + normal_y * normal_y); boundary_normal_x[(bi)] = normal_x / normal_mag; boundary_normal_y[(bi)] = normal_y / normal_mag; } }
GB_binop__min_uint8.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 Generated/ folder, do not edit it (auto-generated). #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__min_uint8) // A.B function (eWiseMult): GB (_AemultB) // A.B function (eWiseMult): GB (_AemultB_02__min_uint8) // A.B function (eWiseMult): GB (_AemultB_03__min_uint8) // A.B function (eWiseMult): GB (_AemultB_bitmap__min_uint8) // AD function (colscale): GB (_AxD__min_uint8) // DA function (rowscale): GB (_DxB__min_uint8) // C+=B function (dense accum): GB (_Cdense_accumB__min_uint8) // C+=b function (dense accum): GB (_Cdense_accumb__min_uint8) // C+=A+B function (dense ewise3): GB (_Cdense_ewise3_accum__min_uint8) // C=A+B function (dense ewise3): GB (_Cdense_ewise3_noaccum__min_uint8) // C=scalar+B GB (_bind1st__min_uint8) // C=scalar+B' GB (_bind1st_tran__min_uint8) // C=A+scalar GB (_bind2nd__min_uint8) // C=A'+scalar GB (_bind2nd_tran__min_uint8) // C type: uint8_t // A type: uint8_t // B,b type: uint8_t // BinaryOp: cij = GB_IMIN (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, i, j) \ z = GB_IMIN (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_MIN \|\| GxB_NO_UINT8 \|\| GxB_NO_MIN_UINT8) //------------------------------------------------------------------------------ // 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__min_uint8) ( 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__min_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__min_uint8) ( 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__min_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__min_uint8) ( 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 uint8_t 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__min_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 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__min_uint8) ( 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__min_uint8) ( 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__min_uint8) ( 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__min_uint8) ( 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__min_uint8) ( 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__min_uint8) ( 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 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++) { if (!GBB (Bb, p)) continue ; uint8_t bij = Bx [p] ; Cx [p] = GB_IMIN (x, bij) ; } return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // Cx = op (Ax,y): apply a binary operator to a matrix with scalar bind2nd //------------------------------------------------------------------------------ GrB_Info GB (_bind2nd__min_uint8) ( 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 ; 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++) { if (!GBB (Ab, p)) continue ; uint8_t aij = Ax [p] ; Cx [p] = GB_IMIN (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) \ { \ uint8_t aij = Ax [pA] ; \ Cx [pC] = GB_IMIN (x, aij) ; \ } GrB_Info GB (_bind1st_tran__min_uint8) ( 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 \ uint8_t #if GB_DISABLE return (GrB_NO_VALUE) ; #else uint8_t x = (((const uint8_t ) x_input)) ; #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 typecasting (in spite of the macro name) #undef GB_CAST_OP #define GB_CAST_OP(pC,pA) \ { \ uint8_t aij = Ax [pA] ; \ Cx [pC] = GB_IMIN (aij, y) ; \ } GrB_Info GB (_bind2nd_tran__min_uint8) ( 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 uint8_t y = (((const uint8_t *) y_input)) ; #include "GB_unop_transpose.c" return (GrB_SUCCESS) ; #endif } #endif
3d7pt.c	/* * 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] = 4; tile_size[1] = 4; tile_size[2] = 24; tile_size[3] = 2048; 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 #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] = alpha * (A[t%2][i][j][k]) + beta * (A[t%2][i - 1][j][k] + A[t%2][i][j - 1][k] + A[t%2][i][j][k - 1] + A[t%2][i + 1][j][k] + A[t%2][i][j + 1][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, "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; }
requires-4.c	#pragma omp requires unified_shared_memory,unified_address,reverse_offload void foo (void) { #pragma omp target ; } #pragma omp requires unified_shared_memory /* { dg-error "'unified_shared_memory' clause used lexically after first target construct or offloading API" } / #pragma omp requires unified_address / { dg-error "'unified_address' clause used lexically after first target construct or offloading API" } / #pragma omp requires reverse_offload / { dg-error "'reverse_offload' clause used lexically after first target construct or offloading API" } / / { dg-prune-output "not supported yet" } */
core_zher2k.c	/** * * @file * * PLASMA is a software package provided by: * University of Tennessee, US, * University of Manchester, UK. * * @precisions normal z -> c * / #include <plasma_core_blas.h> #include "plasma_types.h" #include "core_lapack.h" #undef REAL #define COMPLEX /***********************************************************************// * * @ingroup core_her2k * * Performs one of the Hermitian rank 2k operations * * \f[ C = \alpha A \times B^H + conjg( \alpha ) B \times A^H + \beta C, \f] * or * \f[ C = \alpha A^H \times B + conjg( \alpha ) B^H \times A + \beta C, \f] * * where alpha is a complex scalar, beta is a real scalar, * C is an n-by-n Hermitian matrix, and A and B are n-by-k matrices * in the first case and k-by-n matrices in the second case. * ******************************************************************************* * * @param[in] uplo * - PlasmaUpper: Upper triangle of C is stored; * - PlasmaLower: Lower triangle of C is stored. * * @param[in] trans * - PlasmaNoTrans: * \f[ C = \alpha A \times B^H * + conjg( \alpha ) B \times A^H + \beta C; \f] * - PlasmaConjTrans: * \f[ C = \alpha A^H \times B * + conjg( \alpha ) B^H \times A + \beta C. \f] * * @param[in] n * The order of the matrix C. n >= zero. * * @param[in] k * If trans = PlasmaNoTrans, number of columns of the A and B matrices; * if trans = PlasmaConjTrans, number of rows of the A and B matrices. * * @param[in] alpha * The scalar alpha. * * @param[in] A * An lda-by-ka matrix. * If trans = PlasmaNoTrans, ka = k; * if trans = PlasmaConjTrans, ka = n. * * @param[in] lda * The leading dimension of the array A. * If trans = PlasmaNoTrans, lda >= max(1, n); * if trans = PlasmaConjTrans, lda >= max(1, k). * * @param[in] B * An ldb-by-kb matrix. * If trans = PlasmaNoTrans, kb = k; * if trans = PlasmaConjTrans, kb = n. * * @param[in] ldb * The leading dimension of the array B. * If trans = PlasmaNoTrans, ldb >= max(1, n); * if trans = PlasmaConjTrans, ldb >= max(1, k). * * @param[in] beta * The scalar beta. * * @param[in,out] C * An ldc-by-n matrix. * On exit, the uplo part of the matrix is overwritten * by the uplo part of the updated matrix. * * @param[in] ldc * The leading dimension of the array C. ldc >= max(1, n). * *****************************************************************************/ __attribute__((weak)) void plasma_core_zher2k(plasma_enum_t uplo, plasma_enum_t trans, int n, int k, plasma_complex64_t alpha, const plasma_complex64_t A, int lda, const plasma_complex64_t B, int ldb, double beta, plasma_complex64_t C, int ldc) { cblas_zher2k(CblasColMajor, (CBLAS_UPLO)uplo, (CBLAS_TRANSPOSE)trans, n, k, CBLAS_SADDR(alpha), A, lda, B, ldb, beta, C, ldc); } /*****************************************************************************/ void plasma_core_omp_zher2k( plasma_enum_t uplo, plasma_enum_t trans, int n, int k, plasma_complex64_t alpha, const plasma_complex64_t A, int lda, const plasma_complex64_t B, int ldb, double beta, plasma_complex64_t C, int ldc, plasma_sequence_t sequence, plasma_request_t request) { int ak; int bk; if (trans == PlasmaNoTrans) { ak = k; bk = k; } else { ak = n; bk = n; } #pragma omp task depend(in:A[0:ldaak]) \ depend(in:B[0:ldbbk]) \ depend(inout:C[0:ldc*n]) { if (sequence->status == PlasmaSuccess) plasma_core_zher2k(uplo, trans, n, k, alpha, A, lda, B, ldb, beta, C, ldc); } }
suma2.c	#include <omp.h> #include <stdlib.h> // biblioteca con funciones atoi(), malloc() y free() #include <stdio.h> // biblioteca donde se encuentra la función printf() #include <time.h>// biblioteca donde se encuentra la función clock_gettime() #define VECTOR_GLOBAL// descomentar para que los vectores sean variables ... // globales (su longitud no estará limitada por el ... // tamaño de la pila del programa) //#define PRINTF_ALL// comentar para quitar el printf ... // que imprime todos los componentes #ifdef VECTOR_GLOBAL #define MAX 33554432 //=2^25 double v1[MAX], v2[MAX], v3[MAX]; #endif int main(int argc, char** argv){ int i; //Leer argumento de entrada (nº de componentes del vector) if (argc<2){ printf("Faltan nº componentes del vector\n"); exit(-1); } unsigned int N = atoi(argv[1]); // Máximo N =2^32-1=4294967295 (sizeof(unsigned int) = 4 B) #pragma omp sections { #pragma omp section for(i=0; i<N/4; i++){ v3[i] = v1[i] + v2[i]; printf("/ Tamaño Vectores:%u / V1[%d]+V2[%d]=V3[%d](%8.6f+%8.6f=%8.6f) /\n",N,i,i,i,v1[i],v2[i],v3[i]); } #pragma omp section for(i=N/4; i<N/3; i++){ v3[i] = v1[i] + v2[i]; printf("/ Tamaño Vectores:%u / V1[%d]+V2[%d]=V3[%d](%8.6f+%8.6f=%8.6f) /\n",N,i,i,i,v1[i],v2[i],v3[i]); } #pragma omp section for(i=N/3; i<N/2; i++){ v3[i] = v1[i] + v2[i]; printf("/ Tamaño Vectores:%u / V1[%d]+V2[%d]=V3[%d](%8.6f+%8.6f=%8.6f) /\n",N,i,i,i,v1[i],v2[i],v3[i]); } #pragma omp section for(i=N/2; i<N; i++){ v3[i] = v1[i] + v2[i]; printf("/ Tamaño Vectores:%u / V1[%d]+V2[%d]=V3[%d](%8.6f+%8.6f=%8.6f) /\n",N,i,i,i,v1[i],v2[i],v3[i]); } } double start, end; start= omp_get_wtime(); //Calcular suma de vectores #pragma omp parallel for for(i=0; i<N; i++){ v3[i] = v1[i] + v2[i]; printf("/ Tamaño Vectores:%u / V1[%d]+V2[%d]=V3[%d](%8.6f+%8.6f=%8.6f) /\n",N,i,i,i,v1[i],v2[i],v3[i]); } end= omp_get_wtime(); double tiempo= 0; tiempo = end - start; printf("Tiempo(seg.):%11.9f\t / Tamaño Vectores:%u\n",tiempo,N); //printf("/ V1[8]+V2[8]=V3[8](%8.6f+%8.6f=%8.6f) /\n",v1[7],v2[7],v3[7]); printf("/ V1[11]+V2[11]=V3[11](%8.6f+%8.6f=%8.6f) /\n",v1[10],v2[10],v3[10]); return 0; }
dropout-inl.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. / /! * \file dropout-inl.h * \brief * \author Bing Xu / #ifndef MXNET_OPERATOR_DROPOUT_INL_H_ #define MXNET_OPERATOR_DROPOUT_INL_H_ #include <dmlc/logging.h> #include <dmlc/parameter.h> #include <mxnet/operator.h> #include <map> #include <vector> #include <string> #include <utility> #include <algorithm> #include "./operator_common.h" #include "./mshadow_op.h" #include "../engine/openmp.h" #if defined(USE_MKL) && defined(_OPENMP) #include <omp.h> #include <mkl_vml_functions.h> #include <mkl_vsl.h> #endif // USE_MKL && _OPENMP namespace dropout { enum DropoutOpInputs {kData}; enum DropoutOpOutputs {kOut, kMask}; enum DropoutOpForwardResource {kRandom}; enum DropoutOpMode {kTraining, kAlways}; } // namespace dropout namespace mxnet { namespace op { #if defined(USE_MKL) && defined(_OPENMP) static void bernoulli_generate(int n, double p, int r) { const int seed = 17 + rand() % 4096; // NOLINT(runtime/threadsafe_fn) const int nthr = engine::OpenMP::Get()->GetRecommendedOMPThreadCount(); # pragma omp parallel num_threads(nthr) { const int ithr = omp_get_thread_num(); const int avg_amount = (n + nthr - 1) / nthr; const int my_offset = ithr * avg_amount; const int my_amount = std::min(my_offset + avg_amount, n) - my_offset; if (my_amount > 0) { VSLStreamStatePtr stream; vslNewStream(&stream, VSL_BRNG_MCG31, seed); vslSkipAheadStream(stream, my_offset); viRngBernoulli(VSL_RNG_METHOD_BERNOULLI_ICDF, stream, my_amount, r + my_offset, p); vslDeleteStream(&stream); } } } #endif // USE_MKL && _OPENMP struct DropoutParam : public dmlc::Parameter<DropoutParam> { float p; int mode; DMLC_DECLARE_PARAMETER(DropoutParam) { DMLC_DECLARE_FIELD(p).set_default(0.5) .set_range(0, 1) .describe("Fraction of the input that gets dropped out during training time."); DMLC_DECLARE_FIELD(mode) .add_enum("training", dropout::kTraining) .add_enum("always", dropout::kAlways) .set_default(dropout::kTraining) .describe("Whether to only turn on dropout during training or to also turn on for inference."); } }; // struct DropoutParam template<typename xpu, typename DType> class DropoutOp : public Operator { public: explicit DropoutOp(DropoutParam param) { this->pkeep_ = 1.0f - param.p; this->mode_ = param.mode; } virtual void Forward(const OpContext &ctx, const std::vector<TBlob> &in_data, const std::vector<OpReqType> &req, const std::vector<TBlob> &out_data, const std::vector<TBlob> &aux_states) { using namespace mshadow; using namespace mshadow::expr; CHECK_EQ(in_data.size(), 1U); if (ctx.is_train) { CHECK_EQ(out_data.size(), 2U); } Stream<xpu> s = ctx.get_stream<xpu>(); Tensor<xpu, 2, DType> data = in_data[dropout::kData].FlatTo2D<xpu, DType>(s); Tensor<xpu, 2, DType> out = out_data[dropout::kOut].FlatTo2D<xpu, DType>(s); if (ctx.is_train \|\| mode_ == dropout::kAlways) { Tensor<xpu, 2, DType> mask = out_data[dropout::kMask].FlatTo2D<xpu, DType>(s); #if !defined(__CUDACC__) && defined(USE_MKL) && defined(_OPENMP) DType outptr = out.dptr_; DType* dataptr = data.dptr_; auto maskptr = reinterpret_cast<int>(mask.dptr_); int count = mask.shape_[0]mask.shape_[1]; bernoulli_generate(count, this->pkeep_, maskptr); const float pk_1 = 1.0f / pkeep_; #pragma omp parallel for num_threads(engine::OpenMP::Get()->GetRecommendedOMPThreadCount()) for (int i = 0; i < count; ++i) { outptr[i] = dataptr[i] * maskptr[i] * pk_1; } #else Random<xpu> prnd = ctx.requested[dropout::kRandom].get_random<xpu, real_t>(s); mask = tcast<DType>(F<mshadow_op::threshold>( prnd->uniform(mask.shape_), pkeep_) (1.0f / pkeep_)); Assign(out, req[dropout::kOut], data * mask); #endif // USE_MKL && _OPENMP } else { Assign(out, req[dropout::kOut], F<mshadow_op::identity>(data)); } } virtual void Backward(const OpContext &ctx, const std::vector<TBlob> &out_grad, const std::vector<TBlob> &in_data, const std::vector<TBlob> &out_data, const std::vector<OpReqType> &req, const std::vector<TBlob> &in_grad, const std::vector<TBlob> &aux_states) { using namespace mshadow; using namespace mshadow::expr; CHECK_EQ(out_grad.size(), 1U); CHECK_EQ(in_grad.size(), 1U); Stream<xpu> s = ctx.get_stream<xpu>(); Tensor<xpu, 2, DType> grad = out_grad[dropout::kOut].FlatTo2D<xpu, DType>(s); Tensor<xpu, 2, DType> mask = out_data[dropout::kMask].FlatTo2D<xpu, DType>(s); Tensor<xpu, 2, DType> gdata = in_grad[dropout::kData].FlatTo2D<xpu, DType>(s); if (ctx.is_train \|\| mode_ == dropout::kAlways) { #if !defined(__CUDACC__) && defined(USE_MKL) && defined(_OPENMP) DType ingradptr = gdata.dptr_; DType* outgradptr = grad.dptr_; auto maskptr = reinterpret_cast<int>(mask.dptr_); int count = mask.shape_[0]mask.shape_[1]; const float pk_1 = 1.0f / pkeep_; #pragma omp parallel for num_threads(engine::OpenMP::Get()->GetRecommendedOMPThreadCount()) for (int i = 0; i < count; ++i) { ingradptr[i] = outgradptr[i] * maskptr[i] * pk_1; } #else // USE_MKL && _OPENMP CHECK_EQ(grad.shape_.Size(), mask.shape_.Size()); Assign(gdata, req[dropout::kData], grad * mask); #endif // USE_MKL && _OPENMP } else { Assign(gdata, req[dropout::kData], F<mshadow_op::identity>(grad)); } } private: real_t pkeep_; int mode_; }; // class DropoutOp template<typename xpu> Operator CreateOp(DropoutParam param, int dtype); #if DMLC_USE_CXX11 class DropoutProp : public OperatorProperty { public: void Init(const std::vector<std::pair<std::string, std::string> >& kwargs) override { param_.Init(kwargs); } std::map<std::string, std::string> GetParams() const override { return param_.__DICT__(); } bool InferShape(std::vector<TShape> in_shape, std::vector<TShape> out_shape, std::vector<TShape> aux_shape) const override { using namespace mshadow; CHECK_EQ(in_shape->size(), 1U); const TShape &dshape = in_shape->at(0); if (dshape.ndim() == 0) return false; out_shape->clear(); out_shape->push_back(dshape); out_shape->push_back(dshape); return true; } bool InferType(std::vector<int> in_type, std::vector<int> out_type, std::vector<int> aux_type) const override { CHECK_EQ(in_type->size(), 1U); int dtype = in_type->at(0); if (dtype == -1) { LOG(FATAL) << "input type to dropout is not specified."; return false; } size_t nout = this->ListOutputs().size(); out_type->clear(); for (size_t i = 0; i < nout; ++i) out_type->push_back(dtype); return true; } OperatorProperty Copy() const override { auto ptr = new DropoutProp(); ptr->param_ = param_; return ptr; } std::string TypeString() const override { return "Dropout"; } std::vector<int> DeclareBackwardDependency( const std::vector<int> &out_grad, const std::vector<int> &in_data, const std::vector<int> &out_data) const override { return {out_grad[dropout::kOut], out_data[dropout::kMask]}; } std::vector<std::pair<int, void> > BackwardInplaceOption( const std::vector<int> &out_grad, const std::vector<int> &in_data, const std::vector<int> &out_data, const std::vector<void> &in_grad) const override { return {{out_grad[dropout::kOut], in_grad[dropout::kData]}}; } std::vector<std::pair<int, void> > ForwardInplaceOption( const std::vector<int> &in_data, const std::vector<void> &out_data) const override { return {{in_data[dropout::kData], out_data[dropout::kOut]}}; } std::vector<ResourceRequest> ForwardResource( const std::vector<TShape> &in_shape) const override { return {ResourceRequest::kRandom}; } int NumVisibleOutputs() const override { return 1; } int NumOutputs() const override { return 2; } std::vector<std::string> ListOutputs() const override { return {"output", "mask"}; } Operator* CreateOperator(Context ctx) const override { LOG(FATAL) << "Not Implemented"; return NULL; } Operator* CreateOperatorEx(Context ctx, std::vector<TShape> in_shape, std::vector<int> in_type) const override; private: DropoutParam param_; }; // class DropoutProp #endif // DMLC_USE_CXX11 } // namespace op } // namespace mxnet #endif // MXNET_OPERATOR_DROPOUT_INL_H_
blake2sp-ref.c	/* BLAKE2 reference source code package - reference C implementations Written in 2012 by Samuel Neves <sneves@dei.uc.pt> To the extent possible under law, the author(s) have dedicated all copyright and related and neighboring rights to this software to the public domain worldwide. This software is distributed without any warranty. You should have received a copy of the CC0 Public Domain Dedication along with this software. If not, see <http://creativecommons.org/publicdomain/zero/1.0/>. / #include <stdlib.h> #include <string.h> #include <stdio.h> #if defined(_OPENMP) #include <omp.h> #endif #include "blake2.h" #include "blake2-impl.h" #define PARALLELISM_DEGREE 8 static inline int blake2sp_init_leaf( blake2s_state S, uint8_t outlen, uint8_t keylen, uint64_t offset ) { blake2s_param P[1]; P->digest_length = outlen; P->key_length = keylen; P->fanout = PARALLELISM_DEGREE; P->depth = 2; store32( &P->leaf_length, 0 ); store48( P->node_offset, offset ); P->node_depth = 0; P->inner_length = outlen; memset( P->salt, 0, sizeof( P->salt ) ); memset( P->personal, 0, sizeof( P->personal ) ); return blake2s_init_param( S, P ); } static inline int blake2sp_init_root( blake2s_state S, uint8_t outlen, uint8_t keylen ) { blake2s_param P[1]; P->digest_length = outlen; P->key_length = keylen; P->fanout = PARALLELISM_DEGREE; P->depth = 2; store32( &P->leaf_length, 0 ); store48( P->node_offset, 0ULL ); P->node_depth = 1; P->inner_length = outlen; memset( P->salt, 0, sizeof( P->salt ) ); memset( P->personal, 0, sizeof( P->personal ) ); return blake2s_init_param( S, P ); } int blake2sp_init( blake2sp_state S, const uint8_t outlen ) { if( !outlen \|\| outlen > BLAKE2S_OUTBYTES ) return -1; memset( S->buf, 0, sizeof( S->buf ) ); S->buflen = 0; if( blake2sp_init_root( S->R, outlen, 0 ) < 0 ) return -1; for( size_t i = 0; i < PARALLELISM_DEGREE; ++i ) if( blake2sp_init_leaf( S->S[i], outlen, 0, i ) < 0 ) return -1; S->R->last_node = 1; S->S[PARALLELISM_DEGREE - 1]->last_node = 1; return 0; } int blake2sp_init_key( blake2sp_state S, const uint8_t outlen, const void key, const uint8_t keylen ) { if( !outlen \|\| outlen > BLAKE2S_OUTBYTES ) return -1; if( !key \|\| !keylen \|\| keylen > BLAKE2S_KEYBYTES ) return -1; memset( S->buf, 0, sizeof( S->buf ) ); S->buflen = 0; if( blake2sp_init_root( S->R, outlen, keylen ) < 0 ) return -1; for( size_t i = 0; i < PARALLELISM_DEGREE; ++i ) if( blake2sp_init_leaf( S->S[i], outlen, keylen, i ) < 0 ) return -1; S->R->last_node = 1; S->S[PARALLELISM_DEGREE - 1]->last_node = 1; { uint8_t block[BLAKE2S_BLOCKBYTES]; memset( block, 0, BLAKE2S_BLOCKBYTES ); memcpy( block, key, keylen ); for( size_t i = 0; i < PARALLELISM_DEGREE; ++i ) blake2s_update( S->S[i], block, BLAKE2S_BLOCKBYTES ); secure_zero_memory( block, BLAKE2S_BLOCKBYTES ); /* Burn the key from stack / } return 0; } int blake2sp_update( blake2sp_state S, const uint8_t in, uint64_t inlen ) { size_t left = S->buflen; size_t fill = sizeof( S->buf ) - left; if( left && inlen >= fill ) { memcpy( S->buf + left, in, fill ); for( size_t i = 0; i < PARALLELISM_DEGREE; ++i ) blake2s_update( S->S[i], S->buf + i BLAKE2S_BLOCKBYTES, BLAKE2S_BLOCKBYTES ); in += fill; inlen -= fill; left = 0; } #if defined(_OPENMP) #pragma omp parallel shared(S), num_threads(PARALLELISM_DEGREE) #else for( size_t id__ = 0; id__ < PARALLELISM_DEGREE; ++id__ ) #endif { #if defined(_OPENMP) size_t id__ = omp_get_thread_num(); #endif uint64_t inlen__ = inlen; const uint8_t in__ = ( const uint8_t )in; in__ += id__ * BLAKE2S_BLOCKBYTES; while( inlen__ >= PARALLELISM_DEGREE * BLAKE2S_BLOCKBYTES ) { blake2s_update( S->S[id__], in__, BLAKE2S_BLOCKBYTES ); in__ += PARALLELISM_DEGREE * BLAKE2S_BLOCKBYTES; inlen__ -= PARALLELISM_DEGREE * BLAKE2S_BLOCKBYTES; } } in += inlen - inlen % ( PARALLELISM_DEGREE * BLAKE2S_BLOCKBYTES ); inlen %= PARALLELISM_DEGREE * BLAKE2S_BLOCKBYTES; if( inlen > 0 ) memcpy( S->buf + left, in, inlen ); S->buflen = left + inlen; return 0; } int blake2sp_final( blake2sp_state S, uint8_t out, const uint8_t outlen ) { uint8_t hash[PARALLELISM_DEGREE][BLAKE2S_OUTBYTES]; for( size_t i = 0; i < PARALLELISM_DEGREE; ++i ) { if( S->buflen > i * BLAKE2S_BLOCKBYTES ) { size_t left = S->buflen - i * BLAKE2S_BLOCKBYTES; if( left > BLAKE2S_BLOCKBYTES ) left = BLAKE2S_BLOCKBYTES; blake2s_update( S->S[i], S->buf + i * BLAKE2S_BLOCKBYTES, left ); } blake2s_final( S->S[i], hash[i], BLAKE2S_OUTBYTES ); } for( size_t i = 0; i < PARALLELISM_DEGREE; ++i ) blake2s_update( S->R, hash[i], BLAKE2S_OUTBYTES ); blake2s_final( S->R, out, outlen ); return 0; } int blake2sp( uint8_t out, const void in, const void key, uint8_t outlen, uint64_t inlen, uint8_t keylen ) { uint8_t hash[PARALLELISM_DEGREE][BLAKE2S_OUTBYTES]; blake2s_state S[PARALLELISM_DEGREE][1]; blake2s_state FS[1]; / Verify parameters / if ( NULL == in ) return -1; if ( NULL == out ) return -1; if ( NULL == key ) keylen = 0; for( size_t i = 0; i < PARALLELISM_DEGREE; ++i ) if( blake2sp_init_leaf( S[i], outlen, keylen, i ) < 0 ) return -1; S[PARALLELISM_DEGREE - 1]->last_node = 1; // mark last node if( keylen > 0 ) { uint8_t block[BLAKE2S_BLOCKBYTES]; memset( block, 0, BLAKE2S_BLOCKBYTES ); memcpy( block, key, keylen ); for( size_t i = 0; i < PARALLELISM_DEGREE; ++i ) blake2s_update( S[i], block, BLAKE2S_BLOCKBYTES ); secure_zero_memory( block, BLAKE2S_BLOCKBYTES ); / Burn the key from stack / } #if defined(_OPENMP) #pragma omp parallel shared(S,hash), num_threads(PARALLELISM_DEGREE) #else for( size_t id__ = 0; id__ < PARALLELISM_DEGREE; ++id__ ) #endif { #if defined(_OPENMP) size_t id__ = omp_get_thread_num(); #endif uint64_t inlen__ = inlen; const uint8_t in__ = ( const uint8_t * )in; in__ += id__ * BLAKE2S_BLOCKBYTES; while( inlen__ >= PARALLELISM_DEGREE * BLAKE2S_BLOCKBYTES ) { blake2s_update( S[id__], in__, BLAKE2S_BLOCKBYTES ); in__ += PARALLELISM_DEGREE * BLAKE2S_BLOCKBYTES; inlen__ -= PARALLELISM_DEGREE * BLAKE2S_BLOCKBYTES; } if( inlen__ > id__ * BLAKE2S_BLOCKBYTES ) { const size_t left = inlen__ - id__ * BLAKE2S_BLOCKBYTES; const size_t len = left <= BLAKE2S_BLOCKBYTES ? left : BLAKE2S_BLOCKBYTES; blake2s_update( S[id__], in__, len ); } blake2s_final( S[id__], hash[id__], BLAKE2S_OUTBYTES ); } if( blake2sp_init_root( FS, outlen, keylen ) < 0 ) return -1; FS->last_node = 1; for( size_t i = 0; i < PARALLELISM_DEGREE; ++i ) blake2s_update( FS, hash[i], BLAKE2S_OUTBYTES ); blake2s_final( FS, out, outlen ); return 0; } #if defined(BLAKE2SP_SELFTEST) #include <string.h> #include "blake2-kat.h" int main( int argc, char **argv ) { uint8_t key[BLAKE2S_KEYBYTES]; uint8_t buf[KAT_LENGTH]; for( size_t i = 0; i < BLAKE2S_KEYBYTES; ++i ) key[i] = ( uint8_t )i; for( size_t i = 0; i < KAT_LENGTH; ++i ) buf[i] = ( uint8_t )i; for( size_t i = 0; i < KAT_LENGTH; ++i ) { uint8_t hash[BLAKE2S_OUTBYTES]; blake2sp( hash, buf, key, BLAKE2S_OUTBYTES, i, BLAKE2S_KEYBYTES ); if( 0 != memcmp( hash, blake2sp_keyed_kat[i], BLAKE2S_OUTBYTES ) ) { puts( "error" ); return -1; } } puts( "ok" ); return 0; } #endif
slow_flow_calculator_cython.c	/* Generated by Cython 0.25.2 / / BEGIN: Cython Metadata { "distutils": { "depends": [], "extra_compile_args": [ "-fopenmp" ], "extra_link_args": [ "-fopenmp" ] }, "module_name": "triplet_flow_loss.slow_flow_calculator_cython" } END: Cython Metadata / #define 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 < 0x03020000) #error Cython requires Python 2.6+ or Python 3.2+. #else #define CYTHON_ABI "0_25_2" #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 #ifndef HAVE_LONG_LONG #if PY_VERSION_HEX >= 0x03030000 \|\| (PY_MAJOR_VERSION == 2 && 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_ASYNC_SLOTS #define CYTHON_USE_ASYNC_SLOTS 0 #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 #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_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 #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_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 #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 1 #endif #endif #if !defined(CYTHON_FAST_PYCCALL) #define CYTHON_FAST_PYCCALL (CYTHON_FAST_PYCALL && PY_VERSION_HEX >= 0x030600B1) #endif #if CYTHON_USE_PYLONG_INTERNALS #include "longintrepr.h" #undef SHIFT #undef BASE #undef MASK #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, 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#if CYTHON_ATOMICS #define __pyx_add_acquisition_count(memview)\ __pyx_atomic_incr_aligned(__pyx_get_slice_count_pointer(memview), memview->lock) #define __pyx_sub_acquisition_count(memview)\ __pyx_atomic_decr_aligned(__pyx_get_slice_count_pointer(memview), memview->lock) #else #define __pyx_add_acquisition_count(memview)\ __pyx_add_acquisition_count_locked(__pyx_get_slice_count_pointer(memview), memview->lock) #define __pyx_sub_acquisition_count(memview)\ __pyx_sub_acquisition_count_locked(__pyx_get_slice_count_pointer(memview), memview->lock) #endif / "../../../../../../usr/local/lib/python2.7/dist-packages/Cython/Includes/numpy/__init__.pxd":725 * # in Cython to enable them only on the right systems. * * ctypedef npy_int8 int8_t # <<<<<<<<<<<<<< * ctypedef npy_int16 int16_t * ctypedef npy_int32 int32_t / typedef npy_int8 __pyx_t_5numpy_int8_t; / "../../../../../../usr/local/lib/python2.7/dist-packages/Cython/Includes/numpy/__init__.pxd":726 * * ctypedef npy_int8 int8_t * ctypedef npy_int16 int16_t # <<<<<<<<<<<<<< * ctypedef npy_int32 int32_t * ctypedef npy_int64 int64_t / typedef npy_int16 __pyx_t_5numpy_int16_t; / "../../../../../../usr/local/lib/python2.7/dist-packages/Cython/Includes/numpy/__init__.pxd":727 * ctypedef npy_int8 int8_t * ctypedef npy_int16 int16_t * ctypedef npy_int32 int32_t # <<<<<<<<<<<<<< * ctypedef npy_int64 int64_t * #ctypedef npy_int96 int96_t / typedef npy_int32 __pyx_t_5numpy_int32_t; / "../../../../../../usr/local/lib/python2.7/dist-packages/Cython/Includes/numpy/__init__.pxd":728 * ctypedef npy_int16 int16_t * ctypedef npy_int32 int32_t * ctypedef npy_int64 int64_t # <<<<<<<<<<<<<< * #ctypedef npy_int96 int96_t * #ctypedef npy_int128 int128_t / typedef npy_int64 __pyx_t_5numpy_int64_t; / "../../../../../../usr/local/lib/python2.7/dist-packages/Cython/Includes/numpy/__init__.pxd":732 * #ctypedef npy_int128 int128_t * * ctypedef npy_uint8 uint8_t # <<<<<<<<<<<<<< * ctypedef npy_uint16 uint16_t * ctypedef npy_uint32 uint32_t / typedef npy_uint8 __pyx_t_5numpy_uint8_t; / "../../../../../../usr/local/lib/python2.7/dist-packages/Cython/Includes/numpy/__init__.pxd":733 * * ctypedef npy_uint8 uint8_t * ctypedef npy_uint16 uint16_t # <<<<<<<<<<<<<< * ctypedef npy_uint32 uint32_t * ctypedef npy_uint64 uint64_t / typedef npy_uint16 __pyx_t_5numpy_uint16_t; / "../../../../../../usr/local/lib/python2.7/dist-packages/Cython/Includes/numpy/__init__.pxd":734 * ctypedef npy_uint8 uint8_t * ctypedef npy_uint16 uint16_t * ctypedef npy_uint32 uint32_t # <<<<<<<<<<<<<< * ctypedef npy_uint64 uint64_t * #ctypedef npy_uint96 uint96_t / typedef npy_uint32 __pyx_t_5numpy_uint32_t; / "../../../../../../usr/local/lib/python2.7/dist-packages/Cython/Includes/numpy/__init__.pxd":735 * ctypedef npy_uint16 uint16_t * ctypedef npy_uint32 uint32_t * ctypedef npy_uint64 uint64_t # <<<<<<<<<<<<<< * #ctypedef npy_uint96 uint96_t * #ctypedef npy_uint128 uint128_t / typedef npy_uint64 __pyx_t_5numpy_uint64_t; / "../../../../../../usr/local/lib/python2.7/dist-packages/Cython/Includes/numpy/__init__.pxd":739 * #ctypedef npy_uint128 uint128_t * * ctypedef npy_float32 float32_t # <<<<<<<<<<<<<< * ctypedef npy_float64 float64_t * #ctypedef npy_float80 float80_t / typedef npy_float32 __pyx_t_5numpy_float32_t; / "../../../../../../usr/local/lib/python2.7/dist-packages/Cython/Includes/numpy/__init__.pxd":740 * * ctypedef npy_float32 float32_t * ctypedef npy_float64 float64_t # <<<<<<<<<<<<<< * #ctypedef npy_float80 float80_t * #ctypedef npy_float128 float128_t / typedef npy_float64 __pyx_t_5numpy_float64_t; / "../../../../../../usr/local/lib/python2.7/dist-packages/Cython/Includes/numpy/__init__.pxd":749 * # The int types are mapped a bit surprising -- * # numpy.int corresponds to 'l' and numpy.long to 'q' * ctypedef npy_long int_t # <<<<<<<<<<<<<< * ctypedef npy_longlong long_t * ctypedef npy_longlong longlong_t / typedef npy_long __pyx_t_5numpy_int_t; / "../../../../../../usr/local/lib/python2.7/dist-packages/Cython/Includes/numpy/__init__.pxd":750 * # numpy.int corresponds to 'l' and numpy.long to 'q' * ctypedef npy_long int_t * ctypedef npy_longlong long_t # <<<<<<<<<<<<<< * ctypedef npy_longlong longlong_t * / typedef npy_longlong __pyx_t_5numpy_long_t; / "../../../../../../usr/local/lib/python2.7/dist-packages/Cython/Includes/numpy/__init__.pxd":751 * ctypedef npy_long int_t * ctypedef npy_longlong long_t * ctypedef npy_longlong longlong_t # <<<<<<<<<<<<<< * * ctypedef npy_ulong uint_t / typedef npy_longlong __pyx_t_5numpy_longlong_t; / "../../../../../../usr/local/lib/python2.7/dist-packages/Cython/Includes/numpy/__init__.pxd":753 * ctypedef npy_longlong longlong_t * * ctypedef npy_ulong uint_t # <<<<<<<<<<<<<< * ctypedef npy_ulonglong ulong_t * ctypedef npy_ulonglong ulonglong_t / typedef npy_ulong __pyx_t_5numpy_uint_t; / "../../../../../../usr/local/lib/python2.7/dist-packages/Cython/Includes/numpy/__init__.pxd":754 * * ctypedef npy_ulong uint_t * ctypedef npy_ulonglong ulong_t # <<<<<<<<<<<<<< * ctypedef npy_ulonglong ulonglong_t * / typedef npy_ulonglong __pyx_t_5numpy_ulong_t; / "../../../../../../usr/local/lib/python2.7/dist-packages/Cython/Includes/numpy/__init__.pxd":755 * ctypedef npy_ulong uint_t * ctypedef npy_ulonglong ulong_t * ctypedef npy_ulonglong ulonglong_t # <<<<<<<<<<<<<< * * ctypedef npy_intp intp_t / typedef npy_ulonglong __pyx_t_5numpy_ulonglong_t; / "../../../../../../usr/local/lib/python2.7/dist-packages/Cython/Includes/numpy/__init__.pxd":757 * ctypedef npy_ulonglong ulonglong_t * * ctypedef npy_intp intp_t # <<<<<<<<<<<<<< * ctypedef npy_uintp uintp_t * / typedef npy_intp __pyx_t_5numpy_intp_t; / "../../../../../../usr/local/lib/python2.7/dist-packages/Cython/Includes/numpy/__init__.pxd":758 * * ctypedef npy_intp intp_t * ctypedef npy_uintp uintp_t # <<<<<<<<<<<<<< * * ctypedef npy_double float_t / typedef npy_uintp __pyx_t_5numpy_uintp_t; / "../../../../../../usr/local/lib/python2.7/dist-packages/Cython/Includes/numpy/__init__.pxd":760 * ctypedef npy_uintp uintp_t * * ctypedef npy_double float_t # <<<<<<<<<<<<<< * ctypedef npy_double double_t * ctypedef npy_longdouble longdouble_t / typedef npy_double __pyx_t_5numpy_float_t; / "../../../../../../usr/local/lib/python2.7/dist-packages/Cython/Includes/numpy/__init__.pxd":761 * * ctypedef npy_double float_t * ctypedef npy_double double_t # <<<<<<<<<<<<<< * ctypedef npy_longdouble longdouble_t * / typedef npy_double __pyx_t_5numpy_double_t; / "../../../../../../usr/local/lib/python2.7/dist-packages/Cython/Includes/numpy/__init__.pxd":762 * ctypedef npy_double float_t * ctypedef npy_double double_t * ctypedef npy_longdouble longdouble_t # <<<<<<<<<<<<<< * * ctypedef npy_cfloat cfloat_t / typedef npy_longdouble __pyx_t_5numpy_longdouble_t; / Declarations.proto / #if CYTHON_CCOMPLEX #ifdef __cplusplus typedef ::std::complex< float > __pyx_t_float_complex; #else typedef float _Complex __pyx_t_float_complex; #endif #else typedef struct { float real, imag; } __pyx_t_float_complex; #endif static CYTHON_INLINE __pyx_t_float_complex __pyx_t_float_complex_from_parts(float, float); / Declarations.proto / #if CYTHON_CCOMPLEX #ifdef __cplusplus typedef ::std::complex< double > __pyx_t_double_complex; #else typedef double _Complex __pyx_t_double_complex; #endif #else typedef struct { double real, imag; } __pyx_t_double_complex; #endif static CYTHON_INLINE __pyx_t_double_complex __pyx_t_double_complex_from_parts(double, double); /--- Type declarations ---/ struct __pyx_array_obj; struct __pyx_MemviewEnum_obj; struct __pyx_memoryview_obj; struct __pyx_memoryviewslice_obj; / "../../../../../../usr/local/lib/python2.7/dist-packages/Cython/Includes/numpy/__init__.pxd":764 * ctypedef npy_longdouble longdouble_t * * ctypedef npy_cfloat cfloat_t # <<<<<<<<<<<<<< * ctypedef npy_cdouble cdouble_t * ctypedef npy_clongdouble clongdouble_t / typedef npy_cfloat __pyx_t_5numpy_cfloat_t; / "../../../../../../usr/local/lib/python2.7/dist-packages/Cython/Includes/numpy/__init__.pxd":765 * * ctypedef npy_cfloat cfloat_t * ctypedef npy_cdouble cdouble_t # <<<<<<<<<<<<<< * ctypedef npy_clongdouble clongdouble_t * / typedef npy_cdouble __pyx_t_5numpy_cdouble_t; / "../../../../../../usr/local/lib/python2.7/dist-packages/Cython/Includes/numpy/__init__.pxd":766 * ctypedef npy_cfloat cfloat_t * ctypedef npy_cdouble cdouble_t * ctypedef npy_clongdouble clongdouble_t # <<<<<<<<<<<<<< * * ctypedef npy_cdouble complex_t / typedef npy_clongdouble __pyx_t_5numpy_clongdouble_t; / "../../../../../../usr/local/lib/python2.7/dist-packages/Cython/Includes/numpy/__init__.pxd":768 * ctypedef npy_clongdouble clongdouble_t * * ctypedef npy_cdouble complex_t # <<<<<<<<<<<<<< * * cdef inline object PyArray_MultiIterNew1(a): / typedef npy_cdouble __pyx_t_5numpy_complex_t; / "View.MemoryView":103 * * @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":275 * * @cname('__pyx_MemviewEnum') * cdef class Enum(object): # <<<<<<<<<<<<<< * cdef object name * def __init__(self, name): / struct __pyx_MemviewEnum_obj { PyObject_HEAD PyObject name; 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/* GetModuleGlobalName.proto / static CYTHON_INLINE PyObject __Pyx_GetModuleGlobalName(PyObject name); / 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 ? 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static CYTHON_INLINE PyObject __Pyx_GetItemInt_Fast(PyObject o, Py_ssize_t i, int is_list, int wraparound, int boundscheck); /* 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 / SliceObject.proto / static CYTHON_INLINE PyObject __Pyx_PyObject_GetSlice( PyObject* obj, Py_ssize_t cstart, Py_ssize_t cstop, PyObject py_start, PyObject py_stop, PyObject** py_slice, int has_cstart, int has_cstop, int wraparound); /* 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, int nargs, PyObject kwargs); #else #define __Pyx_PyFunction_FastCallDict(func, args, nargs, kwargs) _PyFunction_FastCallDict(func, args, nargs, kwargs) #endif #endif /* 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 / 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); /* ExtTypeTest.proto / static CYTHON_INLINE int __Pyx_TypeTest(PyObject obj, PyTypeObject type); / BufferFormatCheck.proto / static CYTHON_INLINE int __Pyx_GetBufferAndValidate(Py_buffer buf, PyObject* obj, __Pyx_TypeInfo* dtype, int flags, int nd, int cast, __Pyx_BufFmt_StackElem* stack); static CYTHON_INLINE void __Pyx_SafeReleaseBuffer(Py_buffer* info); 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); // PROTO /* MemviewSliceInit.proto / #define __Pyx_BUF_MAX_NDIMS %(BUF_MAX_NDIMS)d #define __Pyx_MEMVIEW_DIRECT 1 #define __Pyx_MEMVIEW_PTR 2 #define __Pyx_MEMVIEW_FULL 4 #define __Pyx_MEMVIEW_CONTIG 8 #define __Pyx_MEMVIEW_STRIDED 16 #define __Pyx_MEMVIEW_FOLLOW 32 #define __Pyx_IS_C_CONTIG 1 #define __Pyx_IS_F_CONTIG 2 static int __Pyx_init_memviewslice( struct __pyx_memoryview_obj memview, int ndim, __Pyx_memviewslice memviewslice, int memview_is_new_reference); 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); /* PyThreadStateGet.proto / #if CYTHON_FAST_THREAD_STATE #define __Pyx_PyThreadState_declare PyThreadState __pyx_tstate; #define __Pyx_PyThreadState_assign __pyx_tstate = PyThreadState_GET(); #else #define __Pyx_PyThreadState_declare #define __Pyx_PyThreadState_assign #endif /* PyErrFetchRestore.proto / #if CYTHON_FAST_THREAD_STATE #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); #else #define __Pyx_ErrRestoreWithState(type, value, tb) PyErr_Restore(type, value, tb) #define __Pyx_ErrFetchWithState(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); / DictGetItem.proto / #if PY_MAJOR_VERSION >= 3 && !CYTHON_COMPILING_IN_PYPY static PyObject __Pyx_PyDict_GetItem(PyObject d, PyObject key) { PyObject value; value = PyDict_GetItemWithError(d, key); if (unlikely(!value)) { if (!PyErr_Occurred()) { PyObject args = PyTuple_Pack(1, key); if (likely(args)) PyErr_SetObject(PyExc_KeyError, args); Py_XDECREF(args); } return NULL; } Py_INCREF(value); return value; } #else #define __Pyx_PyDict_GetItem(d, key) PyObject_GetItem(d, key) #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); / 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 / 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 /* 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 /* ArgTypeTest.proto / static CYTHON_INLINE int __Pyx_ArgTypeTest(PyObject obj, PyTypeObject type, int none_allowed, const char name, int exact); /* 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 / 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 ); /* 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)); / 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); 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); Py_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); #else #define __Pyx_PyInt_AddObjC(op1, op2, intval, inplace)\ (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); Py_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); /* ForceInitThreads.proto / #ifndef __PYX_FORCE_INIT_THREADS #define __PYX_FORCE_INIT_THREADS 0 #endif / WriteUnraisableException.proto / static void __Pyx_WriteUnraisable(const char name, int clineno, int lineno, const char filename, int full_traceback, int nogil); / SetVTable.proto / static int __Pyx_SetVtable(PyObject dict, void vtable); / 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; / None.proto / static Py_ssize_t __Pyx_zeros[] = {0, 0, 0, 0, 0, 0, 0, 0}; static Py_ssize_t __Pyx_minusones[] = {-1, -1, -1, -1, -1, -1, -1, -1}; / 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); /* CIntToPy.proto / static CYTHON_INLINE PyObject __Pyx_PyInt_From_long(long value); /* CIntToPy.proto / static CYTHON_INLINE PyObject __Pyx_PyInt_From_int(int value); /* MemviewDtypeToObject.proto / static CYTHON_INLINE PyObject __pyx_memview_get_float(const char itemp); static CYTHON_INLINE int __pyx_memview_set_float(const char itemp, PyObject obj); / RealImag.proto / #if CYTHON_CCOMPLEX #ifdef __cplusplus #define __Pyx_CREAL(z) ((z).real()) #define __Pyx_CIMAG(z) ((z).imag()) #else #define __Pyx_CREAL(z) (__real__(z)) #define __Pyx_CIMAG(z) (__imag__(z)) #endif #else #define __Pyx_CREAL(z) ((z).real) #define __Pyx_CIMAG(z) ((z).imag) #endif #if defined(__cplusplus) && CYTHON_CCOMPLEX\ && (defined(_WIN32) \|\| defined(__clang__) \|\| (defined(__GNUC__) && (__GNUC__ >= 5 \|\| __GNUC__ == 4 && __GNUC_MINOR__ >= 4 )) \|\| __cplusplus >= 201103) #define __Pyx_SET_CREAL(z,x) ((z).real(x)) #define __Pyx_SET_CIMAG(z,y) ((z).imag(y)) #else #define __Pyx_SET_CREAL(z,x) __Pyx_CREAL(z) = (x) #define __Pyx_SET_CIMAG(z,y) __Pyx_CIMAG(z) = (y) #endif / Arithmetic.proto / #if CYTHON_CCOMPLEX #define __Pyx_c_eq_float(a, b) ((a)==(b)) #define __Pyx_c_sum_float(a, b) ((a)+(b)) #define __Pyx_c_diff_float(a, b) ((a)-(b)) #define __Pyx_c_prod_float(a, b) ((a)(b)) #define __Pyx_c_quot_float(a, b) ((a)/(b)) #define __Pyx_c_neg_float(a) (-(a)) #ifdef __cplusplus #define __Pyx_c_is_zero_float(z) ((z)==(float)0) #define __Pyx_c_conj_float(z) (::std::conj(z)) #if 1 #define __Pyx_c_abs_float(z) (::std::abs(z)) #define __Pyx_c_pow_float(a, b) (::std::pow(a, b)) #endif #else #define __Pyx_c_is_zero_float(z) ((z)==0) #define __Pyx_c_conj_float(z) (conjf(z)) #if 1 #define __Pyx_c_abs_float(z) (cabsf(z)) #define __Pyx_c_pow_float(a, b) (cpowf(a, b)) #endif #endif #else static CYTHON_INLINE int __Pyx_c_eq_float(__pyx_t_float_complex, __pyx_t_float_complex); static CYTHON_INLINE __pyx_t_float_complex __Pyx_c_sum_float(__pyx_t_float_complex, __pyx_t_float_complex); static CYTHON_INLINE __pyx_t_float_complex __Pyx_c_diff_float(__pyx_t_float_complex, __pyx_t_float_complex); static CYTHON_INLINE __pyx_t_float_complex __Pyx_c_prod_float(__pyx_t_float_complex, __pyx_t_float_complex); static CYTHON_INLINE __pyx_t_float_complex __Pyx_c_quot_float(__pyx_t_float_complex, __pyx_t_float_complex); static CYTHON_INLINE __pyx_t_float_complex __Pyx_c_neg_float(__pyx_t_float_complex); static CYTHON_INLINE int __Pyx_c_is_zero_float(__pyx_t_float_complex); static CYTHON_INLINE __pyx_t_float_complex __Pyx_c_conj_float(__pyx_t_float_complex); #if 1 static CYTHON_INLINE float __Pyx_c_abs_float(__pyx_t_float_complex); static CYTHON_INLINE __pyx_t_float_complex __Pyx_c_pow_float(__pyx_t_float_complex, __pyx_t_float_complex); #endif #endif /* Arithmetic.proto / #if CYTHON_CCOMPLEX #define __Pyx_c_eq_double(a, b) ((a)==(b)) #define __Pyx_c_sum_double(a, b) ((a)+(b)) #define __Pyx_c_diff_double(a, b) ((a)-(b)) #define __Pyx_c_prod_double(a, b) ((a)(b)) #define __Pyx_c_quot_double(a, b) ((a)/(b)) #define __Pyx_c_neg_double(a) (-(a)) #ifdef __cplusplus #define __Pyx_c_is_zero_double(z) ((z)==(double)0) #define __Pyx_c_conj_double(z) (::std::conj(z)) #if 1 #define __Pyx_c_abs_double(z) (::std::abs(z)) #define __Pyx_c_pow_double(a, b) (::std::pow(a, b)) #endif #else #define __Pyx_c_is_zero_double(z) ((z)==0) #define __Pyx_c_conj_double(z) (conj(z)) #if 1 #define __Pyx_c_abs_double(z) (cabs(z)) #define __Pyx_c_pow_double(a, b) (cpow(a, b)) #endif #endif #else static CYTHON_INLINE int __Pyx_c_eq_double(__pyx_t_double_complex, __pyx_t_double_complex); static CYTHON_INLINE __pyx_t_double_complex __Pyx_c_sum_double(__pyx_t_double_complex, __pyx_t_double_complex); static CYTHON_INLINE __pyx_t_double_complex __Pyx_c_diff_double(__pyx_t_double_complex, __pyx_t_double_complex); static CYTHON_INLINE __pyx_t_double_complex __Pyx_c_prod_double(__pyx_t_double_complex, __pyx_t_double_complex); static CYTHON_INLINE __pyx_t_double_complex __Pyx_c_quot_double(__pyx_t_double_complex, __pyx_t_double_complex); static CYTHON_INLINE __pyx_t_double_complex __Pyx_c_neg_double(__pyx_t_double_complex); static CYTHON_INLINE int __Pyx_c_is_zero_double(__pyx_t_double_complex); static CYTHON_INLINE __pyx_t_double_complex __Pyx_c_conj_double(__pyx_t_double_complex); #if 1 static CYTHON_INLINE double __Pyx_c_abs_double(__pyx_t_double_complex); static CYTHON_INLINE __pyx_t_double_complex __Pyx_c_pow_double(__pyx_t_double_complex, __pyx_t_double_complex); #endif #endif /* CIntToPy.proto / static CYTHON_INLINE PyObject __Pyx_PyInt_From_enum__NPY_TYPES(enum NPY_TYPES value); /* 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 int __Pyx_PyInt_As_int(PyObject ); /* CIntFromPy.proto / static CYTHON_INLINE char __Pyx_PyInt_As_char(PyObject ); /* CIntFromPy.proto / static CYTHON_INLINE long __Pyx_PyInt_As_long(PyObject ); /* 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_dsdsds_float(PyObject ); /* ObjectToMemviewSlice.proto / static CYTHON_INLINE __Pyx_memviewslice __Pyx_PyObject_to_MemoryviewSlice_dsds_int(PyObject ); /* ObjectToMemviewSlice.proto / static CYTHON_INLINE __Pyx_memviewslice __Pyx_PyObject_to_MemoryviewSlice_dsds_float(PyObject ); /* CheckBinaryVersion.proto / static int __Pyx_check_binary_version(void); / PyIdentifierFromString.proto / #if !defined(__Pyx_PyIdentifier_FromString) #if PY_MAJOR_VERSION < 3 #define __Pyx_PyIdentifier_FromString(s) PyString_FromString(s) #else #define __Pyx_PyIdentifier_FromString(s) PyUnicode_FromString(s) #endif #endif / ModuleImport.proto / static PyObject __Pyx_ImportModule(const char name); / TypeImport.proto / static PyTypeObject __Pyx_ImportType(const char module_name, const char class_name, size_t size, int strict); /* 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 'cpython.buffer' / / Module declarations from 'libc.string' / / Module declarations from 'libc.stdio' / / Module declarations from '__builtin__' / / Module declarations from 'cpython.type' / static PyTypeObject __pyx_ptype_7cpython_4type_type = 0; /* Module declarations from 'cpython' / / Module declarations from 'cpython.object' / / Module declarations from 'cpython.ref' / / Module declarations from 'libc.stdlib' / / Module declarations from 'numpy' / / Module declarations from 'numpy' / static PyTypeObject __pyx_ptype_5numpy_dtype = 0; static PyTypeObject __pyx_ptype_5numpy_flatiter = 0; static PyTypeObject __pyx_ptype_5numpy_broadcast = 0; static PyTypeObject __pyx_ptype_5numpy_ndarray = 0; static PyTypeObject __pyx_ptype_5numpy_ufunc = 0; static CYTHON_INLINE char __pyx_f_5numpy__util_dtypestring(PyArray_Descr , char , char , int ); /proto/ / Module declarations from 'libc.math' / / Module declarations from 'triplet_flow_loss.slow_flow_calculator_cython' / 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 PyObject __pyx_f_17triplet_flow_loss_27slow_flow_calculator_cython_compute_flow_helper(PyArrayObject , PyArrayObject , PyArrayObject , int, PyArrayObject , PyArrayObject , int); /proto/ static void __pyx_f_17triplet_flow_loss_27slow_flow_calculator_cython_set_flow_at_point(int, int, float, float, __Pyx_memviewslice); /proto/ static CYTHON_INLINE float __pyx_f_17triplet_flow_loss_27slow_flow_calculator_cython_dist(__Pyx_memviewslice, __Pyx_memviewslice, int, int, int, int, int); /proto/ static CYTHON_INLINE int __pyx_f_17triplet_flow_loss_27slow_flow_calculator_cython_max_int(int, int); /proto/ static CYTHON_INLINE int __pyx_f_17triplet_flow_loss_27slow_flow_calculator_cython_min_int(int, int); /proto/ 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 __Pyx_TypeInfo __Pyx_TypeInfo_nn___pyx_t_5numpy_float32_t = { "float32_t", NULL, sizeof(__pyx_t_5numpy_float32_t), { 0 }, 0, 'R', 0, 0 }; static __Pyx_TypeInfo __Pyx_TypeInfo_nn___pyx_t_5numpy_int32_t = { "int32_t", NULL, sizeof(__pyx_t_5numpy_int32_t), { 0 }, 0, IS_UNSIGNED(__pyx_t_5numpy_int32_t) ? 'U' : 'I', IS_UNSIGNED(__pyx_t_5numpy_int32_t), 0 }; static __Pyx_TypeInfo __Pyx_TypeInfo_float = { "float", NULL, sizeof(float), { 0 }, 0, 'R', 0, 0 }; static __Pyx_TypeInfo __Pyx_TypeInfo_int = { "int", NULL, sizeof(int), { 0 }, 0, IS_UNSIGNED(int) ? 'U' : 'I', IS_UNSIGNED(int), 0 }; #define __Pyx_MODULE_NAME "triplet_flow_loss.slow_flow_calculator_cython" int __pyx_module_is_main_triplet_flow_loss__slow_flow_calculator_cython = 0; /* Implementation of 'triplet_flow_loss.slow_flow_calculator_cython' / static PyObject __pyx_builtin_range; static PyObject __pyx_builtin_ValueError; static PyObject __pyx_builtin_RuntimeError; static PyObject __pyx_builtin_ImportError; static PyObject __pyx_builtin_MemoryError; static PyObject __pyx_builtin_enumerate; static PyObject __pyx_builtin_Ellipsis; static PyObject __pyx_builtin_TypeError; 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_id[] = "id"; static const char __pyx_k_np[] = "np"; static const char __pyx_k_obj[] = "obj"; static const char __pyx_k_base[] = "base"; static const char __pyx_k_main[] = "__main__"; static const char __pyx_k_mask[] = "mask"; static const char __pyx_k_math[] = "math"; 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_class[] = "__class__"; static const char __pyx_k_dtype[] = "dtype"; static const char __pyx_k_error[] = "error"; static const char __pyx_k_flags[] = "flags"; static const char __pyx_k_int32[] = "int32"; static const char __pyx_k_numpy[] = "numpy"; static const char __pyx_k_range[] = "range"; static const char __pyx_k_shape[] = "shape"; static const char __pyx_k_start[] = "start"; static const char __pyx_k_zeros[] = "zeros"; static const char __pyx_k_astype[] = "astype"; 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_struct[] = "struct"; static const char __pyx_k_unpack[] = "unpack"; static const char __pyx_k_asarray[] = "asarray"; static const char __pyx_k_float32[] = "float32"; static const char __pyx_k_fortran[] = "fortran"; static const char __pyx_k_memview[] = "memview"; static const char __pyx_k_Ellipsis[] = "Ellipsis"; static const char __pyx_k_itemsize[] = "itemsize"; static const char __pyx_k_TypeError[] = "TypeError"; static const char __pyx_k_enumerate[] = "enumerate"; static const char __pyx_k_IndexError[] = "IndexError"; static const char __pyx_k_ValueError[] = "ValueError"; static const char __pyx_k_pyx_vtable[] = "__pyx_vtable__"; static const char __pyx_k_ImportError[] = "ImportError"; static const char __pyx_k_MemoryError[] = "MemoryError"; static const char __pyx_k_array_equal[] = "array_equal"; static const char __pyx_k_interpolate[] = "interpolate"; static const char __pyx_k_RuntimeError[] = "RuntimeError"; static const char __pyx_k_compute_flow[] = "compute_flow"; static const char __pyx_k_left_features[] = "left_features"; static const char __pyx_k_pyx_getbuffer[] = "__pyx_getbuffer"; static const char __pyx_k_initialization[] = "initialization"; static const char __pyx_k_right_features[] = "right_features"; 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_feature_error_arr[] = "feature_error_arr"; static const char __pyx_k_interpolate_after[] = "interpolate_after"; static const char __pyx_k_strided_and_direct[] = "<strided and direct>"; 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_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_neighborhood_len_import[] = "neighborhood_len_import"; 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_itemsize_0_for_cython_array[] = "itemsize <= 0 for cython.array"; static const char __pyx_k_ndarray_is_not_C_contiguous[] = "ndarray is not C contiguous"; 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_home_davidm_DA_RNN_DA_RNN_lib_t[] = "/home/davidm/DA-RNN/DA-RNN/lib/triplet_flow_loss/slow_flow_calculator_cython.pyx"; static const char __pyx_k_numpy_core_multiarray_failed_to[] = "numpy.core.multiarray failed to import"; static const char __pyx_k_unknown_dtype_code_in_numpy_pxd[] = "unknown dtype code in numpy.pxd (%d)"; 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_Empty_shape_tuple_for_cython_arr[] = "Empty shape tuple for cython.array"; static const char __pyx_k_Format_string_allocated_too_shor[] = "Format string allocated too short, see comment in numpy.pxd"; 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_Non_native_byte_order_not_suppor[] = "Non-native byte order not supported"; 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_ndarray_is_not_Fortran_contiguou[] = "ndarray is not Fortran contiguous"; static const char __pyx_k_numpy_core_umath_failed_to_impor[] = "numpy.core.umath failed to import"; static const char __pyx_k_triplet_flow_loss_slow_flow_calc[] = "triplet_flow_loss.slow_flow_calculator_cython"; static const char __pyx_k_unable_to_allocate_shape_and_str[] = "unable to allocate shape and strides."; static const char __pyx_k_Format_string_allocated_too_shor_2[] = "Format string allocated too short."; 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_index_with_type_s; static PyObject __pyx_n_s_Ellipsis; static PyObject __pyx_kp_s_Empty_shape_tuple_for_cython_arr; static PyObject __pyx_kp_u_Format_string_allocated_too_shor; static PyObject __pyx_kp_u_Format_string_allocated_too_shor_2; static PyObject __pyx_n_s_ImportError; 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_kp_u_Non_native_byte_order_not_suppor; static PyObject __pyx_n_b_O; static PyObject __pyx_kp_s_Out_of_bounds_on_buffer_access_a; static PyObject __pyx_n_s_RuntimeError; 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_allocate_buffer; static PyObject __pyx_n_s_array_equal; static PyObject __pyx_n_s_asarray; static PyObject __pyx_n_s_astype; static PyObject __pyx_n_s_base; static PyObject __pyx_n_s_c; static PyObject __pyx_n_u_c; static PyObject __pyx_n_s_class; static PyObject __pyx_n_s_compute_flow; static PyObject __pyx_kp_s_contiguous_and_direct; static PyObject __pyx_kp_s_contiguous_and_indirect; static PyObject __pyx_n_s_dtype; 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_feature_error_arr; static PyObject __pyx_n_s_flags; static PyObject __pyx_n_s_float32; static PyObject __pyx_n_s_format; static PyObject __pyx_n_s_fortran; static PyObject __pyx_n_u_fortran; static PyObject __pyx_kp_s_got_differing_extents_in_dimensi; static PyObject __pyx_kp_s_home_davidm_DA_RNN_DA_RNN_lib_t; static PyObject __pyx_n_s_id; static PyObject __pyx_n_s_import; static PyObject __pyx_n_s_initialization; static PyObject __pyx_n_s_int32; static PyObject __pyx_n_s_interpolate; static PyObject __pyx_n_s_interpolate_after; static PyObject __pyx_n_s_itemsize; static PyObject __pyx_kp_s_itemsize_0_for_cython_array; static PyObject __pyx_n_s_left_features; static PyObject __pyx_n_s_main; static PyObject __pyx_n_s_mask; static PyObject __pyx_n_s_math; 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_kp_u_ndarray_is_not_C_contiguous; static PyObject __pyx_kp_u_ndarray_is_not_Fortran_contiguou; static PyObject __pyx_n_s_ndim; static PyObject __pyx_n_s_neighborhood_len_import; static PyObject __pyx_n_s_np; static PyObject __pyx_n_s_numpy; static PyObject __pyx_kp_s_numpy_core_multiarray_failed_to; static PyObject __pyx_kp_s_numpy_core_umath_failed_to_impor; static PyObject __pyx_n_s_obj; static PyObject __pyx_n_s_pack; static PyObject __pyx_n_s_pyx_getbuffer; static PyObject __pyx_n_s_pyx_vtable; static PyObject __pyx_n_s_range; static PyObject __pyx_n_s_right_features; static PyObject __pyx_n_s_shape; 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_n_s_struct; static PyObject __pyx_n_s_test; static PyObject __pyx_n_s_triplet_flow_loss_slow_flow_calc; static PyObject __pyx_kp_s_unable_to_allocate_array_data; static PyObject __pyx_kp_s_unable_to_allocate_shape_and_str; static PyObject __pyx_kp_u_unknown_dtype_code_in_numpy_pxd; static PyObject __pyx_n_s_unpack; static PyObject __pyx_n_s_zeros; static PyObject __pyx_pf_17triplet_flow_loss_27slow_flow_calculator_cython_compute_flow(CYTHON_UNUSED PyObject __pyx_self, PyObject __pyx_v_left_features, PyObject __pyx_v_right_features, PyObject __pyx_v_mask, PyObject __pyx_v_initialization, PyObject __pyx_v_neighborhood_len_import, PyObject __pyx_v_interpolate_after); /* proto / static int __pyx_pf_5numpy_7ndarray___getbuffer__(PyArrayObject __pyx_v_self, Py_buffer __pyx_v_info, int __pyx_v_flags); / proto / static void __pyx_pf_5numpy_7ndarray_2__releasebuffer__(PyArrayObject __pyx_v_self, Py_buffer __pyx_v_info); / 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 PyObject __pyx_array___pyx_pf_15View_dot_MemoryView_5array_6__getattr__(struct __pyx_array_obj __pyx_v_self, PyObject __pyx_v_attr); /* proto / static PyObject __pyx_array___pyx_pf_15View_dot_MemoryView_5array_8__getitem__(struct __pyx_array_obj __pyx_v_self, PyObject __pyx_v_item); /* proto / static int __pyx_array___pyx_pf_15View_dot_MemoryView_5array_10__setitem__(struct __pyx_array_obj __pyx_v_self, PyObject __pyx_v_item, PyObject __pyx_v_value); /* 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 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); 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__pyx_pybuffernd_feature_error_obj.diminfo[1].strides = __pyx_pybuffernd_feature_error_obj.rcbuffer->pybuffer.strides[1]; __pyx_pybuffernd_feature_error_obj.diminfo[1].shape = __pyx_pybuffernd_feature_error_obj.rcbuffer->pybuffer.shape[1]; / "triplet_flow_loss/slow_flow_calculator_cython.pyx":51 * cdef int start_a, stop_a, start_b, stop_b * cdef int left_len_0, left_len_1, right_len_0, right_len_1, feature_depth, neighborhood_len * left_len_0 = <int> left_features_obj.shape[0] # <<<<<<<<<<<<<< * left_len_1 = <int> left_features_obj.shape[1] * right_len_0 = <int> right_features_obj.shape[0] / __pyx_v_left_len_0 = ((int)(__pyx_v_left_features_obj->dimensions[0])); / "triplet_flow_loss/slow_flow_calculator_cython.pyx":52 * cdef int left_len_0, left_len_1, right_len_0, right_len_1, feature_depth, neighborhood_len * left_len_0 = <int> left_features_obj.shape[0] * left_len_1 = <int> left_features_obj.shape[1] # <<<<<<<<<<<<<< * right_len_0 = <int> right_features_obj.shape[0] * right_len_1 = <int> right_features_obj.shape[1] / __pyx_v_left_len_1 = ((int)(__pyx_v_left_features_obj->dimensions[1])); / "triplet_flow_loss/slow_flow_calculator_cython.pyx":53 * left_len_0 = <int> left_features_obj.shape[0] * left_len_1 = <int> left_features_obj.shape[1] * right_len_0 = <int> right_features_obj.shape[0] # <<<<<<<<<<<<<< * right_len_1 = <int> right_features_obj.shape[1] * feature_depth = <int> left_features_obj.shape[2] / __pyx_v_right_len_0 = ((int)(__pyx_v_right_features_obj->dimensions[0])); / "triplet_flow_loss/slow_flow_calculator_cython.pyx":54 * left_len_1 = <int> left_features_obj.shape[1] * right_len_0 = <int> right_features_obj.shape[0] * right_len_1 = <int> right_features_obj.shape[1] # <<<<<<<<<<<<<< * feature_depth = <int> left_features_obj.shape[2] * neighborhood_len = <int> neighborhood_len_import / __pyx_v_right_len_1 = ((int)(__pyx_v_right_features_obj->dimensions[1])); / "triplet_flow_loss/slow_flow_calculator_cython.pyx":55 * right_len_0 = <int> right_features_obj.shape[0] * right_len_1 = <int> right_features_obj.shape[1] * feature_depth = <int> left_features_obj.shape[2] # <<<<<<<<<<<<<< * neighborhood_len = <int> neighborhood_len_import * / __pyx_v_feature_depth = ((int)(__pyx_v_left_features_obj->dimensions[2])); / "triplet_flow_loss/slow_flow_calculator_cython.pyx":56 * right_len_1 = <int> right_features_obj.shape[1] * feature_depth = <int> left_features_obj.shape[2] * neighborhood_len = <int> neighborhood_len_import # <<<<<<<<<<<<<< * * cdef float[:,:,:] left_features = left_features_obj / __pyx_v_neighborhood_len = ((int)__pyx_v_neighborhood_len_import); / "triplet_flow_loss/slow_flow_calculator_cython.pyx":58 * neighborhood_len = <int> neighborhood_len_import * * cdef float[:,:,:] left_features = left_features_obj # <<<<<<<<<<<<<< * cdef float[:,:,:] right_features = right_features_obj * cdef float[:,:,:] flow_arr = flow_arr_obj / __pyx_t_1 = __Pyx_PyObject_to_MemoryviewSlice_dsdsds_float(((PyObject )__pyx_v_left_features_obj)); if (unlikely(!__pyx_t_1.memview)) __PYX_ERR(0, 58, __pyx_L1_error) __pyx_v_left_features = __pyx_t_1; __pyx_t_1.memview = NULL; __pyx_t_1.data = NULL; /* "triplet_flow_loss/slow_flow_calculator_cython.pyx":59 * * cdef float[:,:,:] left_features = left_features_obj * cdef float[:,:,:] right_features = right_features_obj # <<<<<<<<<<<<<< * cdef float[:,:,:] flow_arr = flow_arr_obj * cdef int[:,:] mask = mask_obj / __pyx_t_1 = __Pyx_PyObject_to_MemoryviewSlice_dsdsds_float(((PyObject )__pyx_v_right_features_obj)); if (unlikely(!__pyx_t_1.memview)) __PYX_ERR(0, 59, __pyx_L1_error) __pyx_v_right_features = __pyx_t_1; __pyx_t_1.memview = NULL; __pyx_t_1.data = NULL; /* "triplet_flow_loss/slow_flow_calculator_cython.pyx":60 * cdef float[:,:,:] left_features = left_features_obj * cdef float[:,:,:] right_features = right_features_obj * cdef float[:,:,:] flow_arr = flow_arr_obj # <<<<<<<<<<<<<< * cdef int[:,:] mask = mask_obj * cdef float[:,:] feature_errors = feature_error_obj / __pyx_t_1 = __Pyx_PyObject_to_MemoryviewSlice_dsdsds_float(((PyObject )__pyx_v_flow_arr_obj)); if (unlikely(!__pyx_t_1.memview)) __PYX_ERR(0, 60, __pyx_L1_error) __pyx_v_flow_arr = __pyx_t_1; __pyx_t_1.memview = NULL; __pyx_t_1.data = NULL; /* "triplet_flow_loss/slow_flow_calculator_cython.pyx":61 * cdef float[:,:,:] right_features = right_features_obj * cdef float[:,:,:] flow_arr = flow_arr_obj * cdef int[:,:] mask = mask_obj # <<<<<<<<<<<<<< * cdef float[:,:] feature_errors = feature_error_obj * / __pyx_t_2 = __Pyx_PyObject_to_MemoryviewSlice_dsds_int(((PyObject )__pyx_v_mask_obj)); if (unlikely(!__pyx_t_2.memview)) __PYX_ERR(0, 61, __pyx_L1_error) __pyx_v_mask = __pyx_t_2; __pyx_t_2.memview = NULL; __pyx_t_2.data = NULL; /* "triplet_flow_loss/slow_flow_calculator_cython.pyx":62 * cdef float[:,:,:] flow_arr = flow_arr_obj * cdef int[:,:] mask = mask_obj * cdef float[:,:] feature_errors = feature_error_obj # <<<<<<<<<<<<<< * * cdef float current_dist, best_dist, temp, temp2, best_index_u, best_index_v, best_a, best_b, x_average / __pyx_t_3 = __Pyx_PyObject_to_MemoryviewSlice_dsds_float(((PyObject )__pyx_v_feature_error_obj)); if (unlikely(!__pyx_t_3.memview)) __PYX_ERR(0, 62, __pyx_L1_error) __pyx_v_feature_errors = __pyx_t_3; __pyx_t_3.memview = NULL; __pyx_t_3.data = NULL; /* "triplet_flow_loss/slow_flow_calculator_cython.pyx":72 * cdef int best_x, best_y * * for i in prange(0, left_len_0, nogil=True, schedule='dynamic', num_threads=20): # <<<<<<<<<<<<<< * # for i in range(left_len_0): * for j in range(0, left_len_1): / { #ifdef WITH_THREAD PyThreadState _save; Py_UNBLOCK_THREADS #endif /try:/ { __pyx_t_4 = __pyx_v_left_len_0; 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_6 = (__pyx_t_4 - 0 + 1 - 1/abs(1)) / 1; if (__pyx_t_6 > 0) { #ifdef _OPENMP #pragma omp parallel num_threads(20) private(__pyx_t_10, __pyx_t_11, __pyx_t_12, __pyx_t_13, __pyx_t_14, __pyx_t_15, __pyx_t_16, __pyx_t_17, __pyx_t_18, __pyx_t_19, __pyx_t_20, __pyx_t_21, __pyx_t_22, __pyx_t_23, __pyx_t_24, __pyx_t_7, __pyx_t_8, __pyx_t_9) #endif /* _OPENMP / { #ifdef _OPENMP #pragma omp for lastprivate(__pyx_v_a) lastprivate(__pyx_v_b) lastprivate(__pyx_v_best_dist) lastprivate(__pyx_v_best_index_u) lastprivate(__pyx_v_best_index_v) lastprivate(__pyx_v_current_dist) lastprivate(__pyx_v_dist1) lastprivate(__pyx_v_dist2) firstprivate(__pyx_v_i) lastprivate(__pyx_v_i) lastprivate(__pyx_v_initial_i) lastprivate(__pyx_v_initial_j) lastprivate(__pyx_v_j) lastprivate(__pyx_v_start_a) lastprivate(__pyx_v_start_b) lastprivate(__pyx_v_stop_a) lastprivate(__pyx_v_stop_b) lastprivate(__pyx_v_u1) lastprivate(__pyx_v_u2) lastprivate(__pyx_v_v1) lastprivate(__pyx_v_v2) schedule(dynamic) #endif / _OPENMP / for (__pyx_t_5 = 0; __pyx_t_5 < __pyx_t_6; __pyx_t_5++){ { __pyx_v_i = (int)(0 + 1 __pyx_t_5); /* Initialize private variables to invalid values / __pyx_v_a = ((int)0xbad0bad0); __pyx_v_b = ((int)0xbad0bad0); __pyx_v_best_dist = ((float)__PYX_NAN()); __pyx_v_best_index_u = ((float)__PYX_NAN()); __pyx_v_best_index_v = ((float)__PYX_NAN()); __pyx_v_current_dist = ((float)__PYX_NAN()); __pyx_v_dist1 = ((float)__PYX_NAN()); __pyx_v_dist2 = ((float)__PYX_NAN()); __pyx_v_initial_i = ((int)0xbad0bad0); __pyx_v_initial_j = ((int)0xbad0bad0); __pyx_v_j = ((int)0xbad0bad0); __pyx_v_start_a = ((int)0xbad0bad0); __pyx_v_start_b = ((int)0xbad0bad0); __pyx_v_stop_a = ((int)0xbad0bad0); __pyx_v_stop_b = ((int)0xbad0bad0); __pyx_v_u1 = ((int)0xbad0bad0); __pyx_v_u2 = ((int)0xbad0bad0); __pyx_v_v1 = ((int)0xbad0bad0); __pyx_v_v2 = ((int)0xbad0bad0); / "triplet_flow_loss/slow_flow_calculator_cython.pyx":74 * for i in prange(0, left_len_0, nogil=True, schedule='dynamic', num_threads=20): * # for i in range(left_len_0): * for j in range(0, left_len_1): # <<<<<<<<<<<<<< * if mask[i, j] != 0: * set_flow_at_point(i, j, 0.0, 0.0, flow_arr) / __pyx_t_7 = __pyx_v_left_len_1; for (__pyx_t_8 = 0; __pyx_t_8 < __pyx_t_7; __pyx_t_8+=1) { __pyx_v_j = __pyx_t_8; / "triplet_flow_loss/slow_flow_calculator_cython.pyx":75 * # for i in range(left_len_0): * for j in range(0, left_len_1): * if mask[i, j] != 0: # <<<<<<<<<<<<<< * set_flow_at_point(i, j, 0.0, 0.0, flow_arr) * else: / __pyx_t_9 = __pyx_v_i; __pyx_t_10 = __pyx_v_j; __pyx_t_11 = (((((int ) ( / dim=1 / (( / dim=0 / (__pyx_v_mask.data + __pyx_t_9 __pyx_v_mask.strides[0]) ) + __pyx_t_10 * __pyx_v_mask.strides[1]) ))) != 0) != 0); if (__pyx_t_11) { /* "triplet_flow_loss/slow_flow_calculator_cython.pyx":76 * for j in range(0, left_len_1): * if mask[i, j] != 0: * set_flow_at_point(i, j, 0.0, 0.0, flow_arr) # <<<<<<<<<<<<<< * else: * best_index_u = i / __pyx_f_17triplet_flow_loss_27slow_flow_calculator_cython_set_flow_at_point(__pyx_v_i, __pyx_v_j, 0.0, 0.0, __pyx_v_flow_arr); / "triplet_flow_loss/slow_flow_calculator_cython.pyx":75 * # for i in range(left_len_0): * for j in range(0, left_len_1): * if mask[i, j] != 0: # <<<<<<<<<<<<<< * set_flow_at_point(i, j, 0.0, 0.0, flow_arr) * else: / goto __pyx_L12; } / "triplet_flow_loss/slow_flow_calculator_cython.pyx":78 * set_flow_at_point(i, j, 0.0, 0.0, flow_arr) * else: * best_index_u = i # <<<<<<<<<<<<<< * best_index_v = j * / /else/ { __pyx_v_best_index_u = __pyx_v_i; / "triplet_flow_loss/slow_flow_calculator_cython.pyx":79 * else: * best_index_u = i * best_index_v = j # <<<<<<<<<<<<<< * * # set the starting distance to no be no movement. Otherwise the default will be large / __pyx_v_best_index_v = __pyx_v_j; / "triplet_flow_loss/slow_flow_calculator_cython.pyx":82 * * # set the starting distance to no be no movement. Otherwise the default will be large * current_dist = 10*5 # just a really big number # <<<<<<<<<<<<<< * initial_i = <int> flow_arr[i, j, 1] + i / __pyx_v_current_dist = 100000.0; / "triplet_flow_loss/slow_flow_calculator_cython.pyx":84 * current_dist = 10*5 # just a really big number * initial_i = <int> flow_arr[i, j, 1] + i # <<<<<<<<<<<<<< * initial_j = <int> flow_arr[i, j, 0] + j * current_dist = dist(left_features, right_features, i, j, initial_i, initial_j, feature_depth) / __pyx_t_12 = __pyx_v_i; __pyx_t_13 = __pyx_v_j; __pyx_t_14 = 1; __pyx_v_initial_i = (((int)(((float ) ( / dim=2 / (( / dim=1 / (( / dim=0 / (__pyx_v_flow_arr.data + __pyx_t_12 __pyx_v_flow_arr.strides[0]) ) + __pyx_t_13 * __pyx_v_flow_arr.strides[1]) ) + __pyx_t_14 * __pyx_v_flow_arr.strides[2]) )))) + __pyx_v_i); /* "triplet_flow_loss/slow_flow_calculator_cython.pyx":85 * * initial_i = <int> flow_arr[i, j, 1] + i * initial_j = <int> flow_arr[i, j, 0] + j # <<<<<<<<<<<<<< * current_dist = dist(left_features, right_features, i, j, initial_i, initial_j, feature_depth) * best_dist = current_dist / __pyx_t_15 = __pyx_v_i; __pyx_t_16 = __pyx_v_j; __pyx_t_17 = 0; __pyx_v_initial_j = (((int)(((float ) ( / dim=2 / (( / dim=1 / (( / dim=0 / (__pyx_v_flow_arr.data + __pyx_t_15 __pyx_v_flow_arr.strides[0]) ) + __pyx_t_16 * __pyx_v_flow_arr.strides[1]) ) + __pyx_t_17 * __pyx_v_flow_arr.strides[2]) )))) + __pyx_v_j); /* "triplet_flow_loss/slow_flow_calculator_cython.pyx":86 * initial_i = <int> flow_arr[i, j, 1] + i * initial_j = <int> flow_arr[i, j, 0] + j * current_dist = dist(left_features, right_features, i, j, initial_i, initial_j, feature_depth) # <<<<<<<<<<<<<< * best_dist = current_dist * / __pyx_v_current_dist = __pyx_f_17triplet_flow_loss_27slow_flow_calculator_cython_dist(__pyx_v_left_features, __pyx_v_right_features, __pyx_v_i, __pyx_v_j, __pyx_v_initial_i, __pyx_v_initial_j, __pyx_v_feature_depth); / "triplet_flow_loss/slow_flow_calculator_cython.pyx":87 * initial_j = <int> flow_arr[i, j, 0] + j * current_dist = dist(left_features, right_features, i, j, initial_i, initial_j, feature_depth) * best_dist = current_dist # <<<<<<<<<<<<<< * * start_a = max_int(0, initial_i - neighborhood_len/2) / __pyx_v_best_dist = __pyx_v_current_dist; / "triplet_flow_loss/slow_flow_calculator_cython.pyx":89 * best_dist = current_dist * * start_a = max_int(0, initial_i - neighborhood_len/2) # <<<<<<<<<<<<<< * stop_a = min_int(left_len_0, initial_i + (neighborhood_len - neighborhood_len/2)) * start_b = max_int(0, initial_j - neighborhood_len / 2) / __pyx_v_start_a = __pyx_f_17triplet_flow_loss_27slow_flow_calculator_cython_max_int(0, (__pyx_v_initial_i - (__pyx_v_neighborhood_len / 2))); / "triplet_flow_loss/slow_flow_calculator_cython.pyx":90 * * start_a = max_int(0, initial_i - neighborhood_len/2) * stop_a = min_int(left_len_0, initial_i + (neighborhood_len - neighborhood_len/2)) # <<<<<<<<<<<<<< * start_b = max_int(0, initial_j - neighborhood_len / 2) * stop_b = min_int(left_len_1, initial_j + (<int> neighborhood_len - <int> neighborhood_len / 2)) / __pyx_v_stop_a = __pyx_f_17triplet_flow_loss_27slow_flow_calculator_cython_min_int(__pyx_v_left_len_0, (__pyx_v_initial_i + (__pyx_v_neighborhood_len - (__pyx_v_neighborhood_len / 2)))); / "triplet_flow_loss/slow_flow_calculator_cython.pyx":91 * start_a = max_int(0, initial_i - neighborhood_len/2) * stop_a = min_int(left_len_0, initial_i + (neighborhood_len - neighborhood_len/2)) * start_b = max_int(0, initial_j - neighborhood_len / 2) # <<<<<<<<<<<<<< * stop_b = min_int(left_len_1, initial_j + (<int> neighborhood_len - <int> neighborhood_len / 2)) * for a in range(start_a, stop_a): / __pyx_v_start_b = __pyx_f_17triplet_flow_loss_27slow_flow_calculator_cython_max_int(0, (__pyx_v_initial_j - (__pyx_v_neighborhood_len / 2))); / "triplet_flow_loss/slow_flow_calculator_cython.pyx":92 * stop_a = min_int(left_len_0, initial_i + (neighborhood_len - neighborhood_len/2)) * start_b = max_int(0, initial_j - neighborhood_len / 2) * stop_b = min_int(left_len_1, initial_j + (<int> neighborhood_len - <int> neighborhood_len / 2)) # <<<<<<<<<<<<<< * for a in range(start_a, stop_a): * for b in range(start_b, stop_b): / __pyx_v_stop_b = __pyx_f_17triplet_flow_loss_27slow_flow_calculator_cython_min_int(__pyx_v_left_len_1, (__pyx_v_initial_j + (((int)__pyx_v_neighborhood_len) - (((int)__pyx_v_neighborhood_len) / 2)))); / "triplet_flow_loss/slow_flow_calculator_cython.pyx":93 * start_b = max_int(0, initial_j - neighborhood_len / 2) * stop_b = min_int(left_len_1, initial_j + (<int> neighborhood_len - <int> neighborhood_len / 2)) * for a in range(start_a, stop_a): # <<<<<<<<<<<<<< * for b in range(start_b, stop_b): * current_dist = dist(left_features, right_features, i, j, a, b, feature_depth) / __pyx_t_18 = __pyx_v_stop_a; for (__pyx_t_19 = __pyx_v_start_a; __pyx_t_19 < __pyx_t_18; __pyx_t_19+=1) { __pyx_v_a = __pyx_t_19; / "triplet_flow_loss/slow_flow_calculator_cython.pyx":94 * stop_b = min_int(left_len_1, initial_j + (<int> neighborhood_len - <int> neighborhood_len / 2)) * for a in range(start_a, stop_a): * for b in range(start_b, stop_b): # <<<<<<<<<<<<<< * current_dist = dist(left_features, right_features, i, j, a, b, feature_depth) * if current_dist < best_dist: / __pyx_t_20 = __pyx_v_stop_b; for (__pyx_t_21 = __pyx_v_start_b; __pyx_t_21 < __pyx_t_20; __pyx_t_21+=1) { __pyx_v_b = __pyx_t_21; / "triplet_flow_loss/slow_flow_calculator_cython.pyx":95 * for a in range(start_a, stop_a): * for b in range(start_b, stop_b): * current_dist = dist(left_features, right_features, i, j, a, b, feature_depth) # <<<<<<<<<<<<<< * if current_dist < best_dist: * best_dist = current_dist / __pyx_v_current_dist = __pyx_f_17triplet_flow_loss_27slow_flow_calculator_cython_dist(__pyx_v_left_features, __pyx_v_right_features, __pyx_v_i, __pyx_v_j, __pyx_v_a, __pyx_v_b, __pyx_v_feature_depth); / "triplet_flow_loss/slow_flow_calculator_cython.pyx":96 * for b in range(start_b, stop_b): * current_dist = dist(left_features, right_features, i, j, a, b, feature_depth) * if current_dist < best_dist: # <<<<<<<<<<<<<< * best_dist = current_dist * best_index_u = a / __pyx_t_11 = ((__pyx_v_current_dist < __pyx_v_best_dist) != 0); if (__pyx_t_11) { / "triplet_flow_loss/slow_flow_calculator_cython.pyx":97 * current_dist = dist(left_features, right_features, i, j, a, b, feature_depth) * if current_dist < best_dist: * best_dist = current_dist # <<<<<<<<<<<<<< * best_index_u = a * best_index_v = b / __pyx_v_best_dist = __pyx_v_current_dist; / "triplet_flow_loss/slow_flow_calculator_cython.pyx":98 * if current_dist < best_dist: * best_dist = current_dist * best_index_u = a # <<<<<<<<<<<<<< * best_index_v = b * / __pyx_v_best_index_u = __pyx_v_a; / "triplet_flow_loss/slow_flow_calculator_cython.pyx":99 * best_dist = current_dist * best_index_u = a * best_index_v = b # <<<<<<<<<<<<<< * * if interpolate_after == 1 and best_index_u != -1: / __pyx_v_best_index_v = __pyx_v_b; / "triplet_flow_loss/slow_flow_calculator_cython.pyx":96 * for b in range(start_b, stop_b): * current_dist = dist(left_features, right_features, i, j, a, b, feature_depth) * if current_dist < best_dist: # <<<<<<<<<<<<<< * best_dist = current_dist * best_index_u = a / } } } / "triplet_flow_loss/slow_flow_calculator_cython.pyx":101 * best_index_v = b * * if interpolate_after == 1 and best_index_u != -1: # <<<<<<<<<<<<<< * u1 = <int> best_index_u - 1 * if u1 < 0: / __pyx_t_22 = ((__pyx_v_interpolate_after == 1) != 0); if (__pyx_t_22) { } else { __pyx_t_11 = __pyx_t_22; goto __pyx_L19_bool_binop_done; } __pyx_t_22 = ((__pyx_v_best_index_u != -1.0) != 0); __pyx_t_11 = __pyx_t_22; __pyx_L19_bool_binop_done:; if (__pyx_t_11) { / "triplet_flow_loss/slow_flow_calculator_cython.pyx":102 * * if interpolate_after == 1 and best_index_u != -1: * u1 = <int> best_index_u - 1 # <<<<<<<<<<<<<< * if u1 < 0: * u1 = 0 / __pyx_v_u1 = (((int)__pyx_v_best_index_u) - 1); / "triplet_flow_loss/slow_flow_calculator_cython.pyx":103 * if interpolate_after == 1 and best_index_u != -1: * u1 = <int> best_index_u - 1 * if u1 < 0: # <<<<<<<<<<<<<< * u1 = 0 * if u1 >= right_len_0 - 3: / __pyx_t_11 = ((__pyx_v_u1 < 0) != 0); if (__pyx_t_11) { / "triplet_flow_loss/slow_flow_calculator_cython.pyx":104 * u1 = <int> best_index_u - 1 * if u1 < 0: * u1 = 0 # <<<<<<<<<<<<<< * if u1 >= right_len_0 - 3: * u1 = right_len_0 - 3 / __pyx_v_u1 = 0; / "triplet_flow_loss/slow_flow_calculator_cython.pyx":103 * if interpolate_after == 1 and best_index_u != -1: * u1 = <int> best_index_u - 1 * if u1 < 0: # <<<<<<<<<<<<<< * u1 = 0 * if u1 >= right_len_0 - 3: / } / "triplet_flow_loss/slow_flow_calculator_cython.pyx":105 * if u1 < 0: * u1 = 0 * if u1 >= right_len_0 - 3: # <<<<<<<<<<<<<< * u1 = right_len_0 - 3 * u2 = u1 + 2 / __pyx_t_11 = ((__pyx_v_u1 >= (__pyx_v_right_len_0 - 3)) != 0); if (__pyx_t_11) { / "triplet_flow_loss/slow_flow_calculator_cython.pyx":106 * u1 = 0 * if u1 >= right_len_0 - 3: * u1 = right_len_0 - 3 # <<<<<<<<<<<<<< * u2 = u1 + 2 * / __pyx_v_u1 = (__pyx_v_right_len_0 - 3); / "triplet_flow_loss/slow_flow_calculator_cython.pyx":105 * if u1 < 0: * u1 = 0 * if u1 >= right_len_0 - 3: # <<<<<<<<<<<<<< * u1 = right_len_0 - 3 * u2 = u1 + 2 / } / "triplet_flow_loss/slow_flow_calculator_cython.pyx":107 * if u1 >= right_len_0 - 3: * u1 = right_len_0 - 3 * u2 = u1 + 2 # <<<<<<<<<<<<<< * * dist1 = dist(left_features, right_features, i, j, u1, <int> best_index_v, feature_depth) / __pyx_v_u2 = (__pyx_v_u1 + 2); / "triplet_flow_loss/slow_flow_calculator_cython.pyx":109 * u2 = u1 + 2 * * dist1 = dist(left_features, right_features, i, j, u1, <int> best_index_v, feature_depth) # <<<<<<<<<<<<<< * dist2 = dist(left_features, right_features, i, j, u2, <int> best_index_v, feature_depth) * best_index_u = dist1 / (dist1 + dist2 + 0.00001) * u2 + dist2 / (dist1 + dist2 + 0.00001) * u1 / __pyx_v_dist1 = __pyx_f_17triplet_flow_loss_27slow_flow_calculator_cython_dist(__pyx_v_left_features, __pyx_v_right_features, __pyx_v_i, __pyx_v_j, __pyx_v_u1, ((int)__pyx_v_best_index_v), __pyx_v_feature_depth); / "triplet_flow_loss/slow_flow_calculator_cython.pyx":110 * * dist1 = dist(left_features, right_features, i, j, u1, <int> best_index_v, feature_depth) * dist2 = dist(left_features, right_features, i, j, u2, <int> best_index_v, feature_depth) # <<<<<<<<<<<<<< * best_index_u = dist1 / (dist1 + dist2 + 0.00001) * u2 + dist2 / (dist1 + dist2 + 0.00001) * u1 * # if not (u1 <= best_index_u and u2 >= best_index_u): / __pyx_v_dist2 = __pyx_f_17triplet_flow_loss_27slow_flow_calculator_cython_dist(__pyx_v_left_features, __pyx_v_right_features, __pyx_v_i, __pyx_v_j, __pyx_v_u2, ((int)__pyx_v_best_index_v), __pyx_v_feature_depth); / "triplet_flow_loss/slow_flow_calculator_cython.pyx":111 * dist1 = dist(left_features, right_features, i, j, u1, <int> best_index_v, feature_depth) * dist2 = dist(left_features, right_features, i, j, u2, <int> best_index_v, feature_depth) * best_index_u = dist1 / (dist1 + dist2 + 0.00001) * u2 + dist2 / (dist1 + dist2 + 0.00001) * u1 # <<<<<<<<<<<<<< * # if not (u1 <= best_index_u and u2 >= best_index_u): * # printf("i %3i, j, %3i, u1 %2i, u2 %2i, best_index_v %2.1f, dist1 %3.2f,\t dist2 %3.2f,\t best_index_u %3.1lf\n", i, j, u1, u2, best_index_v, dist1, dist2, best_index_u) / __pyx_v_best_index_u = (((__pyx_v_dist1 / ((__pyx_v_dist1 + __pyx_v_dist2) + 0.00001)) __pyx_v_u2) + ((__pyx_v_dist2 / ((__pyx_v_dist1 + __pyx_v_dist2) + 0.00001)) * __pyx_v_u1)); /* "triplet_flow_loss/slow_flow_calculator_cython.pyx":115 * # printf("i %3i, j, %3i, u1 %2i, u2 %2i, best_index_v %2.1f, dist1 %3.2f,\t dist2 %3.2f,\t best_index_u %3.1lf\n", i, j, u1, u2, best_index_v, dist1, dist2, best_index_u) * * v1 = <int> best_index_v - 1 # <<<<<<<<<<<<<< * if v1 < 0: * v1 = 0 / __pyx_v_v1 = (((int)__pyx_v_best_index_v) - 1); / "triplet_flow_loss/slow_flow_calculator_cython.pyx":116 * * v1 = <int> best_index_v - 1 * if v1 < 0: # <<<<<<<<<<<<<< * v1 = 0 * if v1 >= right_len_1 - 3: / __pyx_t_11 = ((__pyx_v_v1 < 0) != 0); if (__pyx_t_11) { / "triplet_flow_loss/slow_flow_calculator_cython.pyx":117 * v1 = <int> best_index_v - 1 * if v1 < 0: * v1 = 0 # <<<<<<<<<<<<<< * if v1 >= right_len_1 - 3: * v1 = right_len_1 - 3 / __pyx_v_v1 = 0; / "triplet_flow_loss/slow_flow_calculator_cython.pyx":116 * * v1 = <int> best_index_v - 1 * if v1 < 0: # <<<<<<<<<<<<<< * v1 = 0 * if v1 >= right_len_1 - 3: / } / "triplet_flow_loss/slow_flow_calculator_cython.pyx":118 * if v1 < 0: * v1 = 0 * if v1 >= right_len_1 - 3: # <<<<<<<<<<<<<< * v1 = right_len_1 - 3 * v2 = v1 + 2 / __pyx_t_11 = ((__pyx_v_v1 >= (__pyx_v_right_len_1 - 3)) != 0); if (__pyx_t_11) { / "triplet_flow_loss/slow_flow_calculator_cython.pyx":119 * v1 = 0 * if v1 >= right_len_1 - 3: * v1 = right_len_1 - 3 # <<<<<<<<<<<<<< * v2 = v1 + 2 * / __pyx_v_v1 = (__pyx_v_right_len_1 - 3); / "triplet_flow_loss/slow_flow_calculator_cython.pyx":118 * if v1 < 0: * v1 = 0 * if v1 >= right_len_1 - 3: # <<<<<<<<<<<<<< * v1 = right_len_1 - 3 * v2 = v1 + 2 / } / "triplet_flow_loss/slow_flow_calculator_cython.pyx":120 * if v1 >= right_len_1 - 3: * v1 = right_len_1 - 3 * v2 = v1 + 2 # <<<<<<<<<<<<<< * * dist1 = dist(left_features, right_features, i, j, <int> best_index_u, v1, feature_depth) / __pyx_v_v2 = (__pyx_v_v1 + 2); / "triplet_flow_loss/slow_flow_calculator_cython.pyx":122 * v2 = v1 + 2 * * dist1 = dist(left_features, right_features, i, j, <int> best_index_u, v1, feature_depth) # <<<<<<<<<<<<<< * dist2 = dist(left_features, right_features, i, j, <int> best_index_u, v2, feature_depth) * best_index_v = (dist1 + 0.00001) / (dist1 + dist2 + 0.00002) * v2 + (dist2 + 0.00001) / (dist1 + dist2 + 0.00002) * v1 / __pyx_v_dist1 = __pyx_f_17triplet_flow_loss_27slow_flow_calculator_cython_dist(__pyx_v_left_features, __pyx_v_right_features, __pyx_v_i, __pyx_v_j, ((int)__pyx_v_best_index_u), __pyx_v_v1, __pyx_v_feature_depth); / "triplet_flow_loss/slow_flow_calculator_cython.pyx":123 * * dist1 = dist(left_features, right_features, i, j, <int> best_index_u, v1, feature_depth) * dist2 = dist(left_features, right_features, i, j, <int> best_index_u, v2, feature_depth) # <<<<<<<<<<<<<< * best_index_v = (dist1 + 0.00001) / (dist1 + dist2 + 0.00002) * v2 + (dist2 + 0.00001) / (dist1 + dist2 + 0.00002) * v1 * # if not (v1 <= best_index_v and v2 >= best_index_v): / __pyx_v_dist2 = __pyx_f_17triplet_flow_loss_27slow_flow_calculator_cython_dist(__pyx_v_left_features, __pyx_v_right_features, __pyx_v_i, __pyx_v_j, ((int)__pyx_v_best_index_u), __pyx_v_v2, __pyx_v_feature_depth); / "triplet_flow_loss/slow_flow_calculator_cython.pyx":124 * dist1 = dist(left_features, right_features, i, j, <int> best_index_u, v1, feature_depth) * dist2 = dist(left_features, right_features, i, j, <int> best_index_u, v2, feature_depth) * best_index_v = (dist1 + 0.00001) / (dist1 + dist2 + 0.00002) * v2 + (dist2 + 0.00001) / (dist1 + dist2 + 0.00002) * v1 # <<<<<<<<<<<<<< * # if not (v1 <= best_index_v and v2 >= best_index_v): * # printf("i %3i, j, %3i, v1 %2i, v2 %2i, best_index_u %2.1f, dist1 %3.2f,\t dist2 %3.2f,\t best_index_v %3.1lf\n", i, j, v1, v2, best_index_u, dist1, dist2, best_index_v) / __pyx_v_best_index_v = ((((__pyx_v_dist1 + 0.00001) / ((__pyx_v_dist1 + __pyx_v_dist2) + 0.00002)) __pyx_v_v2) + (((__pyx_v_dist2 + 0.00001) / ((__pyx_v_dist1 + __pyx_v_dist2) + 0.00002)) * __pyx_v_v1)); /* "triplet_flow_loss/slow_flow_calculator_cython.pyx":101 * best_index_v = b * * if interpolate_after == 1 and best_index_u != -1: # <<<<<<<<<<<<<< * u1 = <int> best_index_u - 1 * if u1 < 0: / } / "triplet_flow_loss/slow_flow_calculator_cython.pyx":128 * # printf("i %3i, j, %3i, v1 %2i, v2 %2i, best_index_u %2.1f, dist1 %3.2f,\t dist2 %3.2f,\t best_index_v %3.1lf\n", i, j, v1, v2, best_index_u, dist1, dist2, best_index_v) * * if best_index_u != -1: # <<<<<<<<<<<<<< * set_flow_at_point(i, j, best_index_v - j, best_index_u - i, flow_arr) * feature_errors[i, j] = <float> dist(left_features, right_features, i, j, <int> best_index_u, <int> best_index_v, feature_depth) / __pyx_t_11 = ((__pyx_v_best_index_u != -1.0) != 0); if (__pyx_t_11) { / "triplet_flow_loss/slow_flow_calculator_cython.pyx":129 * * if best_index_u != -1: * set_flow_at_point(i, j, best_index_v - j, best_index_u - i, flow_arr) # <<<<<<<<<<<<<< * feature_errors[i, j] = <float> dist(left_features, right_features, i, j, <int> best_index_u, <int> best_index_v, feature_depth) * else: / __pyx_f_17triplet_flow_loss_27slow_flow_calculator_cython_set_flow_at_point(__pyx_v_i, __pyx_v_j, (__pyx_v_best_index_v - __pyx_v_j), (__pyx_v_best_index_u - __pyx_v_i), __pyx_v_flow_arr); 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cdef memoryview memview_slice(memoryview memview, object indices): # <<<<<<<<<<<<<< * cdef int new_ndim = 0, suboffset_dim = -1, dim * cdef bint negative_step / / function exit code / __pyx_L1_error:; __Pyx_XDECREF(__pyx_t_3); __Pyx_XDECREF(__pyx_t_9); __Pyx_AddTraceback("View.MemoryView.memview_slice", __pyx_clineno, __pyx_lineno, __pyx_filename); __pyx_r = 0; __pyx_L0:; __Pyx_XDECREF((PyObject )__pyx_v_memviewsliceobj); __Pyx_XDECREF(__pyx_v_index); __Pyx_XGIVEREF((PyObject )__pyx_r); __Pyx_RefNannyFinishContext(); return __pyx_r; } / "View.MemoryView":793 * * @cname('__pyx_memoryview_slice_memviewslice') * cdef int slice_memviewslice( # <<<<<<<<<<<<<< * __Pyx_memviewslice dst, Py_ssize_t shape, Py_ssize_t stride, Py_ssize_t suboffset, / static int __pyx_memoryview_slice_memviewslice(__Pyx_memviewslice __pyx_v_dst, Py_ssize_t __pyx_v_shape, Py_ssize_t __pyx_v_stride, Py_ssize_t __pyx_v_suboffset, int __pyx_v_dim, int __pyx_v_new_ndim, int __pyx_v_suboffset_dim, Py_ssize_t __pyx_v_start, Py_ssize_t __pyx_v_stop, Py_ssize_t __pyx_v_step, int __pyx_v_have_start, int __pyx_v_have_stop, int __pyx_v_have_step, int __pyx_v_is_slice) { Py_ssize_t __pyx_v_new_shape; int __pyx_v_negative_step; int __pyx_r; int __pyx_t_1; int __pyx_t_2; int __pyx_t_3; / "View.MemoryView":813 * cdef bint negative_step * * if not is_slice: # <<<<<<<<<<<<<< * * if start < 0: / __pyx_t_1 = ((!(__pyx_v_is_slice != 0)) != 0); if (__pyx_t_1) { / "View.MemoryView":815 * if not is_slice: * * if start < 0: # <<<<<<<<<<<<<< * start += shape * if not 0 <= start < shape: / __pyx_t_1 = ((__pyx_v_start < 0) != 0); if (__pyx_t_1) { / "View.MemoryView":816 * * if start < 0: * start += shape # <<<<<<<<<<<<<< * if not 0 <= start < shape: * _err_dim(IndexError, "Index out of bounds (axis %d)", dim) / __pyx_v_start = (__pyx_v_start + __pyx_v_shape); / "View.MemoryView":815 * if not is_slice: * * if start < 0: # <<<<<<<<<<<<<< * start += shape * if not 0 <= start < shape: / } / "View.MemoryView":817 * if start < 0: * start += shape * if not 0 <= start < shape: # <<<<<<<<<<<<<< * _err_dim(IndexError, "Index out of bounds (axis %d)", dim) * else: / __pyx_t_1 = (0 <= __pyx_v_start); if (__pyx_t_1) { __pyx_t_1 = (__pyx_v_start < __pyx_v_shape); } __pyx_t_2 = ((!(__pyx_t_1 != 0)) != 0); if (__pyx_t_2) { / "View.MemoryView":818 * start += shape * if not 0 <= start < shape: * _err_dim(IndexError, "Index out of bounds (axis %d)", dim) # <<<<<<<<<<<<<< * else: * / __pyx_t_3 = __pyx_memoryview_err_dim(__pyx_builtin_IndexError, ((char )"Index out of bounds (axis %d)"), __pyx_v_dim); if (unlikely(__pyx_t_3 == -1)) __PYX_ERR(2, 818, __pyx_L1_error) /* "View.MemoryView":817 * if start < 0: * start += shape * if not 0 <= start < shape: # <<<<<<<<<<<<<< * _err_dim(IndexError, "Index out of bounds (axis %d)", dim) * else: / } / "View.MemoryView":813 * cdef bint negative_step * * if not is_slice: # <<<<<<<<<<<<<< * * if start < 0: / goto __pyx_L3; } / "View.MemoryView":821 * else: * * negative_step = have_step != 0 and step < 0 # <<<<<<<<<<<<<< * * if have_step and step == 0: / /else/ { __pyx_t_1 = ((__pyx_v_have_step != 0) != 0); if (__pyx_t_1) { } else { __pyx_t_2 = __pyx_t_1; goto __pyx_L6_bool_binop_done; } __pyx_t_1 = ((__pyx_v_step < 0) != 0); __pyx_t_2 = __pyx_t_1; __pyx_L6_bool_binop_done:; __pyx_v_negative_step = __pyx_t_2; / "View.MemoryView":823 * negative_step = have_step != 0 and step < 0 * * if have_step and step == 0: # <<<<<<<<<<<<<< * _err_dim(ValueError, "Step may not be zero (axis %d)", dim) * / __pyx_t_1 = (__pyx_v_have_step != 0); if (__pyx_t_1) { } else { __pyx_t_2 = __pyx_t_1; goto __pyx_L9_bool_binop_done; } __pyx_t_1 = ((__pyx_v_step == 0) != 0); __pyx_t_2 = __pyx_t_1; __pyx_L9_bool_binop_done:; if (__pyx_t_2) { / "View.MemoryView":824 * * if have_step and step == 0: * _err_dim(ValueError, "Step may not be zero (axis %d)", dim) # <<<<<<<<<<<<<< * * / __pyx_t_3 = __pyx_memoryview_err_dim(__pyx_builtin_ValueError, ((char )"Step may not be zero (axis %d)"), __pyx_v_dim); if (unlikely(__pyx_t_3 == -1)) __PYX_ERR(2, 824, __pyx_L1_error) /* "View.MemoryView":823 * negative_step = have_step != 0 and step < 0 * * if have_step and step == 0: # <<<<<<<<<<<<<< * _err_dim(ValueError, "Step may not be zero (axis %d)", dim) * / } / "View.MemoryView":827 * * * if have_start: # <<<<<<<<<<<<<< * if start < 0: * start += shape / __pyx_t_2 = (__pyx_v_have_start != 0); if (__pyx_t_2) { / "View.MemoryView":828 * * if have_start: * if start < 0: # <<<<<<<<<<<<<< * start += shape * if start < 0: / __pyx_t_2 = ((__pyx_v_start < 0) != 0); if (__pyx_t_2) { / "View.MemoryView":829 * if have_start: * if start < 0: * start += shape # <<<<<<<<<<<<<< * if start < 0: * start = 0 / __pyx_v_start = (__pyx_v_start + __pyx_v_shape); / "View.MemoryView":830 * if start < 0: * start += shape * if start < 0: # <<<<<<<<<<<<<< * start = 0 * elif start >= shape: / __pyx_t_2 = ((__pyx_v_start < 0) != 0); if (__pyx_t_2) { / "View.MemoryView":831 * start += shape * if start < 0: * start = 0 # <<<<<<<<<<<<<< * elif start >= shape: * if negative_step: / __pyx_v_start = 0; / "View.MemoryView":830 * if start < 0: * start += shape * if start < 0: # <<<<<<<<<<<<<< * start = 0 * elif start >= shape: / } / "View.MemoryView":828 * * if have_start: * if start < 0: # <<<<<<<<<<<<<< * start += shape * if start < 0: / goto __pyx_L12; } / "View.MemoryView":832 * if start < 0: * start = 0 * elif start >= shape: # <<<<<<<<<<<<<< * if negative_step: * start = shape - 1 / __pyx_t_2 = ((__pyx_v_start >= __pyx_v_shape) != 0); if (__pyx_t_2) { / "View.MemoryView":833 * start = 0 * elif start >= shape: * if negative_step: # <<<<<<<<<<<<<< * start = shape - 1 * else: / __pyx_t_2 = (__pyx_v_negative_step != 0); if (__pyx_t_2) { / "View.MemoryView":834 * elif start >= shape: * if negative_step: * start = shape - 1 # <<<<<<<<<<<<<< * else: * start = shape / __pyx_v_start = (__pyx_v_shape - 1); / "View.MemoryView":833 * start = 0 * elif start >= shape: * if negative_step: # <<<<<<<<<<<<<< * start = shape - 1 * else: / goto __pyx_L14; } / "View.MemoryView":836 * start = shape - 1 * else: * start = shape # <<<<<<<<<<<<<< * else: * if negative_step: / /else/ { __pyx_v_start = __pyx_v_shape; } __pyx_L14:; / "View.MemoryView":832 * if start < 0: * start = 0 * elif start >= shape: # <<<<<<<<<<<<<< * if negative_step: * start = shape - 1 / } __pyx_L12:; / "View.MemoryView":827 * * * if have_start: # <<<<<<<<<<<<<< * if start < 0: * start += shape / goto __pyx_L11; } / "View.MemoryView":838 * 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":839 * else: * if negative_step: * start = shape - 1 # <<<<<<<<<<<<<< * else: * start = 0 / __pyx_v_start = (__pyx_v_shape - 1); / "View.MemoryView":838 * start = shape * else: * if negative_step: # <<<<<<<<<<<<<< * start = shape - 1 * else: / goto __pyx_L15; } / "View.MemoryView":841 * start = shape - 1 * else: * start = 0 # <<<<<<<<<<<<<< * * if have_stop: / /else/ { __pyx_v_start = 0; } __pyx_L15:; } __pyx_L11:; / "View.MemoryView":843 * start = 0 * * if have_stop: # <<<<<<<<<<<<<< * if stop < 0: * stop += shape / __pyx_t_2 = (__pyx_v_have_stop != 0); if (__pyx_t_2) { / "View.MemoryView":844 * * if have_stop: * if stop < 0: # <<<<<<<<<<<<<< * stop += shape * if stop < 0: / __pyx_t_2 = ((__pyx_v_stop < 0) != 0); if (__pyx_t_2) { / "View.MemoryView":845 * if have_stop: * if stop < 0: * stop += shape # <<<<<<<<<<<<<< * if stop < 0: * stop = 0 / __pyx_v_stop = (__pyx_v_stop + __pyx_v_shape); / "View.MemoryView":846 * if stop < 0: * stop += shape * if stop < 0: # <<<<<<<<<<<<<< * stop = 0 * elif stop > shape: / __pyx_t_2 = ((__pyx_v_stop < 0) != 0); if (__pyx_t_2) { / "View.MemoryView":847 * stop += shape * if stop < 0: * stop = 0 # <<<<<<<<<<<<<< * elif stop > shape: * stop = shape / __pyx_v_stop = 0; / "View.MemoryView":846 * if stop < 0: * stop += shape * if stop < 0: # <<<<<<<<<<<<<< * stop = 0 * elif stop > shape: / } / "View.MemoryView":844 * * if have_stop: * if stop < 0: # <<<<<<<<<<<<<< * stop += shape * if stop < 0: / goto __pyx_L17; } / "View.MemoryView":848 * if stop < 0: * stop = 0 * elif stop > shape: # <<<<<<<<<<<<<< * stop = shape * else: / __pyx_t_2 = ((__pyx_v_stop > __pyx_v_shape) != 0); if (__pyx_t_2) { / "View.MemoryView":849 * stop = 0 * elif stop > shape: * stop = shape # <<<<<<<<<<<<<< * else: * if negative_step: / __pyx_v_stop = __pyx_v_shape; / "View.MemoryView":848 * if stop < 0: * stop = 0 * elif stop > shape: # <<<<<<<<<<<<<< * stop = shape * else: / } __pyx_L17:; / "View.MemoryView":843 * start = 0 * * if have_stop: # <<<<<<<<<<<<<< * if stop < 0: * stop += shape / goto __pyx_L16; } / "View.MemoryView":851 * stop = shape * else: * if negative_step: # <<<<<<<<<<<<<< * stop = -1 * else: / /else/ { __pyx_t_2 = (__pyx_v_negative_step != 0); if (__pyx_t_2) { / "View.MemoryView":852 * else: * if negative_step: * stop = -1 # <<<<<<<<<<<<<< * else: * stop = shape / __pyx_v_stop = -1L; / "View.MemoryView":851 * stop = shape * else: * if negative_step: # <<<<<<<<<<<<<< * stop = -1 * else: / goto __pyx_L19; } / "View.MemoryView":854 * stop = -1 * else: * stop = shape # <<<<<<<<<<<<<< * * if not have_step: / /else/ { __pyx_v_stop = __pyx_v_shape; } __pyx_L19:; } __pyx_L16:; / "View.MemoryView":856 * stop = shape * * if not have_step: # <<<<<<<<<<<<<< * step = 1 * / __pyx_t_2 = ((!(__pyx_v_have_step != 0)) != 0); if (__pyx_t_2) { / "View.MemoryView":857 * * if not have_step: * step = 1 # <<<<<<<<<<<<<< * * / __pyx_v_step = 1; / "View.MemoryView":856 * stop = shape * * if not have_step: # <<<<<<<<<<<<<< * step = 1 * / } / "View.MemoryView":861 * * with cython.cdivision(True): * new_shape = (stop - start) // step # <<<<<<<<<<<<<< * * if (stop - start) - step * new_shape: / __pyx_v_new_shape = ((__pyx_v_stop - __pyx_v_start) / __pyx_v_step); / "View.MemoryView":863 * new_shape = (stop - start) // step * * if (stop - start) - step * new_shape: # <<<<<<<<<<<<<< * new_shape += 1 * / __pyx_t_2 = (((__pyx_v_stop - __pyx_v_start) - (__pyx_v_step __pyx_v_new_shape)) != 0); if (__pyx_t_2) { /* "View.MemoryView":864 * * if (stop - start) - step * new_shape: * new_shape += 1 # <<<<<<<<<<<<<< * * if new_shape < 0: / __pyx_v_new_shape = (__pyx_v_new_shape + 1); / "View.MemoryView":863 * new_shape = (stop - start) // step * * if (stop - start) - step * new_shape: # <<<<<<<<<<<<<< * new_shape += 1 * / } / "View.MemoryView":866 * new_shape += 1 * * if new_shape < 0: # <<<<<<<<<<<<<< * new_shape = 0 * / __pyx_t_2 = ((__pyx_v_new_shape < 0) != 0); if (__pyx_t_2) { / "View.MemoryView":867 * * if new_shape < 0: * new_shape = 0 # <<<<<<<<<<<<<< * * / __pyx_v_new_shape = 0; / "View.MemoryView":866 * new_shape += 1 * * if new_shape < 0: # <<<<<<<<<<<<<< * new_shape = 0 * / } / "View.MemoryView":870 * * * dst.strides[new_ndim] = stride * step # <<<<<<<<<<<<<< * dst.shape[new_ndim] = new_shape * dst.suboffsets[new_ndim] = suboffset / (__pyx_v_dst->strides[__pyx_v_new_ndim]) = (__pyx_v_stride __pyx_v_step); /* "View.MemoryView":871 * * dst.strides[new_ndim] = stride * step * dst.shape[new_ndim] = new_shape # <<<<<<<<<<<<<< * dst.suboffsets[new_ndim] = suboffset * / (__pyx_v_dst->shape[__pyx_v_new_ndim]) = __pyx_v_new_shape; / "View.MemoryView":872 * dst.strides[new_ndim] = stride * step * dst.shape[new_ndim] = new_shape * dst.suboffsets[new_ndim] = suboffset # <<<<<<<<<<<<<< * * / (__pyx_v_dst->suboffsets[__pyx_v_new_ndim]) = __pyx_v_suboffset; } __pyx_L3:; / "View.MemoryView":875 * * * if suboffset_dim[0] < 0: # <<<<<<<<<<<<<< * dst.data += start * stride * else: / __pyx_t_2 = (((__pyx_v_suboffset_dim[0]) < 0) != 0); if (__pyx_t_2) { / "View.MemoryView":876 * * if suboffset_dim[0] < 0: * dst.data += start * stride # <<<<<<<<<<<<<< * else: * dst.suboffsets[suboffset_dim[0]] += start * stride / __pyx_v_dst->data = (__pyx_v_dst->data + (__pyx_v_start __pyx_v_stride)); /* "View.MemoryView":875 * * * if suboffset_dim[0] < 0: # <<<<<<<<<<<<<< * dst.data += start * stride * else: / goto __pyx_L23; } / "View.MemoryView":878 * dst.data += start * stride * else: * dst.suboffsets[suboffset_dim[0]] += start * stride # <<<<<<<<<<<<<< * * if suboffset >= 0: / /else/ { __pyx_t_3 = (__pyx_v_suboffset_dim[0]); (__pyx_v_dst->suboffsets[__pyx_t_3]) = ((__pyx_v_dst->suboffsets[__pyx_t_3]) + (__pyx_v_start __pyx_v_stride)); } __pyx_L23:; /* "View.MemoryView":880 * dst.suboffsets[suboffset_dim[0]] += start * stride * * if suboffset >= 0: # <<<<<<<<<<<<<< * if not is_slice: * if new_ndim == 0: / __pyx_t_2 = ((__pyx_v_suboffset >= 0) != 0); if (__pyx_t_2) { / "View.MemoryView":881 * * if suboffset >= 0: * if not is_slice: # <<<<<<<<<<<<<< * if new_ndim == 0: * dst.data = (<char *> dst.data)[0] + suboffset / __pyx_t_2 = ((!(__pyx_v_is_slice != 0)) != 0); if (__pyx_t_2) { /* "View.MemoryView":882 * if suboffset >= 0: * if not is_slice: * if new_ndim == 0: # <<<<<<<<<<<<<< * dst.data = (<char *> dst.data)[0] + suboffset 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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":1094 * 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":1093 * * cdef Py_ssize_t abs_py_ssize_t(Py_ssize_t arg) nogil: * if arg < 0: # <<<<<<<<<<<<<< * return -arg * else: / } / "View.MemoryView":1096 * return -arg * else: * return arg # <<<<<<<<<<<<<< * * @cname('__pyx_get_best_slice_order') / /else/ { __pyx_r = __pyx_v_arg; goto __pyx_L0; } / "View.MemoryView":1092 * * * 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":1099 * * @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; /* "View.MemoryView":1104 * """ * cdef int i * cdef Py_ssize_t c_stride = 0 # <<<<<<<<<<<<<< * cdef Py_ssize_t f_stride = 0 * / __pyx_v_c_stride = 0; / "View.MemoryView":1105 * 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":1107 * 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 > -1L; __pyx_t_1-=1) { __pyx_v_i = __pyx_t_1; / "View.MemoryView":1108 * * 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":1109 * 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":1110 * if mslice.shape[i] > 1: * c_stride = mslice.strides[i] * break # <<<<<<<<<<<<<< * * for i in range(ndim): / goto __pyx_L4_break; / "View.MemoryView":1108 * * for i in range(ndim - 1, -1, -1): * if mslice.shape[i] > 1: # <<<<<<<<<<<<<< * c_stride = mslice.strides[i] * break / } } __pyx_L4_break:; / "View.MemoryView":1112 * break * * for i in range(ndim): # <<<<<<<<<<<<<< * if mslice.shape[i] > 1: * f_stride = mslice.strides[i] / __pyx_t_1 = __pyx_v_ndim; for (__pyx_t_3 = 0; __pyx_t_3 < __pyx_t_1; __pyx_t_3+=1) { __pyx_v_i = __pyx_t_3; / "View.MemoryView":1113 * * 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":1114 * 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":1115 * 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":1113 * * for i in range(ndim): * if mslice.shape[i] > 1: # <<<<<<<<<<<<<< * f_stride = mslice.strides[i] * break / } } __pyx_L7_break:; / "View.MemoryView":1117 * 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":1118 * * 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":1117 * break * * if abs_py_ssize_t(c_stride) <= abs_py_ssize_t(f_stride): # <<<<<<<<<<<<<< * return 'C' * else: / } / "View.MemoryView":1120 * return 'C' * else: * return 'F' # <<<<<<<<<<<<<< * * @cython.cdivision(True) / /else/ { __pyx_r = 'F'; goto __pyx_L0; } / "View.MemoryView":1099 * * @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":1123 * * @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; / "View.MemoryView":1130 * * 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":1131 * 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":1132 * 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":1133 * 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":1135 * 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":1136 * * 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":1137 * 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":1136 * * 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":1138 * if (src_stride > 0 and dst_stride > 0 and * <size_t> src_stride == itemsize == <size_t> dst_stride): * 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copy_data_to_temp(&src, &tmp, order, ndim) / __pyx_v_order = __pyx_get_best_slice_order((&__pyx_v_dst), __pyx_v_ndim); / "View.MemoryView":1288 * if slices_overlap(&src, &dst, ndim, itemsize): * * if not slice_is_contig(src, order, ndim): # <<<<<<<<<<<<<< * order = get_best_order(&dst, ndim) * / } / "View.MemoryView":1291 * order = get_best_order(&dst, ndim) * * tmpdata = copy_data_to_temp(&src, &tmp, order, ndim) # <<<<<<<<<<<<<< * src = tmp * / __pyx_t_6 = __pyx_memoryview_copy_data_to_temp((&__pyx_v_src), (&__pyx_v_tmp), __pyx_v_order, __pyx_v_ndim); if (unlikely(__pyx_t_6 == NULL)) __PYX_ERR(2, 1291, __pyx_L1_error) __pyx_v_tmpdata = __pyx_t_6; / "View.MemoryView":1292 * * tmpdata = copy_data_to_temp(&src, &tmp, order, ndim) * src = tmp # <<<<<<<<<<<<<< * * if not broadcasting: / __pyx_v_src = __pyx_v_tmp; / "View.MemoryView":1286 * _err_dim(ValueError, "Dimension %d is not direct", i) * * if slices_overlap(&src, &dst, ndim, itemsize): # <<<<<<<<<<<<<< * * if not slice_is_contig(src, order, ndim): / } / "View.MemoryView":1294 * src = tmp * * if not broadcasting: # <<<<<<<<<<<<<< * * / __pyx_t_2 = ((!(__pyx_v_broadcasting != 0)) != 0); if (__pyx_t_2) { / "View.MemoryView":1297 * * * if slice_is_contig(src, 'C', ndim): # <<<<<<<<<<<<<< * direct_copy = slice_is_contig(dst, 'C', ndim) * elif slice_is_contig(src, 'F', ndim): / __pyx_t_2 = (__pyx_memviewslice_is_contig(__pyx_v_src, 'C', __pyx_v_ndim) != 0); if (__pyx_t_2) { / "View.MemoryView":1298 * * if slice_is_contig(src, 'C', ndim): * direct_copy = slice_is_contig(dst, 'C', ndim) # <<<<<<<<<<<<<< * elif slice_is_contig(src, 'F', ndim): * direct_copy = slice_is_contig(dst, 'F', ndim) / __pyx_v_direct_copy = __pyx_memviewslice_is_contig(__pyx_v_dst, 'C', __pyx_v_ndim); / "View.MemoryView":1297 * * * if slice_is_contig(src, 'C', ndim): # <<<<<<<<<<<<<< * direct_copy = slice_is_contig(dst, 'C', ndim) * elif slice_is_contig(src, 'F', ndim): / goto __pyx_L12; } / "View.MemoryView":1299 * if slice_is_contig(src, 'C', ndim): * direct_copy = slice_is_contig(dst, 'C', ndim) * elif slice_is_contig(src, 'F', ndim): # <<<<<<<<<<<<<< * direct_copy = slice_is_contig(dst, 'F', ndim) * / __pyx_t_2 = (__pyx_memviewslice_is_contig(__pyx_v_src, 'F', __pyx_v_ndim) != 0); if (__pyx_t_2) { / "View.MemoryView":1300 * direct_copy = slice_is_contig(dst, 'C', ndim) * elif slice_is_contig(src, 'F', ndim): * direct_copy = slice_is_contig(dst, 'F', ndim) # <<<<<<<<<<<<<< * * if direct_copy: / __pyx_v_direct_copy = __pyx_memviewslice_is_contig(__pyx_v_dst, 'F', __pyx_v_ndim); / "View.MemoryView":1299 * if slice_is_contig(src, 'C', ndim): * direct_copy = slice_is_contig(dst, 'C', ndim) * elif slice_is_contig(src, 'F', ndim): # <<<<<<<<<<<<<< * direct_copy = slice_is_contig(dst, 'F', ndim) * / } __pyx_L12:; / "View.MemoryView":1302 * direct_copy = slice_is_contig(dst, 'F', ndim) * * if direct_copy: # <<<<<<<<<<<<<< * * refcount_copying(&dst, dtype_is_object, ndim, False) / __pyx_t_2 = (__pyx_v_direct_copy != 0); if (__pyx_t_2) { / "View.MemoryView":1304 * if direct_copy: * * refcount_copying(&dst, dtype_is_object, ndim, False) # <<<<<<<<<<<<<< * memcpy(dst.data, src.data, slice_get_size(&src, ndim)) * refcount_copying(&dst, dtype_is_object, ndim, True) / __pyx_memoryview_refcount_copying((&__pyx_v_dst), __pyx_v_dtype_is_object, __pyx_v_ndim, 0); / "View.MemoryView":1305 * * refcount_copying(&dst, dtype_is_object, ndim, False) * memcpy(dst.data, src.data, slice_get_size(&src, ndim)) # <<<<<<<<<<<<<< * refcount_copying(&dst, dtype_is_object, ndim, True) * free(tmpdata) / memcpy(__pyx_v_dst.data, __pyx_v_src.data, __pyx_memoryview_slice_get_size((&__pyx_v_src), __pyx_v_ndim)); / "View.MemoryView":1306 * refcount_copying(&dst, dtype_is_object, ndim, False) * memcpy(dst.data, src.data, slice_get_size(&src, ndim)) * refcount_copying(&dst, dtype_is_object, ndim, True) # <<<<<<<<<<<<<< * free(tmpdata) * return 0 / __pyx_memoryview_refcount_copying((&__pyx_v_dst), __pyx_v_dtype_is_object, __pyx_v_ndim, 1); / "View.MemoryView":1307 * memcpy(dst.data, src.data, slice_get_size(&src, ndim)) * refcount_copying(&dst, dtype_is_object, ndim, True) * free(tmpdata) # <<<<<<<<<<<<<< * return 0 * / free(__pyx_v_tmpdata); / "View.MemoryView":1308 * refcount_copying(&dst, dtype_is_object, ndim, True) * free(tmpdata) * return 0 # <<<<<<<<<<<<<< * * if order == 'F' == get_best_order(&dst, ndim): / __pyx_r = 0; goto __pyx_L0; / "View.MemoryView":1302 * direct_copy = slice_is_contig(dst, 'F', ndim) * * if direct_copy: # <<<<<<<<<<<<<< * * refcount_copying(&dst, dtype_is_object, ndim, False) / } / "View.MemoryView":1294 * src = tmp * * if not broadcasting: # <<<<<<<<<<<<<< * * / } / "View.MemoryView":1310 * return 0 * * if order == 'F' == get_best_order(&dst, ndim): # <<<<<<<<<<<<<< * * / __pyx_t_2 = (__pyx_v_order == 'F'); if (__pyx_t_2) { __pyx_t_2 = ('F' == __pyx_get_best_slice_order((&__pyx_v_dst), __pyx_v_ndim)); } __pyx_t_7 = (__pyx_t_2 != 0); if (__pyx_t_7) { / "View.MemoryView":1313 * * * transpose_memslice(&src) # <<<<<<<<<<<<<< * transpose_memslice(&dst) * / __pyx_t_5 = __pyx_memslice_transpose((&__pyx_v_src)); if (unlikely(__pyx_t_5 == 0)) __PYX_ERR(2, 1313, __pyx_L1_error) / "View.MemoryView":1314 * * transpose_memslice(&src) * transpose_memslice(&dst) # <<<<<<<<<<<<<< * * refcount_copying(&dst, dtype_is_object, ndim, False) / __pyx_t_5 = __pyx_memslice_transpose((&__pyx_v_dst)); if (unlikely(__pyx_t_5 == 0)) __PYX_ERR(2, 1314, __pyx_L1_error) / "View.MemoryView":1310 * return 0 * * if order == 'F' == get_best_order(&dst, ndim): # <<<<<<<<<<<<<< * * / } / "View.MemoryView":1316 * transpose_memslice(&dst) * * refcount_copying(&dst, dtype_is_object, ndim, False) # <<<<<<<<<<<<<< * copy_strided_to_strided(&src, &dst, ndim, itemsize) * refcount_copying(&dst, dtype_is_object, ndim, True) / __pyx_memoryview_refcount_copying((&__pyx_v_dst), __pyx_v_dtype_is_object, __pyx_v_ndim, 0); / "View.MemoryView":1317 * * refcount_copying(&dst, 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_slice_assign_scalar(dst.data, dst.shape, dst.strides, ndim, * itemsize, item) * refcount_copying(dst, dtype_is_object, ndim, True) # <<<<<<<<<<<<<< * * / __pyx_memoryview_refcount_copying(__pyx_v_dst, __pyx_v_dtype_is_object, __pyx_v_ndim, 1); / "View.MemoryView":1381 * * @cname('__pyx_memoryview_slice_assign_scalar') * cdef void slice_assign_scalar(__Pyx_memviewslice dst, int ndim, # <<<<<<<<<<<<<< size_t itemsize, void item, bint dtype_is_object) nogil: / / function exit code / } / "View.MemoryView":1391 * * @cname('__pyx_memoryview__slice_assign_scalar') * cdef void _slice_assign_scalar(char data, Py_ssize_t shape, # <<<<<<<<<<<<<< * Py_ssize_t strides, int ndim, size_t itemsize, void item) nogil: / static void __pyx_memoryview__slice_assign_scalar(char __pyx_v_data, Py_ssize_t __pyx_v_shape, Py_ssize_t __pyx_v_strides, int __pyx_v_ndim, size_t __pyx_v_itemsize, void __pyx_v_item) { CYTHON_UNUSED Py_ssize_t __pyx_v_i; Py_ssize_t __pyx_v_stride; Py_ssize_t __pyx_v_extent; int __pyx_t_1; Py_ssize_t __pyx_t_2; Py_ssize_t __pyx_t_3; /* "View.MemoryView":1395 * size_t itemsize, void item) nogil: cdef Py_ssize_t i * cdef Py_ssize_t stride = strides[0] # <<<<<<<<<<<<<< * cdef Py_ssize_t extent = shape[0] * / __pyx_v_stride = (__pyx_v_strides[0]); / "View.MemoryView":1396 * cdef Py_ssize_t i * cdef Py_ssize_t stride = strides[0] * cdef Py_ssize_t extent = shape[0] # <<<<<<<<<<<<<< * * if ndim == 1: / __pyx_v_extent = (__pyx_v_shape[0]); / "View.MemoryView":1398 * cdef Py_ssize_t extent = shape[0] * * if ndim == 1: # <<<<<<<<<<<<<< * for i in range(extent): * memcpy(data, item, itemsize) / __pyx_t_1 = ((__pyx_v_ndim == 1) != 0); if (__pyx_t_1) { / "View.MemoryView":1399 * * if ndim == 1: * for i in range(extent): # <<<<<<<<<<<<<< * memcpy(data, item, itemsize) * data += stride / __pyx_t_2 = __pyx_v_extent; for (__pyx_t_3 = 0; __pyx_t_3 < __pyx_t_2; __pyx_t_3+=1) { __pyx_v_i = __pyx_t_3; / "View.MemoryView":1400 * if ndim == 1: * for i in range(extent): * memcpy(data, item, itemsize) # <<<<<<<<<<<<<< * data += stride * else: / memcpy(__pyx_v_data, __pyx_v_item, __pyx_v_itemsize); / "View.MemoryView":1401 * for i in range(extent): * memcpy(data, item, itemsize) * data += stride # <<<<<<<<<<<<<< * else: * for i in range(extent): / __pyx_v_data = (__pyx_v_data + __pyx_v_stride); } / "View.MemoryView":1398 * cdef Py_ssize_t extent = shape[0] * * if ndim == 1: # <<<<<<<<<<<<<< * for i in range(extent): * memcpy(data, item, itemsize) / goto __pyx_L3; } / "View.MemoryView":1403 * data += stride * else: * for i in range(extent): # <<<<<<<<<<<<<< * _slice_assign_scalar(data, shape + 1, strides + 1, * ndim - 1, itemsize, item) / /else/ { __pyx_t_2 = __pyx_v_extent; for (__pyx_t_3 = 0; __pyx_t_3 < __pyx_t_2; __pyx_t_3+=1) { __pyx_v_i = __pyx_t_3; / "View.MemoryView":1404 * else: * for i in range(extent): * _slice_assign_scalar(data, shape + 1, strides + 1, # <<<<<<<<<<<<<< * ndim - 1, itemsize, item) * data += stride / __pyx_memoryview__slice_assign_scalar(__pyx_v_data, (__pyx_v_shape + 1), (__pyx_v_strides + 1), (__pyx_v_ndim - 1), __pyx_v_itemsize, __pyx_v_item); / "View.MemoryView":1406 * _slice_assign_scalar(data, shape + 1, strides + 1, * ndim - 1, itemsize, item) * data += stride # <<<<<<<<<<<<<< * * / __pyx_v_data = (__pyx_v_data + __pyx_v_stride); } } __pyx_L3:; / "View.MemoryView":1391 * * @cname('__pyx_memoryview__slice_assign_scalar') * cdef void _slice_assign_scalar(char data, Py_ssize_t shape, # <<<<<<<<<<<<<< * Py_ssize_t strides, int ndim, size_t itemsize, void item) nogil: / /* function exit code / } static struct __pyx_vtabstruct_array __pyx_vtable_array; static PyObject __pyx_tp_new_array(PyTypeObject t, PyObject a, PyObject k) { struct __pyx_array_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_array_obj )o); p->__pyx_vtab = __pyx_vtabptr_array; p->mode = ((PyObject)Py_None); Py_INCREF(Py_None); p->_format = ((PyObject)Py_None); Py_INCREF(Py_None); if (unlikely(__pyx_array___cinit__(o, a, k) < 0)) goto bad; return o; bad: Py_DECREF(o); o = 0; return NULL; } static void __pyx_tp_dealloc_array(PyObject o) { struct __pyx_array_obj p = (struct __pyx_array_obj )o; #if PY_VERSION_HEX >= 0x030400a1 if (unlikely(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); ++Py_REFCNT(o); __pyx_array___dealloc__(o); --Py_REFCNT(o); 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 = 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}, {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 = { 0, /sq_length/ 0, /sq_concat/ 0, /sq_repeat/ __pyx_sq_item_array, /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_array = { 0, /mp_length/ __pyx_array___getitem__, /mp_subscript/ __pyx_mp_ass_subscript_array, /mp_ass_subscript/ }; static PyBufferProcs __pyx_tp_as_buffer_array = { #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_array_getbuffer, /bf_getbuffer/ 0, /bf_releasebuffer/ }; static PyTypeObject __pyx_type___pyx_array = { PyVarObject_HEAD_INIT(0, 0) "triplet_flow_loss.slow_flow_calculator_cython.array", /tp_name/ sizeof(struct __pyx_array_obj), /tp_basicsize/ 0, /tp_itemsize/ __pyx_tp_dealloc_array, /tp_dealloc/ 0, /tp_print/ 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 }; 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 PY_VERSION_HEX >= 0x030400a1 if (unlikely(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[] = { {0, 0, 0, 0} }; static PyTypeObject __pyx_type___pyx_MemviewEnum = { PyVarObject_HEAD_INIT(0, 0) "triplet_flow_loss.slow_flow_calculator_cython.Enum", /tp_name/ sizeof(struct __pyx_MemviewEnum_obj), /tp_basicsize/ 0, /tp_itemsize/ __pyx_tp_dealloc_Enum, /tp_dealloc/ 0, /tp_print/ 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 }; 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 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__Pyx_PyObject_GetAttrStr(__pyx_b, name); if (unlikely(!result)) { PyErr_Format(PyExc_NameError, #if PY_MAJOR_VERSION >= 3 "name '%U' is not defined", name); #else "name '%.200s' is not defined", PyString_AS_STRING(name)); #endif } return result; } /* RaiseArgTupleInvalid / static void __Pyx_RaiseArgtupleInvalid( const char func_name, int exact, Py_ssize_t num_min, Py_ssize_t num_max, Py_ssize_t num_found) { Py_ssize_t num_expected; const char more_or_less; if (num_found < num_min) { num_expected = num_min; more_or_less = "at least"; } else { num_expected = num_max; more_or_less = "at most"; } if (exact) { more_or_less = "exactly"; } PyErr_Format(PyExc_TypeError, "%.200s() takes %.8s %" CYTHON_FORMAT_SSIZE_T "d positional argument%.1s (%" CYTHON_FORMAT_SSIZE_T "d given)", func_name, more_or_less, num_expected, (num_expected == 1) ? 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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 (PyUnicode_GET_SIZE(name) != PyUnicode_GET_SIZE(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 (PyUnicode_GET_SIZE(argname) != PyUnicode_GET_SIZE(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; } /* GetModuleGlobalName / static CYTHON_INLINE PyObject __Pyx_GetModuleGlobalName(PyObject name) { PyObject result; #if !CYTHON_AVOID_BORROWED_REFS result = PyDict_GetItem(__pyx_d, name); if (likely(result)) { Py_INCREF(result); } else { #else result = PyObject_GetItem(__pyx_d, name); if (!result) { PyErr_Clear(); #endif result = __Pyx_GetBuiltinName(name); } return result; } /* GetItemInt / static CYTHON_INLINE 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 if (wraparound & unlikely(i < 0)) i += PyList_GET_SIZE(o); if ((!boundscheck) \|\| likely((0 <= i) & (i < PyList_GET_SIZE(o)))) { PyObject r = PyList_GET_ITEM(o, 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 if (wraparound & unlikely(i < 0)) i += PyTuple_GET_SIZE(o); if ((!boundscheck) \|\| likely((0 <= i) & (i < PyTuple_GET_SIZE(o)))) { PyObject r = PyTuple_GET_ITEM(o, 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((n >= 0) & (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((n >= 0) & (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)); } /* PyObjectCall / #if CYTHON_COMPILING_IN_CPYTHON static CYTHON_INLINE PyObject __Pyx_PyObject_Call(PyObject func, PyObject arg, PyObject kw) { PyObject result; ternaryfunc call = func->ob_type->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 /* SliceObject / static CYTHON_INLINE PyObject __Pyx_PyObject_GetSlice(PyObject* obj, Py_ssize_t cstart, Py_ssize_t cstop, PyObject _py_start, PyObject _py_stop, PyObject** _py_slice, int has_cstart, int has_cstop, CYTHON_UNUSED int wraparound) { #if CYTHON_USE_TYPE_SLOTS PyMappingMethods* mp; #if PY_MAJOR_VERSION < 3 PySequenceMethods* ms = Py_TYPE(obj)->tp_as_sequence; if (likely(ms && ms->sq_slice)) { if (!has_cstart) { if (_py_start && (_py_start != Py_None)) { cstart = __Pyx_PyIndex_AsSsize_t(_py_start); if ((cstart == (Py_ssize_t)-1) && PyErr_Occurred()) goto bad; } else cstart = 0; } if (!has_cstop) { if (_py_stop && (_py_stop != Py_None)) { cstop = __Pyx_PyIndex_AsSsize_t(_py_stop); if ((cstop == (Py_ssize_t)-1) && PyErr_Occurred()) goto bad; } else cstop = PY_SSIZE_T_MAX; } if (wraparound && unlikely((cstart < 0) \| (cstop < 0)) && likely(ms->sq_length)) { Py_ssize_t l = ms->sq_length(obj); if (likely(l >= 0)) { if (cstop < 0) { cstop += l; if (cstop < 0) cstop = 0; } if (cstart < 0) { cstart += l; if (cstart < 0) cstart = 0; } } else { if (!PyErr_ExceptionMatches(PyExc_OverflowError)) goto bad; PyErr_Clear(); } } return ms->sq_slice(obj, cstart, cstop); } #endif mp = Py_TYPE(obj)->tp_as_mapping; if (likely(mp && mp->mp_subscript)) #endif { PyObject* result; PyObject py_slice, py_start, py_stop; if (_py_slice) { py_slice = _py_slice; } else { PyObject* owned_start = NULL; PyObject* owned_stop = NULL; if (_py_start) { py_start = _py_start; } else { if (has_cstart) { owned_start = py_start = PyInt_FromSsize_t(cstart); if (unlikely(!py_start)) goto bad; } else py_start = Py_None; } if (_py_stop) { py_stop = _py_stop; } else { if (has_cstop) { owned_stop = py_stop = PyInt_FromSsize_t(cstop); if (unlikely(!py_stop)) { Py_XDECREF(owned_start); goto bad; } } else py_stop = Py_None; } py_slice = PySlice_New(py_start, py_stop, Py_None); Py_XDECREF(owned_start); Py_XDECREF(owned_stop); if (unlikely(!py_slice)) goto bad; } #if CYTHON_USE_TYPE_SLOTS result = mp->mp_subscript(obj, py_slice); #else result = PyObject_GetItem(obj, py_slice); #endif if (!_py_slice) { Py_DECREF(py_slice); } return result; } PyErr_Format(PyExc_TypeError, "'%.200s' object is unsliceable", Py_TYPE(obj)->tp_name); bad: return NULL; } /* PyFunctionFastCall / #if CYTHON_FAST_PYCALL #include "frameobject.h" static PyObject __Pyx_PyFunction_FastCallNoKw(PyCodeObject co, PyObject args, Py_ssize_t na, PyObject globals) { PyFrameObject f; PyThreadState tstate = PyThreadState_GET(); 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 = f->f_localsplus; 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, int 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, nargs, k, (int)nk, d, (int)nd, kwdefs, closure); #else result = PyEval_EvalCodeEx(co, globals, (PyObject )NULL, args, nargs, k, (int)nk, d, (int)nd, closure); #endif Py_XDECREF(kwtuple); done: Py_LeaveRecursiveCall(); return result; } #endif // CPython < 3.6 #endif // CYTHON_FAST_PYCALL / 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); assert(PyCFunction_Check(func)); assert(METH_FASTCALL == (PyCFunction_GET_FLAGS(func) & ~(METH_CLASS \| METH_STATIC \| METH_COEXIST))); 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()); return (((__Pyx_PyCFunctionFast)meth)) (self, args, nargs, NULL); } #endif // CYTHON_FAST_PYCCALL /* 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 #ifdef __Pyx_CyFunction_USED if (likely(PyCFunction_Check(func) \|\| PyObject_TypeCheck(func, __pyx_CyFunctionType))) { #else if (likely(PyCFunction_Check(func))) { #endif if (likely(PyCFunction_GET_FLAGS(func) & METH_O)) { return __Pyx_PyObject_CallMethO(func, arg); #if CYTHON_FAST_PYCCALL } else if (PyCFunction_GET_FLAGS(func) & METH_FASTCALL) { 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 /* 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(PyObject_TypeCheck(obj, type))) return 1; PyErr_Format(PyExc_TypeError, "Cannot convert %.200s to %.200s", Py_TYPE(obj)->tp_name, type->tp_name); return 0; } / BufferFormatCheck / static CYTHON_INLINE int __Pyx_IsLittleEndian(void) { unsigned int n = 1; return (unsigned char)(&n) != 0; } 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 '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 '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 '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 CYTHON_INLINE PyObject * __pyx_buffmt_parse_array(__Pyx_BufFmt_Context* ctx, const char** tsp) { const char ts = tsp; int i = 0, number; int ndim = ctx->head->field->type->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; 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_IsLittleEndian()) { PyErr_SetString(PyExc_ValueError, "Little-endian buffer not supported on big-endian compiler"); return NULL; } ctx->new_packmode = '='; ++ts; break; case '>': case '!': if (__Pyx_IsLittleEndian()) { 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; } 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->enc_count += ctx->new_count; ctx->new_count = 1; got_Z = 0; ++ts; break; } 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; } } } } static CYTHON_INLINE void __Pyx_ZeroBuffer(Py_buffer buf) { buf->buf = NULL; buf->obj = NULL; buf->strides = __Pyx_zeros; buf->shape = __Pyx_zeros; buf->suboffsets = __Pyx_minusones; } static CYTHON_INLINE int __Pyx_GetBufferAndValidate( Py_buffer* buf, PyObject* obj, __Pyx_TypeInfo* dtype, int flags, int nd, int cast, __Pyx_BufFmt_StackElem* stack) { if (obj == Py_None \|\| obj == NULL) { __Pyx_ZeroBuffer(buf); return 0; } buf->buf = NULL; if (__Pyx_GetBuffer(obj, buf, flags) == -1) goto fail; if (buf->ndim != nd) { PyErr_Format(PyExc_ValueError, "Buffer has wrong number of dimensions (expected %d, got %d)", nd, buf->ndim); goto fail; } if (!cast) { __Pyx_BufFmt_Context ctx; __Pyx_BufFmt_Init(&ctx, stack, dtype); if (!__Pyx_BufFmt_CheckString(&ctx, buf->format)) goto fail; } if ((unsigned)buf->itemsize != dtype->size) { PyErr_Format(PyExc_ValueError, "Item size of buffer (%" CYTHON_FORMAT_SSIZE_T "d byte%s) does not match size of '%s' (%" CYTHON_FORMAT_SSIZE_T "d byte%s)", buf->itemsize, (buf->itemsize > 1) ? "s" : "", dtype->name, (Py_ssize_t)dtype->size, (dtype->size > 1) ? "s" : ""); goto fail; } if (buf->suboffsets == NULL) buf->suboffsets = __Pyx_minusones; return 0; fail:; __Pyx_ZeroBuffer(buf); return -1; } static CYTHON_INLINE void __Pyx_SafeReleaseBuffer(Py_buffer* info) { if (info->buf == NULL) return; if (info->suboffsets == __Pyx_minusones) info->suboffsets = NULL; __Pyx_ReleaseBuffer(info); } /* 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 (!buf) { PyErr_SetString(PyExc_ValueError, "buf is NULL."); goto fail; } else if (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; } static CYTHON_INLINE void __pyx_fatalerror(const char fmt, ...) { va_list vargs; char msg[200]; #ifdef HAVE_STDARG_PROTOTYPES va_start(vargs, fmt); #else va_start(vargs); #endif vsnprintf(msg, 200, fmt, vargs); Py_FatalError(msg); va_end(vargs); } 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 (!memview \|\| (PyObject ) memview == Py_None) return; if (__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 (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 (!memview ) { return; } else if ((PyObject ) memview == Py_None) { memslice->memview = NULL; return; } if (__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 (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; } } / 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 PY_VERSION_HEX >= 0x03030000 if (cause) { #else if (cause && cause != Py_None) { #endif 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 = PyThreadState_GET(); 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 /* 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"); } / SaveResetException / #if CYTHON_FAST_THREAD_STATE static CYTHON_INLINE void __Pyx__ExceptionSave(PyThreadState tstate, PyObject type, PyObject value, PyObject *tb) { type = tstate->exc_type; value = tstate->exc_value; tb = tstate->exc_traceback; 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; 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; Py_XDECREF(tmp_type); Py_XDECREF(tmp_value); Py_XDECREF(tmp_tb); } #endif /* PyErrExceptionMatches / #if CYTHON_FAST_THREAD_STATE 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; return PyErr_GivenExceptionMatches(exc_type, err); } #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 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; 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; } /* ArgTypeTest / static void __Pyx_RaiseArgumentTypeInvalid(const char name, PyObject obj, PyTypeObject type) { PyErr_Format(PyExc_TypeError, "Argument '%.200s' has incorrect type (expected %.200s, got %.200s)", name, type->tp_name, Py_TYPE(obj)->tp_name); } static CYTHON_INLINE int __Pyx_ArgTypeTest(PyObject obj, PyTypeObject type, int none_allowed, const char name, int exact) { if (unlikely(!type)) { PyErr_SetString(PyExc_SystemError, "Missing type object"); return 0; } if (none_allowed && obj == Py_None) return 1; else if (exact) { if (likely(Py_TYPE(obj) == type)) return 1; #if PY_MAJOR_VERSION == 2 else if ((type == &PyBaseString_Type) && likely(__Pyx_PyBaseString_CheckExact(obj))) return 1; #endif } else { if (likely(PyObject_TypeCheck(obj, type))) return 1; } __Pyx_RaiseArgumentTypeInvalid(name, obj, type); return 0; } / 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 = 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; } 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_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 } /* GetAttr / static CYTHON_INLINE PyObject __Pyx_GetAttr(PyObject o, PyObject n) { #if CYTHON_COMPILING_IN_CPYTHON #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); } /* 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; } length = stop - start; if (unlikely(length <= 0)) return PyUnicode_FromUnicode(NULL, 0); cstring += start; if (decode_func) { return decode_func(cstring, length, errors); } else { return PyUnicode_Decode(cstring, length, encoding, errors); } } / 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; 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; 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_VERSION_HEX < 0x03030000 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 (strchr(__Pyx_MODULE_NAME, '.')) { #if PY_VERSION_HEX < 0x03030000 PyObject py_level = PyInt_FromLong(1); if (!py_level) goto bad; module = PyObject_CallFunctionObjArgs(py_import, name, global_dict, empty_dict, list, py_level, NULL); Py_DECREF(py_level); #else module = PyImport_ImportModuleLevelObject( name, global_dict, empty_dict, list, 1); #endif if (!module) { if (!PyErr_ExceptionMatches(PyExc_ImportError)) goto bad; PyErr_Clear(); } } level = 0; } #endif if (!module) { #if PY_VERSION_HEX < 0x03030000 PyObject py_level = PyInt_FromLong(level); if (!py_level) goto bad; module = PyObject_CallFunctionObjArgs(py_import, name, global_dict, empty_dict, list, py_level, NULL); Py_DECREF(py_level); #else module = PyImport_ImportModuleLevelObject( name, global_dict, empty_dict, list, level); #endif } } bad: #if PY_VERSION_HEX < 0x03030000 Py_XDECREF(py_import); #endif Py_XDECREF(empty_list); Py_XDECREF(empty_dict); return module; } /* PyIntBinop / #if !CYTHON_COMPILING_IN_PYPY static PyObject __Pyx_PyInt_AddObjC(PyObject op1, PyObject op2, CYTHON_UNUSED long intval, CYTHON_UNUSED int inplace) { #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 } 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 } 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 } 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 } 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 } 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 } 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); } /* WriteUnraisableException / static void __Pyx_WriteUnraisable(const char name, CYTHON_UNUSED int clineno, CYTHON_UNUSED int lineno, CYTHON_UNUSED const char filename, int full_traceback, CYTHON_UNUSED int nogil) { PyObject old_exc, old_val, old_tb; PyObject ctx; __Pyx_PyThreadState_declare #ifdef WITH_THREAD PyGILState_STATE state; if (nogil) state = PyGILState_Ensure(); #ifdef _MSC_VER else state = (PyGILState_STATE)-1; #endif #endif __Pyx_PyThreadState_assign __Pyx_ErrFetch(&old_exc, &old_val, &old_tb); if (full_traceback) { Py_XINCREF(old_exc); Py_XINCREF(old_val); Py_XINCREF(old_tb); __Pyx_ErrRestore(old_exc, old_val, old_tb); PyErr_PrintEx(1); } #if PY_MAJOR_VERSION < 3 ctx = PyString_FromString(name); #else ctx = PyUnicode_FromString(name); #endif __Pyx_ErrRestore(old_exc, old_val, old_tb); if (!ctx) { PyErr_WriteUnraisable(Py_None); } else { PyErr_WriteUnraisable(ctx); Py_DECREF(ctx); } #ifdef WITH_THREAD if (nogil) PyGILState_Release(state); #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; } / 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_maxsizeof(__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 = 0; PyObject py_srcfile = 0; PyObject py_funcname = 0; #if PY_MAJOR_VERSION < 3 py_srcfile = PyString_FromString(filename); #else py_srcfile = PyUnicode_FromString(filename); #endif if (!py_srcfile) goto bad; if (c_line) { #if PY_MAJOR_VERSION < 3 py_funcname = PyString_FromFormat( "%s (%s:%d)", funcname, __pyx_cfilenm, c_line); #else py_funcname = PyUnicode_FromFormat( "%s (%s:%d)", funcname, __pyx_cfilenm, c_line); #endif } else { #if PY_MAJOR_VERSION < 3 py_funcname = PyString_FromString(funcname); #else py_funcname = PyUnicode_FromString(funcname); #endif } if (!py_funcname) goto bad; 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); Py_DECREF(py_funcname); return py_code; bad: Py_XDECREF(py_srcfile); Py_XDECREF(py_funcname); 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; 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( PyThreadState_GET(), /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 (PyObject_TypeCheck(obj, __pyx_ptype_5numpy_ndarray)) return __pyx_pw_5numpy_7ndarray_1__getbuffer__(obj, view, flags); if (PyObject_TypeCheck(obj, __pyx_array_type)) return __pyx_array_getbuffer(obj, view, flags); if (PyObject_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 (PyObject_TypeCheck(obj, __pyx_ptype_5numpy_ndarray)) { __pyx_pw_5numpy_7ndarray_3__releasebuffer__(obj, view); return; } Py_DECREF(obj); view->obj = NULL; } #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; } / CIntToPy / static CYTHON_INLINE PyObject __Pyx_PyInt_From_long(long value) { const long neg_one = (long) -1, const_zero = (long) 0; 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); } } /* 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;\ } / CIntToPy / static CYTHON_INLINE PyObject __Pyx_PyInt_From_int(int value) { const int neg_one = (int) -1, const_zero = (int) 0; 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); } } /* MemviewDtypeToObject / static CYTHON_INLINE PyObject __pyx_memview_get_float(const char itemp) { return (PyObject ) PyFloat_FromDouble((float ) itemp); } static CYTHON_INLINE int __pyx_memview_set_float(const char itemp, PyObject obj) { float value = __pyx_PyFloat_AsFloat(obj); if ((value == (float)-1) && PyErr_Occurred()) return 0; (float ) itemp = value; return 1; } /* Declarations / #if CYTHON_CCOMPLEX #ifdef __cplusplus static CYTHON_INLINE __pyx_t_float_complex __pyx_t_float_complex_from_parts(float x, float y) { return ::std::complex< float >(x, y); } #else static CYTHON_INLINE __pyx_t_float_complex __pyx_t_float_complex_from_parts(float x, float y) { return x + y(__pyx_t_float_complex)_Complex_I; } #endif #else static CYTHON_INLINE __pyx_t_float_complex __pyx_t_float_complex_from_parts(float x, float y) { __pyx_t_float_complex z; z.real = x; z.imag = y; return z; } #endif /* Arithmetic / #if CYTHON_CCOMPLEX #else static CYTHON_INLINE int __Pyx_c_eq_float(__pyx_t_float_complex a, __pyx_t_float_complex b) { return (a.real == b.real) && (a.imag == b.imag); } static CYTHON_INLINE __pyx_t_float_complex __Pyx_c_sum_float(__pyx_t_float_complex a, __pyx_t_float_complex b) { __pyx_t_float_complex z; z.real = a.real + b.real; z.imag = a.imag + b.imag; return z; } static CYTHON_INLINE __pyx_t_float_complex __Pyx_c_diff_float(__pyx_t_float_complex a, __pyx_t_float_complex b) { __pyx_t_float_complex z; z.real = a.real - b.real; z.imag = a.imag - b.imag; return z; } static CYTHON_INLINE __pyx_t_float_complex __Pyx_c_prod_float(__pyx_t_float_complex a, __pyx_t_float_complex b) { __pyx_t_float_complex z; z.real = a.real b.real - a.imag * b.imag; z.imag = a.real * b.imag + a.imag * b.real; return z; } #if 1 static CYTHON_INLINE __pyx_t_float_complex __Pyx_c_quot_float(__pyx_t_float_complex a, __pyx_t_float_complex b) { if (b.imag == 0) { return __pyx_t_float_complex_from_parts(a.real / b.real, a.imag / b.real); } else if (fabsf(b.real) >= fabsf(b.imag)) { if (b.real == 0 && b.imag == 0) { return __pyx_t_float_complex_from_parts(a.real / b.real, a.imag / b.imag); } else { float r = b.imag / b.real; float s = 1.0 / (b.real + b.imag * r); return __pyx_t_float_complex_from_parts( (a.real + a.imag * r) * s, (a.imag - a.real * r) * s); } } else { float r = b.real / b.imag; float s = 1.0 / (b.imag + b.real * r); return __pyx_t_float_complex_from_parts( (a.real * r + a.imag) * s, (a.imag * r - a.real) * s); } } #else static CYTHON_INLINE __pyx_t_float_complex __Pyx_c_quot_float(__pyx_t_float_complex a, __pyx_t_float_complex b) { if (b.imag == 0) { return __pyx_t_float_complex_from_parts(a.real / b.real, a.imag / b.real); } else { float denom = b.real * b.real + b.imag * b.imag; return __pyx_t_float_complex_from_parts( (a.real * b.real + a.imag * b.imag) / denom, (a.imag * b.real - a.real * b.imag) / denom); } } #endif static CYTHON_INLINE __pyx_t_float_complex __Pyx_c_neg_float(__pyx_t_float_complex a) { __pyx_t_float_complex z; z.real = -a.real; z.imag = -a.imag; return z; } static CYTHON_INLINE int __Pyx_c_is_zero_float(__pyx_t_float_complex a) { return (a.real == 0) && (a.imag == 0); } static CYTHON_INLINE __pyx_t_float_complex __Pyx_c_conj_float(__pyx_t_float_complex a) { __pyx_t_float_complex z; z.real = a.real; z.imag = -a.imag; return z; } #if 1 static CYTHON_INLINE float __Pyx_c_abs_float(__pyx_t_float_complex z) { #if !defined(HAVE_HYPOT) \|\| defined(_MSC_VER) return sqrtf(z.realz.real + z.imagz.imag); #else return hypotf(z.real, z.imag); #endif } static CYTHON_INLINE __pyx_t_float_complex __Pyx_c_pow_float(__pyx_t_float_complex a, __pyx_t_float_complex b) { __pyx_t_float_complex z; float r, lnr, theta, z_r, z_theta; if (b.imag == 0 && b.real == (int)b.real) { if (b.real < 0) { float denom = a.real * a.real + a.imag * a.imag; a.real = a.real / denom; a.imag = -a.imag / denom; b.real = -b.real; } switch ((int)b.real) { case 0: z.real = 1; z.imag = 0; return z; case 1: return a; case 2: z = __Pyx_c_prod_float(a, a); return __Pyx_c_prod_float(a, a); case 3: z = __Pyx_c_prod_float(a, a); return __Pyx_c_prod_float(z, a); case 4: z = __Pyx_c_prod_float(a, a); return __Pyx_c_prod_float(z, z); } } if (a.imag == 0) { if (a.real == 0) { return a; } else if (b.imag == 0) { z.real = powf(a.real, b.real); z.imag = 0; return z; } else if (a.real > 0) { r = a.real; theta = 0; } else { r = -a.real; theta = atan2f(0, -1); } } else { r = __Pyx_c_abs_float(a); theta = atan2f(a.imag, a.real); } lnr = logf(r); z_r = expf(lnr * b.real - theta * b.imag); z_theta = theta * b.real + lnr * b.imag; z.real = z_r * cosf(z_theta); z.imag = z_r * sinf(z_theta); return z; } #endif #endif /* Declarations / #if CYTHON_CCOMPLEX #ifdef __cplusplus static CYTHON_INLINE __pyx_t_double_complex __pyx_t_double_complex_from_parts(double x, double y) { return ::std::complex< double >(x, y); } #else static CYTHON_INLINE __pyx_t_double_complex __pyx_t_double_complex_from_parts(double x, double y) { return x + y(__pyx_t_double_complex)_Complex_I; } #endif #else static CYTHON_INLINE __pyx_t_double_complex __pyx_t_double_complex_from_parts(double x, double y) { __pyx_t_double_complex z; z.real = x; z.imag = y; return z; } #endif /* Arithmetic / #if CYTHON_CCOMPLEX #else static CYTHON_INLINE int __Pyx_c_eq_double(__pyx_t_double_complex a, __pyx_t_double_complex b) { return (a.real == b.real) && (a.imag == b.imag); } static CYTHON_INLINE __pyx_t_double_complex __Pyx_c_sum_double(__pyx_t_double_complex a, __pyx_t_double_complex b) { __pyx_t_double_complex z; z.real = a.real + b.real; z.imag = a.imag + b.imag; return z; } static CYTHON_INLINE __pyx_t_double_complex __Pyx_c_diff_double(__pyx_t_double_complex a, __pyx_t_double_complex b) { __pyx_t_double_complex z; z.real = a.real - b.real; z.imag = a.imag - b.imag; return z; } static CYTHON_INLINE __pyx_t_double_complex __Pyx_c_prod_double(__pyx_t_double_complex a, __pyx_t_double_complex b) { __pyx_t_double_complex z; z.real = a.real b.real - a.imag * b.imag; z.imag = a.real * b.imag + a.imag * b.real; return z; } #if 1 static CYTHON_INLINE __pyx_t_double_complex __Pyx_c_quot_double(__pyx_t_double_complex a, __pyx_t_double_complex b) { if (b.imag == 0) { return __pyx_t_double_complex_from_parts(a.real / b.real, a.imag / b.real); } else if (fabs(b.real) >= fabs(b.imag)) { if (b.real == 0 && b.imag == 0) { return __pyx_t_double_complex_from_parts(a.real / b.real, a.imag / b.imag); } else { double r = b.imag / b.real; double s = 1.0 / (b.real + b.imag * r); return __pyx_t_double_complex_from_parts( (a.real + a.imag * r) * s, (a.imag - a.real * r) * s); } } else { double r = b.real / b.imag; double s = 1.0 / (b.imag + b.real * r); return __pyx_t_double_complex_from_parts( (a.real * r + a.imag) * s, (a.imag * r - a.real) * s); } } #else static CYTHON_INLINE __pyx_t_double_complex __Pyx_c_quot_double(__pyx_t_double_complex a, __pyx_t_double_complex b) { if (b.imag == 0) { return __pyx_t_double_complex_from_parts(a.real / b.real, a.imag / b.real); } else { double denom = b.real * b.real + b.imag * b.imag; return __pyx_t_double_complex_from_parts( (a.real * b.real + a.imag * b.imag) / denom, (a.imag * b.real - a.real * b.imag) / denom); } } #endif static CYTHON_INLINE __pyx_t_double_complex __Pyx_c_neg_double(__pyx_t_double_complex a) { __pyx_t_double_complex z; z.real = -a.real; z.imag = -a.imag; return z; } static CYTHON_INLINE int __Pyx_c_is_zero_double(__pyx_t_double_complex a) { return (a.real == 0) && (a.imag == 0); } static CYTHON_INLINE __pyx_t_double_complex __Pyx_c_conj_double(__pyx_t_double_complex a) { __pyx_t_double_complex z; z.real = a.real; z.imag = -a.imag; return z; } #if 1 static CYTHON_INLINE double __Pyx_c_abs_double(__pyx_t_double_complex z) { #if !defined(HAVE_HYPOT) \|\| defined(_MSC_VER) return sqrt(z.realz.real + z.imagz.imag); #else return hypot(z.real, z.imag); #endif } static CYTHON_INLINE __pyx_t_double_complex __Pyx_c_pow_double(__pyx_t_double_complex a, __pyx_t_double_complex b) { __pyx_t_double_complex z; double r, lnr, theta, z_r, z_theta; if (b.imag == 0 && b.real == (int)b.real) { if (b.real < 0) { double denom = a.real * a.real + a.imag * a.imag; a.real = a.real / denom; a.imag = -a.imag / denom; b.real = -b.real; } switch ((int)b.real) { case 0: z.real = 1; z.imag = 0; return z; case 1: return a; case 2: z = __Pyx_c_prod_double(a, a); return __Pyx_c_prod_double(a, a); case 3: z = __Pyx_c_prod_double(a, a); return __Pyx_c_prod_double(z, a); case 4: z = __Pyx_c_prod_double(a, a); return __Pyx_c_prod_double(z, z); } } if (a.imag == 0) { if (a.real == 0) { return a; } else if (b.imag == 0) { z.real = pow(a.real, b.real); z.imag = 0; return z; } else if (a.real > 0) { r = a.real; theta = 0; } else { r = -a.real; theta = atan2(0, -1); } } else { r = __Pyx_c_abs_double(a); theta = atan2(a.imag, a.real); } lnr = log(r); z_r = exp(lnr * b.real - theta * b.imag); z_theta = theta * b.real + lnr * b.imag; z.real = z_r * cos(z_theta); z.imag = z_r * sin(z_theta); return z; } #endif #endif /* CIntToPy / static CYTHON_INLINE PyObject __Pyx_PyInt_From_enum__NPY_TYPES(enum NPY_TYPES value) { const enum NPY_TYPES neg_one = (enum NPY_TYPES) -1, const_zero = (enum NPY_TYPES) 0; const int is_unsigned = neg_one > const_zero; if (is_unsigned) { if (sizeof(enum NPY_TYPES) < sizeof(long)) { return PyInt_FromLong((long) value); } else if (sizeof(enum NPY_TYPES) <= sizeof(unsigned long)) { return PyLong_FromUnsignedLong((unsigned long) value); #ifdef HAVE_LONG_LONG } else if (sizeof(enum NPY_TYPES) <= sizeof(unsigned PY_LONG_LONG)) { return PyLong_FromUnsignedLongLong((unsigned PY_LONG_LONG) value); #endif } } else { if (sizeof(enum NPY_TYPES) <= sizeof(long)) { return PyInt_FromLong((long) value); #ifdef HAVE_LONG_LONG } else if (sizeof(enum NPY_TYPES) <= 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(enum NPY_TYPES), little, !is_unsigned); } } /* 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 (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 int __Pyx_PyInt_As_int(PyObject x) { const int neg_one = (int) -1, const_zero = (int) 0; 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; } /* CIntFromPy / static CYTHON_INLINE char __Pyx_PyInt_As_char(PyObject x) { const char neg_one = (char) -1, const_zero = (char) 0; 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; } /* CIntFromPy / static CYTHON_INLINE long __Pyx_PyInt_As_long(PyObject x) { const long neg_one = (long) -1, const_zero = (long) 0; 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; } /* 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 (buf->strides[dim] != sizeof(void )) { PyErr_Format(PyExc_ValueError, "Buffer is not indirectly contiguous " "in dimension %d.", dim); goto fail; } } else if (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 (stride < buf->itemsize) { PyErr_SetString(PyExc_ValueError, "Buffer and memoryview are not contiguous " "in the same dimension."); goto fail; } } } else { if (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 (spec & (__Pyx_MEMVIEW_PTR)) { PyErr_Format(PyExc_ValueError, "C-contiguous buffer is not indirect in " "dimension %d", dim); goto fail; } else if (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 (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 (!buf->suboffsets \|\| (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 (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 (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 (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 (!__Pyx_BufFmt_CheckString(&ctx, buf->format)) goto fail; } if ((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; } for (i = 0; i < ndim; i++) { spec = axes_specs[i]; if (!__pyx_check_strides(buf, i, ndim, spec)) goto fail; if (!__pyx_check_suboffsets(buf, i, ndim, spec)) goto fail; } if (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_dsdsds_float(PyObject obj) { __Pyx_memviewslice result = { 0, 0, { 0 }, { 0 }, { 0 } }; __Pyx_BufFmt_StackElem stack[1]; int axes_specs[] = { (__Pyx_MEMVIEW_DIRECT \| __Pyx_MEMVIEW_STRIDED), (__Pyx_MEMVIEW_DIRECT \| __Pyx_MEMVIEW_STRIDED), (__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, 3, &__Pyx_TypeInfo_float, 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_dsds_int(PyObject obj) { __Pyx_memviewslice result = { 0, 0, { 0 }, { 0 }, { 0 } }; __Pyx_BufFmt_StackElem stack[1]; int axes_specs[] = { (__Pyx_MEMVIEW_DIRECT \| __Pyx_MEMVIEW_STRIDED), (__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, 2, &__Pyx_TypeInfo_int, 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_dsds_float(PyObject obj) { __Pyx_memviewslice result = { 0, 0, { 0 }, { 0 }, { 0 } }; __Pyx_BufFmt_StackElem stack[1]; int axes_specs[] = { (__Pyx_MEMVIEW_DIRECT \| __Pyx_MEMVIEW_STRIDED), (__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, 2, &__Pyx_TypeInfo_float, stack, &result, obj); if (unlikely(retcode == -1)) goto __pyx_fail; return result; __pyx_fail: result.memview = NULL; result.data = NULL; return result; } / 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; } / ModuleImport / #ifndef __PYX_HAVE_RT_ImportModule #define __PYX_HAVE_RT_ImportModule static PyObject __Pyx_ImportModule(const char name) { PyObject py_name = 0; PyObject py_module = 0; py_name = __Pyx_PyIdentifier_FromString(name); if (!py_name) goto bad; py_module = PyImport_Import(py_name); Py_DECREF(py_name); return py_module; bad: Py_XDECREF(py_name); return 0; } #endif / TypeImport / #ifndef __PYX_HAVE_RT_ImportType #define __PYX_HAVE_RT_ImportType static PyTypeObject __Pyx_ImportType(const char module_name, const char class_name, size_t size, int strict) { PyObject py_module = 0; PyObject result = 0; PyObject py_name = 0; char warning[200]; Py_ssize_t basicsize; #ifdef Py_LIMITED_API PyObject py_basicsize; #endif py_module = __Pyx_ImportModule(module_name); if (!py_module) goto bad; py_name = __Pyx_PyIdentifier_FromString(class_name); if (!py_name) goto bad; result = PyObject_GetAttr(py_module, py_name); Py_DECREF(py_name); py_name = 0; Py_DECREF(py_module); py_module = 0; if (!result) goto bad; if (!PyType_Check(result)) { PyErr_Format(PyExc_TypeError, "%.200s.%.200s is not a type object", module_name, class_name); goto bad; } #ifndef Py_LIMITED_API basicsize = ((PyTypeObject )result)->tp_basicsize; #else py_basicsize = PyObject_GetAttrString(result, "__basicsize__"); if (!py_basicsize) goto bad; basicsize = PyLong_AsSsize_t(py_basicsize); Py_DECREF(py_basicsize); py_basicsize = 0; if (basicsize == (Py_ssize_t)-1 && PyErr_Occurred()) goto bad; #endif if (!strict && (size_t)basicsize > size) { PyOS_snprintf(warning, sizeof(warning), "%s.%s size changed, may indicate binary incompatibility. Expected %zd, got %zd", module_name, class_name, basicsize, size); if (PyErr_WarnEx(NULL, warning, 0) < 0) goto bad; } else if ((size_t)basicsize != size) { PyErr_Format(PyExc_ValueError, "%.200s.%.200s has the wrong size, try recompiling. Expected %zd, got %zd", module_name, class_name, basicsize, size); goto bad; } return (PyTypeObject )result; bad: Py_XDECREF(py_module); Py_XDECREF(result); return NULL; } #endif /* 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; ++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 char* __Pyx_PyObject_AsString(PyObject* o) { Py_ssize_t ignore; return __Pyx_PyObject_AsStringAndSize(o, &ignore); } static CYTHON_INLINE char* __Pyx_PyObject_AsStringAndSize(PyObject* o, Py_ssize_t length) { #if CYTHON_COMPILING_IN_CPYTHON && (__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)) { #if PY_VERSION_HEX < 0x03030000 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 if (__Pyx_PyUnicode_READY(o) == -1) return NULL; #if __PYX_DEFAULT_STRING_ENCODING_IS_ASCII if (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 } 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 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 (PyInt_Check(x) \|\| PyLong_Check(x)) #else if (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 = PyNumber_Int(x); } else if (m && m->nb_long) { name = "long"; res = PyNumber_Long(x); } #else if (m && m->nb_int) { name = "int"; res = PyNumber_Long(x); } #endif #else res = PyNumber_Int(x); #endif if (res) { #if PY_MAJOR_VERSION < 3 if (!PyInt_Check(res) && !PyLong_Check(res)) { #else if (!PyLong_Check(res)) { #endif PyErr_Format(PyExc_TypeError, "__%.4s__ returned non-%.4s (type %.200s)", name, name, Py_TYPE(res)->tp_name); Py_DECREF(res); return NULL; } } 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(x); } #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 PyObject * __Pyx_PyInt_FromSize_t(size_t ival) { return PyInt_FromSize_t(ival); } #endif /* Py_PYTHON_H */
DRB020-privatemissing-var-yes.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. / / tmp should be put as private to avoid race condition Data race pair: tmp@65 vs. tmp@66 / #include <stdlib.h> #include <omp.h> int main(int argc,char argv[]) { int i; int tmp; int len = 100; if (argc > 1) len = atoi(argv[1]); int a[len]; #pragma omp parallel for private (i) for (i = 0; i <= len - 1; i += 1) { a[i] = i; } #pragma omp parallel for private (tmp,i) for (i = 0; i <= len - 1; i += 1) { tmp = a[i] + i; a[i] = tmp; } for (i = 0; i <= len - 1; i += 1) { printf("%d\n",a[i]); } return 0; }
residualbased_block_builder_and_solver.h	// \| / \| // ' / __\| _` \| __\| _ \ __\| // . \ \| ( \| \| ( \|\__ ` // _\|\_\_\| \__,_\|\__\|\___/ ____/ // Multi-Physics // // License: BSD License // Kratos default license: kratos/license.txt // // Main authors: Riccardo Rossi // Collaborators: Vicente Mataix // // #if !defined(KRATOS_RESIDUAL_BASED_BLOCK_BUILDER_AND_SOLVER ) #define KRATOS_RESIDUAL_BASED_BLOCK_BUILDER_AND_SOLVER /* System includes / #include <unordered_set> / External includes / / Project includes / #include "includes/define.h" #include "solving_strategies/builder_and_solvers/builder_and_solver.h" #include "includes/model_part.h" #include "includes/key_hash.h" #include "utilities/timer.h" #include "utilities/openmp_utils.h" #include "utilities/variable_utils.h" #include "includes/kratos_flags.h" #include "includes/lock_object.h" #include "utilities/sparse_matrix_multiplication_utility.h" namespace Kratos { ///@name Kratos Globals ///@{ ///@} ///@name Type Definitions ///@{ ///@} ///@name Enum's ///@{ ///@} ///@name Functions ///@{ ///@} ///@name Kratos Classes ///@{ /* * @class ResidualBasedEliminationBuilderAndSolver * @ingroup KratosCore * @brief Current class provides an implementation for standard builder and solving operations. * @details The RHS is constituted by the unbalanced loads (residual) * Degrees of freedom are reordered putting the restrained degrees of freedom at * the end of the system ordered in reverse order with respect to the DofSet. * Imposition of the dirichlet conditions is naturally dealt with as the residual already contains * this information. * Calculation of the reactions involves a cost very similiar to the calculation of the total residual * @tparam TSparseSpace The sparse system considered * @tparam TDenseSpace The dense system considered * @tparam TLinearSolver The linear solver considered * @author Riccardo Rossi / template<class TSparseSpace, class TDenseSpace, //= DenseSpace<double>, class TLinearSolver //= LinearSolver<TSparseSpace,TDenseSpace> > class ResidualBasedBlockBuilderAndSolver : public BuilderAndSolver< TSparseSpace, TDenseSpace, TLinearSolver > { public: ///@name Type Definitions ///@{ /// Definition of the flags KRATOS_DEFINE_LOCAL_FLAG( SILENT_WARNINGS ); // Scaling enum enum class SCALING_DIAGONAL {NO_SCALING = 0, CONSIDER_NORM_DIAGONAL = 1, CONSIDER_MAX_DIAGONAL = 2, CONSIDER_PRESCRIBED_DIAGONAL = 3}; /// Definition of the pointer KRATOS_CLASS_POINTER_DEFINITION(ResidualBasedBlockBuilderAndSolver); /// Definition of the base class typedef BuilderAndSolver<TSparseSpace, TDenseSpace, TLinearSolver> BaseType; // The size_t types typedef std::size_t SizeType; typedef std::size_t IndexType; /// Definition of the classes from the base class typedef typename BaseType::TSchemeType TSchemeType; typedef typename BaseType::TDataType TDataType; typedef typename BaseType::DofsArrayType DofsArrayType; typedef typename BaseType::TSystemMatrixType TSystemMatrixType; typedef typename BaseType::TSystemVectorType TSystemVectorType; typedef typename BaseType::LocalSystemVectorType LocalSystemVectorType; typedef typename BaseType::LocalSystemMatrixType LocalSystemMatrixType; typedef typename BaseType::TSystemMatrixPointerType TSystemMatrixPointerType; typedef typename BaseType::TSystemVectorPointerType TSystemVectorPointerType; typedef typename BaseType::NodesArrayType NodesArrayType; typedef typename BaseType::ElementsArrayType ElementsArrayType; typedef typename BaseType::ConditionsArrayType ConditionsArrayType; /// Additional definitions typedef PointerVectorSet<Element, IndexedObject> ElementsContainerType; typedef Element::EquationIdVectorType EquationIdVectorType; typedef Element::DofsVectorType DofsVectorType; typedef boost::numeric::ublas::compressed_matrix<double> CompressedMatrixType; /// DoF types definition typedef Node<3> NodeType; typedef typename NodeType::DofType DofType; typedef typename DofType::Pointer DofPointerType; ///@} ///@name Life Cycle ///@{ /* * @brief Default constructor. (with parameters) / explicit ResidualBasedBlockBuilderAndSolver( typename TLinearSolver::Pointer pNewLinearSystemSolver, Parameters ThisParameters ) : BaseType(pNewLinearSystemSolver) { // Validate default parameters Parameters default_parameters = Parameters(R"( { "name" : "ResidualBasedBlockBuilderAndSolver", "block_builder" : true, "diagonal_values_for_dirichlet_dofs" : "use_max_diagonal", "silent_warnings" : false })" ); ThisParameters.ValidateAndAssignDefaults(default_parameters); // Setting flags const std::string& r_diagonal_values_for_dirichlet_dofs = ThisParameters["diagonal_values_for_dirichlet_dofs"].GetString(); std::set<std::string> available_options_for_diagonal = {"no_scaling","use_max_diagonal","use_diagonal_norm","defined_in_process_info"}; if (available_options_for_diagonal.find(r_diagonal_values_for_dirichlet_dofs) == available_options_for_diagonal.end()) { std::stringstream msg; msg << "Currently prescribed diagonal values for dirichlet dofs : " << r_diagonal_values_for_dirichlet_dofs << "\n"; msg << "Admissible values for the diagonal scaling are : no_scaling, use_max_diagonal, use_diagonal_norm, or defined_in_process_info" << "\n"; KRATOS_ERROR << msg.str() << std::endl; } // The first option will not consider any scaling (the diagonal values will be replaced with 1) if (r_diagonal_values_for_dirichlet_dofs == "no_scaling") { mScalingDiagonal = SCALING_DIAGONAL::NO_SCALING; } else if (r_diagonal_values_for_dirichlet_dofs == "use_max_diagonal") { mScalingDiagonal = SCALING_DIAGONAL::CONSIDER_MAX_DIAGONAL; } else if (r_diagonal_values_for_dirichlet_dofs == "use_diagonal_norm") { // On this case the norm of the diagonal will be considered mScalingDiagonal = SCALING_DIAGONAL::CONSIDER_NORM_DIAGONAL; } else { // Otherwise we will assume we impose a numerical value mScalingDiagonal = SCALING_DIAGONAL::CONSIDER_PRESCRIBED_DIAGONAL; } mOptions.Set(SILENT_WARNINGS, ThisParameters["silent_warnings"].GetBool()); } /* * @brief Default constructor. / explicit ResidualBasedBlockBuilderAndSolver(typename TLinearSolver::Pointer pNewLinearSystemSolver) : BaseType(pNewLinearSystemSolver) { mScalingDiagonal = SCALING_DIAGONAL::NO_SCALING; } /* Destructor. / ~ResidualBasedBlockBuilderAndSolver() override { } ///@} ///@name Operators ///@{ ///@} ///@name Operations ///@{ /* * @brief Function to perform the build of the RHS. The vector could be sized as the total number * of dofs or as the number of unrestrained ones * @param pScheme The integration scheme considered * @param rModelPart The model part of the problem to solve * @param A The LHS matrix * @param b The RHS vector / void Build( typename TSchemeType::Pointer pScheme, ModelPart& rModelPart, TSystemMatrixType& A, TSystemVectorType& b) override { KRATOS_TRY KRATOS_ERROR_IF(!pScheme) << "No scheme provided!" << std::endl; // Getting the elements from the model const int nelements = static_cast<int>(rModelPart.Elements().size()); // Getting the array of the conditions const int nconditions = static_cast<int>(rModelPart.Conditions().size()); const ProcessInfo& CurrentProcessInfo = rModelPart.GetProcessInfo(); ModelPart::ElementsContainerType::iterator el_begin = rModelPart.ElementsBegin(); ModelPart::ConditionsContainerType::iterator cond_begin = rModelPart.ConditionsBegin(); //contributions to the system LocalSystemMatrixType LHS_Contribution = LocalSystemMatrixType(0, 0); LocalSystemVectorType RHS_Contribution = LocalSystemVectorType(0); //vector containing the localization in the system of the different //terms Element::EquationIdVectorType EquationId; // assemble all elements double start_build = OpenMPUtils::GetCurrentTime(); #pragma omp parallel firstprivate(nelements,nconditions, LHS_Contribution, RHS_Contribution, EquationId ) { # pragma omp for schedule(guided, 512) nowait for (int k = 0; k < nelements; k++) { ModelPart::ElementsContainerType::iterator it = el_begin + k; //detect if the element is active or not. If the user did not make any choice the element //is active by default bool element_is_active = true; if ((it)->IsDefined(ACTIVE)) element_is_active = (it)->Is(ACTIVE); if (element_is_active) { //calculate elemental contribution pScheme->CalculateSystemContributions(it, LHS_Contribution, RHS_Contribution, EquationId, CurrentProcessInfo); //assemble the elemental contribution Assemble(A, b, LHS_Contribution, RHS_Contribution, EquationId); // clean local elemental memory pScheme->CleanMemory(it); } } #pragma omp for schedule(guided, 512) for (int k = 0; k < nconditions; k++) { ModelPart::ConditionsContainerType::iterator it = cond_begin + k; //detect if the element is active or not. If the user did not make any choice the element //is active by default bool condition_is_active = true; if ((it)->IsDefined(ACTIVE)) condition_is_active = (it)->Is(ACTIVE); if (condition_is_active) { //calculate elemental contribution pScheme->CalculateSystemContributions(it, LHS_Contribution, RHS_Contribution, EquationId, CurrentProcessInfo); //assemble the elemental contribution Assemble(A, b, LHS_Contribution, RHS_Contribution, EquationId); // clean local elemental memory pScheme->CleanMemory(it); } } } const double stop_build = OpenMPUtils::GetCurrentTime(); KRATOS_INFO_IF("ResidualBasedBlockBuilderAndSolver", (this->GetEchoLevel() >= 1 && rModelPart.GetCommunicator().MyPID() == 0)) << "Build time: " << stop_build - start_build << std::endl; KRATOS_INFO_IF("ResidualBasedBlockBuilderAndSolver", (this->GetEchoLevel() > 2 && rModelPart.GetCommunicator().MyPID() == 0)) << "Finished parallel building" << std::endl; KRATOS_CATCH("") } /* * @brief Function to perform the building of the LHS * @details Depending on the implementation choosen the size of the matrix could * be equal to the total number of Dofs or to the number of unrestrained dofs * @param pScheme The integration scheme considered * @param rModelPart The model part of the problem to solve * @param A The LHS matrix / void BuildLHS( typename TSchemeType::Pointer pScheme, ModelPart& rModelPart, TSystemMatrixType& rA ) override { KRATOS_TRY KRATOS_ERROR_IF(!pScheme) << "No scheme provided!" << std::endl; // Getting the elements from the model const int nelements = static_cast<int>(rModelPart.Elements().size()); // Getting the array of the conditions const int nconditions = static_cast<int>(rModelPart.Conditions().size()); const ProcessInfo& r_current_process_info = rModelPart.GetProcessInfo(); const auto it_elem_begin = rModelPart.ElementsBegin(); const auto it_cond_begin = rModelPart.ConditionsBegin(); // Contributions to the system LocalSystemMatrixType lhs_contribution(0, 0); // Vector containing the localization in the system of the different terms Element::EquationIdVectorType equation_id; // Assemble all elements double start_build = OpenMPUtils::GetCurrentTime(); #pragma omp parallel firstprivate(nelements, nconditions, lhs_contribution, equation_id ) { # pragma omp for schedule(guided, 512) nowait for (int k = 0; k < nelements; ++k) { auto it_elem = it_elem_begin + k; // Detect if the element is active or not. If the user did not make any choice the element is active by default bool element_is_active = true; if (it_elem->IsDefined(ACTIVE)) element_is_active = it_elem->Is(ACTIVE); if (element_is_active) { // Calculate elemental contribution pScheme->CalculateLHSContribution(it_elem, lhs_contribution, equation_id, r_current_process_info); // Assemble the elemental contribution AssembleLHS(rA, lhs_contribution, equation_id); // Clean local elemental memory pScheme->CleanMemory(it_elem); } } #pragma omp for schedule(guided, 512) for (int k = 0; k < nconditions; ++k) { auto it_cond = it_cond_begin + k; // Detect if the element is active or not. If the user did not make any choice the element is active by default bool condition_is_active = true; if (it_cond->IsDefined(ACTIVE)) condition_is_active = it_cond->Is(ACTIVE); if (condition_is_active) { // Calculate elemental contribution pScheme->CalculateLHSContribution(it_cond, lhs_contribution, equation_id, r_current_process_info); // Assemble the elemental contribution AssembleLHS(rA, lhs_contribution, equation_id); // Clean local elemental memory pScheme->CleanMemory(it_cond); } } } const double stop_build = OpenMPUtils::GetCurrentTime(); KRATOS_INFO_IF("ResidualBasedBlockBuilderAndSolver", this->GetEchoLevel() >= 1) << "Build time LHS: " << stop_build - start_build << std::endl; KRATOS_INFO_IF("ResidualBasedBlockBuilderAndSolver", this->GetEchoLevel() > 2) << "Finished parallel building LHS" << std::endl; KRATOS_CATCH("") } /* * @brief Build a rectangular matrix of size nN where "n" is the number of unrestrained degrees of freedom and "N" is the total number of degrees of freedom involved. * @details This matrix is obtained by building the total matrix without the lines corresponding to the fixed * degrees of freedom (but keeping the columns!!) * @param pScheme The integration scheme considered * @param rModelPart The model part of the problem to solve * @param A The LHS matrix / void BuildLHS_CompleteOnFreeRows( typename TSchemeType::Pointer pScheme, ModelPart& rModelPart, TSystemMatrixType& A) override { KRATOS_TRY TSystemVectorType tmp(A.size1(), 0.0); this->Build(pScheme, rModelPart, A, tmp); KRATOS_CATCH("") } /* * @brief This is a call to the linear system solver * @param A The LHS matrix * @param Dx The Unknowns vector * @param b The RHS vector / void SystemSolve( TSystemMatrixType& A, TSystemVectorType& Dx, TSystemVectorType& b ) override { KRATOS_TRY double norm_b; if (TSparseSpace::Size(b) != 0) norm_b = TSparseSpace::TwoNorm(b); else norm_b = 0.00; if (norm_b != 0.00) { //do solve BaseType::mpLinearSystemSolver->Solve(A, Dx, b); } else TSparseSpace::SetToZero(Dx); if(mT.size1() != 0) //if there are master-slave constraints { //recover solution of the original problem TSystemVectorType Dxmodified = Dx; TSparseSpace::Mult(mT, Dxmodified, Dx); } //prints informations about the current time KRATOS_INFO_IF("ResidualBasedBlockBuilderAndSolver", this->GetEchoLevel() > 1) << (BaseType::mpLinearSystemSolver) << std::endl; KRATOS_CATCH("") } /** * @brief This is a call to the linear system solver (taking into account some physical particularities of the problem) * @param rA The LHS matrix * @param rDx The Unknowns vector * @param rb The RHS vector * @param rModelPart The model part of the problem to solve / virtual void SystemSolveWithPhysics( TSystemMatrixType& rA, TSystemVectorType& rDx, TSystemVectorType& rb, ModelPart& rModelPart ) { if(rModelPart.MasterSlaveConstraints().size() != 0) { TSystemVectorType Dxmodified(rb.size()); InternalSystemSolveWithPhysics(rA, Dxmodified, rb, rModelPart); //recover solution of the original problem TSparseSpace::Mult(mT, Dxmodified, rDx); } else { InternalSystemSolveWithPhysics(rA, rDx, rb, rModelPart); } } /* @brief This is a call to the linear system solver (taking into account some physical particularities of the problem) @param A The LHS matrix * @param Dx The Unknowns vector * @param b The RHS vector * @param rModelPart The model part of the problem to solve / void InternalSystemSolveWithPhysics( TSystemMatrixType& A, TSystemVectorType& Dx, TSystemVectorType& b, ModelPart& rModelPart ) { KRATOS_TRY double norm_b; if (TSparseSpace::Size(b) != 0) norm_b = TSparseSpace::TwoNorm(b); else norm_b = 0.00; if (norm_b != 0.00) { //provide physical data as needed if(BaseType::mpLinearSystemSolver->AdditionalPhysicalDataIsNeeded() ) BaseType::mpLinearSystemSolver->ProvideAdditionalData(A, Dx, b, BaseType::mDofSet, rModelPart); //do solve BaseType::mpLinearSystemSolver->Solve(A, Dx, b); } else { TSparseSpace::SetToZero(Dx); KRATOS_WARNING_IF("ResidualBasedBlockBuilderAndSolver", mOptions.IsNot(SILENT_WARNINGS)) << "ATTENTION! setting the RHS to zero!" << std::endl; } // Prints informations about the current time KRATOS_INFO_IF("ResidualBasedBlockBuilderAndSolver", this->GetEchoLevel() > 1) << (BaseType::mpLinearSystemSolver) << std::endl; KRATOS_CATCH("") } /** * @brief Function to perform the building and solving phase at the same time. * @details It is ideally the fastest and safer function to use when it is possible to solve * just after building * @param pScheme The integration scheme considered * @param rModelPart The model part of the problem to solve * @param A The LHS matrix * @param Dx The Unknowns vector * @param b The RHS vector / void BuildAndSolve( typename TSchemeType::Pointer pScheme, ModelPart& rModelPart, TSystemMatrixType& A, TSystemVectorType& Dx, TSystemVectorType& b) override { KRATOS_TRY Timer::Start("Build"); Build(pScheme, rModelPart, A, b); Timer::Stop("Build"); if(rModelPart.MasterSlaveConstraints().size() != 0) { Timer::Start("ApplyConstraints"); ApplyConstraints(pScheme, rModelPart, A, b); Timer::Stop("ApplyConstraints"); } ApplyDirichletConditions(pScheme, rModelPart, A, Dx, b); KRATOS_INFO_IF("ResidualBasedBlockBuilderAndSolver", ( this->GetEchoLevel() == 3)) << "Before the solution of the system" << "\nSystem Matrix = " << A << "\nUnknowns vector = " << Dx << "\nRHS vector = " << b << std::endl; const double start_solve = OpenMPUtils::GetCurrentTime(); Timer::Start("Solve"); SystemSolveWithPhysics(A, Dx, b, rModelPart); Timer::Stop("Solve"); const double stop_solve = OpenMPUtils::GetCurrentTime(); KRATOS_INFO_IF("ResidualBasedBlockBuilderAndSolver", (this->GetEchoLevel() >=1 && rModelPart.GetCommunicator().MyPID() == 0)) << "System solve time: " << stop_solve - start_solve << std::endl; KRATOS_INFO_IF("ResidualBasedBlockBuilderAndSolver", ( this->GetEchoLevel() == 3)) << "After the solution of the system" << "\nSystem Matrix = " << A << "\nUnknowns vector = " << Dx << "\nRHS vector = " << b << std::endl; KRATOS_CATCH("") } /* * @brief Function to perform the building and solving phase at the same time Linearizing with the database at the old iteration * @details It is ideally the fastest and safer function to use when it is possible to solve just after building * @param pScheme The pointer to the integration scheme * @param rModelPart The model part to compute * @param rA The LHS matrix of the system of equations * @param rDx The vector of unkowns * @param rb The RHS vector of the system of equations * @param MoveMesh tells if the update of the scheme needs to be performed when calling the Update of the scheme / void BuildAndSolveLinearizedOnPreviousIteration( typename TSchemeType::Pointer pScheme, ModelPart& rModelPart, TSystemMatrixType& rA, TSystemVectorType& rDx, TSystemVectorType& rb, const bool MoveMesh ) override { KRATOS_INFO_IF("BlockBuilderAndSolver", this->GetEchoLevel() > 0) << "Linearizing on Old iteration" << std::endl; KRATOS_ERROR_IF(rModelPart.GetBufferSize() == 1) << "BlockBuilderAndSolver: \n" << "The buffer size needs to be at least 2 in order to use \n" << "BuildAndSolveLinearizedOnPreviousIteration \n" << "current buffer size for modelpart: " << rModelPart.Name() << std::endl << "is :" << rModelPart.GetBufferSize() << " Please set IN THE STRATEGY SETTINGS " << " UseOldStiffnessInFirstIteration=false " << std::endl; DofsArrayType fixed_dofs; for(auto& r_dof : BaseType::mDofSet){ if(r_dof.IsFixed()){ fixed_dofs.push_back(&r_dof); r_dof.FreeDof(); } } //TODO: Here we need to take the vector from other ones because // We cannot create a trilinos vector without a communicator. To be improved! TSystemVectorType dx_prediction(rDx); TSystemVectorType rhs_addition(rb); //we know it is zero here, so we do not need to set it // Here we bring back the database to before the prediction, // but we store the prediction increment in dx_prediction. // The goal is that the stiffness is computed with the // converged configuration at the end of the previous step. const auto it_dof_begin = BaseType::mDofSet.begin(); #pragma omp parallel for for (int i = 0; i < static_cast<int>(BaseType::mDofSet.size()); ++i) { auto it_dof = it_dof_begin + i; //NOTE: this is initialzed to - the value of dx prediction dx_prediction[it_dof->EquationId()] = -(it_dof->GetSolutionStepValue() - it_dof->GetSolutionStepValue(1)); } // Use UpdateDatabase to bring back the solution to how it was at the end of the previous step pScheme->Update(rModelPart, BaseType::mDofSet, rA, dx_prediction, rb); if (MoveMesh) { VariableUtils().UpdateCurrentPosition(rModelPart.Nodes(),DISPLACEMENT,0); } this->Build(pScheme, rModelPart, rA, rb); // Put back the prediction into the database TSparseSpace::InplaceMult(dx_prediction, -1.0); //change sign to dx_prediction TSparseSpace::UnaliasedAdd(rDx, 1.0, dx_prediction); // Use UpdateDatabase to bring back the solution // to where it was taking into account BCs // it is done here so that constraints are correctly taken into account right after pScheme->Update(rModelPart, BaseType::mDofSet, rA, dx_prediction, rb); if (MoveMesh) { VariableUtils().UpdateCurrentPosition(rModelPart.Nodes(),DISPLACEMENT,0); } // Apply rb -= Adx_prediction TSparseSpace::Mult(rA, dx_prediction, rhs_addition); TSparseSpace::UnaliasedAdd(rb, -1.0, rhs_addition); for(auto& dof : fixed_dofs) dof.FixDof(); if (!rModelPart.MasterSlaveConstraints().empty()) { this->ApplyConstraints(pScheme, rModelPart, rA, rb); } this->ApplyDirichletConditions(pScheme, rModelPart, rA, rDx, rb); this->SystemSolveWithPhysics(rA, rDx, rb, rModelPart); } /** * @brief Corresponds to the previews, but the System's matrix is considered already built and only the RHS is built again * @param pScheme The integration scheme considered * @param rModelPart The model part of the problem to solve * @param rA The LHS matrix * @param rDx The Unknowns vector * @param rb The RHS vector / void BuildRHSAndSolve( typename TSchemeType::Pointer pScheme, ModelPart& rModelPart, TSystemMatrixType& rA, TSystemVectorType& rDx, TSystemVectorType& rb ) override { KRATOS_TRY Timer::Start("BuildRHS"); BuildRHS(pScheme, rModelPart, rb); Timer::Stop("BuildRHS"); if(rModelPart.MasterSlaveConstraints().size() != 0) { Timer::Start("ApplyRHSConstraints"); ApplyRHSConstraints(pScheme, rModelPart, rb); Timer::Stop("ApplyRHSConstraints"); } ApplyDirichletConditions(pScheme, rModelPart, rA, rDx, rb); KRATOS_INFO_IF("ResidualBasedBlockBuilderAndSolver", ( this->GetEchoLevel() == 3)) << "Before the solution of the system" << "\nSystem Matrix = " << rA << "\nUnknowns vector = " << rDx << "\nRHS vector = " << rb << std::endl; const double start_solve = OpenMPUtils::GetCurrentTime(); Timer::Start("Solve"); SystemSolveWithPhysics(rA, rDx, rb, rModelPart); Timer::Stop("Solve"); const double stop_solve = OpenMPUtils::GetCurrentTime(); KRATOS_INFO_IF("ResidualBasedBlockBuilderAndSolver", (this->GetEchoLevel() >=1 && rModelPart.GetCommunicator().MyPID() == 0)) << "System solve time: " << stop_solve - start_solve << std::endl; KRATOS_INFO_IF("ResidualBasedBlockBuilderAndSolver", ( this->GetEchoLevel() == 3)) << "After the solution of the system" << "\nSystem Matrix = " << rA << "\nUnknowns vector = " << rDx << "\nRHS vector = " << rb << std::endl; KRATOS_CATCH("") } /* * @brief Function to perform the build of the RHS. * @details The vector could be sized as the total number of dofs or as the number of unrestrained ones * @param pScheme The integration scheme considered * @param rModelPart The model part of the problem to solve / void BuildRHS( typename TSchemeType::Pointer pScheme, ModelPart& rModelPart, TSystemVectorType& b) override { KRATOS_TRY BuildRHSNoDirichlet(pScheme,rModelPart,b); const int ndofs = static_cast<int>(BaseType::mDofSet.size()); //NOTE: dofs are assumed to be numbered consecutively in the BlockBuilderAndSolver #pragma omp parallel for firstprivate(ndofs) for (int k = 0; k<ndofs; k++) { typename DofsArrayType::iterator dof_iterator = BaseType::mDofSet.begin() + k; const std::size_t i = dof_iterator->EquationId(); if (dof_iterator->IsFixed()) b[i] = 0.0; } KRATOS_CATCH("") } /* * @brief Builds the list of the DofSets involved in the problem by "asking" to each element * and condition its Dofs. * @details The list of dofs is stores insde the BuilderAndSolver as it is closely connected to the * way the matrix and RHS are built * @param pScheme The integration scheme considered * @param rModelPart The model part of the problem to solve / void SetUpDofSet( typename TSchemeType::Pointer pScheme, ModelPart& rModelPart ) override { KRATOS_TRY; KRATOS_INFO_IF("ResidualBasedBlockBuilderAndSolver", ( this->GetEchoLevel() > 1 && rModelPart.GetCommunicator().MyPID() == 0)) << "Setting up the dofs" << std::endl; //Gets the array of elements from the modeler ElementsArrayType& r_elements_array = rModelPart.Elements(); const int number_of_elements = static_cast<int>(r_elements_array.size()); DofsVectorType dof_list, second_dof_list; // NOTE: The second dof list is only used on constraints to include master/slave relations unsigned int nthreads = OpenMPUtils::GetNumThreads(); typedef std::unordered_set < NodeType::DofType::Pointer, DofPointerHasher> set_type; KRATOS_INFO_IF("ResidualBasedBlockBuilderAndSolver", ( this->GetEchoLevel() > 2)) << "Number of threads" << nthreads << "\n" << std::endl; KRATOS_INFO_IF("ResidualBasedBlockBuilderAndSolver", ( this->GetEchoLevel() > 2)) << "Initializing element loop" << std::endl; /* * Here we declare three sets. * - The global set: Contains all the DoF of the system * - The slave set: The DoF that are not going to be solved, due to MPC formulation / set_type dof_global_set; dof_global_set.reserve(number_of_elements20); #pragma omp parallel firstprivate(dof_list, second_dof_list) { const ProcessInfo& r_current_process_info = rModelPart.GetProcessInfo(); // We cleate the temporal set and we reserve some space on them set_type dofs_tmp_set; dofs_tmp_set.reserve(20000); // Gets the array of elements from the modeler #pragma omp for schedule(guided, 512) nowait for (int i = 0; i < number_of_elements; ++i) { auto it_elem = r_elements_array.begin() + i; // Gets list of Dof involved on every element pScheme->GetDofList(it_elem, dof_list, r_current_process_info); dofs_tmp_set.insert(dof_list.begin(), dof_list.end()); } // Gets the array of conditions from the modeler ConditionsArrayType& r_conditions_array = rModelPart.Conditions(); const int number_of_conditions = static_cast<int>(r_conditions_array.size()); #pragma omp for schedule(guided, 512) nowait for (int i = 0; i < number_of_conditions; ++i) { auto it_cond = r_conditions_array.begin() + i; // Gets list of Dof involved on every element pScheme->GetDofList(it_cond, dof_list, r_current_process_info); dofs_tmp_set.insert(dof_list.begin(), dof_list.end()); } // Gets the array of constraints from the modeler auto& r_constraints_array = rModelPart.MasterSlaveConstraints(); const int number_of_constraints = static_cast<int>(r_constraints_array.size()); #pragma omp for schedule(guided, 512) nowait for (int i = 0; i < number_of_constraints; ++i) { auto it_const = r_constraints_array.begin() + i; // Gets list of Dof involved on every element it_const->GetDofList(dof_list, second_dof_list, r_current_process_info); dofs_tmp_set.insert(dof_list.begin(), dof_list.end()); dofs_tmp_set.insert(second_dof_list.begin(), second_dof_list.end()); } // We merge all the sets in one thread #pragma omp critical { dof_global_set.insert(dofs_tmp_set.begin(), dofs_tmp_set.end()); } } KRATOS_INFO_IF("ResidualBasedBlockBuilderAndSolver", ( this->GetEchoLevel() > 2)) << "Initializing ordered array filling\n" << std::endl; DofsArrayType Doftemp; BaseType::mDofSet = DofsArrayType(); Doftemp.reserve(dof_global_set.size()); for (auto it= dof_global_set.begin(); it!= dof_global_set.end(); it++) { Doftemp.push_back( it ); } Doftemp.Sort(); BaseType::mDofSet = Doftemp; //Throws an exception if there are no Degrees Of Freedom involved in the analysis KRATOS_ERROR_IF(BaseType::mDofSet.size() == 0) << "No degrees of freedom!" << std::endl; KRATOS_INFO_IF("ResidualBasedBlockBuilderAndSolver", ( this->GetEchoLevel() > 2)) << "Number of degrees of freedom:" << BaseType::mDofSet.size() << std::endl; BaseType::mDofSetIsInitialized = true; KRATOS_INFO_IF("ResidualBasedBlockBuilderAndSolver", ( this->GetEchoLevel() > 2 && rModelPart.GetCommunicator().MyPID() == 0)) << "Finished setting up the dofs" << std::endl; #ifdef KRATOS_DEBUG // If reactions are to be calculated, we check if all the dofs have reactions defined // This is tobe done only in debug mode if (BaseType::GetCalculateReactionsFlag()) { for (auto dof_iterator = BaseType::mDofSet.begin(); dof_iterator != BaseType::mDofSet.end(); ++dof_iterator) { KRATOS_ERROR_IF_NOT(dof_iterator->HasReaction()) << "Reaction variable not set for the following : " <<std::endl << "Node : "<<dof_iterator->Id()<< std::endl << "Dof : "<<(dof_iterator)<<std::endl<<"Not possible to calculate reactions."<<std::endl; } } #endif KRATOS_CATCH(""); } /** * @brief Organises the dofset in order to speed up the building phase * @param rModelPart The model part of the problem to solve / void SetUpSystem( ModelPart& rModelPart ) override { //int free_id = 0; BaseType::mEquationSystemSize = BaseType::mDofSet.size(); int ndofs = static_cast<int>(BaseType::mDofSet.size()); #pragma omp parallel for firstprivate(ndofs) for (int i = 0; i < static_cast<int>(ndofs); i++) { typename DofsArrayType::iterator dof_iterator = BaseType::mDofSet.begin() + i; dof_iterator->SetEquationId(i); } } //*********************************************************************** //************************************************************************ void ResizeAndInitializeVectors( typename TSchemeType::Pointer pScheme, TSystemMatrixPointerType& pA, TSystemVectorPointerType& pDx, TSystemVectorPointerType& pb, ModelPart& rModelPart ) override { KRATOS_TRY if (pA == NULL) //if the pointer is not initialized initialize it to an empty matrix { TSystemMatrixPointerType pNewA = TSystemMatrixPointerType(new TSystemMatrixType(0, 0)); pA.swap(pNewA); } if (pDx == NULL) //if the pointer is not initialized initialize it to an empty matrix { TSystemVectorPointerType pNewDx = TSystemVectorPointerType(new TSystemVectorType(0)); pDx.swap(pNewDx); } if (pb == NULL) //if the pointer is not initialized initialize it to an empty matrix { TSystemVectorPointerType pNewb = TSystemVectorPointerType(new TSystemVectorType(0)); pb.swap(pNewb); } TSystemMatrixType& A = pA; TSystemVectorType& Dx = pDx; TSystemVectorType& b = pb; //resizing the system vectors and matrix if (A.size1() == 0 \|\| BaseType::GetReshapeMatrixFlag() == true) //if the matrix is not initialized { A.resize(BaseType::mEquationSystemSize, BaseType::mEquationSystemSize, false); ConstructMatrixStructure(pScheme, A, rModelPart); } else { if (A.size1() != BaseType::mEquationSystemSize \|\| A.size2() != BaseType::mEquationSystemSize) { KRATOS_ERROR <<"The equation system size has changed during the simulation. This is not permited."<<std::endl; A.resize(BaseType::mEquationSystemSize, BaseType::mEquationSystemSize, true); ConstructMatrixStructure(pScheme, A, rModelPart); } } if (Dx.size() != BaseType::mEquationSystemSize) Dx.resize(BaseType::mEquationSystemSize, false); TSparseSpace::SetToZero(Dx); if (b.size() != BaseType::mEquationSystemSize) { b.resize(BaseType::mEquationSystemSize, false); } TSparseSpace::SetToZero(b); ConstructMasterSlaveConstraintsStructure(rModelPart); KRATOS_CATCH("") } //*********************************************************************** //********************************************************************** void InitializeSolutionStep( ModelPart& rModelPart, TSystemMatrixType& rA, TSystemVectorType& rDx, TSystemVectorType& rb) override { KRATOS_TRY BaseType::InitializeSolutionStep(rModelPart, rA, rDx, rb); // Getting process info const ProcessInfo& r_process_info = rModelPart.GetProcessInfo(); // Computing constraints const int n_constraints = static_cast<int>(rModelPart.MasterSlaveConstraints().size()); auto constraints_begin = rModelPart.MasterSlaveConstraintsBegin(); #pragma omp parallel for schedule(guided, 512) firstprivate(n_constraints, constraints_begin) for (int k = 0; k < n_constraints; ++k) { auto it = constraints_begin + k; it->InitializeSolutionStep(r_process_info); // Here each constraint constructs and stores its T and C matrices. Also its equation slave_ids. } KRATOS_CATCH("") } //********************************************************************** //********************************************************************** void FinalizeSolutionStep( ModelPart& rModelPart, TSystemMatrixType& rA, TSystemVectorType& rDx, TSystemVectorType& rb) override { BaseType::FinalizeSolutionStep(rModelPart, rA, rDx, rb); // Getting process info const ProcessInfo& r_process_info = rModelPart.GetProcessInfo(); // Computing constraints const int n_constraints = static_cast<int>(rModelPart.MasterSlaveConstraints().size()); const auto constraints_begin = rModelPart.MasterSlaveConstraintsBegin(); #pragma omp parallel for schedule(guided, 512) firstprivate(n_constraints, constraints_begin) for (int k = 0; k < n_constraints; ++k) { auto it = constraints_begin + k; it->FinalizeSolutionStep(r_process_info); } } //********************************************************************** //********************************************************************** void CalculateReactions( typename TSchemeType::Pointer pScheme, ModelPart& rModelPart, TSystemMatrixType& A, TSystemVectorType& Dx, TSystemVectorType& b) override { TSparseSpace::SetToZero(b); //refresh RHS to have the correct reactions BuildRHSNoDirichlet(pScheme, rModelPart, b); const int ndofs = static_cast<int>(BaseType::mDofSet.size()); //NOTE: dofs are assumed to be numbered consecutively in the BlockBuilderAndSolver #pragma omp parallel for firstprivate(ndofs) for (int k = 0; k<ndofs; k++) { typename DofsArrayType::iterator dof_iterator = BaseType::mDofSet.begin() + k; const int i = (dof_iterator)->EquationId(); (dof_iterator)->GetSolutionStepReactionValue() = -b[i]; } } / * @brief Applies the dirichlet conditions. This operation may be very heavy or completely * unexpensive depending on the implementation choosen and on how the System Matrix is built. * @details For explanation of how it works for a particular implementation the user * should refer to the particular Builder And Solver choosen * @param pScheme The integration scheme considered * @param rModelPart The model part of the problem to solve * @param rA The LHS matrix * @param rDx The Unknowns vector * @param rb The RHS vector / void ApplyDirichletConditions( typename TSchemeType::Pointer pScheme, ModelPart& rModelPart, TSystemMatrixType& rA, TSystemVectorType& rDx, TSystemVectorType& rb ) override { const std::size_t system_size = rA.size1(); Vector scaling_factors (system_size); const auto it_dof_iterator_begin = BaseType::mDofSet.begin(); const int ndofs = static_cast<int>(BaseType::mDofSet.size()); // NOTE: dofs are assumed to be numbered consecutively in the BlockBuilderAndSolver #pragma omp parallel for firstprivate(ndofs) for (int k = 0; k<ndofs; k++) { auto it_dof_iterator = it_dof_iterator_begin + k; if (it_dof_iterator->IsFixed()) { scaling_factors[k] = 0.0; } else { scaling_factors[k] = 1.0; } } double Avalues = rA.value_data().begin(); std::size_t* Arow_indices = rA.index1_data().begin(); std::size_t* Acol_indices = rA.index2_data().begin(); // The diagonal considered mScaleFactor = GetScaleNorm(rModelPart, rA); // Detect if there is a line of all zeros and set the diagonal to a 1 if this happens #pragma omp parallel firstprivate(system_size) { std::size_t col_begin = 0, col_end = 0; bool empty = true; #pragma omp for for (int k = 0; k < static_cast<int>(system_size); ++k) { col_begin = Arow_indices[k]; col_end = Arow_indices[k + 1]; empty = true; for (std::size_t j = col_begin; j < col_end; ++j) { if(Avalues[j] != 0.0) { empty = false; break; } } if(empty) { rA(k, k) = mScaleFactor; rb[k] = 0.0; } } } #pragma omp parallel for firstprivate(system_size) for (int k = 0; k < static_cast<int>(system_size); ++k) { std::size_t col_begin = Arow_indices[k]; std::size_t col_end = Arow_indices[k+1]; const double k_factor = scaling_factors[k]; if (k_factor == 0.0) { // Zero out the whole row, except the diagonal for (std::size_t j = col_begin; j < col_end; ++j) if (static_cast<int>(Acol_indices[j]) != k ) Avalues[j] = 0.0; // Zero out the RHS rb[k] = 0.0; } else { // Zero out the column which is associated with the zero'ed row for (std::size_t j = col_begin; j < col_end; ++j) if(scaling_factors[ Acol_indices[j] ] == 0 ) Avalues[j] = 0.0; } } } /** * @brief Applies the constraints with master-slave relation matrix (RHS only) * @param pScheme The integration scheme considered * @param rModelPart The model part of the problem to solve * @param rb The RHS vector / void ApplyRHSConstraints( typename TSchemeType::Pointer pScheme, ModelPart& rModelPart, TSystemVectorType& rb ) override { KRATOS_TRY if (rModelPart.MasterSlaveConstraints().size() != 0) { BuildMasterSlaveConstraints(rModelPart); // We compute the transposed matrix of the global relation matrix TSystemMatrixType T_transpose_matrix(mT.size2(), mT.size1()); SparseMatrixMultiplicationUtility::TransposeMatrix<TSystemMatrixType, TSystemMatrixType>(T_transpose_matrix, mT, 1.0); TSystemVectorType b_modified(rb.size()); TSparseSpace::Mult(T_transpose_matrix, rb, b_modified); TSparseSpace::Copy(b_modified, rb); // Apply diagonal values on slaves #pragma omp parallel for for (int i = 0; i < static_cast<int>(mSlaveIds.size()); ++i) { const IndexType slave_equation_id = mSlaveIds[i]; if (mInactiveSlaveDofs.find(slave_equation_id) == mInactiveSlaveDofs.end()) { rb[slave_equation_id] = 0.0; } } } KRATOS_CATCH("") } /* * @brief Applies the constraints with master-slave relation matrix * @param pScheme The integration scheme considered * @param rModelPart The model part of the problem to solve * @param rA The LHS matrix * @param rb The RHS vector / void ApplyConstraints( typename TSchemeType::Pointer pScheme, ModelPart& rModelPart, TSystemMatrixType& rA, TSystemVectorType& rb ) override { KRATOS_TRY if (rModelPart.MasterSlaveConstraints().size() != 0) { BuildMasterSlaveConstraints(rModelPart); // We compute the transposed matrix of the global relation matrix TSystemMatrixType T_transpose_matrix(mT.size2(), mT.size1()); SparseMatrixMultiplicationUtility::TransposeMatrix<TSystemMatrixType, TSystemMatrixType>(T_transpose_matrix, mT, 1.0); TSystemVectorType b_modified(rb.size()); TSparseSpace::Mult(T_transpose_matrix, rb, b_modified); TSparseSpace::Copy(b_modified, rb); TSystemMatrixType auxiliar_A_matrix(mT.size2(), rA.size2()); SparseMatrixMultiplicationUtility::MatrixMultiplication(T_transpose_matrix, rA, auxiliar_A_matrix); //auxiliar = T_transpose rA T_transpose_matrix.resize(0, 0, false); //free memory SparseMatrixMultiplicationUtility::MatrixMultiplication(auxiliar_A_matrix, mT, rA); //A = auxilar * T NOTE: here we are overwriting the old A matrix! auxiliar_A_matrix.resize(0, 0, false); //free memory const double max_diag = GetMaxDiagonal(rA); // Apply diagonal values on slaves #pragma omp parallel for for (int i = 0; i < static_cast<int>(mSlaveIds.size()); ++i) { const IndexType slave_equation_id = mSlaveIds[i]; if (mInactiveSlaveDofs.find(slave_equation_id) == mInactiveSlaveDofs.end()) { rA(slave_equation_id, slave_equation_id) = max_diag; rb[slave_equation_id] = 0.0; } } } KRATOS_CATCH("") } /** * @brief This function is intended to be called at the end of the solution step to clean up memory storage not needed / void Clear() override { BaseType::Clear(); mSlaveIds.clear(); mMasterIds.clear(); mInactiveSlaveDofs.clear(); mT.resize(0,0,false); mConstantVector.resize(0,false); } /* * @brief This function is designed to be called once to perform all the checks needed * on the input provided. Checks can be "expensive" as the function is designed * to catch user's errors. * @param rModelPart The model part of the problem to solve * @return 0 all ok / int Check(ModelPart& rModelPart) override { KRATOS_TRY return 0; KRATOS_CATCH(""); } ///@} ///@name Access ///@{ ///@} ///@name Inquiry ///@{ ///@} ///@name Input and output ///@{ /// Turn back information as a string. std::string Info() const override { return "ResidualBasedBlockBuilderAndSolver"; } /// Print information about this object. void PrintInfo(std::ostream& rOStream) const override { rOStream << Info(); } /// Print object's data. void PrintData(std::ostream& rOStream) const override { rOStream << Info(); } ///@} ///@name Friends ///@{ ///@} protected: ///@name Protected static Member Variables ///@{ ///@} ///@name Protected member Variables ///@{ TSystemMatrixType mT; /// This is matrix containing the global relation for the constraints TSystemVectorType mConstantVector; /// This is vector containing the rigid movement of the constraint std::vector<IndexType> mSlaveIds; /// The equation ids of the slaves std::vector<IndexType> mMasterIds; /// The equation ids of the master std::unordered_set<IndexType> mInactiveSlaveDofs; /// The set containing the inactive slave dofs double mScaleFactor = 1.0; /// The manuallyset scale factor SCALING_DIAGONAL mScalingDiagonal; /// We identify the scaling considered for the dirichlet dofs Flags mOptions; /// Some flags used internally ///@} ///@name Protected Operators ///@{ ///@} ///@name Protected Operations ///@{ void BuildRHSNoDirichlet( typename TSchemeType::Pointer pScheme, ModelPart& rModelPart, TSystemVectorType& b) { KRATOS_TRY //Getting the Elements ElementsArrayType& pElements = rModelPart.Elements(); //getting the array of the conditions ConditionsArrayType& ConditionsArray = rModelPart.Conditions(); const ProcessInfo& CurrentProcessInfo = rModelPart.GetProcessInfo(); //contributions to the system LocalSystemMatrixType LHS_Contribution = LocalSystemMatrixType(0, 0); LocalSystemVectorType RHS_Contribution = LocalSystemVectorType(0); //vector containing the localization in the system of the different //terms Element::EquationIdVectorType EquationId; // assemble all elements //for (typename ElementsArrayType::ptr_iterator it = pElements.ptr_begin(); it != pElements.ptr_end(); ++it) const int nelements = static_cast<int>(pElements.size()); #pragma omp parallel firstprivate(nelements, RHS_Contribution, EquationId) { #pragma omp for schedule(guided, 512) nowait for (int i=0; i<nelements; i++) { typename ElementsArrayType::iterator it = pElements.begin() + i; //detect if the element is active or not. If the user did not make any choice the element //is active by default bool element_is_active = true; if( (it)->IsDefined(ACTIVE) ) { element_is_active = (it)->Is(ACTIVE); } if(element_is_active) { //calculate elemental Right Hand Side Contribution pScheme->CalculateRHSContribution(it, RHS_Contribution, EquationId, CurrentProcessInfo); //assemble the elemental contribution AssembleRHS(b, RHS_Contribution, EquationId); } } LHS_Contribution.resize(0, 0, false); RHS_Contribution.resize(0, false); // assemble all conditions const int nconditions = static_cast<int>(ConditionsArray.size()); #pragma omp for schedule(guided, 512) for (int i = 0; i<nconditions; i++) { auto it = ConditionsArray.begin() + i; //detect if the element is active or not. If the user did not make any choice the element //is active by default bool condition_is_active = true; if( (it)->IsDefined(ACTIVE) ) { condition_is_active = (it)->Is(ACTIVE); } if(condition_is_active) { //calculate elemental contribution pScheme->CalculateRHSContribution(it, RHS_Contribution, EquationId, CurrentProcessInfo); //assemble the elemental contribution AssembleRHS(b, RHS_Contribution, EquationId); } } } KRATOS_CATCH("") } virtual void ConstructMasterSlaveConstraintsStructure(ModelPart& rModelPart) { if (rModelPart.MasterSlaveConstraints().size() > 0) { const ProcessInfo& r_current_process_info = rModelPart.GetProcessInfo(); // Vector containing the localization in the system of the different terms DofsVectorType slave_dof_list, master_dof_list; // Constraint initial iterator const auto it_const_begin = rModelPart.MasterSlaveConstraints().begin(); std::vector<std::unordered_set<IndexType>> indices(BaseType::mDofSet.size()); std::vector<LockObject> lock_array(indices.size()); #pragma omp parallel firstprivate(slave_dof_list, master_dof_list) { Element::EquationIdVectorType slave_ids(3); Element::EquationIdVectorType master_ids(3); std::unordered_map<IndexType, std::unordered_set<IndexType>> temp_indices; #pragma omp for schedule(guided, 512) nowait for (int i_const = 0; i_const < static_cast<int>(rModelPart.MasterSlaveConstraints().size()); ++i_const) { auto it_const = it_const_begin + i_const; // Detect if the constraint is active or not. If the user did not make any choice the constraint // It is active by default bool constraint_is_active = true; if( it_const->IsDefined(ACTIVE) ) { constraint_is_active = it_const->Is(ACTIVE); } if(constraint_is_active) { it_const->EquationIdVector(slave_ids, master_ids, r_current_process_info); // Slave DoFs for (auto &id_i : slave_ids) { temp_indices[id_i].insert(master_ids.begin(), master_ids.end()); } } } // Merging all the temporal indexes for (int i = 0; i < static_cast<int>(temp_indices.size()); ++i) { lock_array[i].SetLock(); indices[i].insert(temp_indices[i].begin(), temp_indices[i].end()); lock_array[i].UnSetLock(); } } mSlaveIds.clear(); mMasterIds.clear(); for (int i = 0; i < static_cast<int>(indices.size()); ++i) { if (indices[i].size() == 0) // Master dof! mMasterIds.push_back(i); else // Slave dof mSlaveIds.push_back(i); indices[i].insert(i); // Ensure that the diagonal is there in T } // Count the row sizes std::size_t nnz = 0; for (IndexType i = 0; i < indices.size(); ++i) nnz += indices[i].size(); mT = TSystemMatrixType(indices.size(), indices.size(), nnz); mConstantVector.resize(indices.size(), false); double Tvalues = mT.value_data().begin(); IndexType Trow_indices = mT.index1_data().begin(); IndexType Tcol_indices = mT.index2_data().begin(); // Filling the index1 vector - DO NOT MAKE PARALLEL THE FOLLOWING LOOP! Trow_indices[0] = 0; for (int i = 0; i < static_cast<int>(mT.size1()); i++) Trow_indices[i + 1] = Trow_indices[i] + indices[i].size(); #pragma omp parallel for for (int i = 0; i < static_cast<int>(mT.size1()); ++i) { const IndexType row_begin = Trow_indices[i]; const IndexType row_end = Trow_indices[i + 1]; IndexType k = row_begin; for (auto it = indices[i].begin(); it != indices[i].end(); ++it) { Tcol_indices[k] = it; Tvalues[k] = 0.0; k++; } indices[i].clear(); //deallocating the memory std::sort(&Tcol_indices[row_begin], &Tcol_indices[row_end]); } mT.set_filled(indices.size() + 1, nnz); Timer::Stop("ConstraintsRelationMatrixStructure"); } } virtual void BuildMasterSlaveConstraints(ModelPart& rModelPart) { KRATOS_TRY TSparseSpace::SetToZero(mT); TSparseSpace::SetToZero(mConstantVector); // The current process info const ProcessInfo& r_current_process_info = rModelPart.GetProcessInfo(); // Vector containing the localization in the system of the different terms DofsVectorType slave_dof_list, master_dof_list; // Contributions to the system Matrix transformation_matrix = LocalSystemMatrixType(0, 0); Vector constant_vector = LocalSystemVectorType(0); // Vector containing the localization in the system of the different terms Element::EquationIdVectorType slave_equation_ids, master_equation_ids; const int number_of_constraints = static_cast<int>(rModelPart.MasterSlaveConstraints().size()); // We clear the set mInactiveSlaveDofs.clear(); #pragma omp parallel firstprivate(transformation_matrix, constant_vector, slave_equation_ids, master_equation_ids) { std::unordered_set<IndexType> auxiliar_inactive_slave_dofs; #pragma omp for schedule(guided, 512) for (int i_const = 0; i_const < number_of_constraints; ++i_const) { auto it_const = rModelPart.MasterSlaveConstraints().begin() + i_const; // Detect if the constraint is active or not. If the user did not make any choice the constraint // It is active by default bool constraint_is_active = true; if (it_const->IsDefined(ACTIVE)) constraint_is_active = it_const->Is(ACTIVE); if (constraint_is_active) { it_const->CalculateLocalSystem(transformation_matrix, constant_vector, r_current_process_info); it_const->EquationIdVector(slave_equation_ids, master_equation_ids, r_current_process_info); for (IndexType i = 0; i < slave_equation_ids.size(); ++i) { const IndexType i_global = slave_equation_ids[i]; // Assemble matrix row AssembleRowContribution(mT, transformation_matrix, i_global, i, master_equation_ids); // Assemble constant vector const double constant_value = constant_vector[i]; double& r_value = mConstantVector[i_global]; #pragma omp atomic r_value += constant_value; } } else { // Taking into account inactive constraints it_const->EquationIdVector(slave_equation_ids, master_equation_ids, r_current_process_info); auxiliar_inactive_slave_dofs.insert(slave_equation_ids.begin(), slave_equation_ids.end()); } } // We merge all the sets in one thread #pragma omp critical { mInactiveSlaveDofs.insert(auxiliar_inactive_slave_dofs.begin(), auxiliar_inactive_slave_dofs.end()); } } // Setting the master dofs into the T and C system for (auto eq_id : mMasterIds) { mConstantVector[eq_id] = 0.0; mT(eq_id, eq_id) = 1.0; } // Setting inactive slave dofs in the T and C system for (auto eq_id : mInactiveSlaveDofs) { mConstantVector[eq_id] = 0.0; mT(eq_id, eq_id) = 1.0; } KRATOS_CATCH("") } virtual void ConstructMatrixStructure( typename TSchemeType::Pointer pScheme, TSystemMatrixType& A, ModelPart& rModelPart) { //filling with zero the matrix (creating the structure) Timer::Start("MatrixStructure"); // Getting the elements from the model const int nelements = static_cast<int>(rModelPart.Elements().size()); // Getting the array of the conditions const int nconditions = static_cast<int>(rModelPart.Conditions().size()); const ProcessInfo& CurrentProcessInfo = rModelPart.GetProcessInfo(); ModelPart::ElementsContainerType::iterator el_begin = rModelPart.ElementsBegin(); ModelPart::ConditionsContainerType::iterator cond_begin = rModelPart.ConditionsBegin(); const std::size_t equation_size = BaseType::mEquationSystemSize; std::vector< LockObject > lock_array(equation_size); std::vector<std::unordered_set<std::size_t> > indices(equation_size); #pragma omp parallel for firstprivate(equation_size) for (int iii = 0; iii < static_cast<int>(equation_size); iii++) { indices[iii].reserve(40); } Element::EquationIdVectorType ids(3, 0); #pragma omp parallel for firstprivate(nelements, ids) for (int iii=0; iii<nelements; iii++) { typename ElementsContainerType::iterator i_element = el_begin + iii; pScheme->EquationId(i_element, ids, CurrentProcessInfo); for (std::size_t i = 0; i < ids.size(); i++) { lock_array[ids[i]].SetLock(); auto& row_indices = indices[ids[i]]; row_indices.insert(ids.begin(), ids.end()); lock_array[ids[i]].UnSetLock(); } } #pragma omp parallel for firstprivate(nconditions, ids) for (int iii = 0; iii<nconditions; iii++) { typename ConditionsArrayType::iterator i_condition = cond_begin + iii; pScheme->EquationId(i_condition, ids, CurrentProcessInfo); for (std::size_t i = 0; i < ids.size(); i++) { lock_array[ids[i]].SetLock(); auto& row_indices = indices[ids[i]]; row_indices.insert(ids.begin(), ids.end()); lock_array[ids[i]].UnSetLock(); } } //destroy locks lock_array = std::vector< LockObject >(); //count the row sizes unsigned int nnz = 0; for (unsigned int i = 0; i < indices.size(); i++) { nnz += indices[i].size(); } A = CompressedMatrixType(indices.size(), indices.size(), nnz); double Avalues = A.value_data().begin(); std::size_t* Arow_indices = A.index1_data().begin(); std::size_t* Acol_indices = A.index2_data().begin(); //filling the index1 vector - DO NOT MAKE PARALLEL THE FOLLOWING LOOP! Arow_indices[0] = 0; for (int i = 0; i < static_cast<int>(A.size1()); i++) { Arow_indices[i+1] = Arow_indices[i] + indices[i].size(); } #pragma omp parallel for for (int i = 0; i < static_cast<int>(A.size1()); i++) { const unsigned int row_begin = Arow_indices[i]; const unsigned int row_end = Arow_indices[i+1]; unsigned int k = row_begin; for (auto it = indices[i].begin(); it != indices[i].end(); it++) { Acol_indices[k] = it; Avalues[k] = 0.0; k++; } indices[i].clear(); //deallocating the memory std::sort(&Acol_indices[row_begin], &Acol_indices[row_end]); } A.set_filled(indices.size()+1, nnz); Timer::Stop("MatrixStructure"); } void Assemble( TSystemMatrixType& A, TSystemVectorType& b, const LocalSystemMatrixType& LHS_Contribution, const LocalSystemVectorType& RHS_Contribution, Element::EquationIdVectorType& EquationId ) { unsigned int local_size = LHS_Contribution.size1(); for (unsigned int i_local = 0; i_local < local_size; i_local++) { unsigned int i_global = EquationId[i_local]; double& r_a = b[i_global]; const double& v_a = RHS_Contribution(i_local); #pragma omp atomic r_a += v_a; AssembleRowContribution(A, LHS_Contribution, i_global, i_local, EquationId); } } //*********************************************************************** void AssembleLHS( TSystemMatrixType& rA, const LocalSystemMatrixType& rLHSContribution, Element::EquationIdVectorType& rEquationId ) { const SizeType local_size = rLHSContribution.size1(); for (IndexType i_local = 0; i_local < local_size; i_local++) { const IndexType i_global = rEquationId[i_local]; AssembleRowContribution(rA, rLHSContribution, i_global, i_local, rEquationId); } } //************************************************************************ void AssembleRHS( TSystemVectorType& b, LocalSystemVectorType& RHS_Contribution, Element::EquationIdVectorType& EquationId ) { unsigned int local_size = RHS_Contribution.size(); for (unsigned int i_local = 0; i_local < local_size; i_local++) { unsigned int i_global = EquationId[i_local]; // ASSEMBLING THE SYSTEM VECTOR double& b_value = b[i_global]; const double& rhs_value = RHS_Contribution[i_local]; #pragma omp atomic b_value += rhs_value; } } inline void AssembleRowContribution(TSystemMatrixType& A, const Matrix& Alocal, const unsigned int i, const unsigned int i_local, Element::EquationIdVectorType& EquationId) { double* values_vector = A.value_data().begin(); std::size_t* index1_vector = A.index1_data().begin(); std::size_t* index2_vector = A.index2_data().begin(); size_t left_limit = index1_vector[i]; // size_t right_limit = index1_vector[i+1]; //find the first entry size_t last_pos = ForwardFind(EquationId[0],left_limit,index2_vector); size_t last_found = EquationId[0]; double& r_a = values_vector[last_pos]; const double& v_a = Alocal(i_local,0); #pragma omp atomic r_a += v_a; //now find all of the other entries size_t pos = 0; for (unsigned int j=1; j<EquationId.size(); j++) { unsigned int id_to_find = EquationId[j]; if(id_to_find > last_found) { pos = ForwardFind(id_to_find,last_pos+1,index2_vector); } else if(id_to_find < last_found) { pos = BackwardFind(id_to_find,last_pos-1,index2_vector); } else { pos = last_pos; } double& r = values_vector[pos]; const double& v = Alocal(i_local,j); #pragma omp atomic r += v; last_found = id_to_find; last_pos = pos; } } /** * @brief This method returns the scale norm considering for scaling the diagonal * @param rModelPart The problem model part * @param rA The LHS matrix * @return The scale norm / double GetScaleNorm( ModelPart& rModelPart, TSystemMatrixType& rA ) { switch (mScalingDiagonal) { case SCALING_DIAGONAL::NO_SCALING: return 1.0; case SCALING_DIAGONAL::CONSIDER_PRESCRIBED_DIAGONAL: { const ProcessInfo& r_current_process_info = rModelPart.GetProcessInfo(); KRATOS_ERROR_IF_NOT(r_current_process_info.Has(BUILD_SCALE_FACTOR)) << "Scale factor not defined at process info" << std::endl; return r_current_process_info.GetValue(BUILD_SCALE_FACTOR); } case SCALING_DIAGONAL::CONSIDER_NORM_DIAGONAL: return GetDiagonalNorm(rA)/static_cast<double>(rA.size1()); case SCALING_DIAGONAL::CONSIDER_MAX_DIAGONAL: return GetMaxDiagonal(rA); // return TSparseSpace::TwoNorm(rA)/static_cast<double>(rA.size1()); default: return GetMaxDiagonal(rA); } } /* * @brief This method returns the diagonal norm considering for scaling the diagonal * @param rA The LHS matrix * @return The diagonal norm / double GetDiagonalNorm(TSystemMatrixType& rA) { double diagonal_norm = 0.0; #pragma omp parallel for reduction(+:diagonal_norm) for(int i = 0; i < static_cast<int>(TSparseSpace::Size1(rA)); ++i) { diagonal_norm += std::pow(rA(i,i), 2); } return std::sqrt(diagonal_norm); } /* * @brief This method returns the diagonal max value * @param rA The LHS matrix * @return The diagonal max value / double GetAveragevalueDiagonal(TSystemMatrixType& rA) { return 0.5 (GetMaxDiagonal(rA) + GetMinDiagonal(rA)); } /** * @brief This method returns the diagonal max value * @param rA The LHS matrix * @return The diagonal max value / double GetMaxDiagonal(TSystemMatrixType& rA) { // // NOTE: Reduction failing in MSVC // double max_diag = 0.0; // #pragma omp parallel for reduction(max:max_diag) // for(int i = 0; i < static_cast<int>(TSparseSpace::Size1(rA)); ++i) { // max_diag = std::max(max_diag, std::abs(rA(i,i))); // } // return max_diag; // Creating a buffer for parallel vector fill const int num_threads = OpenMPUtils::GetNumThreads(); Vector max_vector(num_threads, 0.0); #pragma omp parallel for for(int i = 0; i < static_cast<int>(TSparseSpace::Size1(rA)); ++i) { const int id = OpenMPUtils::ThisThread(); const double abs_value_ii = std::abs(rA(i,i)); if (abs_value_ii > max_vector[id]) max_vector[id] = abs_value_ii; } double max_diag = 0.0; for(int i = 0; i < num_threads; ++i) { max_diag = std::max(max_diag, max_vector[i]); } return max_diag; } /* * @brief This method returns the diagonal min value * @param rA The LHS matrix * @return The diagonal min value / double GetMinDiagonal(TSystemMatrixType& rA) { // // NOTE: Reduction failing in MSVC // double min_diag = std::numeric_limits<double>::max(); // #pragma omp parallel for reduction(min:min_diag) // for(int i = 0; i < static_cast<int>(TSparseSpace::Size1(rA)); ++i) { // min_diag = std::min(min_diag, std::abs(rA(i,i))); // } // return min_diag; // Creating a buffer for parallel vector fill const int num_threads = OpenMPUtils::GetNumThreads(); Vector min_vector(num_threads, std::numeric_limits<double>::max()); #pragma omp parallel for for(int i = 0; i < static_cast<int>(TSparseSpace::Size1(rA)); ++i) { const int id = OpenMPUtils::ThisThread(); const double abs_value_ii = std::abs(rA(i,i)); if (abs_value_ii < min_vector[id]) min_vector[id] = abs_value_ii; } double min_diag = std::numeric_limits<double>::max(); for(int i = 0; i < num_threads; ++i) { min_diag = std::min(min_diag, min_vector[i]); } return min_diag; } ///@} ///@name Protected Access ///@{ ///@} ///@name Protected Inquiry ///@{ ///@} ///@name Protected LifeCycle ///@{ ///@} private: ///@name Static Member Variables ///@{ ///@} ///@name Member Variables ///@{ ///@} ///@name Private Operators ///@{ ///@} ///@name Private Operations ///@{ inline void AddUnique(std::vector<std::size_t>& v, const std::size_t& candidate) { std::vector<std::size_t>::iterator i = v.begin(); std::vector<std::size_t>::iterator endit = v.end(); while (i != endit && (i) != candidate) { i++; } if (i == endit) { v.push_back(candidate); } } //**************************************************************************************** //**************************************************************************************** inline void CreatePartition(unsigned int number_of_threads, const int number_of_rows, DenseVector<unsigned int>& partitions) { partitions.resize(number_of_threads + 1); int partition_size = number_of_rows / number_of_threads; partitions[0] = 0; partitions[number_of_threads] = number_of_rows; for (unsigned int i = 1; i < number_of_threads; i++) { partitions[i] = partitions[i - 1] + partition_size; } } inline unsigned int ForwardFind(const unsigned int id_to_find, const unsigned int start, const size_t* index_vector) { unsigned int pos = start; while(id_to_find != index_vector[pos]) pos++; return pos; } inline unsigned int BackwardFind(const unsigned int id_to_find, const unsigned int start, const size_t* index_vector) { unsigned int pos = start; while(id_to_find != index_vector[pos]) pos--; return pos; } ///@} ///@name Private Operations ///@{ ///@} ///@name Private Access ///@{ ///@} ///@name Private Inquiry ///@{ ///@} ///@name Un accessible methods ///@{ ///@} }; /* Class ResidualBasedBlockBuilderAndSolver / ///@} ///@name Type Definitions ///@{ // Here one should use the KRATOS_CREATE_LOCAL_FLAG, but it does not play nice with template parameters template<class TSparseSpace, class TDenseSpace, class TLinearSolver> const Kratos::Flags ResidualBasedBlockBuilderAndSolver<TSparseSpace, TDenseSpace, TLinearSolver>::SILENT_WARNINGS(Kratos::Flags::Create(0)); ///@} } / namespace Kratos./ #endif / KRATOS_RESIDUAL_BASED_BLOCK_BUILDER_AND_SOLVER defined */
c_print_results.c	/***************************************************************/ /** C _ P R I N T _ R E S U L T S **/ /**************************************************************/ #include <stdlib.h> #include <stdio.h> #include <omp.h> void c_print_results( char name, char class, int n1, int n2, int n3, int niter, double t, double mops, char optype, int passed_verification, char npbversion, char compiletime, char cc, char clink, char c_lib, char c_inc, char cflags, char clinkflags ) { int num_threads; char num_threads_set; /* figure out number of threads used / #pragma omp parallel shared(num_threads) { #pragma omp master num_threads = omp_get_num_threads(); } num_threads_set = getenv("OMP_NUM_THREADS"); if (!num_threads_set) num_threads_set = "unset"; printf( "\n\n %s Benchmark Completed\n", name ); printf( " Class = %c\n", class ); if( n2 == 0 && n3 == 0 ) printf( " Size = %12d\n", n1 ); / as in IS / else printf( " Size = %3dx %3dx %3d\n", n1,n2,n3 ); printf( " Iterations = %12d\n", niter ); printf( " Time in seconds = %12.2f\n", t ); printf( " Total threads = %12d\n", num_threads); printf( " Request threads = %12s\n", num_threads_set); printf( " Mop/s total = %12.2f\n", mops ); printf( " Mop/s/thread = %12.2f\n", mops/(double)num_threads ); printf( " Operation type = %24s\n", optype); if( passed_verification ) printf( " Verification = SUCCESSFUL\n" ); else printf( " Verification = UNSUCCESSFUL\n" ); printf( " Version = %12s\n", npbversion ); printf( " Compile date = %12s\n", compiletime ); printf( "\n Compile options:\n" ); printf( " CC = %s\n", cc ); printf( " CLINK = %s\n", clink ); printf( " C_LIB = %s\n", c_lib ); printf( " C_INC = %s\n", c_inc ); printf( " CFLAGS = %s\n", cflags ); printf( " CLINKFLAGS = %s\n", clinkflags ); printf( "\n\n" ); printf( " Please send all errors/feedbacks to:\n\n" ); printf( " NPB Development Team\n" ); printf( " npb@nas.nasa.gov\n\n" ); / printf( " Please send the results of this run to:\n\n" ); printf( " NPB Development Team\n" ); printf( " Internet: npb@nas.nasa.gov\n \n" ); printf( " If email is not available, send this to:\n\n" ); printf( " MS T27A-1\n" ); printf( " NASA Ames Research Center\n" ); printf( " Moffett Field, CA 94035-1000\n\n" ); printf( " Fax: 650-604-3957\n\n" ); */ }
blas.c	#include "blas.h" #include <math.h> #include <assert.h> #include <float.h> #include <stdio.h> #include <stdlib.h> #include <string.h> void reorg_cpu(float x, int out_w, int out_h, int out_c, int batch, int stride, int forward, float out) { int b,i,j,k; int in_c = out_c/(stridestride); //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); for(b = 0; b < batch; ++b){ for(k = 0; k < out_c; ++k){ for(j = 0; j < out_h; ++j){ for(i = 0; i < out_w; ++i){ int in_index = i + out_w(j + out_h(k + out_cb)); int c2 = k % in_c; int offset = k / in_c; int w2 = istride + offset % stride; int h2 = jstride + offset / stride; int out_index = w2 + out_wstride(h2 + out_hstride(c2 + in_cb)); if(forward) out[out_index] = x[in_index]; // used by default for forward (i.e. forward = 0) else out[in_index] = x[out_index]; } } } } } void flatten(float x, int size, int layers, int batch, int forward) { float* swap = (float)calloc(size layers * batch, sizeof(float)); int i,c,b; for(b = 0; b < batch; ++b){ for(c = 0; c < layers; ++c){ for(i = 0; i < size; ++i){ int i1 = blayerssize + csize + i; int i2 = blayerssize + ilayers + c; if (forward) swap[i2] = x[i1]; else swap[i1] = x[i2]; } } } memcpy(x, swap, sizelayersbatchsizeof(float)); free(swap); } void weighted_sum_cpu(float a, float b, float s, int n, float c) { int i; for(i = 0; i < n; ++i){ c[i] = s[i]a[i] + (1-s[i])(b ? b[i] : 0); } } void weighted_delta_cpu(float a, float b, float s, float da, float db, float ds, int n, float dc) { int i; for(i = 0; i < n; ++i){ if(da) da[i] += dc[i] * s[i]; if(db) db[i] += dc[i] * (1-s[i]); ds[i] += dc[i] * (a[i] - b[i]); } } void shortcut_cpu(int batch, int w1, int h1, int c1, float add, int w2, int h2, int c2, float out) { int stride = w1/w2; int sample = w2/w1; assert(stride == h1/h2); assert(sample == h2/h1); if(stride < 1) stride = 1; if(sample < 1) sample = 1; int minw = (w1 < w2) ? w1 : w2; int minh = (h1 < h2) ? h1 : h2; int minc = (c1 < c2) ? c1 : c2; int i,j,k,b; for(b = 0; b < batch; ++b){ for(k = 0; k < minc; ++k){ for(j = 0; j < minh; ++j){ for(i = 0; i < minw; ++i){ int out_index = isample + w2(jsample + h2(k + c2b)); int add_index = istride + w1(jstride + h1(k + c1b)); out[out_index] += add[add_index]; } } } } } void mean_cpu(float x, int batch, int filters, int spatial, float mean) { float scale = 1./(batch * spatial); int i,j,k; for(i = 0; i < filters; ++i){ mean[i] = 0; for(j = 0; j < batch; ++j){ for(k = 0; k < spatial; ++k){ int index = jfiltersspatial + ispatial + k; mean[i] += x[index]; } } mean[i] = scale; } } void variance_cpu(float x, float mean, int batch, int filters, int spatial, float variance) { float scale = 1./(batch spatial - 1); int i,j,k; for(i = 0; i < filters; ++i){ variance[i] = 0; for(j = 0; j < batch; ++j){ for(k = 0; k < spatial; ++k){ int index = jfiltersspatial + ispatial + k; variance[i] += pow((x[index] - mean[i]), 2); } } variance[i] = scale; } } void normalize_cpu(float x, float mean, float variance, int batch, int filters, int spatial) { #pragma omp simd collapse(2) for(int b = 0; b < batch; ++b){ for(int f = 0; f < filters; ++f){ float meanf = mean[f]; float sqrtvarfc = sqrt(variance[f]) + .000001f; for(int i = 0; i < spatial; ++i){ int index = bfiltersspatial + fspatial + i; x[index] = (x[index] - meanf) / sqrtvarfc; } } } } #pragma omp declare simd void const_cpu(int N, float ALPHA, float X, int INCX) { int NINCX = N INCX; #pragma omp simd for(int i = 0; i < NINCX; i += INCX){ X[i] = ALPHA; } } #pragma omp declare simd aligned(X,Y:16) void mul_cpu(int N, float __restrict__ X, int INCX, float __restrict__ Y, int INCY) { #pragma omp simd aligned(X,Y:16) safelen(4) for(int i = 0; i < N; ++i){ Y[iINCY] = X[iINCX]; } } #pragma omp declare simd aligned(X,Y:16) void pow_cpu(int N, float ALPHA, float __restrict__ X, int INCX, float __restrict__ Y, int INCY) { #pragma omp simd aligned(X,Y:16) safelen(4) for(int i = 0; i < N; ++i){ Y[iINCY] = pow(X[iINCX], ALPHA); } } #pragma omp declare simd aligned(X,Y:16) void axpy_cpu(int N, float ALPHA, float __restrict__ X, int INCX, float __restrict__ Y, int INCY) { #pragma omp simd aligned(X,Y:16) safelen(4) for(int i = 0; i < N; ++i){ Y[iINCY] += ALPHAX[iINCX]; } } #pragma omp declare simd void scal_cpu(int N, float ALPHA, float X, int INCX) { int NINCX = N INCX; #pragma omp simd for(int i = 0; i < NINCX; i += INCX){ X[i] = ALPHA; } } #pragma omp declare simd void fill_cpu(int N, float ALPHA, float X, int INCX) { int NINCX; if (INCX == 1 && ALPHA == 0) { memset(X, 0, N * sizeof(float)); } else { NINCX = N * INCX; #pragma omp simd for(int i = 0; i < NINCX; i += INCX){ X[i] = ALPHA; } } } void deinter_cpu(int NX, float X, int NY, float Y, int B, float OUT) { int i, j; int index = 0; for(j = 0; j < B; ++j) { for(i = 0; i < NX; ++i){ if(X) X[jNX + i] += OUT[index]; ++index; } for(i = 0; i < NY; ++i){ if(Y) Y[jNY + i] += OUT[index]; ++index; } } } void inter_cpu(int NX, float X, int NY, float Y, int B, float OUT) { int i, j; int index = 0; for(j = 0; j < B; ++j) { for(i = 0; i < NX; ++i){ OUT[index++] = X[jNX + i]; } for(i = 0; i < NY; ++i){ OUT[index++] = Y[jNY + i]; } } } #pragma omp declare simd aligned(X,Y:16) void copy_cpu(int N, float __restrict__ X, int INCX, float __restrict__ Y, int INCY) { #pragma omp simd aligned(X,Y:16) safelen(4) for(int i = 0; i < N; ++i){ Y[iINCY] = X[iINCX]; } } #pragma omp declare simd aligned(X,Y,Z:16) void mult_add_into_cpu(int N, float __restrict__ X, float __restrict__ Y, float __restrict__ Z) { #pragma omp simd aligned(X,Y,Z:16) safelen(4) for(int i = 0; i < N; ++i){ Z[i] += X[i]Y[i]; } } void smooth_l1_cpu(int n, float pred, float truth, float delta, float error) { int i; for(i = 0; i < n; ++i){ float diff = truth[i] - pred[i]; float abs_val = fabs(diff); if(abs_val < 1) { error[i] = diff * diff; delta[i] = diff; } else { error[i] = 2abs_val - 1; delta[i] = (diff > 0) ? 1 : -1; } } } void l1_cpu(int n, float pred, float truth, float delta, float error) { int i; for(i = 0; i < n; ++i){ float diff = truth[i] - pred[i]; error[i] = fabs(diff); delta[i] = diff > 0 ? 1 : -1; } } void softmax_x_ent_cpu(int n, float pred, float truth, float delta, float error) { int i; for(i = 0; i < n; ++i){ float t = truth[i]; float p = pred[i]; error[i] = (t) ? -log(p) : 0; delta[i] = t-p; } } void logistic_x_ent_cpu(int n, float pred, float truth, float delta, float error) { int i; for(i = 0; i < n; ++i){ float t = truth[i]; float p = pred[i]; error[i] = -tlog(p) - (1-t)log(1-p); delta[i] = t-p; } } void l2_cpu(int n, float pred, float truth, float delta, float error) { int i; for(i = 0; i < n; ++i){ float diff = truth[i] - pred[i]; error[i] = diff diff; delta[i] = diff; } } #pragma omp declare simd aligned(X,Y:16) float dot_cpu(int N, float __restrict__ X, int INCX, float __restrict__ Y, int INCY) { int i; float dot = 0; #pragma omp simd reduction(+:dot) for(i = 0; i < N; ++i){ dot += X[iINCX] Y[iINCY]; } return dot; } void softmax(float input, int n, float temp, float output, int stride) { int i; float sum = 0; float largest = -FLT_MAX; for(i = 0; i < n; ++i){ if(input[istride] > largest) largest = input[istride]; } for(i = 0; i < n; ++i){ float e = exp(input[istride]/temp - largest/temp); sum += e; output[istride] = e; } for(i = 0; i < n; ++i){ output[istride] /= sum; } } void softmax_cpu(float input, int n, int batch, int batch_offset, int groups, int group_offset, int stride, float temp, float output) { int g, b; for(b = 0; b < batch; ++b){ for(g = 0; g < groups; ++g){ softmax(input + bbatch_offset + ggroup_offset, n, temp, output + bbatch_offset + ggroup_offset, stride); } } } void upsample_cpu(float in, int w, int h, int c, int batch, int stride, int forward, float scale, float out) { int i, j, k, b; for (b = 0; b < batch; ++b) { for (k = 0; k < c; ++k) { for (j = 0; j < hstride; ++j) { for (i = 0; i < wstride; ++i) { int in_index = bwhc + kwh + (j / stride)w + i / stride; int out_index = bwhcstridestride + kwhstridestride + jwstride + i; if (forward) out[out_index] = scalein[in_index]; else in[in_index] += scale*out[out_index]; } } } } }
postgres_fmt_plug.c	/* PostgreSQL MD5 challenge-response cracker patch for JtR. Hacked together * during October of 2012 by Dhiru Kholia <dhiru.kholia at gmail.com>. * * Use Ettercap to get PostgreSQL MD5 challenge-response pairs in JtR format. * E.g. ettercap -Tq -r /home/user/sample.pcap * * Input format: * $postgres$usersalthash * * This software is Copyright (c) 2012, Dhiru Kholia <dhiru.kholia at gmail.com> * and Copyright magnum 2013, * 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. / #if FMT_EXTERNS_H extern struct fmt_main fmt_postgres; #elif FMT_REGISTERS_H john_register_one(&fmt_postgres); #else #include <string.h> #include <errno.h> #ifdef _OPENMP static int omp_t = 1; #include <omp.h> #ifndef OMP_SCALE #define OMP_SCALE 2048 // scaled on K8-dual HT #endif #endif #include "md5.h" #include "arch.h" #include "misc.h" #include "common.h" #include "formats.h" #include "params.h" #include "options.h" #include "memdbg.h" #define FORMAT_LABEL "postgres" #define FORMAT_NAME "PostgreSQL C/R" #define FORMAT_TAG "$postgres$" #define FORMAT_TAG_LEN (sizeof(FORMAT_TAG)-1) #define FORMAT_TAG2 "$postgre$" #define FORMAT_TAG2_LEN (sizeof(FORMAT_TAG2)-1) #define ALGORITHM_NAME "MD5 32/" ARCH_BITS_STR #define BENCHMARK_COMMENT "" #define BENCHMARK_LENGTH -1 #define PLAINTEXT_LENGTH 32 #define BINARY_SIZE 16 #define BINARY_ALIGN MEM_ALIGN_WORD #define SALT_SIZE sizeof(struct custom_salt) #define SALT_ALIGN MEM_ALIGN_NONE #define MAX_USERNAME_LEN 64 #define MIN_KEYS_PER_CRYPT 1 #define MAX_KEYS_PER_CRYPT 1 static struct fmt_tests postgres_tests[] = { {"$postgres$postgresf063f05d1d586cc8d137e5f1733f234d224393e8", "openwall"}, {"$postgres$postgresc31803a21c4e11fb51835c3bbe9851ec91ec1375", "password"}, / $postgre$ is supported but deprecated / {"$postgre$postgres684697c8bf2a64f35feba7bf1b633d60393c1356", "openwall"}, / $postgres$ with longer user name / {"$postgres$Twelve_chars55393156c01df9affa7573ef32ec143759f3e005", "HookFish__2"}, {"$postgres$postgres65687433b782eca219ad84b58f26d25e19a1bbc9", "thisisalongstring"}, {"$postgres$postgres3337427377e0016f1b92cdea7291ab0ed21798b8", "string with space"}, {"$postgres$postgres6f734f37d5451e93f6ac9a0d30336ec106e91cf5", "123456789"}, {"$postgres$postgres3348654b0f0f46a3dfebf45f4320d2edeabc318f", ""}, {NULL} }; static char (saved_key)[PLAINTEXT_LENGTH + 1]; static ARCH_WORD_32 (crypt_out)[BINARY_SIZE / sizeof(ARCH_WORD_32)]; static struct custom_salt { unsigned char user[MAX_USERNAME_LEN + 1]; unsigned char salt[4]; } cur_salt; static void init(struct fmt_main self) { #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(self->params.max_keys_per_crypt, sizeof(saved_key)); crypt_out = mem_calloc(self->params.max_keys_per_crypt, sizeof(crypt_out)); } static void done(void) { MEM_FREE(crypt_out); MEM_FREE(saved_key); } static int valid(char ciphertext, struct fmt_main self) { const char p; int extra; if (strncmp(ciphertext, FORMAT_TAG, FORMAT_TAG_LEN)) return 0; / Check hash / if (!(p = strrchr(ciphertext, ''))) return 0; if (hexlenl(&p[1], &extra) != 2BINARY_SIZE \|\| extra) return 0; / Check salt / p -= 9; if (p != '') return 0; if (hexlenl(&p[1], 0) != 8) return 0; / Check username length / if (p - ciphertext - FORMAT_TAG_LEN > MAX_USERNAME_LEN) return 0; return 1; } static char prepare(char split_fields[10], struct fmt_main self) { static char out[FORMAT_TAG_LEN + sizeof(struct custom_salt) + 2BINARY_SIZE +2+1]; / Replace deprecated tag / if (split_fields[1] && !strncmp(split_fields[1], FORMAT_TAG2, FORMAT_TAG2_LEN)) { snprintf(out, sizeof(out), "%s%s", FORMAT_TAG, &split_fields[1][FORMAT_TAG2_LEN]); if (valid(out, self)) return out; } return split_fields[1]; } static void get_salt(char ciphertext) { char ctcopy = strdup(ciphertext); char keeptr = ctcopy; char p; int i; static struct custom_salt cs; ctcopy += FORMAT_TAG_LEN; / skip over "$postgres$" / p = strtokm(ctcopy, ""); memset(&cs, 0, sizeof(cs)); strnzcpy((char)cs.user, p, MAX_USERNAME_LEN + 1); p = strtokm(NULL, ""); for (i = 0; i < 4; i++) cs.salt[i] = atoi16[ARCH_INDEX(p[i * 2])] * 16 + atoi16[ARCH_INDEX(p[i * 2 + 1])]; MEM_FREE(keeptr); return (void )&cs; } 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 get_hash_0(int index) { return crypt_out[index][0] & PH_MASK_0; } static int get_hash_1(int index) { return crypt_out[index][0] & PH_MASK_1; } static int get_hash_2(int index) { return crypt_out[index][0] & PH_MASK_2; } static int get_hash_3(int index) { return crypt_out[index][0] & PH_MASK_3; } static int get_hash_4(int index) { return crypt_out[index][0] & PH_MASK_4; } static int get_hash_5(int index) { return crypt_out[index][0] & PH_MASK_5; } static int get_hash_6(int index) { return crypt_out[index][0] & PH_MASK_6; } static void set_salt(void salt) { cur_salt = (struct custom_salt )salt; } 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 int crypt_all(int pcount, struct db_salt salt) { const int count = pcount; int index = 0; #ifdef _OPENMP #pragma omp parallel for #endif #if defined(_OPENMP) \|\| MAX_KEYS_PER_CRYPT > 1 for (index = 0; index < count; index++) #endif { MD5_CTX ctx; unsigned char out[32]; MD5_Init(&ctx); MD5_Update(&ctx, saved_key[index], strlen(saved_key[index])); MD5_Update(&ctx, cur_salt->user, strlen((char)cur_salt->user)); MD5_Final((unsigned char)crypt_out[index], &ctx); hex_encode((unsigned char)crypt_out[index], 16, out); MD5_Init(&ctx); MD5_Update(&ctx, out, 32); MD5_Update(&ctx, cur_salt->salt, 4); MD5_Final((unsigned char)crypt_out[index], &ctx); } return count; } static int cmp_all(void binary, int count) { int index = 0; #if defined(_OPENMP) \|\| MAX_KEYS_PER_CRYPT > 1 for (; index < count; index++) #endif if (!memcmp(binary, crypt_out[index], ARCH_SIZE)) return 1; return 0; } static int cmp_one(void binary, int index) { return !memcmp(binary, crypt_out[index], BINARY_SIZE); } static int cmp_exact(char source, int index) { return 1; } static void postgres_set_key(char key, int index) { int saved_len = strlen(key); if (saved_len > PLAINTEXT_LENGTH) saved_len = PLAINTEXT_LENGTH; memcpy(saved_key[index], key, saved_len); saved_key[index][saved_len] = 0; } static char get_key(int index) { return saved_key[index]; } struct fmt_main fmt_postgres = { { 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_OMP \| FMT_OMP_BAD, { NULL }, { FORMAT_TAG, FORMAT_TAG2 }, postgres_tests }, { init, done, fmt_default_reset, prepare, valid, fmt_default_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 }, fmt_default_salt_hash, NULL, set_salt, postgres_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 */
utils.c	#include <stdio.h> #include <stdlib.h> #include <time.h> #include <omp.h> void print_mat(int n , int mat) { int i,j; for (i = 0; i < n; i++){ printf("%X: ",mat[i]); for (j = 0; j < n; j++){ printf("%d ",mat[i][j]); } printf("\n"); } printf("\n"); } void free_mat(int n, int mat) { int i; for(i = 0; i < n; i++) { free(mat[i]); } free(mat); } int make_rand_mat(int n, int max_val) { double begin,end; int i,j; int mat = malloc(sizeof(int)n); begin = omp_get_wtime(); srand(time(NULL)); // generate rand seed from current time #pragma omp parallel for private(i,j) firstprivate (n) for (i = 0; i < n; i++) { mat[i] = malloc(sizeof(int)n); #pragma omp parallel for private(j) for (j = 0; j < n; j++) { mat[i][j] = rand() % max_val; } } end = omp_get_wtime(); printf("matrix initialization with random numbers took %lf seconds\n", end - begin); return mat; } int make_rand_mat_1d(int n, int max_val) { double begin,end; int* mat = malloc(nnsizeof(int)); int i; begin = omp_get_wtime(); srand(time(NULL)); // generate rand seed from current time #pragma omp parallel for private(i) firstprivate (n) for (i = 0; i < nn; i++) { mat[i] = 1; //rand() % max_val; } end = omp_get_wtime(); printf("matrix initialization with random numbers took %lf seconds\n", end - begin); return mat; } int* make_zero_mat(int n) { double begin,end; int i,j; int** mat = malloc (sizeof(int)n); begin = omp_get_wtime(); srand(time(NULL)); // generate rand seed from current time #pragma omp parallel for private(i,j) firstprivate (n) for (i = 0; i < n; i++) { mat[i] = calloc(n, sizeof(int)); } end = omp_get_wtime(); printf("matrix initialization with zeros took %lf seconds\n", end - begin); return mat; } int* make_zero_mat_1d(int n) { double begin,end; int i; int* mat = malloc (nnsizeof(int)); begin = omp_get_wtime(); srand(time(NULL)); // generate rand seed from current time mat = calloc(nn, sizeof(int)); end = omp_get_wtime(); printf("matrix initialization with zeros took %lf seconds\n", end - begin); return mat; } int compare_pat(int n, int* bad_i, int* bad_j, int mat1, int mat2) { int i,j; for(i = 0; i < n; i++) { for(j = 0; j < n; j++) { if(mat1[i][j] - mat2[i][j]) { bad_i = i; bad_j = j; return 1; } } } return 0; }
2mm.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 "2mm.h" / Array initialization. / static void init_array( int ni, int nj, int nk, int nl, DATA_TYPE alpha, DATA_TYPE beta, DATA_TYPE POLYBENCH_2D( A, NI, NK, ni, nl ), DATA_TYPE POLYBENCH_2D( B, NK, NJ, nk, nj ), DATA_TYPE POLYBENCH_2D( C, NL, NJ, nl, nj ), DATA_TYPE POLYBENCH_2D( D, NI, NL, ni, nl ) ) { int i, j; alpha = 32412; beta = 2123; 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 < nl; i++ ) for ( j = 0; j < nj; j++ ) { C[i][j] = ( ( DATA_TYPE ) i * ( j + 3 ) ) / nl; } for ( i = 0; i < ni; 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( D, NI, NL, ni, nl ) ) { int i, j; for ( i = 0; i < ni; i++ ) for ( j = 0; j < nl; j++ ) { fprintf ( stderr, DATA_PRINTF_MODIFIER, D[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_2mm( int ni, int nj, int nk, int nl, DATA_TYPE alpha, DATA_TYPE beta, DATA_TYPE POLYBENCH_2D( tmp, 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( C, NL, NJ, nl, nj ), DATA_TYPE POLYBENCH_2D( D, NI, NL, ni, nl ) ) { int i, j, k; //~ #pragma omp parallel //~ { #pragma omp parallel for private (j, k) for ( i = 0; i < _PB_NI; i++ ) for ( j = 0; j < _PB_NJ; j++ ) { tmp[i][j] = 0; for ( k = 0; k < _PB_NK; ++k ) { tmp[i][j] += alpha A[i][k] * B[k][j]; } } #pragma omp parallel for private (j, k) for ( i = 0; i < _PB_NI; i++ ) for ( j = 0; j < _PB_NL; j++ ) { D[i][j] = beta; for ( k = 0; k < _PB_NJ; ++k ) { D[i][j] += tmp[i][k] C[k][j]; } } //~ } } static void * xmalloc ( size_t num ) { void* new = NULL; int ret = posix_memalign ( &new, 32, num ); if ( ! new \|\| ret ) { fprintf ( stderr, "[PolyBench] posix_memalign: cannot allocate memory" ); exit ( 1 ); } return new; } void polybench_alloc_data( unsigned long long int n, int elt_size ) { / FIXME: detect overflow! / size_t val = n; void ret; val = elt_size; ret = xmalloc( val ); return ret; } int main( int argc, char* argv ) { /* Retrieve problem size. / int ni = NI; int nj = NJ; int nk = NK; int nl = NL; / Variable declaration/allocation. / DATA_TYPE alpha; DATA_TYPE beta; POLYBENCH_2D_ARRAY_DECL( tmp, 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( C, DATA_TYPE, NL, NJ, nl, nj ); POLYBENCH_2D_ARRAY_DECL( D, DATA_TYPE, NI, NL, ni, nl ); POLYBENCH_2D_ARRAY_ALLOC( tmp, DATA_TYPE, NI, NJ, ni, nj ); POLYBENCH_2D_ARRAY_ALLOC( A, DATA_TYPE, NI, NK, ni, nk ); POLYBENCH_2D_ARRAY_ALLOC( B, DATA_TYPE, NK, NJ, nk, nj ); POLYBENCH_2D_ARRAY_ALLOC( C, DATA_TYPE, NL, NJ, nl, nj ); POLYBENCH_2D_ARRAY_ALLOC( D, DATA_TYPE, NI, NL, ni, nl ); / Initialize array(s). / init_array ( ni, nj, nk, nl, &alpha, &beta, POLYBENCH_ARRAY( A ), POLYBENCH_ARRAY( B ), POLYBENCH_ARRAY( C ), POLYBENCH_ARRAY( D ) ); / Run kernel. / kernel_2mm ( ni, nj, nk, nl, alpha, beta, POLYBENCH_ARRAY( tmp ), POLYBENCH_ARRAY( A ), POLYBENCH_ARRAY( B ), POLYBENCH_ARRAY( C ), POLYBENCH_ARRAY( D ) ); / 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( D ) ) ); / Be clean. */ POLYBENCH_FREE_ARRAY( tmp ); POLYBENCH_FREE_ARRAY( A ); POLYBENCH_FREE_ARRAY( B ); POLYBENCH_FREE_ARRAY( C ); POLYBENCH_FREE_ARRAY( D ); return 0; }
pr64769.c	/* PR tree-optimization/64769 / / { dg-do compile } / / { dg-options "-fopenmp-simd" } */ #pragma omp declare simd linear(i) void foo (int i) { }
pqECDSA_verify.c	/* Name: pqECDSA_verify.c Author: Tan Teik Guan Description: Verify function for pq resistance for ECDSA using ZKBoo. Modified from MPC_SHA256_VERIFIER.c / / ============================================================================ Name : MPC_SHA256_VERIFIER.c Author : Sobuno Version : 0.1 Description : Verifies a proof for SHA-256 generated by MPC_SHA256.c ============================================================================ / #include <stdbool.h> #include <stdint.h> #include <stdio.h> #include <stdlib.h> #include <string.h> #include <sys/time.h> #include "pqECDSA_shared.h" int NUM_ROUNDS = 100; int numLoops = 1; void printbits(uint32_t n) { if (n) { printbits(n >> 1); printf("%d", n & 1); } } int main(int argc, char argv[]) { setbuf(stdout, NULL); init_EVP(); openmp_thread_setup(); unsigned char tbs[MSG_SIZE]; unsigned char r[MSG_SIZE]; unsigned char S[MSG_SIZE]; int i; if (argc != 5) { printf("Usage: %s <number of rounds (e.g. 20, 40, 60, 80, 100)> <to be signed (Hex 64 char)> <Signature r (Hex 64 char)> <Signature s (Hex 64 char)\n",argv[0]); return -1; } NUM_ROUNDS = atoi(argv[1]); hexToBin32(argv[2],tbs); hexToBin32(argv[3],r); hexToBin32(argv[4],S); printf("Iterations of SHA: %d\n", NUM_ROUNDS); a as[NUM_ROUNDS]; z zs[NUM_ROUNDS]; FILE file; char outputFile[3sizeof(int) + 8]; sprintf(outputFile, "ECDSA%i.bin", NUM_ROUNDS); file = fopen(outputFile, "rb"); if (!file) { printf("Unable to open file!"); return -1; } fread(&as, sizeof(a), NUM_ROUNDS, file); fread(&zs, sizeof(z), NUM_ROUNDS, file); fclose(file); struct timeval begin, delta; gettimeofday(&begin,NULL); for (int loops=0;loops<numLoops;loops++) { int err = 0; uint32_t y[32]; for (int i = 0; i< 32; i++) y[i] = as[0].yp[0][i]^as[0].yp[1][i]^as[0].yp[2][i]; int es[NUM_ROUNDS2]; H3(y,as, NUM_ROUNDS, es); #pragma omp parallel for for(int i = 0; i<(NUM_ROUNDS); i++) { unsigned char bufx[32],bufy[32]; MP_INT bigS,bigr; MP_INT Pubx,Puby; MP_INT bigu1,bigu2; MP_INT bigGx, bigGy; MP_INT biginvS; MP_INT bigH,mod; err = 0; mpz_init(&bigS); mpz_init(&bigr); mpz_init(&Pubx); mpz_init(&Puby); ecReconstruct(&(as[i].yp[0][0]),&(as[i].yp[1][0]),&(as[i].yp[2][0]),&(as[i].yp[0][8]),&(as[i].yp[1][8]),&(as[i].yp[2][8]),bufx,bufy); mpz_import(&Pubx,32,1,1,0,0,bufx); mpz_import(&Puby,32,1,1,0,0,bufy); mpz_import(&bigr,8,1,4,0,0,&(as[0].yp[0][16])); mpz_import(&bigS,32,1,1,0,0,r); if (mpz_cmp(&bigr,&bigS)) { printf("signature r does not match: "); mpz_out_str(stdout,16,&bigr); printf("vs "); mpz_out_str(stdout,16,&bigS); printf("\n"); err \|= 1; } reconstruct(&(as[0].yp[0][24]),&(as[0].yp[1][24]),&(as[0].yp[2][24]),bufx); mpz_import(&bigS,32,1,1,0,0,bufx); for (int i=0; i<32;i++) { if (bufx[i] != S[i]) { printf("signature S at byte %d [%02X][%02x] does not match\n",i,bufx[i],S[i]); err \|= 2; } } // printf("verifying signature for ECDSA(tbs): "); mpz_init(&biginvS); mpz_init(&bigu1); mpz_init(&bigu2); mpz_init(&bigH); mpz_import(&bigH,32,1,1,0,0,tbs); mpz_init_set_str(&mod,CURVE_N,16); ecInvMod(&biginvS,&bigS,&mod); mpz_mul(&bigu1,&bigH,&biginvS); mpz_mod(&bigu1,&bigu1,&mod); mpz_mul(&bigu2,&bigr,&biginvS); mpz_mod(&bigu2,&bigu2,&mod); mpz_init_set_str(&bigGx,CURVE_Gx,16); mpz_init_set_str(&bigGy,CURVE_Gy,16); ecMul(&bigGx,&bigGy,&bigu1); ecMul(&Pubx,&Puby,&bigu2); ecAddPoint(&bigGx,&bigGy,&Pubx,&Puby); mpz_mod(&bigGx,&bigGx,&mod); if (mpz_cmp(&bigGx,&bigr)) { printf("invalid r. computed r : "); mpz_out_str(stdout,16,&bigGx); printf("\n"); err \|= 4; } if (!err) { int verifyResult = verify(as[i], es[i], zs[i]); if (verifyResult != 0) { printf("round [%d] : Not Verified rc = %d\n", i, verifyResult); } else { printf("round [%d] ok \n",i); } } else printf("round [%d] error code = %d\n",i,err); mpz_clear(&biginvS); mpz_clear(&bigu1); mpz_clear(&bigu2); mpz_clear(&bigH); mpz_clear(&bigS); mpz_clear(&bigr); mpz_clear(&Pubx); mpz_clear(&Puby); mpz_clear(&mod); mpz_clear(&bigGx); mpz_clear(&bigGy); } } gettimeofday(&delta,NULL); unsigned long inMilli = (delta.tv_sec - begin.tv_sec)1000000 + (delta.tv_usec - begin.tv_usec); inMilli /= 1000; printf("Total time for %d loops of %d rounds: %ju miliseconds\n", numLoops,NUM_ROUNDS,(uintmax_t)inMilli); printf("Time taken for 1 loops: %ju miliseconds\n", (uintmax_t)inMilli/numLoops); openmp_thread_cleanup(); cleanup_EVP(); return EXIT_SUCCESS; }
grid.c	/* Copyright 2014-2015 The Regents of the University of California. * Copyright 2015-2018 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. * * 2011, 2015, 2018 Martin Uecker <martin.uecker@med.uni-goettingen.de> * 2014 Frank Ong <frankong@berkeley.edu> / #include <math.h> #include <complex.h> #include <assert.h> #include <string.h> #include "num/multind.h" #include "num/flpmath.h" #include "num/specfun.h" #include "misc/nested.h" #include "misc/misc.h" #include "grid.h" #define KB_BETA 13.9086 // 13.8551 // 2x oversampling #define KB_WIDTH 3 #ifndef KB128 static double kb(double beta, double x) { if (fabs(x) >= 0.5) return 0.; return bessel_i0(beta sqrt(1. - pow(2. * x, 2.))) / bessel_i0(beta); } static void kb_precompute(double beta, int n, float table[n + 1]) { for (int i = 0; i < n + 1; i++) table[i] = kb(beta, (double)(i) / (double)(n - 1) / 2.); } #endif static double I0_beta(double beta) { #ifndef KB128 return bessel_i0(beta); #else assert(KB_BETA == beta); return 118509.158946; #endif } const float kb_table128[129] = { 1.0000000000000000, 0.9995847139398653, 0.9983398161018390, 0.9962681840754728, 0.9933746024007669, 0.9896657454602714, 0.9851501536396374, 0.9798382028675283, 0.9737420676763386, 0.9668756779551011, 0.9592546695947362, 0.9508963292536357, 0.9418195334980564, 0.9320446825968820, 0.9215936292739139, 0.9104896027426631, 0.8987571283688524, 0.8864219433239096, 0.8735109086091393, 0.8600519178443380, 0.8460738032267725, 0.8316062390762707, 0.8166796433899514, 0.8013250778354499, 0.7855741466147803, 0.7694588946318385, 0.7530117053952898, 0.7362651990850234, 0.7192521312046796, 0.7020052922349470, 0.6845574086924412, 0.6669410459871208, 0.6491885134575039, 0.6313317719473744, 0.6134023442704702, 0.5954312288909031, 0.5774488171268115, 0.5594848141632452, 0.5415681641375969, 0.5237269795371914, 0.5059884751240438, 0.4883789065765270, 0.4709235140117633, 0.4536464705263341, 0.4365708358662894, 0.4197185153108639, 0.4031102238276424, 0.3867654555305848, 0.3707024584462233, 0.3549382145678427, 0.3394884251524746, 0.3243675011914082, 0.3095885589616078, 0.2951634205431575, 0.2811026191666483, 0.2674154092344597, 0.2541097808412017, 0.2411924786012657, 0.2286690245755740, 0.2165437450752543, 0.2048198011071496, 0.1934992222148726, 0.1825829434594916, 0.1720708452759937, 0.1619617959353290, 0.1522536963371723, 0.1429435268554672, 0.1340273959573592, 0.1255005903162311, 0.1173576261411828, 0.1095923014483913, 0.1021977490043101, 0.0951664896765205, 0.0884904859351842, 0.0821611952563688, 0.0761696231879639, 0.0705063758493464, 0.0651617116473479, 0.0601255920032731, 0.0553877308986640, 0.0509376430610617, 0.0467646906251106, 0.0428581281188566, 0.0392071456399203, 0.0358009101012748, 0.0326286044415178, 0.0296794647097185, 0.0269428149500251, 0.0244080998261697, 0.0220649149406994, 0.0199030348181235, 0.0179124385351197, 0.0160833329944038, 0.0144061738517878, 0.0128716841182598, 0.0114708704705587, 0.0101950373146533, 0.0090357986567118, 0.0079850878455423, 0.0070351652590612, 0.0061786240150858, 0.0054083937936397, 0.0047177428639869, 0.0041002784147792, 0.0035499452900106, 0.0030610232369345, 0.0026281227747268, 0.0022461797944939, 0.0019104490022500, 0.0016164963167613, 0.0013601903336964, 0.0011376929663821, 0.0009454493716780, 0.0007801772670918, 0.0006388557423128, 0.0005187136648862, 0.0004172177758400, 0.0003320605667526, 0.0002611480250751, 0.0002025873295356, 0.0001546745722200, 0.0001158825784783, 0.0000848488902175, 0.0000603639724392, 0.0000413596971257, 0.0000268981528101, 0.0000161608224276, 0.0000000000000000, 0.0000000000000000, }; static double ftkb(double beta, double x) { double a = sqrt(pow(beta, 2.) - pow(M_PI * x, 2.)); return ((0. == a) ? 1. : (sinh(a) / a)) / I0_beta(beta); } static float rolloff(float x, double beta, float width) { return (float)ftkb(beta, x * width) / ftkb(beta, 0.); } // Linear interpolation static float lerp(float a, float b, float c) { return (1. - c) * a + c * b; } // Linear interpolation look up static float intlookup(int n, const float table[n + 1], float x) { float fpart; // fpart = modff(x * n, &ipart); // int index = ipart; int index = (int)(x * (n - 1)); fpart = x * (n - 1) - (float)index; #if 1 assert(index >= 0); assert(index <= n); assert(fpart >= 0.); assert(fpart <= 1.); #endif float l = lerp(table[index], table[index + 1], fpart); #if 1 assert(l <= 1.); assert(0 >= 0.); #endif return l; } void gridH(const struct grid_conf_s* conf, const complex float* traj, const long ksp_dims[4], complex float* dst, const long grid_dims[4], const complex float* grid) { long C = ksp_dims[3]; #ifndef KB128 // precompute kaiser bessel table int kb_size = 500; float kb_table[kb_size + 1]; kb_precompute(conf->beta, kb_size, kb_table); #else assert(KB_BETA == beta); int kb_size = 128; const float* kb_table = kb_table128; #endif assert(1 == ksp_dims[0]); long samples = ksp_dims[1] * ksp_dims[2]; #pragma omp parallel for for(int i = 0; i < samples; i++) { float pos[3]; pos[0] = conf->os * (creal(traj[i * 3 + 0])); pos[1] = conf->os * (creal(traj[i * 3 + 1])); pos[2] = conf->os * (creal(traj[i * 3 + 2])); pos[0] += (grid_dims[0] > 1) ? ((float)grid_dims[0] / 2.) : 0.; pos[1] += (grid_dims[1] > 1) ? ((float)grid_dims[1] / 2.) : 0.; pos[2] += (grid_dims[2] > 1) ? ((float)grid_dims[2] / 2.) : 0.; complex float val[C]; for (int j = 0; j < C; j++) val[j] = 0.0; grid_pointH(C, 3, grid_dims, pos, val, grid, conf->periodic, conf->width, kb_size, kb_table); for (int j = 0; j < C; j++) dst[j * samples + i] += val[j]; } } void grid(const struct grid_conf_s* conf, const complex float* traj, const long grid_dims[4], complex float* grid, const long ksp_dims[4], const complex float* src) { long C = ksp_dims[3]; #ifndef KB128 // precompute kaiser bessel table int kb_size = 500; float kb_table[kb_size + 1]; kb_precompute(conf->beta, kb_size, kb_table); #else assert(KB_BETA == beta); int kb_size = 128; const float* kb_table = kb_table128; #endif assert(1 == ksp_dims[0]); long samples = ksp_dims[1] * ksp_dims[2]; // grid #pragma omp parallel for for(int i = 0; i < samples; i++) { float pos[3]; pos[0] = conf->os * (creal(traj[i * 3 + 0])); pos[1] = conf->os * (creal(traj[i * 3 + 1])); pos[2] = conf->os * (creal(traj[i * 3 + 2])); pos[0] += (grid_dims[0] > 1) ? ((float) grid_dims[0] / 2.) : 0.; pos[1] += (grid_dims[1] > 1) ? ((float) grid_dims[1] / 2.) : 0.; pos[2] += (grid_dims[2] > 1) ? ((float) grid_dims[2] / 2.) : 0.; complex float val[C]; for (int j = 0; j < C; j++) val[j] = src[j * samples + i]; grid_point(C, 3, grid_dims, pos, grid, val, conf->periodic, conf->width, kb_size, kb_table); } } static void grid2_dims(unsigned int D, const long trj_dims[D], const long ksp_dims[D], const long grid_dims[D]) { assert(D >= 4); assert(md_check_compat(D - 3, ~0, grid_dims + 3, ksp_dims + 3)); // assert(md_check_compat(D - 3, ~(MD_BIT(0) \| MD_BIT(1)), trj_dims + 3, ksp_dims + 3)); assert(md_check_bounds(D - 3, ~0, trj_dims + 3, ksp_dims + 3)); assert(3 == trj_dims[0]); assert(1 == trj_dims[3]); assert(1 == ksp_dims[0]); } void grid2(const struct grid_conf_s* conf, unsigned int D, const long trj_dims[D], const complex float* traj, const long grid_dims[D], complex float* dst, const long ksp_dims[D], const complex float* src) { grid2_dims(D, trj_dims, ksp_dims, grid_dims); long ksp_strs[D]; md_calc_strides(D, ksp_strs, ksp_dims, CFL_SIZE); long trj_strs[D]; md_calc_strides(D, trj_strs, trj_dims, CFL_SIZE); long grid_strs[D]; md_calc_strides(D, grid_strs, grid_dims, CFL_SIZE); long pos[D]; for (unsigned int i = 0; i < D; i++) pos[i] = 0; do { grid(conf, &MD_ACCESS(D, trj_strs, pos, traj), grid_dims, &MD_ACCESS(D, grid_strs, pos, dst), ksp_dims, &MD_ACCESS(D, ksp_strs, pos, src)); } while(md_next(D, ksp_dims, (~0 ^ 15), pos)); } void grid2H(const struct grid_conf_s* conf, unsigned int D, const long trj_dims[D], const complex float* traj, const long ksp_dims[D], complex float* dst, const long grid_dims[D], const complex float* src) { grid2_dims(D, trj_dims, ksp_dims, grid_dims); long ksp_strs[D]; md_calc_strides(D, ksp_strs, ksp_dims, CFL_SIZE); long trj_strs[D]; md_calc_strides(D, trj_strs, trj_dims, CFL_SIZE); long grid_strs[D]; md_calc_strides(D, grid_strs, grid_dims, CFL_SIZE); long pos[D]; for (unsigned int i = 0; i < D; i++) pos[i] = 0; do { gridH(conf, &MD_ACCESS(D, trj_strs, pos, traj), ksp_dims, &MD_ACCESS(D, ksp_strs, pos, dst), grid_dims, &MD_ACCESS(D, grid_strs, pos, src)); } while(md_next(D, ksp_dims, (~0 ^ 15), pos)); } typedef void CLOSURE_TYPE(grid_update_t)(int ind, float d); #ifndef __clang__ #define VLA(x) x #else // blocks extension does not play well even with arguments which // just look like variably-modified types #define VLA(x) #endif static void grid_point_gen(int N, const long dims[VLA(N)], const float pos[VLA(N)], bool periodic, float width, int kb_size, const float kb_table[VLA(kb_size + 1)], grid_update_t update) { #ifndef __clang__ int sti[N]; int eni[N]; int off[N]; #else // blocks extension does not play well with variably-modified types int* sti = alloca(sizeof(int[N])); int* eni = alloca(sizeof(int[N])); int* off = alloca(sizeof(int[N])); #endif for (int j = 0; j < N; j++) { sti[j] = (int)ceil(pos[j] - width); eni[j] = (int)floor(pos[j] + width); off[j] = 0; if (sti[j] > eni[j]) return; if (!periodic) { sti[j] = MAX(sti[j], 0); eni[j] = MIN(eni[j], dims[j] - 1); } else { while (sti[j] + off[j] < 0) off[j] += dims[j]; } if (1 == dims[j]) { assert(0. == pos[j]); // ==0. fails nondeterministically for test_nufft_forward bbdec08cb sti[j] = 0; eni[j] = 0; } } __block NESTED(void, grid_point_r, (int N, int ind, float d)) // __block for recursion { if (0 == N) { update(ind, d); } else { N--; for (int w = sti[N]; w <= eni[N]; w++) { float frac = fabs(((float)w - pos[N])); float d2 = d * intlookup(kb_size, kb_table, frac / width); int ind2 = (ind * dims[N] + ((w + off[N]) % dims[N])); grid_point_r(N, ind2, d2); } } }; grid_point_r(N, 0, 1.); } void grid_point(unsigned int ch, int N, const long dims[VLA(N)], const float pos[VLA(N)], complex float* dst, const complex float val[VLA(ch)], bool periodic, float width, int kb_size, const float kb_table[kb_size + 1]) { NESTED(void, update, (int ind, float d)) { for (unsigned int c = 0; c < ch; c++) { // we are allowed to update real and imaginary part independently which works atomically #pragma omp atomic __real(dst[ind + c * dims[0] * dims[1] * dims[2]]) += __real(val[c]) * d; #pragma omp atomic __imag(dst[ind + c * dims[0] * dims[1] * dims[2]]) += __imag(val[c]) * d; } }; grid_point_gen(N, dims, pos, periodic, width, kb_size, kb_table, update); } void grid_pointH(unsigned int ch, int N, const long dims[VLA(N)], const float pos[VLA(N)], complex float val[VLA(ch)], const complex float* src, bool periodic, float width, int kb_size, const float kb_table[kb_size + 1]) { NESTED(void, update, (int ind, float d)) { for (unsigned int c = 0; c < ch; c++) { // we are allowed to update real and imaginary part independently which works atomically #pragma omp atomic __real(val[c]) += __real(src[ind + c * dims[0] * dims[1] * dims[2]]) * d; #pragma omp atomic __imag(val[c]) += __imag(src[ind + c * dims[0] * dims[1] * dims[2]]) * d; } }; grid_point_gen(N, dims, pos, periodic, width, kb_size, kb_table, update); } double calc_beta(float os, float width) { return M_PI * sqrt(pow((width * 2. / os) * (os - 0.5), 2.) - 0.8); } static float pos(int d, int i) { return (1 == d) ? 0. : (((float)i - (float)d / 2.) / (float)d); } void rolloff_correction(float os, float width, float beta, const long dimensions[3], complex float* dst) { UNUSED(os); #pragma omp parallel for collapse(3) for (int z = 0; z < dimensions[2]; z++) for (int y = 0; y < dimensions[1]; y++) for (int x = 0; x < dimensions[0]; x++) dst[x + dimensions[0] * (y + z * dimensions[1])] = 1. / ( rolloff(pos(dimensions[0], x), beta, width) * rolloff(pos(dimensions[1], y), beta, width) * rolloff(pos(dimensions[2], z), beta, width) ); }
GB_unop__cos_fp64_fp64.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 Generated2/ folder, do not edit it // (it is auto-generated from Generator/). #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__cos_fp64_fp64) // op(A') function: GB (_unop_tran__cos_fp64_fp64) // C type: double // A type: double // cast: double cij = aij // unaryop: cij = cos (aij) #define GB_ATYPE \ double #define GB_CTYPE \ double // aij = Ax [pA] #define GB_GETA(aij,Ax,pA) \ double aij = Ax [pA] #define GB_CX(p) Cx [p] // unary operator #define GB_OP(z, x) \ z = cos (x) ; // casting #define GB_CAST(z, aij) \ double z = aij ; // cij = op (aij) #define GB_CAST_OP(pC,pA) \ { \ / aij = Ax [pA] / \ double aij = Ax [pA] ; \ / Cx [pC] = op (cast (aij)) / \ double z = aij ; \ Cx [pC] = cos (z) ; \ } // disable this operator and use the generic case if these conditions hold #define GB_DISABLE \ (GxB_NO_COS \|\| GxB_NO_FP64) //------------------------------------------------------------------------------ // Cx = op (cast (Ax)): apply a unary operator //------------------------------------------------------------------------------ GrB_Info GB (_unop_apply__cos_fp64_fp64) ( double Cx, // Cx and Ax may be aliased const double 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 ; if (Ab == NULL) { #pragma omp parallel for num_threads(nthreads) schedule(static) for (p = 0 ; p < anz ; p++) { double aij = Ax [p] ; double z = aij ; Cx [p] = cos (z) ; } } 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 ; double aij = Ax [p] ; double z = aij ; Cx [p] = cos (z) ; } } return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // C = op (cast (A')): transpose, typecast, and apply a unary operator //------------------------------------------------------------------------------ GrB_Info GB (_unop_tran__cos_fp64_fp64) ( 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
linAlgAXMY.c	/* The MIT License (MIT) Copyright (c) 2017 Tim Warburton, Noel Chalmers, Jesse Chan, Ali Karakus 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. / extern "C" void FUNC(axmy)(const dlong & N, const dfloat& alpha, const dfloat __restrict__ cpu_w, dfloat * __restrict__ cpu_a){ #ifdef __NEKRS__OMP__ #pragma omp parallel for #endif for(int i=0;i<N;++i){ const dfloat ai = cpu_a[i]; const dfloat wi = cpu_w[i]; cpu_a[i] = alphaaiwi; } } extern "C" void FUNC(axmyMany)(const dlong & N, const dlong & Nfields, const dlong & offset, const dlong & mode, const dfloat & alpha, const dfloat * __restrict__ cpu_w, dfloat * __restrict__ cpu_a){ #ifdef __NEKRS__OMP__ #pragma omp parallel for collapse(2) #endif for(int fld=0;fld<Nfields;fld++) { for(int i=0;i<N;++i){ const dlong id = i + fldoffset; const dfloat ai = cpu_a[id]; const dfloat wi = cpu_w[i + mode fld * offset]; cpu_a[id] = alphaaiwi; } } } extern "C" void FUNC(axmyVector)(const dlong & N, const dlong & offset, const dlong & mode, const dfloat & alpha, const dfloat * __restrict__ cpu_w, dfloat * __restrict__ cpu_a){ #ifdef __NEKRS__OMP__ #pragma omp parallel for collapse(2) #endif for(int fld=0;fld<p_NVec;fld++) { for(int i=0;i<N;++i){ const dlong id = i + fldoffset; const dfloat ai = cpu_a[id]; const dfloat wi = cpu_w[i + mode fld * offset]; cpu_a[id] = alphaaiwi; } } }
GB_unaryop__identity_uint8_uint16.c	//------------------------------------------------------------------------------ // GB_unaryop: hard-coded functions for each built-in unary operator //------------------------------------------------------------------------------ // SuiteSparse:GraphBLAS, Timothy A. Davis, (c) 2017-2019, 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_uint8_uint16 // op(A') function: GB_tran__identity_uint8_uint16 // C type: uint8_t // A type: uint16_t // cast: uint8_t cij = (uint8_t) aij // unaryop: cij = aij #define GB_ATYPE \ uint16_t #define GB_CTYPE \ uint8_t // aij = Ax [pA] #define GB_GETA(aij,Ax,pA) \ uint16_t aij = Ax [pA] #define GB_CX(p) Cx [p] // unary operator #define GB_OP(z, x) \ z = x ; // casting #define GB_CASTING(z, x) \ uint8_t z = (uint8_t) x ; // 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 (x, aij) ; \ GB_OP (GB_CX (pC), x) ; \ } // disable this operator and use the generic case if these conditions hold #define GB_DISABLE \ (GxB_NO_IDENTITY \|\| GxB_NO_UINT8 \|\| GxB_NO_UINT16) //------------------------------------------------------------------------------ // Cx = op (cast (Ax)): apply a unary operator //------------------------------------------------------------------------------ GrB_Info GB_unop__identity_uint8_uint16 ( uint8_t restrict Cx, const uint16_t restrict Ax, int64_t anz, int nthreads ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else #pragma omp parallel for num_threads(nthreads) schedule(static) for (int64_t 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_uint8_uint16 ( GrB_Matrix C, const GrB_Matrix A, int64_t restrict Rowcounts, GBI_single_iterator Iter, const int64_t 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
GB_unaryop__minv_int32_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__minv_int32_uint64 // op(A') function: GB_tran__minv_int32_uint64 // C type: int32_t // A type: uint64_t // cast: int32_t cij = (int32_t) aij // unaryop: cij = GB_IMINV_SIGNED (aij, 32) #define GB_ATYPE \ uint64_t #define GB_CTYPE \ int32_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 = GB_IMINV_SIGNED (x, 32) ; // casting #define GB_CASTING(z, aij) \ int32_t z = (int32_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_MINV \|\| GxB_NO_INT32 \|\| GxB_NO_UINT64) //------------------------------------------------------------------------------ // Cx = op (cast (Ax)): apply a unary operator //------------------------------------------------------------------------------ GrB_Info GB_unop__minv_int32_uint64 ( int32_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__minv_int32_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
lsh_index.h	/*********************************************************************** * Software License Agreement (BSD License) * * Copyright 2008-2009 Marius Muja (mariusm@cs.ubc.ca). All rights reserved. * Copyright 2008-2009 David G. Lowe (lowe@cs.ubc.ca). All rights reserved. * * THE BSD LICENSE * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. 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. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``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 AUTHOR 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: Vincent Rabaud ************************************************************************/ #ifndef FLANN_LSH_INDEX_H_ #define FLANN_LSH_INDEX_H_ #include <algorithm> #include <cassert> #include <cstring> #include <map> #include <vector> #include "flann/general.h" #include "flann/algorithms/nn_index.h" #include "flann/util/matrix.h" #include "flann/util/result_set.h" #include "flann/util/heap.h" #include "flann/util/lsh_table.h" #include "flann/util/allocator.h" #include "flann/util/random.h" #include "flann/util/saving.h" namespace flann { struct LshIndexParams : public IndexParams { LshIndexParams(unsigned int table_number = 12, unsigned int key_size = 20, unsigned int multi_probe_level = 2) { ( this)["algorithm"] = FLANN_INDEX_LSH; // The number of hash tables to use (this)["table_number"] = table_number; // The length of the key in the hash tables (this)["key_size"] = key_size; // Number of levels to use in multi-probe (0 for standard LSH) (this)["multi_probe_level"] = multi_probe_level; } }; /* * Randomized kd-tree index * * Contains the k-d trees and other information for indexing a set of points * for nearest-neighbor matching. / template<typename Distance> class LshIndex : public NNIndex<Distance> { public: typedef typename Distance::ElementType ElementType; typedef typename Distance::ResultType DistanceType; typedef Eigen::Matrix<ElementType, Eigen::Dynamic, Eigen::Dynamic> MatrixType; typedef Eigen::Matrix<ElementType, Eigen::Dynamic, 1> VectorType; typedef Eigen::Matrix<DistanceType, Eigen::Dynamic, Eigen::Dynamic> DistanceMatrix; typedef Eigen::Matrix<DistanceType, Eigen::Dynamic, 1> DistanceVector; typedef Eigen::Matrix<size_t, Eigen::Dynamic, Eigen::Dynamic> IndexMatrix; typedef Eigen::Matrix<size_t, Eigen::Dynamic, 1> IndexVector; typedef NNIndex<Distance> BaseClass; /* Constructor * @param params parameters passed to the LSH algorithm * @param d the distance used / LshIndex(const IndexParams& params = LshIndexParams(), Distance d = Distance()) : BaseClass(params, d) { table_number_ = get_param<unsigned int>(index_params_,"table_number",12); key_size_ = get_param<unsigned int>(index_params_,"key_size",20); multi_probe_level_ = get_param<unsigned int>(index_params_,"multi_probe_level",2); fill_xor_mask(0, key_size_, multi_probe_level_, xor_masks_); } /* Constructor * @param input_data dataset with the input features * @param params parameters passed to the LSH algorithm * @param d the distance used / LshIndex(const Matrix<ElementType>& input_data, const IndexParams& params = LshIndexParams(), Distance d = Distance()) : BaseClass(params, d) { table_number_ = get_param<unsigned int>(index_params_,"table_number",12); key_size_ = get_param<unsigned int>(index_params_,"key_size",20); multi_probe_level_ = get_param<unsigned int>(index_params_,"multi_probe_level",2); fill_xor_mask(0, key_size_, multi_probe_level_, xor_masks_); setDataset(input_data); } LshIndex(const LshIndex& other) : BaseClass(other), tables_(other.tables_), table_number_(other.table_number_), key_size_(other.key_size_), multi_probe_level_(other.multi_probe_level_), xor_masks_(other.xor_masks_) { } LshIndex& operator=(LshIndex other) { this->swap(other); return this; } virtual ~LshIndex() { freeIndex(); } BaseClass* clone() const { return new LshIndex(this); } using BaseClass::buildIndex; void addPoints(const Matrix<ElementType>& points, float rebuild_threshold = 2) { assert(points.cols==veclen_); size_t old_size = size_; extendDataset(points); if (rebuild_threshold>1 && size_at_build_rebuild_threshold<size_) { buildIndex(); } else { for (unsigned int i = 0; i < table_number_; ++i) { lsh::LshTable<ElementType>& table = tables_[i]; for (size_t i=old_size;i<size_;++i) { table.add(i, points_[i]); } } } } flann_algorithm_t getType() const { return FLANN_INDEX_LSH; } template<typename Archive> void serialize(Archive& ar) { ar.setObject(this); ar & static_cast<NNIndex<Distance>>(this); ar & table_number_; ar & key_size_; ar & multi_probe_level_; ar & xor_masks_; ar & tables_; if (Archive::is_loading::value) { index_params_["algorithm"] = getType(); index_params_["table_number"] = table_number_; index_params_["key_size"] = key_size_; index_params_["multi_probe_level"] = multi_probe_level_; } } void saveIndex(FILE* stream) { serialization::SaveArchive sa(stream); sa & this; } void loadIndex(FILE stream) { serialization::LoadArchive la(stream); la & this; } /* * Computes the index memory usage * Returns: memory used by the index / int usedMemory() const { return size_ sizeof(int); } /** * \brief Perform k-nearest neighbor search * \param[in] queries The query points for which to find the nearest neighbors * \param[out] indices The indices of the nearest neighbors found * \param[out] dists Distances to the nearest neighbors found * \param[in] knn Number of nearest neighbors to return * \param[in] params Search parameters / int knnSearch(const Matrix<ElementType>& queries, Matrix<size_t>& indices, Matrix<DistanceType>& dists, size_t knn, const SearchParams& params) const { assert(queries.cols == veclen_); assert(indices.rows >= queries.rows); assert(dists.rows >= queries.rows); assert(indices.cols >= knn); assert(dists.cols >= knn); int count = 0; if (params.use_heap==FLANN_True) { #pragma omp parallel num_threads(params.cores) { KNNUniqueResultSet<DistanceType> resultSet(knn); #pragma omp for schedule(static) reduction(+:count) for (int i = 0; i < (int)queries.rows; i++) { resultSet.clear(); findNeighbors(resultSet, queries[i], params); size_t n = std::min(resultSet.size(), knn); resultSet.copy(indices[i], dists[i], n, params.sorted); indices_to_ids(indices[i], indices[i], n); count += n; } } } else { #pragma omp parallel num_threads(params.cores) { KNNResultSet<DistanceType> resultSet(knn); #pragma omp for schedule(static) reduction(+:count) for (int i = 0; i < (int)queries.rows; i++) { resultSet.clear(); findNeighbors(resultSet, queries[i], params); size_t n = std::min(resultSet.size(), knn); resultSet.copy(indices[i], dists[i], n, params.sorted); indices_to_ids(indices[i], indices[i], n); count += n; } } } return count; } /* * \brief Perform k-nearest neighbor search * \param[in] queries The query points for which to find the nearest neighbors * \param[out] indices The indices of the nearest neighbors found * \param[out] dists Distances to the nearest neighbors found * \param[in] knn Number of nearest neighbors to return * \param[in] params Search parameters / int knnSearch(const Matrix<ElementType>& queries, std::vector< std::vector<size_t> >& indices, std::vector<std::vector<DistanceType> >& dists, size_t knn, const SearchParams& params) const { assert(queries.cols == veclen_); if (indices.size() < queries.rows ) indices.resize(queries.rows); if (dists.size() < queries.rows ) dists.resize(queries.rows); int count = 0; if (params.use_heap==FLANN_True) { #pragma omp parallel num_threads(params.cores) { KNNUniqueResultSet<DistanceType> resultSet(knn); #pragma omp for schedule(static) reduction(+:count) for (int i = 0; i < (int)queries.rows; i++) { resultSet.clear(); findNeighbors(resultSet, queries[i], params); size_t n = std::min(resultSet.size(), knn); indices[i].resize(n); dists[i].resize(n); if (n > 0) { resultSet.copy(&indices[i][0], &dists[i][0], n, params.sorted); indices_to_ids(&indices[i][0], &indices[i][0], n); } count += n; } } } else { #pragma omp parallel num_threads(params.cores) { KNNResultSet<DistanceType> resultSet(knn); #pragma omp for schedule(static) reduction(+:count) for (int i = 0; i < (int)queries.rows; i++) { resultSet.clear(); findNeighbors(resultSet, queries[i], params); size_t n = std::min(resultSet.size(), knn); indices[i].resize(n); dists[i].resize(n); if (n > 0) { resultSet.copy(&indices[i][0], &dists[i][0], n, params.sorted); indices_to_ids(&indices[i][0], &indices[i][0], n); } count += n; } } } return count; } /* * Find set of nearest neighbors to vec. Their indices are stored inside * the result object. * * Params: * result = the result object in which the indices of the nearest-neighbors are stored * vec = the vector for which to search the nearest neighbors * maxCheck = the maximum number of restarts (in a best-bin-first manner) / void findNeighbors(ResultSet<DistanceType>& result, const ElementType vec, const SearchParams& /searchParams/) const { getNeighbors(vec, result); } protected: /** * Builds the index / void buildIndexImpl() { tables_.resize(table_number_); std::vector<std::pair<size_t,ElementType> > features; features.reserve(points_.size()); for (size_t i=0;i<points_.size();++i) { features.push_back(std::make_pair(i, points_[i])); } for (unsigned int i = 0; i < table_number_; ++i) { lsh::LshTable<ElementType>& table = tables_[i]; table = lsh::LshTable<ElementType>(veclen_, key_size_); // Add the features to the table table.add(features); } } void freeIndex() { /* nothing to do here / } private: /* Defines the comparator on score and index / typedef std::pair<float, unsigned int> ScoreIndexPair; struct SortScoreIndexPairOnSecond { bool operator()(const ScoreIndexPair& left, const ScoreIndexPair& right) const { return left.second < right.second; } }; /* Fills the different xor masks to use when getting the neighbors in multi-probe LSH * @param key the key we build neighbors from * @param lowest_index the lowest index of the bit set * @param level the multi-probe level we are at * @param xor_masks all the xor mask / void fill_xor_mask(lsh::BucketKey key, int lowest_index, unsigned int level, std::vector<lsh::BucketKey>& xor_masks) { xor_masks.push_back(key); if (level == 0) return; for (int index = lowest_index - 1; index >= 0; --index) { // Create a new key lsh::BucketKey new_key = key \| (lsh::BucketKey(1) << index); fill_xor_mask(new_key, index, level - 1, xor_masks); } } /* Performs the approximate nearest-neighbor search. * @param vec the feature to analyze * @param do_radius flag indicating if we check the radius too * @param radius the radius if it is a radius search * @param do_k flag indicating if we limit the number of nn * @param k_nn the number of nearest neighbors * @param checked_average used for debugging / void getNeighbors(const ElementType vec, bool do_radius, float radius, bool do_k, unsigned int k_nn, float& checked_average) { static std::vector<ScoreIndexPair> score_index_heap; if (do_k) { unsigned int worst_score = std::numeric_limits<unsigned int>::max(); typename std::vector<lsh::LshTable<ElementType> >::const_iterator table = tables_.begin(); typename std::vector<lsh::LshTable<ElementType> >::const_iterator table_end = tables_.end(); for (; table != table_end; ++table) { size_t key = table->getKey(vec); std::vector<lsh::BucketKey>::const_iterator xor_mask = xor_masks_.begin(); std::vector<lsh::BucketKey>::const_iterator xor_mask_end = xor_masks_.end(); for (; xor_mask != xor_mask_end; ++xor_mask) { size_t sub_key = key ^ (xor_mask); const lsh::Bucket bucket = table->getBucketFromKey(sub_key); if (bucket == 0) continue; // Go over each descriptor index std::vector<lsh::FeatureIndex>::const_iterator training_index = bucket->begin(); std::vector<lsh::FeatureIndex>::const_iterator last_training_index = bucket->end(); DistanceType hamming_distance; // Process the rest of the candidates for (; training_index < last_training_index; ++training_index) { if (removed_ && removed_points_.test(training_index)) continue; hamming_distance = distance_(vec, points_[training_index].point, veclen_); if (hamming_distance < worst_score) { // Insert the new element score_index_heap.push_back(ScoreIndexPair(hamming_distance, training_index)); std::push_heap(score_index_heap.begin(), score_index_heap.end()); if (score_index_heap.size() > (unsigned int)k_nn) { // Remove the highest distance value as we have too many elements std::pop_heap(score_index_heap.begin(), score_index_heap.end()); score_index_heap.pop_back(); // Keep track of the worst score worst_score = score_index_heap.front().first; } } } } } } else { typename std::vector<lsh::LshTable<ElementType> >::const_iterator table = tables_.begin(); typename std::vector<lsh::LshTable<ElementType> >::const_iterator table_end = tables_.end(); for (; table != table_end; ++table) { size_t key = table->getKey(vec); std::vector<lsh::BucketKey>::const_iterator xor_mask = xor_masks_.begin(); std::vector<lsh::BucketKey>::const_iterator xor_mask_end = xor_masks_.end(); for (; xor_mask != xor_mask_end; ++xor_mask) { size_t sub_key = key ^ (xor_mask); const lsh::Bucket bucket = table->getBucketFromKey(sub_key); if (bucket == 0) continue; // Go over each descriptor index std::vector<lsh::FeatureIndex>::const_iterator training_index = bucket->begin(); std::vector<lsh::FeatureIndex>::const_iterator last_training_index = bucket->end(); DistanceType hamming_distance; // Process the rest of the candidates for (; training_index < last_training_index; ++training_index) { if (removed_ && removed_points_.test(training_index)) continue; // Compute the Hamming distance hamming_distance = distance_(vec, points_[training_index].point, veclen_); if (hamming_distance < radius) score_index_heap.push_back(ScoreIndexPair(hamming_distance, training_index)); } } } } } /** Performs the approximate nearest-neighbor search. * This is a slower version than the above as it uses the ResultSet * @param vec the feature to analyze / void getNeighbors(const ElementType vec, ResultSet<DistanceType>& result) const { typename std::vector<lsh::LshTable<ElementType> >::const_iterator table = tables_.begin(); typename std::vector<lsh::LshTable<ElementType> >::const_iterator table_end = tables_.end(); for (; table != table_end; ++table) { size_t key = table->getKey(vec); std::vector<lsh::BucketKey>::const_iterator xor_mask = xor_masks_.begin(); std::vector<lsh::BucketKey>::const_iterator xor_mask_end = xor_masks_.end(); for (; xor_mask != xor_mask_end; ++xor_mask) { size_t sub_key = key ^ (xor_mask); const lsh::Bucket bucket = table->getBucketFromKey(sub_key); if (bucket == 0) continue; // Go over each descriptor index std::vector<lsh::FeatureIndex>::const_iterator training_index = bucket->begin(); std::vector<lsh::FeatureIndex>::const_iterator last_training_index = bucket->end(); DistanceType hamming_distance; // Process the rest of the candidates for (; training_index < last_training_index; ++training_index) { if (removed_ && removed_points_.test(training_index)) continue; // Compute the Hamming distance hamming_distance = distance_(vec, points_[training_index], veclen_); result.addPoint(hamming_distance, training_index); } } } } void swap(LshIndex& other) { BaseClass::swap(other); std::swap(tables_, other.tables_); std::swap(size_at_build_, other.size_at_build_); std::swap(table_number_, other.table_number_); std::swap(key_size_, other.key_size_); std::swap(multi_probe_level_, other.multi_probe_level_); std::swap(xor_masks_, other.xor_masks_); } /* The different hash tables / std::vector<lsh::LshTable<ElementType> > tables_; /* table number / unsigned int table_number_; /* key size / unsigned int key_size_; /* How far should we look for neighbors in multi-probe LSH / unsigned int multi_probe_level_; /* The XOR masks to apply to a key to get the neighboring buckets */ std::vector<lsh::BucketKey> xor_masks_; USING_BASECLASS_SYMBOLS }; } #endif //FLANN_LSH_INDEX_H_
DRB064-outeronly2-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. / / Only the outmost loop can be parallelized. The inner loop has loop carried true data dependence. However, the loop is not parallelized so no race condition. / #include <omp.h> double b[100][100]; #define N 100 int init() { int i; int j; int k; #pragma omp parallel for private (i,j) for (i = 0; i <= 99; i += 1) { #pragma omp parallel for private (j) for (j = 0; j <= 99; j += 1) { b[i][j] = (i j); } } return 0; } void foo(int n,int m) { int i; int j; #pragma omp parallel for private (i,j) firstprivate (n,m) for (i = 0; i <= n - 1; i += 1) { // Be careful about bounds of j for (j = 1; j <= m - 1; j += 1) { b[i][j] = b[i][j - 1]; } } } int print() { int i; int j; int k; for (i = 0; i <= 99; i += 1) { for (j = 0; j <= 99; j += 1) { printf("%lf\n",b[i][j]); } } return 0; } int main() { init(); foo(100,100); print(); return 0; }
main.c	#include <stdlib.h> #include <stdio.h> #include <omp.h> #include <string.h> int number_of_threads; double A; double L; double U; void crout0(double L, double *U, int n) { int i, j, k; double sum = 0; for (i = 0; i < n; i++) { U[i][i] = 1; } for (j = 0; j < n; j++) { for (i = j; i < n; i++) { sum = 0; for (k = 0; k < j; k++) { sum = sum + L[i][k] U[k][j]; } L[i][j] = A[i][j] - sum; } for (i = j; i < n; i++) { sum = 0; for(k = 0; k < j; k++) { sum = sum + L[j][k] * U[k][i]; } if (L[j][j] == 0) { exit(0); } U[j][i] = (A[j][i] - sum) / L[j][j]; } } } void crout1(double L, double U, int n, int number_of_threads) { int i, j, k; double sum = 0; #pragma omp parallel for num_threads(number_of_threads) private(i) for (i = 0; i < n; i++) { U[i][i] = 1; } for (j = 0; j < n; j++) { #pragma omp parallel for num_threads(number_of_threads) private(i,k,sum) for (i = j; i < n; i++) { sum = 0; for (k = 0; k < j; k++) { sum = sum + L[i][k] * U[k][j]; } L[i][j] = A[i][j] - sum; } #pragma omp parallel for num_threads(number_of_threads) private(i,k,sum) for (int i = j; i < n; i++) { double sum = 0; for(int k = 0; k < j; k++) { sum = sum + L[j][k] * U[k][i]; } if (L[j][j] == 0) { exit(0); } U[j][i] = (A[j][i] - sum) / L[j][j]; } } } void crout2(double L, double U, int n, int number_of_threads) { int i,j,k; double sum = 0, sum1 = 0, sum2 = 0; #pragma omp parallel sections num_threads(number_of_threads) private(i) { #pragma omp section { for (i = 0; i < n/16; i++) U[i][i] = 1; } #pragma omp section { for (i = n/16; i < 2n/16; i++) U[i][i] = 1; } #pragma omp section { for (i = 2n/16; i < 3n/16; i++) U[i][i] = 1; } #pragma omp section { for (i = 3n/16; i < 4n/16; i++) U[i][i] = 1; } #pragma omp section { for (i = 4n/16; i < 5n/16; i++) U[i][i] = 1; } #pragma omp section { for (i = 5n/16; i < 6n/16; i++) U[i][i] = 1; } #pragma omp section { for (i = 6n/16; i < 7n/16; i++) U[i][i] = 1; } #pragma omp section { for (i = 7n/16; i < 8n/16; i++) U[i][i] = 1; } #pragma omp section { for (i = 8n/16; i < 9n/16; i++) U[i][i] = 1; } #pragma omp section { for (i = 9n/16; i < 10n/16; i++) U[i][i] = 1; } #pragma omp section { for (i = 10n/16; i < 11n/16; i++) U[i][i] = 1; } #pragma omp section { for (i = 11n/16; i < 12n/16; i++) U[i][i] = 1; } #pragma omp section { for (i = 12n/16; i < 13n/16; i++) U[i][i] = 1; } #pragma omp section { for (i = 13n/16; i < 14n/16; i++) U[i][i] = 1; } #pragma omp section { for (i = 14n/16; i < 15n/16; i++) U[i][i] = 1; } #pragma omp section { for (i = 15n/16; i < n; i++) U[i][i] = 1; } } for (j = 0; j < n; j++) { sum = 0 ; for (k = 0; k < j; k++) { sum = sum + L[j][k] * U[k][j]; } L[j][j] = A[j][j] - sum; #pragma omp parallel sections num_threads(number_of_threads) private(sum,i,k) { #pragma omp section { for (i = j+1 + (0(n-j-1))/8; i < j+1 + (1(n-j-1))/8; i++) { sum = 0; for (k = 0; k < j; k++) { sum = sum + L[i][k] * U[k][j]; } L[i][j] = A[i][j] - sum; } } #pragma omp section { for (i = j+1 + (1(n-j-1))/8; i < j+1 + (2(n-j-1))/8; i++) { sum = 0; for (k = 0; k < j; k++) { sum = sum + L[i][k] * U[k][j]; } L[i][j] = A[i][j] - sum; } } #pragma omp section { for (i = j+1 + (2(n-j-1)/8); i < j+1 + (3(n-j-1))/8; i++) { sum = 0; for (k = 0; k < j; k++) { sum = sum + L[i][k] * U[k][j]; } L[i][j] = A[i][j] - sum; } } #pragma omp section { for (i = j+1 + (3(n-j-1))/8; i < j+1 + (4(n-j-1))/8; i++) { sum = 0; for (k = 0; k < j; k++) { sum = sum + L[i][k] * U[k][j]; } L[i][j] = A[i][j] - sum; } } #pragma omp section { for (i = j+1 + (4(n-j-1))/8; i < j+1 + (5(n-j-1))/8; i++) { sum = 0; for (k = 0; k < j; k++) { sum = sum + L[i][k] * U[k][j]; } L[i][j] = A[i][j] - sum; } } #pragma omp section { for (i = j+1 + (5(n-j-1))/8; i < j+1 + (6(n-j-1))/8; i++) { sum = 0; for (k = 0; k < j; k++) { sum = sum + L[i][k] * U[k][j]; } L[i][j] = A[i][j] - sum; } } #pragma omp section { for (i = j+1 + (6(n-j-1))/8; i < j+1 + (7(n-j-1))/8; i++) { sum = 0; for (k = 0; k < j; k++) { sum = sum + L[i][k] * U[k][j]; } L[i][j] = A[i][j] - sum; } } #pragma omp section { for (i = j+1 + (7(n-j-1))/8; i < j+1 + (8(n-j-1))/8; i++) { sum = 0; for (k = 0; k < j; k++) { sum = sum + L[i][k] * U[k][j]; } L[i][j] = A[i][j] - sum; } } #pragma omp section { for (i = j + (0(n-j))/8; i < j + (1(n-j))/8; i++) { sum = 0; for(k = 0; k < j; k++) { sum = sum + L[j][k] * U[k][i]; } if (L[j][j] == 0) { exit(0); } U[j][i] = (A[j][i] - sum) / L[j][j]; } } #pragma omp section { for (i = j + (1(n-j))/8; i < j + (2(n-j))/8; i++) { sum = 0; for(k = 0; k < j; k++) { sum = sum + L[j][k] * U[k][i]; } if (L[j][j] == 0) { exit(0); } U[j][i] = (A[j][i] - sum) / L[j][j]; } } #pragma omp section { for (i = j + (2(n-j))/8; i < j + (3(n-j))/8; i++) { sum = 0; for(k = 0; k < j; k++) { sum = sum + L[j][k] * U[k][i]; } if (L[j][j] == 0) { exit(0); } U[j][i] = (A[j][i] - sum) / L[j][j]; } } #pragma omp section { for (i = j + (3(n-j))/8; i < j + (4(n-j))/8; i++) { sum = 0; for(k = 0; k < j; k++) { sum = sum + L[j][k] * U[k][i]; } if (L[j][j] == 0) { exit(0); } U[j][i] = (A[j][i] - sum) / L[j][j]; } } #pragma omp section { for (i = j + (4(n-j))/8; i < j + (5(n-j))/8; i++) { sum = 0; for(k = 0; k < j; k++) { sum = sum + L[j][k] * U[k][i]; } if (L[j][j] == 0) { exit(0); } U[j][i] = (A[j][i] - sum) / L[j][j]; } } #pragma omp section { for (i = j + (5(n-j))/8; i < j + (6(n-j))/8; i++) { sum = 0; for(k = 0; k < j; k++) { sum = sum + L[j][k] * U[k][i]; } if (L[j][j] == 0) { exit(0); } U[j][i] = (A[j][i] - sum) / L[j][j]; } } #pragma omp section { for (i = j + (6(n-j))/8; i < j + (7(n-j))/8; i++) { sum = 0; for(k = 0; k < j; k++) { sum = sum + L[j][k] * U[k][i]; } if (L[j][j] == 0) { exit(0); } U[j][i] = (A[j][i] - sum) / L[j][j]; } } #pragma omp section { for (i = j + (7(n-j))/8; i < j + (8(n-j))/8; i++) { sum = 0; for(k = 0; k < j; k++) { sum = sum + L[j][k] * U[k][i]; } if (L[j][j] == 0) { exit(0); } U[j][i] = (A[j][i] - sum) / L[j][j]; } } } } } void crout3(double L, double U, int n, int number_of_threads) { #pragma omp parallel num_threads(number_of_threads) for (int i = 0; i < n; i++) { U[i][i] = 1; } for (int j = 0; j < n; j++) { double sum = 0; for (int k = 0; k < j; k++) { sum = sum + L[j][k] * U[k][j]; } L[j][j] = A[j][j] - sum; #pragma omp parallel sections { #pragma omp section { #pragma omp parallel for num_threads(number_of_threads) for (int i = j+1; i < n; i++) { double sum = 0; for (int k = 0; k < j; k++) { sum = sum + L[i][k] * U[k][j]; } L[i][j] = A[i][j] - sum; } } #pragma omp section { #pragma omp parallel for num_threads(number_of_threads) for (int i = j; i < n; i++) { double sum = 0; for(int k = 0; k < j; k++) { sum = sum + L[j][k] * U[k][i]; } if (L[j][j] == 0) { exit(0); } U[j][i] = (A[j][i] - sum) / L[j][j]; } } } } } void print_array(double *arr,int n,char c){ printf("\n--------------------------- %s ---------------------------\n",c); for(int i=0; i<n; i++){ for(int j=0; j<n; j++) printf("%f\t",arr[i][j]); printf("\n"); } printf("----------------------------------------------------------\n\n"); } void write_output(char fname[], double** arr, int n){ FILE f = fopen(fname, "w"); for( int i = 0; i < n; i++){ for(int j = 0; j < n; j++){ fprintf(f, "%0.12f ", arr[i][j]); } fprintf(f, "\n"); } fclose(f); } int main(int argc, char argv[]) { omp_set_nested(1); int n; char input_filename; int strategy; if (argc != 5) {printf("Enter 5 arguments only. Eg.\"executable_filename n input_filename number_of_threads strategy\"\n");return 0;} n = atoi(argv[1]); input_filename = argv[2]; number_of_threads = atoi(argv[3]); strategy = atoi(argv[4]); char not = argv[3]; A=(double *)malloc(nsizeof(double)); for(int i=0;i<n;++i) A[i]=(double )malloc(nsizeof(double)); FILE fptr; if ((fptr = fopen(input_filename, "r")) == NULL) { printf("Error! can't open the input file."); exit(1); } for(int i = 0; i < n; i++) { for(int j = 0; j < n; j++) { if (!fscanf(fptr, "%lf", &A[i][j])) break; } } fclose(fptr); L=(double *)malloc(nsizeof(double)); for(int i=0;i<n;++i) L[i]=(double )malloc(nsizeof(double)); U=(double )malloc(nsizeof(double)); for(int i=0;i<n;++i) U[i]=(double )malloc(nsizeof(double)); if (strategy==0) { crout0(L,U,n); char lf[12] = "output_L_0_"; char uf[12] = "output_U_0_"; char extension[5] = ".txt"; char f1 = (char ) malloc(256); f1[0]='\0'; char f2 = (char ) malloc(256); f2[0]='\0'; strcat(f1,lf); strcat(f1,not); strcat(f1,extension); strcat(f2,uf); strcat(f2,not); strcat(f2,extension); write_output(f1,L,n); write_output(f2,U,n); // print_array(L,n,"L"); // print_array(U,n,"U"); } else if(strategy==1){ crout1(L,U,n,number_of_threads); char lf[12] = "output_L_1_"; char uf[12] = "output_U_1_"; char extension[5] = ".txt"; char f1 = (char ) malloc(256); f1[0]='\0'; char f2 = (char ) malloc(256); f2[0]='\0'; strcat(f1,lf); strcat(f1,not); strcat(f1,extension); strcat(f2,uf); strcat(f2,not); strcat(f2,extension); write_output(f1,L,n); write_output(f2,U,n); // print_array(L,n,"L"); // print_array(U,n,"U"); } else if(strategy==2){ crout2(L,U,n,number_of_threads); char lf[12] = "output_L_2_"; char uf[12] = "output_U_2_"; char extension[5] = ".txt"; char f1 = (char ) malloc(256); f1[0]='\0'; char f2 = (char ) malloc(256); f2[0]='\0'; strcat(f1,lf); strcat(f1,not); strcat(f1,extension); strcat(f2,uf); strcat(f2,not); strcat(f2,extension); write_output(f1,L,n); write_output(f2,U,n); // print_array(L,n,"L"); // print_array(U,n,"U"); } else if(strategy==3){ crout3(L,U,n,number_of_threads); char lf[12] = "output_L_3_"; char uf[12] = "output_U_3_"; char extension[5] = ".txt"; char f1 = (char ) malloc(256); f1[0]='\0'; char f2 = (char *) malloc(256); f2[0]='\0'; strcat(f1,lf); strcat(f1,not); strcat(f1,extension); strcat(f2,uf); strcat(f2,not); strcat(f2,extension); write_output(f1,L,n); write_output(f2,U,n); // print_array(L,n,"L"); // print_array(U,n,"U"); } }
scheduled-clauseModificado4.c	#include <stdio.h> #include <stdlib.h> #ifdef _OPENMP #include <omp.h> #else #define omp_get_thread_num() 0 #endif int main(int argc, char **argv) { int i, n = 16,chunk, a[n],suma=0; int modifier; omp_sched_t kind; if(argc < 2) { fprintf(stderr,"\nFalta chunk \n"); exit(-1); } chunk = atoi(argv[1]); for (i=0; i<n; i++) a[i] = i; #pragma omp parallel { #pragma omp for firstprivate(suma) \ lastprivate(suma) schedule(dynamic,chunk) for (i=0; i<n; i++) { suma = suma + a[i]; printf(" thread %d suma a[%d] suma=%d \n", omp_get_thread_num(),i,suma); } #pragma omp single { printf("omp_get_num_threads: %d \n",omp_get_num_threads()); printf("omp_get_num_procs: %d \n",omp_get_num_procs()); printf("omp_in_parallel: %d \n",omp_in_parallel()); } } printf("Fuera de 'parallel for' suma=%d\n",suma); printf("Fuera de la región paralell: \n"); printf("omp_get_num_threads: %d \n",omp_get_num_threads()); printf("omp_get_num_procs: %d \n",omp_get_num_procs()); printf("omo_in_parallel: %d",omp_in_parallel()); }
loop-15.c	/* { dg-do run } */ volatile int ji = 100, ki = 2; volatile unsigned int ju = 100, ku = 2; volatile long long int jll = 100, kll = 2; volatile unsigned long long int jull = 100, kull = 2; unsigned long long l; void f0 (void) { int i, j, k; unsigned int j2, k2; #pragma omp for reduction(+: l) schedule(runtime) for (i = ji; i < ki; i++) l++; if (l != 0) __builtin_abort (); #pragma omp parallel for reduction(+: l) schedule(runtime) for (i = ji; i < ki; i++) l++; if (l != 0) __builtin_abort (); #pragma omp for reduction(+: l) collapse(3) schedule(runtime) for (j = 0; j < 4; j++) for (i = ji; i < ki; i++) for (k = 0; k < 5; k += 2) l++; if (l != 0) __builtin_abort (); #pragma omp parallel for reduction(+: l) collapse(3) schedule(runtime) for (j = 0; j < 4; j++) for (i = ji; i < ki; i++) for (k = 0; k < 5; k += 2) l++; if (l != 0) __builtin_abort (); #pragma omp for reduction(+: l) collapse(3) schedule(runtime) for (j2 = 0; j2 < 4; j2++) for (i = ji; i < ki; i++) for (k2 = 0; k2 < 5; k2 += 2) l++; if (l != 0) __builtin_abort (); #pragma omp parallel for reduction(+: l) collapse(3) schedule(runtime) for (j2 = 0; j2 < 4; j2++) for (i = ji; i < ki; i++) for (k2 = 0; k2 < 5; k2 += 2) l++; if (l != 0) __builtin_abort (); #pragma omp parallel for reduction(+: l) collapse(3) schedule(runtime) for (j = 0; j < 4; j++) for (i = ji; i < ki; i++) for (k = ki + 10; k < ji - 10; k += 2) l++; if (l != 0) __builtin_abort (); #pragma omp parallel for reduction(+: l) collapse(3) schedule(runtime) for (j = ki + 10; j < ji - 10; j++) for (i = ji; i < ki; i++) for (k = 0; k < 5; k += 2) l++; if (l != 0) __builtin_abort (); } void f1 (void) { unsigned int i, j, k; int j2, k2; #pragma omp for reduction(+: l) schedule(runtime) for (i = ju; i < ku; i++) l++; if (l != 0) __builtin_abort (); #pragma omp parallel for reduction(+: l) schedule(runtime) for (i = ju; i < ku; i++) l++; if (l != 0) __builtin_abort (); #pragma omp for reduction(+: l) collapse(3) schedule(runtime) for (j = 0; j < 4; j++) for (i = ju; i < ku; i++) for (k = 0; k < 5; k += 2) l++; if (l != 0) __builtin_abort (); #pragma omp parallel for reduction(+: l) collapse(3) schedule(runtime) for (j = 0; j < 4; j++) for (i = ju; i < ku; i++) for (k = 0; k < 5; k += 2) l++; if (l != 0) __builtin_abort (); #pragma omp for reduction(+: l) collapse(3) schedule(runtime) for (j2 = 0; j2 < 4; j2++) for (i = ju; i < ku; i++) for (k2 = 0; k2 < 5; k2 += 2) l++; if (l != 0) __builtin_abort (); #pragma omp parallel for reduction(+: l) collapse(3) schedule(runtime) for (j2 = 0; j2 < 4; j2++) for (i = ju; i < ku; i++) for (k2 = 0; k2 < 5; k2 += 2) l++; if (l != 0) __builtin_abort (); #pragma omp parallel for reduction(+: l) collapse(3) schedule(runtime) for (j = 0; j < 4; j++) for (i = ju; i < ku; i++) for (k = ku; k < ju; k += 2) l++; if (l != 0) __builtin_abort (); #pragma omp parallel for reduction(+: l) collapse(3) schedule(runtime) for (j = ku; j < ju; j++) for (i = ju; i < ku; i++) for (k = 0; k < 5; k += 2) l++; if (l != 0) __builtin_abort (); } void f2 (void) { long long int i, j, k; unsigned long long int j2, k2; #pragma omp for reduction(+: l) schedule(runtime) for (i = jll; i < kll; i++) l++; if (l != 0) __builtin_abort (); #pragma omp parallel for reduction(+: l) schedule(runtime) for (i = jll; i < kll; i++) l++; if (l != 0) __builtin_abort (); #pragma omp for reduction(+: l) collapse(3) schedule(runtime) for (j = 0; j < 4; j++) for (i = jll; i < kll; i++) for (k = 0; k < 5; k += 2) l++; if (l != 0) __builtin_abort (); #pragma omp parallel for reduction(+: l) collapse(3) schedule(runtime) for (j = 0; j < 4; j++) for (i = jll; i < kll; i++) for (k = 0; k < 5; k += 2) l++; if (l != 0) __builtin_abort (); #pragma omp for reduction(+: l) collapse(3) schedule(runtime) for (j2 = 0; j2 < 4; j2++) for (i = jll; i < kll; i++) for (k2 = 0; k2 < 5; k2 += 2) l++; if (l != 0) __builtin_abort (); #pragma omp parallel for reduction(+: l) collapse(3) schedule(runtime) for (j2 = 0; j2 < 4; j2++) for (i = jll; i < kll; i++) for (k2 = 0; k2 < 5; k2 += 2) l++; if (l != 0) __builtin_abort (); #pragma omp parallel for reduction(+: l) collapse(3) schedule(runtime) for (j = 0; j < 4; j++) for (i = jll; i < kll; i++) for (k = kll; k < jll; k += 2) l++; if (l != 0) __builtin_abort (); #pragma omp parallel for reduction(+: l) collapse(3) schedule(runtime) for (j = kll; j < jll; j++) for (i = jll; i < kll; i++) for (k = 0; k < 5; k += 2) l++; if (l != 0) __builtin_abort (); } void f3 (void) { unsigned long long int i, j, k; long long int j2, k2; #pragma omp for reduction(+: l) schedule(runtime) for (i = jull; i < kull; i++) l++; if (l != 0) __builtin_abort (); #pragma omp parallel for reduction(+: l) schedule(runtime) for (i = jull; i < kull; i++) l++; if (l != 0) __builtin_abort (); #pragma omp for reduction(+: l) collapse(3) schedule(runtime) for (j = 0; j < 4; j++) for (i = jull; i < kull; i++) for (k = 0; k < 5; k += 2) l++; if (l != 0) __builtin_abort (); #pragma omp parallel for reduction(+: l) collapse(3) schedule(runtime) for (j = 0; j < 4; j++) for (i = jull; i < kull; i++) for (k = 0; k < 5; k += 2) l++; if (l != 0) __builtin_abort (); #pragma omp for reduction(+: l) collapse(3) schedule(runtime) for (j2 = 0; j2 < 4; j2++) for (i = jull; i < kull; i++) for (k2 = 0; k2 < 5; k2 += 2) l++; if (l != 0) __builtin_abort (); #pragma omp parallel for reduction(+: l) collapse(3) schedule(runtime) for (j2 = 0; j2 < 4; j2++) for (i = jull; i < kull; i++) for (k2 = 0; k2 < 5; k2 += 2) l++; if (l != 0) __builtin_abort (); #pragma omp parallel for reduction(+: l) collapse(3) schedule(runtime) for (j = 0; j < 4; j++) for (i = jull; i < kull; i++) for (k = kull; k < jull; k += 2) l++; if (l != 0) __builtin_abort (); #pragma omp parallel for reduction(+: l) collapse(3) schedule(runtime) for (j = kull; j < jull; j++) for (i = jull; i < kull; i++) for (k = 0; k < 5; k += 2) l++; if (l != 0) __builtin_abort (); } int main () { f0 (); f1 (); f2 (); f3 (); return 0; }
layer_example_bf16_sparse_A_multi-instance_mem.c	/****************************************************************************** * Copyright (c) Intel Corporation - All rights reserved. * * This file is part of the LIBXSMM library. * * * * For information on the license, see the LICENSE file. * * Further information: https://github.com/hfp/libxsmm/ * * SPDX-License-Identifier: BSD-3-Clause * *****************************************************************************/ / Evangelos Georganas (Intel Corp.) *****************************************************************************/ #include <libxsmm.h> #include <stdlib.h> #include <string.h> #include <stdio.h> #include <math.h> #if defined(_OPENMP) # include <omp.h> #endif / include c-based dnn library / #include "../common/dnn_common.h" //#define PRINT_PROGRESS #define CHKERR_LIBXSMM_DNN(A) { const int chkerr_libxsmm_dnn_ = A; if (LIBXSMM_DNN_SUCCESS != chkerr_libxsmm_dnn_) { \ fprintf(stderr, "%s\n", libxsmm_dnn_get_error(chkerr_libxsmm_dnn_)); global_status = chkerr_libxsmm_dnn_; } \ } double mean(double array, int N) { double res = 0.0; int i; for (i = 0; i < N; i++) { res += array[i]; } res = res/(double)N; return res; } double std(double array, int N) { double m = mean(array, N); int i; double res = 0.0; for (i = 0; i < N; i++) { res += (array[i] - m) (array[i] - m); } res = sqrt(res/(double)N); return res; } void shuffle_array(unsigned int array, int n) { if (n > 1) { int i; for (i = 0; i < n - 1; i++) { int j = i + rand() / (RAND_MAX / (n - i) + 1); unsigned int t = array[j]; array[j] = array[i]; array[i] = t; } } } unsigned int random_mask_half_full(int sparsity_factor ) { int __i; unsigned int id_array[32]; unsigned int cur_bitmap = 0; for (__i = 0; __i < 32; __i++) { id_array[__i] = __i; } shuffle_array(id_array, 32); for (__i = 0; __i < 32/sparsity_factor; __i++) { unsigned int cur_bit = (1 << id_array[__i]); cur_bitmap = cur_bitmap \| cur_bit; } return cur_bitmap; } int main(int argc, char argv[]) { float naive_input, naive_output, naive_filter, naive_bias; libxsmm_bfloat16 naive_input_bf16, naive_filter_bf16, naive_output_bf16, naive_bias_bf16; float naive_libxsmm_output_f32; libxsmm_bfloat16 naive_libxsmm_output_bf16; libxsmm_bfloat16 filter_libxsmm_sparse; unsigned int sparse_idx_libxsmm; libxsmm_bfloat16 input_libxsmm, output_libxsmm, filter_libxsmm, bias_libxsmm; unsigned char *relumask_libxsmm; char nuke_buffer; naive_fullyconnected_t naive_param; char** scratch; size_t scratch_size = 0; unsigned long long dummies; / some parameters we can overwrite via cli, default is some inner layer of overfeat / int iters = 100; / repetitions of benchmark / int nImg = 32; / mini-batch size, "N" / int nIFm = 256; / number of input feature maps, "C" / int nOFm = 256; / number of input feature maps, "C" / int fuse_type = 0; / 0: nothing fused, 1: relu fused, 2: elementwise fused, 3: relu and elementwise fused / int bn = 32; int bk = 32; int bc = 32; int sparsity_factor = 2; int nuke_caches = 1; int warmup_acts = 1; int nthreads_per_instance = 1; const char const env_check = getenv("CHECK"); const double check = LIBXSMM_ABS(0 == env_check ? 1 : atof(env_check)); #if defined(_OPENMP) int nThreads = omp_get_max_threads(); /* number of threads / #else int nThreads = 1; / number of threads / #endif unsigned long long nuke_size = ((unsigned long long)( (unsigned long long)2 (unsigned long long)1024 * (unsigned long long)1024 * (unsigned long long)1024 + (unsigned long long)nThreads)/ (unsigned long long) nThreads) * (unsigned long long) nThreads; unsigned long long l_start, l_end; double l_total = 0.0; double l_totals; double gflop = 0.0; double gflop_array; double m, s, min_gflops, max_gflops, iter_flops; int i; libxsmm_dnn_fullyconnected_desc fullyconnected_desc; libxsmm_dnn_fullyconnected libxsmm_handle; libxsmm_dnn_tensor libxsmm_input; libxsmm_dnn_tensor libxsmm_output; libxsmm_dnn_tensor libxsmm_filter; libxsmm_dnn_tensor libxsmm_bias; libxsmm_dnn_tensor libxsmm_relumask; libxsmm_dnn_err_t status; libxsmm_dnn_err_t global_status = LIBXSMM_DNN_SUCCESS; libxsmm_matdiff_info norms_fwd, diff; libxsmm_matdiff_clear(&norms_fwd); libxsmm_matdiff_clear(&diff); if (argc > 1 && !strncmp(argv[1], "-h", 3)) { printf("Usage: %s iters MB nIFm nOFm fuse_type bn bk bc sparsity_factor \n", argv[0]); return 0; } libxsmm_rng_set_seed(1); /* reading new values from cli / i = 1; if (argc > i) iters = atoi(argv[i++]); if (argc > i) nImg = atoi(argv[i++]); if (argc > i) nIFm = atoi(argv[i++]); if (argc > i) nOFm = atoi(argv[i++]); if (argc > i) fuse_type = atoi(argv[i++]); if (argc > i) bn = atoi(argv[i++]); if (argc > i) bk = atoi(argv[i++]); if (argc > i) bc = atoi(argv[i++]); if (argc > i) sparsity_factor = atoi(argv[i++]); if (argc > i) nuke_caches = atoi(argv[i++]); if (argc > i) warmup_acts = atoi(argv[i++]); if (argc > i) nthreads_per_instance = atoi(argv[i++]); if ( nImg % bn != 0 ) { bn = nImg; } if ( nIFm % bc != 0 ) { bc = nIFm; } if ( nOFm % bk != 0 ) { bk = nOFm; } if ( (fuse_type < 0) \|\| (fuse_type > 5) ) { printf("Fuse type needs to be 0 (None), 1 (Bias), 2 (ReLU), 3 (Sigmoid), 4 (Bias+ReLU), 5 (Bias+Sigmoid)\n"); return -1; } if ((bk != 32) \|\| (bc != 32)) { printf("BK and BC supported values are only 32 (provided are bk=%d bc=%d)!\n", bk, bc); return -1; } if (nuke_caches > 0) { printf("#############################################\n"); printf("# WEIGHTS are COLD before performance run...#\n"); printf("#############################################\n"); } else { printf("#############################################\n"); printf("# WEIGHTS are HOT before performance run... #\n"); printf("#############################################\n"); } if (warmup_acts > 0) { printf("#############################################\n"); printf("# ACTS are HOT before performance run... #\n"); printf("#############################################\n"); } else { printf("#############################################\n"); printf("# ACTS are COLD before performance run... #\n"); printf("#############################################\n"); } / set struct for naive convolution / naive_param.N = nImg; naive_param.C = nIFm; naive_param.K = nOFm; naive_param.fuse_type = fuse_type; #if defined(__SSE3__) _MM_SET_FLUSH_ZERO_MODE(_MM_FLUSH_ZERO_ON); _MM_SET_DENORMALS_ZERO_MODE(_MM_DENORMALS_ZERO_ON); _MM_SET_ROUNDING_MODE(_MM_ROUND_NEAREST); #endif / print some summary / printf("##########################################\n"); printf("# Setting Up (Common) #\n"); printf("##########################################\n"); printf("PARAMS: N:%d C:%d K:%d\n", nImg, nIFm, nOFm); printf("PARAMS: ITERS:%d", iters); if (LIBXSMM_FEQ(0, check)) printf(" Threads:%d\n", nThreads); else printf("\n"); printf("SIZE Input (MB): %10.2f MiB\n", (double)(nImgnIFmsizeof(libxsmm_bfloat16))/(1024.01024.0) ); printf("SIZE Output (MB): %10.2f MiB\n", (double)(nImgnOFmsizeof(libxsmm_bfloat16))/(1024.01024.0) ); printf("SIZE Filter (sparse): %10.2f MiB\n", (double)(nIFmnOFmsizeof(libxsmm_bfloat16)/sparsity_factor)/(1024.01024.0) ); /* Allocate arrays of pointers/data structures for all threads / input_libxsmm = (libxsmm_bfloat16) libxsmm_aligned_malloc( nThreadssizeof(libxsmm_bfloat16), 2097152); output_libxsmm = (libxsmm_bfloat16) libxsmm_aligned_malloc( nThreadssizeof(libxsmm_bfloat16), 2097152); filter_libxsmm = (libxsmm_bfloat16) libxsmm_aligned_malloc( nThreadssizeof(libxsmm_bfloat16), 2097152); bias_libxsmm = (libxsmm_bfloat16) libxsmm_aligned_malloc( nThreadssizeof(libxsmm_bfloat16), 2097152); relumask_libxsmm = (unsigned char) libxsmm_aligned_malloc( nThreadssizeof(unsigned char), 2097152); nuke_buffer = (char) libxsmm_aligned_malloc( nuke_sizesizeof(char), 2097152); if (nuke_buffer == NULL) { fprintf(stderr, "Nuke buffer alloc failed....\n"); exit(EXIT_FAILURE); } dummies = (unsigned long long) libxsmm_aligned_malloc( nThreadssizeof(unsigned long long), 2097152); l_totals = (double) libxsmm_aligned_malloc( nThreadsiterssizeof(double), 2097152); gflop_array = (double) libxsmm_aligned_malloc( nThreadssizeof(double), 2097152); for (i = 0; i < nThreads; i++) { input_libxsmm[i] = (libxsmm_bfloat16)libxsmm_aligned_malloc( nImgnIFmsizeof(libxsmm_bfloat16), 2097152); output_libxsmm[i] = (libxsmm_bfloat16)libxsmm_aligned_malloc( nImgnOFmsizeof(libxsmm_bfloat16), 2097152); filter_libxsmm[i] = (libxsmm_bfloat16)libxsmm_aligned_malloc( nIFmnOFmsizeof(libxsmm_bfloat16), 2097152); bias_libxsmm[i] = (libxsmm_bfloat16)libxsmm_aligned_malloc( nOFm sizeof(libxsmm_bfloat16), 2097152); relumask_libxsmm[i] = (unsigned char)libxsmm_aligned_malloc( nImgnOFmsizeof(unsigned char), 2097152); gflop_array[i] = 0.0; } /* allocate data / naive_input = (float)libxsmm_aligned_malloc( nImgnIFmsizeof(float), 2097152); naive_output = (float)libxsmm_aligned_malloc( nImgnOFmsizeof(float), 2097152); naive_filter = (float)libxsmm_aligned_malloc( nIFmnOFmsizeof(float), 2097152); naive_bias = (float)libxsmm_aligned_malloc( nOFm sizeof(float), 2097152); naive_input_bf16 = (libxsmm_bfloat16)libxsmm_aligned_malloc( nImgnIFmsizeof(libxsmm_bfloat16), 2097152); naive_output_bf16 = (libxsmm_bfloat16)libxsmm_aligned_malloc( nImgnOFmsizeof(libxsmm_bfloat16), 2097152); naive_filter_bf16 = (libxsmm_bfloat16)libxsmm_aligned_malloc( nIFmnOFmsizeof(libxsmm_bfloat16), 2097152); naive_bias_bf16 = (libxsmm_bfloat16)libxsmm_aligned_malloc( nOFm sizeof(libxsmm_bfloat16), 2097152); naive_libxsmm_output_bf16 = (libxsmm_bfloat16)libxsmm_aligned_malloc( nImgnOFmsizeof(libxsmm_bfloat16), 2097152); naive_libxsmm_output_f32 = (float)libxsmm_aligned_malloc( nImgnOFmsizeof(float), 2097152); filter_libxsmm_sparse = (libxsmm_bfloat16)libxsmm_aligned_malloc( nIFmnOFmsizeof(libxsmm_bfloat16), 2097152); sparse_idx_libxsmm = (unsigned int)libxsmm_aligned_malloc( nIFmnOFmsizeof(unsigned int), 2097152); / initialize data / init_buf( naive_input, nImgnIFm, 0, 0 ); init_buf( naive_output, nImgnOFm, 0, 0 ); init_buf( naive_filter, nIFmnOFm, 0, 0 ); init_buf( naive_bias, nOFm, 0, 0 ); libxsmm_rne_convert_fp32_bf16( naive_input, naive_input_bf16, nImgnIFm ); libxsmm_rne_convert_fp32_bf16( naive_output, naive_output_bf16, nImgnOFm ); libxsmm_rne_convert_fp32_bf16( naive_filter, naive_filter_bf16, nIFmnOFm ); libxsmm_rne_convert_fp32_bf16( naive_bias, naive_bias_bf16, nOFm ); printf("\n"); printf("##########################################\n"); printf("# Setting Up (custom-Storage) #\n"); printf("##########################################\n"); / setup LIBXSMM handle / fullyconnected_desc.N = nImg; fullyconnected_desc.C = nIFm; fullyconnected_desc.K = nOFm; fullyconnected_desc.bn = bn; fullyconnected_desc.bk = bk; fullyconnected_desc.bc = bc; fullyconnected_desc.threads = nthreads_per_instance; fullyconnected_desc.datatype_in = LIBXSMM_DNN_DATATYPE_BF16; fullyconnected_desc.datatype_out = LIBXSMM_DNN_DATATYPE_BF16; fullyconnected_desc.buffer_format = LIBXSMM_DNN_TENSOR_FORMAT_NCPACKED; fullyconnected_desc.filter_format = LIBXSMM_DNN_TENSOR_FORMAT_CKPACKED; fullyconnected_desc.compressed_A = 1; fullyconnected_desc.sparsity_factor_A = sparsity_factor; if ( fuse_type == 0 ) { fullyconnected_desc.fuse_ops = LIBXSMM_DNN_FULLYCONNECTED_FUSE_NONE; } else if ( fuse_type == 1 ) { fullyconnected_desc.fuse_ops = LIBXSMM_DNN_FULLYCONNECTED_FUSE_BIAS; } else if ( fuse_type == 2 ) { fullyconnected_desc.fuse_ops = LIBXSMM_DNN_FULLYCONNECTED_FUSE_RELU; } else if ( fuse_type == 3 ) { fullyconnected_desc.fuse_ops = LIBXSMM_DNN_FULLYCONNECTED_FUSE_SIGMOID; } else if ( fuse_type == 4 ) { fullyconnected_desc.fuse_ops = LIBXSMM_DNN_FULLYCONNECTED_FUSE_BIAS_RELU; } else if ( fuse_type == 5 ) { fullyconnected_desc.fuse_ops = LIBXSMM_DNN_FULLYCONNECTED_FUSE_BIAS_SIGMOID; } else { / cannot happen / } libxsmm_handle = (libxsmm_dnn_fullyconnected) libxsmm_aligned_malloc( nThreadssizeof(libxsmm_dnn_fullyconnected), 2097152); libxsmm_input = (libxsmm_dnn_tensor) libxsmm_aligned_malloc( nThreadssizeof(libxsmm_dnn_tensor), 2097152); libxsmm_output = (libxsmm_dnn_tensor) libxsmm_aligned_malloc( nThreadssizeof(libxsmm_dnn_tensor), 2097152); libxsmm_filter = (libxsmm_dnn_tensor) libxsmm_aligned_malloc( nThreadssizeof(libxsmm_dnn_tensor), 2097152); libxsmm_bias = (libxsmm_dnn_tensor) libxsmm_aligned_malloc( nThreadssizeof(libxsmm_dnn_tensor), 2097152); libxsmm_relumask = (libxsmm_dnn_tensor) libxsmm_aligned_malloc( nThreadssizeof(libxsmm_dnn_tensor), 2097152); #if defined(_OPENMP) # pragma omp parallel #endif { #if defined(_OPENMP) const int _tid = omp_get_thread_num(); #else const int _tid = 0; #endif int tid = _tid / nthreads_per_instance; int member_id = _tid % nthreads_per_instance; if (member_id == 0) { libxsmm_dnn_tensor_datalayout libxsmm_layout; libxsmm_dnn_err_t l_status; libxsmm_handle[tid] = libxsmm_dnn_create_fullyconnected( fullyconnected_desc, &l_status ); CHKERR_LIBXSMM_DNN( l_status ); /* setup LIBXSMM buffers / libxsmm_layout = libxsmm_dnn_fullyconnected_create_tensor_datalayout( libxsmm_handle[tid], LIBXSMM_DNN_REGULAR_INPUT, &l_status ); CHKERR_LIBXSMM_DNN( l_status ); libxsmm_input[tid] = libxsmm_dnn_link_tensor( libxsmm_layout, input_libxsmm[tid], &l_status ); CHKERR_LIBXSMM_DNN( l_status ); libxsmm_dnn_destroy_tensor_datalayout( libxsmm_layout ); libxsmm_layout = libxsmm_dnn_fullyconnected_create_tensor_datalayout( libxsmm_handle[tid], LIBXSMM_DNN_REGULAR_OUTPUT, &l_status ); CHKERR_LIBXSMM_DNN( l_status ); libxsmm_output[tid] = libxsmm_dnn_link_tensor( libxsmm_layout, output_libxsmm[tid], &l_status ); CHKERR_LIBXSMM_DNN( l_status ); libxsmm_dnn_destroy_tensor_datalayout( libxsmm_layout ); libxsmm_layout = libxsmm_dnn_fullyconnected_create_tensor_datalayout( libxsmm_handle[tid], LIBXSMM_DNN_REGULAR_FILTER, &l_status ); CHKERR_LIBXSMM_DNN( l_status ); libxsmm_filter[tid] = libxsmm_dnn_link_tensor( libxsmm_layout, filter_libxsmm[tid], &l_status ); CHKERR_LIBXSMM_DNN( l_status ); libxsmm_dnn_destroy_tensor_datalayout( libxsmm_layout ); libxsmm_layout = libxsmm_dnn_fullyconnected_create_tensor_datalayout( libxsmm_handle[tid], LIBXSMM_DNN_REGULAR_CHANNEL_BIAS, &l_status ); CHKERR_LIBXSMM_DNN( l_status ); libxsmm_bias[tid] = libxsmm_dnn_link_tensor( libxsmm_layout, bias_libxsmm[tid], &l_status ); CHKERR_LIBXSMM_DNN( l_status ); libxsmm_dnn_destroy_tensor_datalayout( libxsmm_layout ); libxsmm_layout = libxsmm_dnn_fullyconnected_create_tensor_datalayout( libxsmm_handle[tid], LIBXSMM_DNN_RELU_MASK, &l_status ); CHKERR_LIBXSMM_DNN( l_status ); libxsmm_relumask[tid] = libxsmm_dnn_link_tensor( libxsmm_layout, relumask_libxsmm[tid], &l_status ); CHKERR_LIBXSMM_DNN( l_status ); libxsmm_dnn_destroy_tensor_datalayout( libxsmm_layout ); / copy in data to LIBXSMM format / / we can also use the layout functions and set the data on our own external to the library / matrix_copy_NC_to_NCNC_bf16_serial( naive_input_bf16, input_libxsmm[tid], 1, nImg, nIFm, bn, bc ); matrix_copy_NC_to_NCNC_bf16_serial( naive_output_bf16, output_libxsmm[tid], 1, nImg, nOFm, bn, bk ); matrix_copy_NC_to_NCNC_bf16_serial( naive_filter_bf16, filter_libxsmm[tid], 1, nIFm, nOFm, bc, bk ); matrix_copy_NC_to_NCNC_bf16_serial( naive_bias_bf16, bias_libxsmm[tid], 1, 1, nOFm, 1, nOFm ); } } / Sparsify filters to requested level / memset(filter_libxsmm_sparse, 0, nIFm nOFm * sizeof(libxsmm_bfloat16)); #if defined(__AVX512VBMI2__) \|\| (defined(__AVX512BW__) && defined(LIBXSMM_INTEL_COMPILER)) int __i = 0, __j = 0, __k = 0; for (__i = 0; __i < nIFm * nOFm; __i+= 32 ) { unsigned int cur_mask_int = random_mask_half_full(sparsity_factor); __mmask32 cur_mask = _cvtu32_mask32(cur_mask_int); __m512i vreg_dense = _mm512_loadu_si512 ((libxsmm_bfloat16)filter_libxsmm[0]+__i); sparse_idx_libxsmm[__k] = cur_mask_int; _mm512_mask_storeu_epi16 ((libxsmm_bfloat16)filter_libxsmm_sparse+__i, cur_mask, vreg_dense); _mm512_mask_compressstoreu_epi16((libxsmm_bfloat16)filter_libxsmm[0]+__j, cur_mask, vreg_dense); __k += 1; __j += 32/sparsity_factor; } #else fprintf(stderr, "ERROR: support for at least " # if defined(LIBXSMM_INTEL_COMPILER) "AVX512BW" # else "AVX512VBMI2" # endif " required for this kernel!\n"); exit(EXIT_FAILURE); #endif / Copyover the sparse idx tensor after the compressed filter buffer / if (sparsity_factor > 1) { memcpy((libxsmm_bfloat16)filter_libxsmm[0] + (nIFm * nOFm)/sparsity_factor, sparse_idx_libxsmm, ((nIFm * nOFm)/32)sizeof(unsigned int)); } #if defined(_OPENMP) # pragma omp parallel #endif { #if defined(_OPENMP) const int _tid = omp_get_thread_num(); #else const int _tid = 0; #endif int tid = _tid / nthreads_per_instance; int member_id = _tid % nthreads_per_instance; if ((member_id == 0) && (_tid > 0)) { memcpy((libxsmm_bfloat16)filter_libxsmm[tid], (libxsmm_bfloat16)filter_libxsmm[0], (nIFm nOFm)/sparsity_factorsizeof(libxsmm_bfloat16)); if (sparsity_factor > 1) { memcpy((libxsmm_bfloat16)filter_libxsmm[tid] + (nIFm * nOFm)/sparsity_factor, sparse_idx_libxsmm, ((nIFm * nOFm)/32)sizeof(unsigned int)); } } } / Copyover the sparse filter ot the reference filter for correctness checks / matrix_copy_KCCK_to_KC_bf16( filter_libxsmm_sparse, naive_filter_bf16, nIFm, nOFm, bc, bk ); libxsmm_convert_bf16_f32( naive_filter_bf16, naive_filter, nIFmnOFm ); if (LIBXSMM_NEQ(0, check)) { printf("##########################################\n"); printf("# Computing Reference ... #\n"); printf("##########################################\n"); naive_fullyconnected_fused_fp(&naive_param, naive_input, naive_output, naive_filter, naive_bias); printf("##########################################\n"); printf("# Computing Reference ... done #\n"); printf("##########################################\n"); } /* bind buffers and filter to handle / for (i = 0; i < nThreads/nthreads_per_instance; i++) { CHKERR_LIBXSMM_DNN( libxsmm_dnn_fullyconnected_bind_tensor( libxsmm_handle[i], libxsmm_input[i], LIBXSMM_DNN_REGULAR_INPUT ) ); CHKERR_LIBXSMM_DNN( libxsmm_dnn_fullyconnected_bind_tensor( libxsmm_handle[i], libxsmm_output[i], LIBXSMM_DNN_REGULAR_OUTPUT ) ); CHKERR_LIBXSMM_DNN( libxsmm_dnn_fullyconnected_bind_tensor( libxsmm_handle[i], libxsmm_filter[i], LIBXSMM_DNN_REGULAR_FILTER ) ); CHKERR_LIBXSMM_DNN( libxsmm_dnn_fullyconnected_bind_tensor( libxsmm_handle[i], libxsmm_bias[i], LIBXSMM_DNN_REGULAR_CHANNEL_BIAS ) ); CHKERR_LIBXSMM_DNN( libxsmm_dnn_fullyconnected_bind_tensor( libxsmm_handle[i], libxsmm_relumask[i], LIBXSMM_DNN_RELU_MASK ) ); } / let's allocate and bind scratch / scratch_size = libxsmm_dnn_fullyconnected_get_scratch_size( libxsmm_handle[0], &status ); CHKERR_LIBXSMM_DNN( status ); scratch = (char) libxsmm_aligned_malloc( nThreadssizeof(char), 2097152); #if defined(_OPENMP) # pragma omp parallel #endif { #if defined(_OPENMP) const int _tid = omp_get_thread_num(); #else const int _tid = 0; #endif int tid = _tid / nthreads_per_instance; int member_id = _tid % nthreads_per_instance; if (member_id == 0) { scratch[tid] = (char) libxsmm_aligned_malloc( scratch_size * sizeof(char), 2097152 ); CHKERR_LIBXSMM_DNN( libxsmm_dnn_fullyconnected_bind_scratch( libxsmm_handle[tid], scratch[tid] ) ); /* set scratch to bogus to make sure that libxsmm takes care of zeroing internally / memset(scratch[tid], 42, scratch_size); } } printf("##########################################\n"); printf("# Correctness - FWD (custom-Storage) #\n"); printf("##########################################\n"); #if defined(_OPENMP) # pragma omp parallel #endif { #if defined(_OPENMP) const int _tid = omp_get_thread_num(); #else const int _tid = 0; #endif int tid = _tid / nthreads_per_instance; int member_id = _tid % nthreads_per_instance; CHKERR_LIBXSMM_DNN( libxsmm_dnn_fullyconnected_execute_st( libxsmm_handle[tid], LIBXSMM_DNN_COMPUTE_KIND_FWD, 0, member_id ) ); } / copy out data / matrix_copy_NCNC_to_NC_bf16( output_libxsmm[0], naive_libxsmm_output_bf16, 1, nImg, nOFm, bn, bk ); libxsmm_convert_bf16_f32( naive_libxsmm_output_bf16, naive_libxsmm_output_f32, nImgnOFm ); /* compare / libxsmm_matdiff(&norms_fwd, LIBXSMM_DATATYPE_F32, nImgnOFm, 1, naive_output, naive_libxsmm_output_f32, 0, 0); printf("L1 reference : %.25g\n", norms_fwd.l1_ref); printf("L1 test : %.25g\n", norms_fwd.l1_tst); printf("L2 abs.error : %.24f\n", norms_fwd.l2_abs); printf("L2 rel.error : %.24f\n", norms_fwd.l2_rel); printf("Linf abs.error: %.24f\n", norms_fwd.linf_abs); printf("Linf rel.error: %.24f\n", norms_fwd.linf_rel); printf("Check-norm : %.24f\n", norms_fwd.normf_rel); libxsmm_matdiff_reduce(&diff, &norms_fwd); printf("##########################################\n"); printf("# Running %d warmup iterations #\n", iters); printf("##########################################\n"); #if defined(_OPENMP) # pragma omp parallel private(i) #endif { #if defined(_OPENMP) const int _tid = omp_get_thread_num(); #else const int _tid = 0; #endif int tid = _tid / nthreads_per_instance; int member_id = _tid % nthreads_per_instance; for (i = 0; i < iters; ++i) { libxsmm_dnn_fullyconnected_execute_st( libxsmm_handle[tid], LIBXSMM_DNN_COMPUTE_KIND_FWD, 0, member_id ); } } #if defined(_OPENMP) # pragma omp parallel private(i) #endif { #if defined(_OPENMP) const int _tid = omp_get_thread_num(); #else const int _tid = 0; #endif int tid = _tid / nthreads_per_instance; int member_id = _tid % nthreads_per_instance; unsigned long long chunk_size = (unsigned long long)nuke_size/((unsigned long long)nThreads); char pt_nuke = (char)nuke_buffer + (unsigned long long) (((unsigned long long)tid) * (unsigned long long) chunk_size); libxsmm_bfloat16* pt_out = (libxsmm_bfloat16) output_libxsmm[tid] + member_id (nImg * nOFm)/nthreads_per_instance; libxsmm_bfloat16* pt_in = (libxsmm_bfloat16) input_libxsmm[tid] + member_id (nImg * nIFm)/nthreads_per_instance; libxsmm_bfloat16* pt_wt = (libxsmm_bfloat16) filter_libxsmm[tid]; char pt_scratch = (char) scratch[tid] + member_id (scratch_size/nthreads_per_instance); int j; int it = 0; unsigned long long __i; unsigned long long _l_start, _l_end; for (it = 0; it < iters; it++) { if (nuke_caches > 0) { #ifdef PRINT_PROGRESS if (tid == 0) { printf("##########################################\n"); printf("# Nuking caches.... \n"); printf("##########################################\n"); } #endif #if USE_NUKE_BUFFER memset((char)nuke_buffer + (unsigned long long)(((unsigned long long)tid) chunk_size), (char)tid, (unsigned long long)chunk_size * (unsigned long long)sizeof(char)); for (j = 0; j < 10; j++) { for (__i = 0; __i < chunk_size; __i++) { dummies[tid] += (unsigned long long) pt_nuke[__i]; } } #else for (__i = 0; __i < (nImgnOFm)/32/nthreads_per_instance; __i++) { _mm_clflushopt((libxsmm_bfloat16)pt_out + __i * 32); } for (__i = 0; __i < (nIFmnOFm)/32; __i++) { _mm_clflushopt((libxsmm_bfloat16)pt_wt + __i * 32); } for (__i = 0; __i < (nImgnIFm)/32/nthreads_per_instance; __i++) { _mm_clflushopt((libxsmm_bfloat16)pt_in + __i * 32); } for (__i = 0; __i < scratch_size/64/nthreads_per_instance; __i++) { _mm_clflushopt((char)pt_scratch+ __i 64); } #endif } if (warmup_acts > 0) { #ifdef PRINT_PROGRESS if (tid == 0) { printf("##################################################\n"); printf("# Bringing input/output activations in cache... \n"); printf("##################################################\n"); } #endif for (j = 0; j < 10; j++) { for (__i = 0; __i < (nImgnOFm)/nthreads_per_instance; __i++) { dummies[_tid] += (unsigned long long) pt_out[__i]; pt_out[__i] = (libxsmm_bfloat16) dummies[_tid]; } for (__i = 0; __i < (nImgnIFm)/nthreads_per_instance; __i++) { dummies[_tid] += (unsigned long long) pt_in[__i]; } for (__i = 0; __i < nIFmbk; __i++) { dummies[_tid] += (unsigned long long) ((libxsmm_bfloat16)scratch[tid] + member_id nIFm * bk + __i); } } } #ifdef PRINT_PROGRESS if (tid == 0) { printf("##########################################\n"); printf("# Performance run,,,, #\n"); printf("##########################################\n"); } #endif #pragma omp barrier _l_start = libxsmm_timer_tick(); libxsmm_dnn_fullyconnected_execute_st( libxsmm_handle[tid], LIBXSMM_DNN_COMPUTE_KIND_FWD, 0, member_id ); _l_end = libxsmm_timer_tick(); l_totals[_tiditers+it] = libxsmm_timer_duration(_l_start, _l_end); } } gflop = (2.0(double)nImg(double)nIFm(double)nOFm(double)nThreadsiters/nthreads_per_instance) / (100010001000); l_total = l_totals[0]; for (i = 1; i< iters; i++) { l_total += l_totals[i]; } printf("GFLOP = %.5g\n", gflop); printf("fp time = %.5g\n", ((double)(l_total))); printf("GFLOPS = %.5g\n", gflop/l_total); m = mean(l_totals, nThreadsiters); s = std(l_totals, nThreadsiters); printf("mean of ALL times is %.5g, std is %.5g which is %.5g%%\n", m, s, s100.0/m); for (i = 1; i < nThreads; i++) { dummies[0] += dummies[i]; } for (i = 0; i < nThreads; i++) { int _i; l_total = l_totals[iiters+0]; for (_i = 1; _i < iters; _i++) { l_total += l_totals[iiters+_i]; } gflop_array[i] = gflop/l_total; } m = mean(gflop_array, nThreads); s = std(gflop_array, nThreads); printf("Mean of ALL GFLOPS is %.5g, std is %.5g which is %.5g%%\n\n", m, s, s100.0/m); min_gflops = gflop_array[0]; max_gflops = gflop_array[0]; for (i = 1; i < nThreads; i++) { min_gflops = LIBXSMM_MIN(min_gflops, gflop_array[i]); max_gflops = LIBXSMM_MAX(max_gflops, gflop_array[i]); } printf("Among threads total MIN is %.5g and total MAX is %.5g\n", min_gflops, max_gflops); iter_flops = (2.0(double)nImg(double)nIFm(double)nOFm(double)nThreads/(double)nthreads_per_instance) / (100010001000); min_gflops = iter_flops / l_totals[0]; max_gflops = iter_flops / l_totals[0]; m = max_gflops; for (i = 1; i < nThreads * iters; i++) { min_gflops = LIBXSMM_MIN(min_gflops, iter_flops / l_totals[i]); max_gflops = LIBXSMM_MAX(max_gflops, iter_flops / l_totals[i]); m += iter_flops / l_totals[i]; } printf("Among threads and iters MIN is %.5g and MAX is %.5g and MEAN is %.5g\n", min_gflops, max_gflops, m/(double)(nThreadsiters)); printf("PERFDUMP,%s,FP,%i,%i,%i,%i,%.5g,%.5g,%f,%f,%f,%f,%f,%f,%f,%llu\n", LIBXSMM_VERSION, nThreads, nImg, nIFm, nOFm, ((double)(l_total/iters)), gflop/l_total, norms_fwd.l1_ref, norms_fwd.l1_tst, norms_fwd.l2_abs, norms_fwd.l2_rel, norms_fwd.linf_abs, norms_fwd.linf_rel, norms_fwd.normf_rel, dummies[0]); / clean-up / for (i = 0; i < nThreads/nthreads_per_instance; i++) { CHKERR_LIBXSMM_DNN( libxsmm_dnn_fullyconnected_release_scratch( libxsmm_handle[i] ) ); CHKERR_LIBXSMM_DNN( libxsmm_dnn_fullyconnected_release_tensor( libxsmm_handle[i], LIBXSMM_DNN_REGULAR_INPUT ) ); CHKERR_LIBXSMM_DNN( libxsmm_dnn_fullyconnected_release_tensor( libxsmm_handle[i], LIBXSMM_DNN_REGULAR_OUTPUT ) ); CHKERR_LIBXSMM_DNN( libxsmm_dnn_fullyconnected_release_tensor( libxsmm_handle[i], LIBXSMM_DNN_REGULAR_FILTER ) ); CHKERR_LIBXSMM_DNN( libxsmm_dnn_fullyconnected_release_tensor( libxsmm_handle[i], LIBXSMM_DNN_REGULAR_CHANNEL_BIAS ) ); CHKERR_LIBXSMM_DNN( libxsmm_dnn_fullyconnected_release_tensor( libxsmm_handle[i], LIBXSMM_DNN_RELU_MASK ) ); CHKERR_LIBXSMM_DNN( libxsmm_dnn_destroy_tensor( libxsmm_input[i] ) ); CHKERR_LIBXSMM_DNN( libxsmm_dnn_destroy_tensor( libxsmm_output[i] ) ); CHKERR_LIBXSMM_DNN( libxsmm_dnn_destroy_tensor( libxsmm_filter[i] ) ); CHKERR_LIBXSMM_DNN( libxsmm_dnn_destroy_tensor( libxsmm_bias[i] ) ); CHKERR_LIBXSMM_DNN( libxsmm_dnn_destroy_tensor( libxsmm_relumask[i] ) ); CHKERR_LIBXSMM_DNN( libxsmm_dnn_destroy_fullyconnected( libxsmm_handle[i] ) ); libxsmm_free(input_libxsmm[i]); libxsmm_free(output_libxsmm[i]); libxsmm_free(filter_libxsmm[i]); libxsmm_free(relumask_libxsmm[i]); libxsmm_free(bias_libxsmm[i]); libxsmm_free(scratch[i]); } / deallocate data / libxsmm_free(naive_input); libxsmm_free(naive_output); libxsmm_free(naive_filter); libxsmm_free(naive_input_bf16); libxsmm_free(naive_output_bf16); libxsmm_free(naive_filter_bf16); libxsmm_free(naive_libxsmm_output_bf16); libxsmm_free(naive_libxsmm_output_f32); libxsmm_free(naive_bias); libxsmm_free(naive_bias_bf16); libxsmm_free(libxsmm_handle); libxsmm_free(libxsmm_input); libxsmm_free(libxsmm_output); libxsmm_free(libxsmm_filter); libxsmm_free(libxsmm_bias); libxsmm_free(libxsmm_relumask); libxsmm_free(input_libxsmm); libxsmm_free(output_libxsmm); libxsmm_free(filter_libxsmm); libxsmm_free(relumask_libxsmm); libxsmm_free(bias_libxsmm); libxsmm_free(scratch); libxsmm_free(nuke_buffer); libxsmm_free(l_totals); libxsmm_free(gflop_array); { const char const env_check_scale = getenv("CHECK_SCALE"); const double check_scale = LIBXSMM_ABS(0 == env_check_scale ? 1.0 : atof(env_check_scale)); if (LIBXSMM_NEQ(0, check) && (check < 100.0 * check_scale * diff.normf_rel) && (global_status == LIBXSMM_DNN_SUCCESS)) { fprintf(stderr, "FAILED with an error of %f%%!\n", 100.0 * diff.normf_rel); exit(EXIT_FAILURE); } } /* some empty lines at the end */ printf("\n\n\n"); return global_status; }
declare_reduction_messages.c	// RUN: %clang_cc1 -verify -fopenmp -ferror-limit 100 %s // RUN: %clang_cc1 -verify -fopenmp-simd -ferror-limit 100 %s int temp; // expected-note 6 {{'temp' declared here}} #pragma omp declare reduction // expected-error {{expected '(' after 'declare reduction'}} #pragma omp declare reduction { // expected-error {{expected '(' after 'declare reduction'}} #pragma omp declare reduction( // expected-error {{expected identifier or one of the following operators: '+', '-', '', '&', '\|', '^', '&&', or '\|\|'}} #pragma omp declare reduction(# // expected-error {{expected identifier or one of the following operators: '+', '-', '', '&', '\|', '^', '&&', or '\|\|'}} #pragma omp declare reduction(/ // expected-error {{expected identifier or one of the following operators: '+', '-', '', '&', '\|', '^', '&&', or '\|\|'}} #pragma omp declare reduction(+ // expected-error {{expected ':'}} #pragma omp declare reduction(for // expected-error {{expected identifier or one of the following operators: '+', '-', '', '&', '\|', '^', '&&', or '\|\|'}} #pragma omp declare reduction(if: // expected-error {{expected identifier or one of the following operators: '+', '-', '', '&', '\|', '^', '&&', or '\|\|'}} expected-error {{expected a type}} #pragma omp declare reduction(oper: // expected-error {{expected a type}} #pragma omp declare reduction(oper; // expected-error {{expected ':'}} expected-error {{expected a type}} #pragma omp declare reduction(fun : int // expected-error {{expected ':'}} expected-error {{expected expression}} #pragma omp declare reduction(+ : const int: // expected-error {{reduction type cannot be qualified with 'const', 'volatile' or 'restrict'}} #pragma omp declare reduction(- : volatile int: // expected-error {{reduction type cannot be qualified with 'const', 'volatile' or 'restrict'}} #pragma omp declare reduction( : int; // expected-error {{expected ','}} expected-error {{expected a type}} #pragma omp declare reduction(& : double char: // expected-error {{cannot combine with previous 'double' declaration specifier}} expected-error {{expected expression}} #pragma omp declare reduction(^ : double, char, : // expected-error {{expected a type}} expected-error {{expected expression}} #pragma omp declare reduction(&& : int, S: // expected-error {{unknown type name 'S'}} expected-error {{expected expression}} #pragma omp declare reduction(\|\| : int, double : temp += omp_in) // expected-error 2 {{only 'omp_in' or 'omp_out' variables are allowed in combiner expression}} #pragma omp declare reduction(\| : char, float : omp_out += temp) // expected-error 2 {{only 'omp_in' or 'omp_out' variables are allowed in combiner expression}} #pragma omp declare reduction(fun : long : omp_out += omp_in) { // expected-error {{expected 'initializer'}} expected-warning {{extra tokens at the end of '#pragma omp declare reduction' are ignored}} #pragma omp declare reduction(fun : unsigned : omp_out += temp)) // expected-error {{expected 'initializer'}} expected-warning {{extra tokens at the end of '#pragma omp declare reduction' are ignored}} expected-error {{only 'omp_in' or 'omp_out' variables are allowed in combiner expression}} #pragma omp declare reduction(fun : long(void) : omp_out += omp_in) // expected-error {{reduction type cannot be a function type}} #pragma omp declare reduction(fun : long[3] : omp_out += omp_in) // expected-error {{reduction type cannot be an array type}} #pragma omp declare reduction(fun23 : long, int, long : omp_out += omp_in) // expected-error {{redefinition of user-defined reduction for type 'long'}} expected-note {{previous definition is here}} #pragma omp declare reduction(fun222 : long : omp_out += omp_in) #pragma omp declare reduction(fun1 : long : omp_out += omp_in) initializer // expected-error {{expected '(' after 'initializer'}} #pragma omp declare reduction(fun2 : long : omp_out += omp_in) initializer { // expected-error {{expected '(' after 'initializer'}} expected-error {{expected expression}} expected-warning {{extra tokens at the end of '#pragma omp declare reduction' are ignored}} #pragma omp declare reduction(fun3 : long : omp_out += omp_in) initializer[ // expected-error {{expected '(' after 'initializer'}} expected-error {{expected expression}} expected-warning {{extra tokens at the end of '#pragma omp declare reduction' are ignored}} #pragma omp declare reduction(fun4 : long : omp_out += omp_in) initializer() // expected-error {{expected expression}} #pragma omp declare reduction(fun5 : long : omp_out += omp_in) initializer(temp) // expected-error {{only 'omp_priv' or 'omp_orig' variables are allowed in initializer expression}} #pragma omp declare reduction(fun6 : long : omp_out += omp_in) initializer(omp_orig // expected-error {{expected ')'}} expected-note {{to match this '('}} #pragma omp declare reduction(fun7 : long : omp_out += omp_in) initializer(omp_priv 12) // expected-error {{expected ')'}} expected-note {{to match this '('}} #pragma omp declare reduction(fun8 : long : omp_out += omp_in) initializer(omp_priv = 23) // expected-note {{previous definition is here}} #pragma omp declare reduction(fun8 : long : omp_out += omp_in) initializer(omp_priv = 23)) // expected-warning {{extra tokens at the end of '#pragma omp declare reduction' are ignored}} expected-error {{redefinition of user-defined reduction for type 'long'}} #pragma omp declare reduction(fun9 : long : omp_out += omp_in) initializer(omp_priv = ) // expected-error {{expected expression}} struct S { int s; }; #pragma omp declare reduction(+: struct S: omp_out.s += omp_in.s) // initializer(omp_priv = { .s = 0 }) int fun(int arg) { struct S s;// expected-note {{'s' defined here}} s.s = 0; #pragma omp parallel for reduction(+ : s) // expected-error {{list item of type 'struct S' is not valid for specified reduction operation: unable to provide default initialization value}} for (arg = 0; arg < 10; ++arg) s.s += arg; #pragma omp declare reduction(red : int : omp_out++) { #pragma omp declare reduction(red : int : omp_out++) // expected-note {{previous definition is here}} #pragma omp declare reduction(red : int : omp_out++) // expected-error {{redefinition of user-defined reduction for type 'int'}} { #pragma omp declare reduction(red : int : omp_out++) } } return arg; }
comms.h	/* //@HEADER // *************************************************************************** // // XtraPuLP: Xtreme-Scale Graph Partitioning using Label Propagation // Copyright (2016) Sandia Corporation // // Under the terms of Contract DE-AC04-94AL85000 with Sandia Corporation, // the U.S. Government retains certain rights in this software. // // Redistribution and use in source and binary forms, with or without // modification, are permitted provided that the following conditions are // met: // // 1. Redistributions of source code must retain the above copyright // notice, this list of conditions and the following disclaimer. // // 2. 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. // // 3. Neither the name of the Corporation nor the names of the // contributors may be used to endorse or promote products derived from // this software without specific prior written permission. // // THIS SOFTWARE IS PROVIDED BY SANDIA CORPORATION "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 SANDIA CORPORATION OR THE // 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. // // Questions? Contact George M. Slota (gmslota@sandia.gov) // Siva Rajamanickam (srajama@sandia.gov) // Kamesh Madduri (madduri@cse.psu.edu) // // *************************************************************************** //@HEADER / #ifndef _COMMS_H_ #define _COMMS_H_ #include <mpi.h> #include <omp.h> #include <stdio.h> #include <stdlib.h> #include <stdint.h> #include <assert.h> #include "xtrapulp.h" #include "util.h" namespace pulp{ extern int procid, nprocs; extern bool verbose, debug, verify; extern MPI_Comm pulp_comm; #define MAX_SEND_SIZE 2147483648 #define THREAD_QUEUE_SIZE 1024 struct mpi_data_t { int32_t sendcounts; uint64_t* sendcounts_temp; int32_t* recvcounts; uint64_t* recvcounts_temp; int32_t* sdispls; int32_t* rdispls; int32_t* sdispls_cpy; uint64_t* sdispls_temp; uint64_t* sendbuf_vert; int32_t* sendbuf_data; uint64_t* recvbuf_vert; int32_t* recvbuf_data; uint64_t total_recv; uint64_t total_send; uint64_t global_queue_size; }; struct queue_data_t { uint64_t* queue; uint64_t* queue_next; uint64_t* queue_send; uint64_t queue_size; uint64_t next_size; uint64_t send_size; }; struct thread_queue_t { int32_t tid; uint64_t* thread_queue; uint64_t* thread_send; uint64_t thread_queue_size; uint64_t thread_send_size; } ; struct thread_comm_t { int32_t tid; bool* v_to_rank; uint64_t* sendcounts_thread; uint64_t* sendbuf_vert_thread; int32_t* sendbuf_data_thread ; int32_t* sendbuf_rank_thread; uint64_t* thread_starts; uint64_t thread_queue_size; }; void init_queue_data(dist_graph_t* g, queue_data_t* q); void clear_queue_data(queue_data_t* q); void init_comm_data(mpi_data_t* comm); void clear_comm_data(mpi_data_t* comm); void init_thread_queue(thread_queue_t* tq); void clear_thread_queue(thread_queue_t* tq); void init_thread_comm(thread_comm_t* tc); void clear_thread_comm(thread_comm_t* tc); void init_sendbuf_vid_data(mpi_data_t* comm); void clear_recvbuf_vid_data(mpi_data_t* comm); inline void exchange_verts(dist_graph_t* g, mpi_data_t* comm, queue_data_t* q); inline void exchange_vert_data(dist_graph_t* g, mpi_data_t* comm, queue_data_t* q); inline void update_sendcounts_thread(dist_graph_t* g, thread_comm_t* tc, uint64_t vert_index); inline void update_vid_data_queues(dist_graph_t* g, thread_comm_t* tc, mpi_data_t* comm, uint64_t vert_index, int32_t* data); inline void add_vid_to_queue(thread_queue_t* tq, queue_data_t* q, uint64_t vertex_id); inline void empty_queue(thread_queue_t* tq, queue_data_t* q); inline void add_vid_to_send(thread_queue_t* tq, queue_data_t* q, uint64_t vertex_id); inline void empty_send(thread_queue_t* tq, queue_data_t* q); inline void add_vid_data_to_send(thread_comm_t* tc, mpi_data_t* comm, uint64_t vertex_id, int32_t data_val, int32_t send_rank); inline void empty_vid_data(thread_comm_t* tc, mpi_data_t* comm); inline void exchange_verts(dist_graph_t* g, mpi_data_t* comm, queue_data_t* q) { comm->global_queue_size = 0; uint64_t task_queue_size = q->next_size + q->send_size; MPI_Allreduce(&task_queue_size, &comm->global_queue_size, 1, MPI_UINT64_T, MPI_SUM, pulp_comm); uint64_t num_comms = comm->global_queue_size / (uint64_t)MAX_SEND_SIZE + 1; uint64_t sum_recv = 0; for (uint64_t c = 0; c < num_comms; ++c) { uint64_t send_begin = (q->send_size * c) / num_comms; uint64_t send_end = (q->send_size * (c + 1)) / num_comms; if (c == (num_comms-1)) send_end = q->send_size; for (int32_t i = 0; i < nprocs; ++i) { comm->sendcounts[i] = 0; comm->recvcounts[i] = 0; } for (uint64_t i = send_begin; i < send_end; ++i) { uint64_t ghost_index = q->queue_send[i] - g->n_local; uint64_t ghost_task = g->ghost_tasks[ghost_index]; ++comm->sendcounts[ghost_task]; } MPI_Alltoall(comm->sendcounts, 1, MPI_INT32_T, comm->recvcounts, 1, MPI_INT32_T, pulp_comm); comm->sdispls[0] = 0; comm->sdispls_cpy[0] = 0; comm->rdispls[0] = 0; for (int32_t i = 1; i < nprocs; ++i) { comm->sdispls[i] = comm->sdispls[i-1] + comm->sendcounts[i-1]; comm->rdispls[i] = comm->rdispls[i-1] + comm->recvcounts[i-1]; comm->sdispls_cpy[i] = comm->sdispls[i]; } int32_t cur_send = comm->sdispls[nprocs-1] + comm->sendcounts[nprocs-1]; int32_t cur_recv = comm->rdispls[nprocs-1] + comm->recvcounts[nprocs-1]; comm->sendbuf_vert = (uint64_t)malloc((uint64_t)(cur_send+1)sizeof(uint64_t)); if (comm->sendbuf_vert == NULL) throw_err("exchange_verts(), unable to allocate comm buffers", procid); for (uint64_t i = send_begin; i < send_end; ++i) { uint64_t ghost_index = q->queue_send[i] - g->n_local; uint64_t ghost_task = g->ghost_tasks[ghost_index]; uint64_t vert = g->ghost_unmap[ghost_index]; comm->sendbuf_vert[comm->sdispls_cpy[ghost_task]++] = vert; } MPI_Alltoallv(comm->sendbuf_vert, comm->sendcounts, comm->sdispls, MPI_UINT64_T, q->queue_next+q->next_size+sum_recv, comm->recvcounts, comm->rdispls, MPI_UINT64_T, pulp_comm); free(comm->sendbuf_vert); sum_recv += cur_recv; } q->queue_size = q->next_size + sum_recv; q->next_size = 0; q->send_size = 0; uint64_t* temp = q->queue; q->queue = q->queue_next; q->queue_next = temp; } inline void exchange_vert_data(dist_graph_t* g, mpi_data_t* comm, queue_data_t* q) { for (int32_t i = 0; i < nprocs; ++i) comm->recvcounts_temp[i] = 0; for (int32_t i = 0; i < nprocs; ++i) comm->sdispls_temp[i] -= comm->sendcounts_temp[i]; MPI_Alltoall(comm->sendcounts_temp, 1, MPI_UINT64_T, comm->recvcounts_temp, 1, MPI_UINT64_T, pulp_comm); comm->total_recv = 0; for (int i = 0; i < nprocs; ++i) comm->total_recv += comm->recvcounts_temp[i]; comm->recvbuf_vert = (uint64_t)malloc(comm->total_recvsizeof(uint64_t)); comm->recvbuf_data = (int32_t)malloc(comm->total_recvsizeof(uint32_t)); if (comm->recvbuf_vert == NULL \|\| comm->sendbuf_vert == NULL) throw_err("exchange_vert_data() unable to allocate comm buffers", procid); comm->global_queue_size = 0; uint64_t task_queue_size = comm->total_send; MPI_Allreduce(&task_queue_size, &comm->global_queue_size, 1, MPI_UINT64_T, MPI_SUM, pulp_comm); uint64_t num_comms = comm->global_queue_size / (uint64_t)MAX_SEND_SIZE + 1; uint64_t sum_recv = 0; uint64_t sum_send = 0; for (uint64_t c = 0; c < num_comms; ++c) { for (int32_t i = 0; i < nprocs; ++i) { uint64_t send_begin = (comm->sendcounts_temp[i] * c) / num_comms; uint64_t send_end = (comm->sendcounts_temp[i] * (c + 1)) / num_comms; if (c == (num_comms-1)) send_end = comm->sendcounts_temp[i]; comm->sendcounts[i] = (int32_t)(send_end - send_begin); assert(comm->sendcounts[i] >= 0); } MPI_Alltoall(comm->sendcounts, 1, MPI_INT32_T, comm->recvcounts, 1, MPI_INT32_T, pulp_comm); comm->sdispls[0] = 0; comm->sdispls_cpy[0] = 0; comm->rdispls[0] = 0; for (int32_t i = 1; i < nprocs; ++i) { comm->sdispls[i] = comm->sdispls[i-1] + comm->sendcounts[i-1]; comm->rdispls[i] = comm->rdispls[i-1] + comm->recvcounts[i-1]; comm->sdispls_cpy[i] = comm->sdispls[i]; } int32_t cur_send = comm->sdispls[nprocs-1] + comm->sendcounts[nprocs-1]; int32_t cur_recv = comm->rdispls[nprocs-1] + comm->recvcounts[nprocs-1]; uint64_t* buf_v = (uint64_t)malloc((uint64_t)(cur_send)sizeof(uint64_t)); int32_t* buf_d = (int32_t)malloc((int32_t)(cur_send)sizeof(int32_t)); if (buf_v == NULL \|\| buf_d == NULL) throw_err("exchange_verts(), unable to allocate comm buffers", procid); for (int32_t i = 0; i < nprocs; ++i) { uint64_t send_begin = (comm->sendcounts_temp[i] * c) / num_comms; uint64_t send_end = (comm->sendcounts_temp[i] * (c + 1)) / num_comms; if (c == (num_comms-1)) send_end = comm->sendcounts_temp[i]; for (uint64_t j = send_begin; j < send_end; ++j) { uint64_t vert = comm->sendbuf_vert[comm->sdispls_temp[i]+j]; int32_t data = comm->sendbuf_data[comm->sdispls_temp[i]+j]; buf_v[comm->sdispls_cpy[i]] = vert; buf_d[comm->sdispls_cpy[i]++] = data; } } MPI_Alltoallv(buf_v, comm->sendcounts, comm->sdispls, MPI_UINT64_T, comm->recvbuf_vert+sum_recv, comm->recvcounts, comm->rdispls, MPI_UINT64_T, pulp_comm); MPI_Alltoallv(buf_d, comm->sendcounts, comm->sdispls, MPI_INT32_T, comm->recvbuf_data+sum_recv, comm->recvcounts, comm->rdispls, MPI_INT32_T, pulp_comm); free(buf_v); free(buf_d); sum_recv += cur_recv; sum_send += cur_send; } free(comm->sendbuf_data); free(comm->sendbuf_vert); assert(sum_recv == comm->total_recv); assert(sum_send == comm->total_send); comm->global_queue_size = 0; task_queue_size = comm->total_recv + q->next_size; MPI_Allreduce(&task_queue_size, &comm->global_queue_size, 1, MPI_UINT64_T, MPI_SUM, pulp_comm); q->next_size = 0; q->send_size = 0; } inline void update_sendcounts_thread(dist_graph_t* g, thread_comm_t* tc, uint64_t vert_index) { for (int32_t i = 0; i < nprocs; ++i) tc->v_to_rank[i] = false; uint64_t out_degree = out_degree(g, vert_index); uint64_t* outs = out_vertices(g, vert_index); for (uint64_t j = 0; j < out_degree; ++j) { uint64_t out_index = outs[j]; if (out_index >= g->n_local) { int32_t out_rank = g->ghost_tasks[out_index-g->n_local]; if (!tc->v_to_rank[out_rank]) { tc->v_to_rank[out_rank] = true; ++tc->sendcounts_thread[out_rank]; } } } } inline void update_vid_data_queues(dist_graph_t* g, thread_comm_t* tc, mpi_data_t* comm, uint64_t vert_index, int32_t data) { for (int32_t i = 0; i < nprocs; ++i) tc->v_to_rank[i] = false; uint64_t out_degree = out_degree(g, vert_index); uint64_t* outs = out_vertices(g, vert_index); for (uint64_t j = 0; j < out_degree; ++j) { uint64_t out_index = outs[j]; if (out_index >= g->n_local) { int32_t out_rank = g->ghost_tasks[out_index - g->n_local]; if (!tc->v_to_rank[out_rank]) { tc->v_to_rank[out_rank] = true; add_vid_data_to_send(tc, comm, g->local_unmap[vert_index], data, out_rank); } } } } inline void add_vid_to_queue(thread_queue_t* tq, queue_data_t* q, uint64_t vertex_id) { tq->thread_queue[tq->thread_queue_size++] = vertex_id; if (tq->thread_queue_size == THREAD_QUEUE_SIZE) { uint64_t start_offset; #pragma omp atomic capture start_offset = q->next_size += THREAD_QUEUE_SIZE; start_offset -= THREAD_QUEUE_SIZE; for (uint64_t i = 0; i < THREAD_QUEUE_SIZE; ++i) q->queue_next[start_offset + i] = tq->thread_queue[i]; tq->thread_queue_size = 0; } } inline void empty_queue(thread_queue_t* tq, queue_data_t* q) { uint64_t start_offset; #pragma omp atomic capture start_offset = q->next_size += tq->thread_queue_size; start_offset -= tq->thread_queue_size; for (uint64_t i = 0; i < tq->thread_queue_size; ++i) q->queue_next[start_offset + i] = tq->thread_queue[i]; tq->thread_queue_size = 0; } inline void add_vid_to_send(thread_queue_t* tq, queue_data_t* q, uint64_t vertex_id) { tq->thread_send[tq->thread_send_size++] = vertex_id; if (tq->thread_send_size == THREAD_QUEUE_SIZE) { uint64_t start_offset; #pragma omp atomic capture start_offset = q->send_size += tq->thread_send_size; start_offset -= tq->thread_send_size; for (uint64_t i = 0; i < THREAD_QUEUE_SIZE; ++i) q->queue_send[start_offset + i] = tq->thread_send[i]; tq->thread_send_size = 0; } } inline void empty_send(thread_queue_t* tq, queue_data_t* q) { uint64_t start_offset; #pragma omp atomic capture start_offset = q->send_size += tq->thread_send_size; start_offset -= tq->thread_send_size; for (uint64_t i = 0; i < tq->thread_send_size; ++i) q->queue_send[start_offset + i] = tq->thread_send[i]; tq->thread_send_size = 0; } inline void add_vid_data_to_send(thread_comm_t* tc, mpi_data_t* comm, uint64_t vertex_id, int32_t data_val, int32_t send_rank) { tc->sendbuf_vert_thread[tc->thread_queue_size] = vertex_id; tc->sendbuf_data_thread[tc->thread_queue_size] = data_val; tc->sendbuf_rank_thread[tc->thread_queue_size] = send_rank; ++tc->thread_queue_size; ++tc->sendcounts_thread[send_rank]; if (tc->thread_queue_size == THREAD_QUEUE_SIZE) { for (int32_t i = 0; i < nprocs; ++i) { #pragma omp atomic capture tc->thread_starts[i] = comm->sdispls_temp[i] += tc->sendcounts_thread[i]; tc->thread_starts[i] -= tc->sendcounts_thread[i]; } for (uint64_t i = 0; i < tc->thread_queue_size; ++i) { int32_t cur_rank = tc->sendbuf_rank_thread[i]; comm->sendbuf_vert[tc->thread_starts[cur_rank]] = tc->sendbuf_vert_thread[i]; comm->sendbuf_data[tc->thread_starts[cur_rank]] = tc->sendbuf_data_thread[i]; ++tc->thread_starts[cur_rank]; } for (int32_t i = 0; i < nprocs; ++i) { tc->thread_starts[i] = 0; tc->sendcounts_thread[i] = 0; } tc->thread_queue_size = 0; } } inline void empty_vid_data(thread_comm_t* tc, mpi_data_t* comm) { for (int32_t i = 0; i < nprocs; ++i) { #pragma omp atomic capture tc->thread_starts[i] = comm->sdispls_temp[i] += tc->sendcounts_thread[i]; tc->thread_starts[i] -= tc->sendcounts_thread[i]; } for (uint64_t i = 0; i < tc->thread_queue_size; ++i) { int32_t cur_rank = tc->sendbuf_rank_thread[i]; comm->sendbuf_vert[tc->thread_starts[cur_rank]] = tc->sendbuf_vert_thread[i]; comm->sendbuf_data[tc->thread_starts[cur_rank]] = tc->sendbuf_data_thread[i]; ++tc->thread_starts[cur_rank]; } for (int32_t i = 0; i < nprocs; ++i) { tc->thread_starts[i] = 0; tc->sendcounts_thread[i] = 0; } tc->thread_queue_size = 0; } } #endif
cell_division_gpu.h	// ----------------------------------------------------------------------------- // // Copyright (C) The BioDynaMo Project. // 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. // // See the LICENSE file distributed with this work for details. // See the NOTICE file distributed with this work for additional information // regarding copyright ownership. // // ----------------------------------------------------------------------------- #ifndef SYSTEM_CELL_DIVISION_GPU_SRC_CELL_DIVISION_GPU_H_ #define SYSTEM_CELL_DIVISION_GPU_SRC_CELL_DIVISION_GPU_H_ #include <array> #include "biodynamo.h" #include "core/param/command_line_options.h" #include "core/util/math.h" #include "core/util/timing.h" namespace bdm { // ---------------------------------------------------------------------------- // Starting with 8 cells, we let each cell grow in volume up until a point // a cell must divide. This tests whether the GPU accelerated mechanical // interactions properly handle the creation of new cells. // ----------------------------------------------------------------------------- inline void ExpectArrayNear(const Double3& actual, const Double3& expected, bool* wrong) { for (size_t i = 0; i < actual.size(); i++) { if (std::fabs(expected[i] - actual[i]) > 1e-9) { wrong = true; std::cout << "Wrong result! Expected " << expected[i] << ", but instead got " << actual[i] << ", which is a difference of " << std::fabs(expected[i] - actual[i]) << ", which is larger than 1e-9" << std::endl; } } } inline void RunTest(bool wrong, OpComputeTarget mode, uint64_t timesteps, uint64_t cells_per_dim) { std::cout << "Running simulation on "; auto set_param = [&](auto* param) { switch (mode) { case kCpu: std::cout << "CPU (" << omp_get_max_threads() << " threads)\n"; break; case kOpenCl: std::cout << "GPU (OpenCL)\n"; param->compute_target = "opencl"; break; case kCuda: std::cout << "GPU (CUDA)\n"; param->compute_target = "cuda"; break; } }; Simulation simulation("cell_division_gpu", set_param); auto* rm = simulation.GetResourceManager(); rm->ClearAgents(); // We need to give every test the same seed for the RNG, because in the cell // division, random numbers are used. Within a single executable these numbers // vary. Also within the threads this needs to be enforced #pragma omp parallel simulation.GetRandom()->SetSeed(1); auto construct = [](const Double3& position) { auto* cell = new Cell(position); cell->SetDiameter(30); cell->SetAdherence(0.4); cell->SetMass(1.0); cell->AddBehavior(new GrowthDivision(30.05, 5000)); return cell; }; for (size_t x = 0; x < cells_per_dim; x++) { double x_pos = x * 20.0; for (size_t y = 0; y < cells_per_dim; y++) { double y_pos = y * 20.0; for (size_t z = 0; z < cells_per_dim; z++) { auto new_simulation_object = construct({x_pos, y_pos, z * 20.0}); rm->AddAgent(new_simulation_object); } } } { Timing timer("Execution time"); simulation.GetScheduler()->Simulate(timesteps); } // TODO: add verification of results } inline int Simulate(int argc, const char** argv) { auto options = CommandLineOptions(argc, argv); options.AddOption<bool>("verify", "false"); options.AddOption<uint64_t>("cells-per-dim", "64"); options.AddOption<uint64_t>("timesteps", "5"); uint64_t cells_per_dim = options.Get<uint64_t>("cells-per-dim"); uint64_t timesteps = options.Get<uint64_t>("timesteps"); bool wrong = true; bool is_opencl = options.Get<bool>("opencl"); bool is_cuda = options.Get<bool>("cuda"); // TODO(ahmad): after Trello card ("Fix inconsistency in cell state due to // direct updates in Biology Modules") enable multithreading, and adjust // results if necessary // omp_set_num_threads(1); if (!is_cuda && !is_opencl) { // Run CPU version RunTest(&wrong, kCpu, timesteps, cells_per_dim); } #ifdef USE_CUDA if (is_cuda) { // Run GPU (CUDA) version RunTest(&wrong, kCuda, timesteps, cells_per_dim); } #endif // USE_CUDA #ifdef USE_OPENCL if (is_opencl) { // Run GPU (OpenCL) version RunTest(&wrong, kOpenCl, timesteps, cells_per_dim); } #endif // USE_OPENCL return !wrong; } } // namespace bdm #endif // SYSTEM_CELL_DIVISION_GPU_SRC_CELL_DIVISION_GPU_H_
GB_unaryop__ainv_int32_int64.c	//------------------------------------------------------------------------------ // GB_unaryop: hard-coded functions for each built-in unary operator //------------------------------------------------------------------------------ // SuiteSparse:GraphBLAS, Timothy A. Davis, (c) 2017-2019, 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__ainv_int32_int64 // op(A') function: GB_tran__ainv_int32_int64 // C type: int32_t // A type: int64_t // cast: int32_t cij = (int32_t) aij // unaryop: cij = -aij #define GB_ATYPE \ int64_t #define GB_CTYPE \ int32_t // aij = Ax [pA] #define GB_GETA(aij,Ax,pA) \ int64_t aij = Ax [pA] #define GB_CX(p) Cx [p] // unary operator #define GB_OP(z, x) \ z = -x ; // casting #define GB_CASTING(z, x) \ int32_t z = (int32_t) x ; // 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 (x, aij) ; \ GB_OP (GB_CX (pC), x) ; \ } // disable this operator and use the generic case if these conditions hold #define GB_DISABLE \ (GxB_NO_AINV \|\| GxB_NO_INT32 \|\| GxB_NO_INT64) //------------------------------------------------------------------------------ // Cx = op (cast (Ax)): apply a unary operator //------------------------------------------------------------------------------ GrB_Info GB_unop__ainv_int32_int64 ( int32_t restrict Cx, const int64_t restrict Ax, int64_t anz, int nthreads ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else #pragma omp parallel for num_threads(nthreads) schedule(static) for (int64_t 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__ainv_int32_int64 ( GrB_Matrix C, const GrB_Matrix A, int64_t restrict Rowcounts, GBI_single_iterator Iter, const int64_t 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
cache.c	/* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % CCCC AAA CCCC H H EEEEE % % C A A C H H E % % C AAAAA C HHHHH EEE % % C A A C H H E % % CCCC A A CCCC H H EEEEE % % % % % % MagickCore Pixel Cache Methods % % % % Software Design % % Cristy % % July 1999 % % % % % % Copyright 1999-2018 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/cache-private.h" #include "MagickCore/color-private.h" #include "MagickCore/colorspace-private.h" #include "MagickCore/composite-private.h" #include "MagickCore/distribute-cache-private.h" #include "MagickCore/exception.h" #include "MagickCore/exception-private.h" #include "MagickCore/geometry.h" #include "MagickCore/list.h" #include "MagickCore/log.h" #include "MagickCore/magick.h" #include "MagickCore/memory_.h" #include "MagickCore/memory-private.h" #include "MagickCore/nt-base-private.h" #include "MagickCore/option.h" #include "MagickCore/pixel.h" #include "MagickCore/pixel-accessor.h" #include "MagickCore/policy.h" #include "MagickCore/quantum.h" #include "MagickCore/random_.h" #include "MagickCore/registry.h" #include "MagickCore/resource_.h" #include "MagickCore/semaphore.h" #include "MagickCore/splay-tree.h" #include "MagickCore/string_.h" #include "MagickCore/string-private.h" #include "MagickCore/thread-private.h" #include "MagickCore/utility.h" #include "MagickCore/utility-private.h" #if defined(MAGICKCORE_ZLIB_DELEGATE) #include "zlib.h" #endif / Define declarations. / #define CacheTick(offset,extent) QuantumTick((MagickOffsetType) offset,extent) #define IsFileDescriptorLimitExceeded() (GetMagickResource(FileResource) > \ GetMagickResourceLimit(FileResource) ? MagickTrue : MagickFalse) / Typedef declarations. / typedef struct _MagickModulo { ssize_t quotient, remainder; } MagickModulo; / Forward declarations. / #if defined(__cplusplus) \|\| defined(c_plusplus) extern "C" { #endif static Cache GetImagePixelCache(Image ,const MagickBooleanType,ExceptionInfo ) magick_hot_spot; static const Quantum GetVirtualPixelCache(const Image ,const VirtualPixelMethod,const ssize_t, const ssize_t,const size_t,const size_t,ExceptionInfo ), GetVirtualPixelsCache(const Image ); static const void GetVirtualMetacontentFromCache(const Image ); static MagickBooleanType GetOneAuthenticPixelFromCache(Image ,const ssize_t,const ssize_t,Quantum , ExceptionInfo ), GetOneVirtualPixelFromCache(const Image ,const VirtualPixelMethod, const ssize_t,const ssize_t,Quantum ,ExceptionInfo ), OpenPixelCache(Image ,const MapMode,ExceptionInfo ), OpenPixelCacheOnDisk(CacheInfo ,const MapMode), ReadPixelCachePixels(CacheInfo magick_restrict,NexusInfo magick_restrict, ExceptionInfo ), ReadPixelCacheMetacontent(CacheInfo magick_restrict, NexusInfo magick_restrict,ExceptionInfo ), SyncAuthenticPixelsCache(Image ,ExceptionInfo ), WritePixelCachePixels(CacheInfo magick_restrict,NexusInfo magick_restrict, ExceptionInfo ), WritePixelCacheMetacontent(CacheInfo ,NexusInfo magick_restrict, ExceptionInfo ); static Quantum GetAuthenticPixelsCache(Image ,const ssize_t,const ssize_t,const size_t, const size_t,ExceptionInfo ), QueueAuthenticPixelsCache(Image ,const ssize_t,const ssize_t,const size_t, const size_t,ExceptionInfo ), SetPixelCacheNexusPixels(const CacheInfo ,const MapMode, const RectangleInfo ,const MagickBooleanType,NexusInfo ,ExceptionInfo ) magick_hot_spot; #if defined(MAGICKCORE_OPENCL_SUPPORT) static void CopyOpenCLBuffer(CacheInfo magick_restrict); #endif #if defined(__cplusplus) \|\| defined(c_plusplus) } #endif / Global declarations. / static SemaphoreInfo cache_semaphore = (SemaphoreInfo ) NULL; static ssize_t cache_anonymous_memory = (-1); static time_t cache_epoch = 0; / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + A c q u i r e P i x e l C a c h e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % AcquirePixelCache() acquires a pixel cache. % % The format of the AcquirePixelCache() method is: % % Cache AcquirePixelCache(const size_t number_threads) % % A description of each parameter follows: % % o number_threads: the number of nexus threads. % / MagickPrivate Cache AcquirePixelCache(const size_t number_threads) { CacheInfo magick_restrict cache_info; char value; cache_info=(CacheInfo ) AcquireCriticalMemory(sizeof(cache_info)); (void) memset(cache_info,0,sizeof(cache_info)); cache_info->type=UndefinedCache; cache_info->mode=IOMode; cache_info->disk_mode=IOMode; cache_info->colorspace=sRGBColorspace; cache_info->file=(-1); cache_info->id=GetMagickThreadId(); cache_info->number_threads=number_threads; if (GetOpenMPMaximumThreads() > cache_info->number_threads) cache_info->number_threads=GetOpenMPMaximumThreads(); if (GetMagickResourceLimit(ThreadResource) > cache_info->number_threads) cache_info->number_threads=(size_t) GetMagickResourceLimit(ThreadResource); if (cache_info->number_threads == 0) cache_info->number_threads=1; cache_info->nexus_info=AcquirePixelCacheNexus(cache_info->number_threads); if (cache_info->nexus_info == (NexusInfo *) NULL) ThrowFatalException(ResourceLimitFatalError,"MemoryAllocationFailed"); value=GetEnvironmentValue("MAGICK_SYNCHRONIZE"); if (value != (const char ) NULL) { cache_info->synchronize=IsStringTrue(value); value=DestroyString(value); } value=GetPolicyValue("cache:synchronize"); if (value != (const char ) NULL) { cache_info->synchronize=IsStringTrue(value); value=DestroyString(value); } cache_info->semaphore=AcquireSemaphoreInfo(); cache_info->reference_count=1; cache_info->file_semaphore=AcquireSemaphoreInfo(); cache_info->debug=IsEventLogging(); cache_info->signature=MagickCoreSignature; return((Cache ) cache_info); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % A c q u i r e P i x e l C a c h e N e x u s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % AcquirePixelCacheNexus() allocates the NexusInfo structure. % % The format of the AcquirePixelCacheNexus method is: % % NexusInfo *AcquirePixelCacheNexus(const size_t number_threads) % % A description of each parameter follows: % % o number_threads: the number of nexus threads. % / MagickPrivate NexusInfo AcquirePixelCacheNexus(const size_t number_threads) { NexusInfo magick_restrict nexus_info; register ssize_t i; nexus_info=(NexusInfo *) MagickAssumeAligned(AcquireAlignedMemory( number_threads,sizeof(nexus_info))); if (nexus_info == (NexusInfo *) NULL) ThrowFatalException(ResourceLimitFatalError,"MemoryAllocationFailed"); nexus_info[0]=(NexusInfo ) AcquireQuantumMemory(number_threads, sizeof(*nexus_info)); if (nexus_info[0] == (NexusInfo ) NULL) ThrowFatalException(ResourceLimitFatalError,"MemoryAllocationFailed"); (void) memset(nexus_info[0],0,number_threadssizeof(nexus_info)); for (i=0; i < (ssize_t) number_threads; i++) { nexus_info[i]=(&nexus_info[0][i]); nexus_info[i]->signature=MagickCoreSignature; } return(nexus_info); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % A c q u i r e P i x e l C a c h e P i x e l s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % AcquirePixelCachePixels() returns the pixels associated with the specified % image. % % The format of the AcquirePixelCachePixels() method is: % % void AcquirePixelCachePixels(const Image image,size_t length, % ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o length: the pixel cache length. % % o exception: return any errors or warnings in this structure. % / MagickExport void AcquirePixelCachePixels(const Image image,size_t length, ExceptionInfo exception) { CacheInfo magick_restrict cache_info; assert(image != (const Image ) NULL); assert(image->signature == MagickCoreSignature); assert(exception != (ExceptionInfo ) NULL); assert(exception->signature == MagickCoreSignature); assert(image->cache != (Cache) NULL); cache_info=(CacheInfo ) image->cache; assert(cache_info->signature == MagickCoreSignature); length=0; if ((cache_info->type != MemoryCache) && (cache_info->type != MapCache)) return((void ) NULL); length=(size_t) cache_info->length; return(cache_info->pixels); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + C a c h e C o m p o n e n t G e n e s i s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % CacheComponentGenesis() instantiates the cache component. % % The format of the CacheComponentGenesis method is: % % MagickBooleanType CacheComponentGenesis(void) % / MagickPrivate MagickBooleanType CacheComponentGenesis(void) { if (cache_semaphore == (SemaphoreInfo ) NULL) cache_semaphore=AcquireSemaphoreInfo(); return(MagickTrue); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + C a c h e C o m p o n e n t T e r m i n u s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % CacheComponentTerminus() destroys the cache component. % % The format of the CacheComponentTerminus() method is: % % CacheComponentTerminus(void) % / MagickPrivate void CacheComponentTerminus(void) { if (cache_semaphore == (SemaphoreInfo ) NULL) ActivateSemaphoreInfo(&cache_semaphore); /* no op-- nothing to destroy / RelinquishSemaphoreInfo(&cache_semaphore); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + C l i p P i x e l C a c h e N e x u s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % ClipPixelCacheNexus() clips the cache nexus as defined by the image clip % mask. The method returns MagickTrue if the pixel region is clipped, % otherwise MagickFalse. % % The format of the ClipPixelCacheNexus() method is: % % MagickBooleanType ClipPixelCacheNexus(Image image,NexusInfo nexus_info, % ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o nexus_info: the cache nexus to clip. % % o exception: return any errors or warnings in this structure. % / static MagickBooleanType ClipPixelCacheNexus(Image image, NexusInfo nexus_info,ExceptionInfo exception) { CacheInfo magick_restrict cache_info; MagickSizeType number_pixels; NexusInfo *magick_restrict image_nexus; register Quantum magick_restrict p, magick_restrict q; register ssize_t n; / Apply clip mask. / if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); if ((image->channels & WriteMaskChannel) == 0) return(MagickTrue); cache_info=(CacheInfo ) image->cache; if (cache_info == (Cache) NULL) return(MagickFalse); image_nexus=AcquirePixelCacheNexus(1); p=GetAuthenticPixelCacheNexus(image,nexus_info->region.x,nexus_info->region.y, nexus_info->region.width,nexus_info->region.height,image_nexus[0], exception); q=nexus_info->pixels; number_pixels=(MagickSizeType) nexus_info->region.width* nexus_info->region.height; for (n=0; n < (ssize_t) number_pixels; n++) { double mask_alpha; register ssize_t i; if (p == (Quantum ) NULL) break; mask_alpha=QuantumScaleGetPixelWriteMask(image,p); if (fabs(mask_alpha) >= MagickEpsilon) { for (i=0; i < (ssize_t) image->number_channels; i++) { PixelChannel channel = GetPixelChannelChannel(image,i); PixelTrait traits = GetPixelChannelTraits(image,channel); if ((traits & UpdatePixelTrait) == 0) continue; q[i]=ClampToQuantum(MagickOver_((double) p[i],mask_alpha* GetPixelAlpha(image,p),(double) q[i],(double) GetPixelAlpha(image,q))); } SetPixelAlpha(image,GetPixelAlpha(image,p),q); } p+=GetPixelChannels(image); q+=GetPixelChannels(image); } image_nexus=DestroyPixelCacheNexus(image_nexus,1); if (n < (ssize_t) number_pixels) return(MagickFalse); return(MagickTrue); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + C l o n e P i x e l C a c h e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % ClonePixelCache() clones a pixel cache. % % The format of the ClonePixelCache() method is: % % Cache ClonePixelCache(const Cache cache) % % A description of each parameter follows: % % o cache: the pixel cache. % / MagickPrivate Cache ClonePixelCache(const Cache cache) { CacheInfo magick_restrict clone_info; const CacheInfo magick_restrict cache_info; assert(cache != NULL); cache_info=(const CacheInfo ) cache; assert(cache_info->signature == MagickCoreSignature); if (cache_info->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s", cache_info->filename); clone_info=(CacheInfo ) AcquirePixelCache(cache_info->number_threads); clone_info->virtual_pixel_method=cache_info->virtual_pixel_method; return((Cache ) clone_info); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + C l o n e P i x e l C a c h e M e t h o d s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % ClonePixelCacheMethods() clones the pixel cache methods from one cache to % another. % % The format of the ClonePixelCacheMethods() method is: % % void ClonePixelCacheMethods(Cache clone,const Cache cache) % % A description of each parameter follows: % % o clone: Specifies a pointer to a Cache structure. % % o cache: the pixel cache. % / MagickPrivate void ClonePixelCacheMethods(Cache clone,const Cache cache) { CacheInfo magick_restrict cache_info, magick_restrict source_info; assert(clone != (Cache) NULL); source_info=(CacheInfo ) clone; assert(source_info->signature == MagickCoreSignature); if (source_info->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s", source_info->filename); assert(cache != (Cache) NULL); cache_info=(CacheInfo ) cache; assert(cache_info->signature == MagickCoreSignature); source_info->methods=cache_info->methods; } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + C l o n e P i x e l C a c h e R e p o s i t o r y % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % ClonePixelCacheRepository() clones the source pixel cache to the destination % cache. % % The format of the ClonePixelCacheRepository() method is: % % MagickBooleanType ClonePixelCacheRepository(CacheInfo cache_info, % CacheInfo source_info,ExceptionInfo exception) % % A description of each parameter follows: % % o cache_info: the pixel cache. % % o source_info: the source pixel cache. % % o exception: return any errors or warnings in this structure. % / static MagickBooleanType ClonePixelCacheOnDisk( CacheInfo magick_restrict cache_info,CacheInfo magick_restrict clone_info) { MagickSizeType extent; size_t quantum; ssize_t count; struct stat file_stats; unsigned char buffer; / Clone pixel cache on disk with identical morphology. / if ((OpenPixelCacheOnDisk(cache_info,ReadMode) == MagickFalse) \|\| (OpenPixelCacheOnDisk(clone_info,IOMode) == MagickFalse)) return(MagickFalse); if ((lseek(cache_info->file,0,SEEK_SET) < 0) \|\| (lseek(clone_info->file,0,SEEK_SET) < 0)) return(MagickFalse); quantum=(size_t) MagickMaxBufferExtent; if ((fstat(cache_info->file,&file_stats) == 0) && (file_stats.st_size > 0)) quantum=(size_t) MagickMin(file_stats.st_size,MagickMaxBufferExtent); buffer=(unsigned char ) AcquireQuantumMemory(quantum,sizeof(buffer)); if (buffer == (unsigned char ) NULL) ThrowFatalException(ResourceLimitFatalError,"MemoryAllocationFailed"); extent=0; while ((count=read(cache_info->file,buffer,quantum)) > 0) { ssize_t number_bytes; number_bytes=write(clone_info->file,buffer,(size_t) count); if (number_bytes != count) break; extent+=number_bytes; } buffer=(unsigned char ) RelinquishMagickMemory(buffer); if (extent != cache_info->length) return(MagickFalse); return(MagickTrue); } static MagickBooleanType ClonePixelCacheRepository( CacheInfo magick_restrict clone_info,CacheInfo magick_restrict cache_info, ExceptionInfo exception) { #define MaxCacheThreads ((size_t) GetMagickResourceLimit(ThreadResource)) #define cache_number_threads(source,destination,chunk,multithreaded) \ num_threads((multithreaded) == 0 ? 1 : \ (((source)->type != MemoryCache) && ((source)->type != MapCache)) \|\| \ (((destination)->type != MemoryCache) && ((destination)->type != MapCache)) ? \ MagickMax(MagickMin(GetMagickResourceLimit(ThreadResource),2),1) : \ MagickMax(MagickMin((ssize_t) GetMagickResourceLimit(ThreadResource),(ssize_t) (chunk)/256),1)) MagickBooleanType optimize, status; NexusInfo magick_restrict cache_nexus, magick_restrict clone_nexus; size_t length; ssize_t y; assert(cache_info != (CacheInfo ) NULL); assert(clone_info != (CacheInfo ) NULL); assert(exception != (ExceptionInfo ) NULL); if (cache_info->type == PingCache) return(MagickTrue); length=cache_info->number_channelssizeof(cache_info->channel_map); if ((cache_info->storage_class == clone_info->storage_class) && (cache_info->colorspace == clone_info->colorspace) && (cache_info->alpha_trait == clone_info->alpha_trait) && (cache_info->channels == clone_info->channels) && (cache_info->columns == clone_info->columns) && (cache_info->rows == clone_info->rows) && (cache_info->number_channels == clone_info->number_channels) && (memcmp(cache_info->channel_map,clone_info->channel_map,length) == 0) && (cache_info->metacontent_extent == clone_info->metacontent_extent)) { / Identical pixel cache morphology. / if (((cache_info->type == MemoryCache) \|\| (cache_info->type == MapCache)) && ((clone_info->type == MemoryCache) \|\| (clone_info->type == MapCache))) { (void) memcpy(clone_info->pixels,cache_info->pixels, cache_info->number_channelscache_info->columnscache_info->rows sizeof(cache_info->pixels)); if ((cache_info->metacontent_extent != 0) && (clone_info->metacontent_extent != 0)) (void) memcpy(clone_info->metacontent,cache_info->metacontent, cache_info->columnscache_info->rows* clone_info->metacontent_extentsizeof(unsigned char)); return(MagickTrue); } if ((cache_info->type == DiskCache) && (clone_info->type == DiskCache)) return(ClonePixelCacheOnDisk(cache_info,clone_info)); } / Mismatched pixel cache morphology. / cache_nexus=AcquirePixelCacheNexus(MaxCacheThreads); clone_nexus=AcquirePixelCacheNexus(MaxCacheThreads); length=cache_info->number_channelssizeof(cache_info->channel_map); optimize=(cache_info->number_channels == clone_info->number_channels) && (memcmp(cache_info->channel_map,clone_info->channel_map,length) == 0) ? MagickTrue : MagickFalse; length=(size_t) MagickMin(cache_info->number_channelscache_info->columns, clone_info->number_channelsclone_info->columns); status=MagickTrue; #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(status) \ cache_number_threads(cache_info,clone_info,cache_info->rows,1) #endif for (y=0; y < (ssize_t) cache_info->rows; y++) { const int id = GetOpenMPThreadId(); Quantum pixels; RectangleInfo region; register ssize_t x; if (status == MagickFalse) continue; if (y >= (ssize_t) clone_info->rows) continue; region.width=cache_info->columns; region.height=1; region.x=0; region.y=y; pixels=SetPixelCacheNexusPixels(cache_info,ReadMode,&region,MagickFalse, cache_nexus[id],exception); if (pixels == (Quantum ) NULL) continue; status=ReadPixelCachePixels(cache_info,cache_nexus[id],exception); if (status == MagickFalse) continue; region.width=clone_info->columns; pixels=SetPixelCacheNexusPixels(clone_info,WriteMode,&region,MagickFalse, clone_nexus[id],exception); if (pixels == (Quantum ) NULL) continue; (void) memset(clone_nexus[id]->pixels,0,(size_t) clone_nexus[id]->length); if (optimize != MagickFalse) (void) memcpy(clone_nexus[id]->pixels,cache_nexus[id]->pixels,length* sizeof(Quantum)); else { register const Quantum magick_restrict p; register Quantum magick_restrict q; /* Mismatched pixel channel map. / p=cache_nexus[id]->pixels; q=clone_nexus[id]->pixels; for (x=0; x < (ssize_t) cache_info->columns; x++) { register ssize_t i; if (x == (ssize_t) clone_info->columns) break; for (i=0; i < (ssize_t) clone_info->number_channels; i++) { PixelChannel channel; PixelTrait traits; channel=clone_info->channel_map[i].channel; traits=cache_info->channel_map[channel].traits; if (traits != UndefinedPixelTrait) q=(p+cache_info->channel_map[channel].offset); q++; } p+=cache_info->number_channels; } } status=WritePixelCachePixels(clone_info,clone_nexus[id],exception); } if ((cache_info->metacontent_extent != 0) && (clone_info->metacontent_extent != 0)) { / Clone metacontent. / length=(size_t) MagickMin(cache_info->metacontent_extent, clone_info->metacontent_extent); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(status) \ cache_number_threads(cache_info,clone_info,cache_info->rows,1) #endif for (y=0; y < (ssize_t) cache_info->rows; y++) { const int id = GetOpenMPThreadId(); Quantum pixels; RectangleInfo region; if (status == MagickFalse) continue; if (y >= (ssize_t) clone_info->rows) continue; region.width=cache_info->columns; region.height=1; region.x=0; region.y=y; pixels=SetPixelCacheNexusPixels(cache_info,ReadMode,&region,MagickFalse, cache_nexus[id],exception); if (pixels == (Quantum ) NULL) continue; status=ReadPixelCacheMetacontent(cache_info,cache_nexus[id],exception); if (status == MagickFalse) continue; region.width=clone_info->columns; pixels=SetPixelCacheNexusPixels(clone_info,WriteMode,&region, MagickFalse,clone_nexus[id],exception); if (pixels == (Quantum ) NULL) continue; if ((clone_nexus[id]->metacontent != (void ) NULL) && (cache_nexus[id]->metacontent != (void ) NULL)) (void) memcpy(clone_nexus[id]->metacontent, cache_nexus[id]->metacontent,lengthsizeof(unsigned char)); status=WritePixelCacheMetacontent(clone_info,clone_nexus[id],exception); } } cache_nexus=DestroyPixelCacheNexus(cache_nexus,MaxCacheThreads); clone_nexus=DestroyPixelCacheNexus(clone_nexus,MaxCacheThreads); if (cache_info->debug != MagickFalse) { char message[MagickPathExtent]; (void) FormatLocaleString(message,MagickPathExtent,"%s => %s", CommandOptionToMnemonic(MagickCacheOptions,(ssize_t) cache_info->type), CommandOptionToMnemonic(MagickCacheOptions,(ssize_t) clone_info->type)); (void) LogMagickEvent(CacheEvent,GetMagickModule(),"%s",message); } return(status); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + D e s t r o y I m a g e P i x e l C a c h e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % DestroyImagePixelCache() deallocates memory associated with the pixel cache. % % The format of the DestroyImagePixelCache() method is: % % void DestroyImagePixelCache(Image image) % % A description of each parameter follows: % % o image: the image. % / static void DestroyImagePixelCache(Image image) { assert(image != (Image ) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); if (image->cache == (void ) NULL) return; image->cache=DestroyPixelCache(image->cache); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + D e s t r o y I m a g e P i x e l s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % DestroyImagePixels() deallocates memory associated with the pixel cache. % % The format of the DestroyImagePixels() method is: % % void DestroyImagePixels(Image image) % % A description of each parameter follows: % % o image: the image. % / MagickExport void DestroyImagePixels(Image image) { CacheInfo magick_restrict cache_info; assert(image != (const Image ) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(image->cache != (Cache) NULL); cache_info=(CacheInfo ) image->cache; assert(cache_info->signature == MagickCoreSignature); if (cache_info->methods.destroy_pixel_handler != (DestroyPixelHandler) NULL) { cache_info->methods.destroy_pixel_handler(image); return; } image->cache=DestroyPixelCache(image->cache); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + D e s t r o y P i x e l C a c h e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % DestroyPixelCache() deallocates memory associated with the pixel cache. % % The format of the DestroyPixelCache() method is: % % Cache DestroyPixelCache(Cache cache) % % A description of each parameter follows: % % o cache: the pixel cache. % / static MagickBooleanType ClosePixelCacheOnDisk(CacheInfo cache_info) { int status; status=(-1); if (cache_info->file != -1) { status=close(cache_info->file); cache_info->file=(-1); RelinquishMagickResource(FileResource,1); } return(status == -1 ? MagickFalse : MagickTrue); } static inline void RelinquishPixelCachePixels(CacheInfo cache_info) { switch (cache_info->type) { case MemoryCache: { #if defined(MAGICKCORE_OPENCL_SUPPORT) if (cache_info->opencl != (MagickCLCacheInfo) NULL) { cache_info->opencl=RelinquishMagickCLCacheInfo(cache_info->opencl, MagickTrue); cache_info->pixels=(Quantum ) NULL; break; } #endif if (cache_info->mapped == MagickFalse) cache_info->pixels=(Quantum ) RelinquishAlignedMemory( cache_info->pixels); else (void) UnmapBlob(cache_info->pixels,(size_t) cache_info->length); RelinquishMagickResource(MemoryResource,cache_info->length); break; } case MapCache: { (void) UnmapBlob(cache_info->pixels,(size_t) cache_info->length); cache_info->pixels=(Quantum ) NULL; if ((cache_info->mode != ReadMode) && (cache_info->mode != PersistMode)) (void) RelinquishUniqueFileResource(cache_info->cache_filename); cache_info->cache_filename='\0'; RelinquishMagickResource(MapResource,cache_info->length); } case DiskCache: { if (cache_info->file != -1) (void) ClosePixelCacheOnDisk(cache_info); if ((cache_info->mode != ReadMode) && (cache_info->mode != PersistMode)) (void) RelinquishUniqueFileResource(cache_info->cache_filename); cache_info->cache_filename='\0'; RelinquishMagickResource(DiskResource,cache_info->length); break; } case DistributedCache: { cache_info->cache_filename='\0'; (void) RelinquishDistributePixelCache((DistributeCacheInfo ) cache_info->server_info); break; } default: break; } cache_info->type=UndefinedCache; cache_info->mapped=MagickFalse; cache_info->metacontent=(void ) NULL; } MagickPrivate Cache DestroyPixelCache(Cache cache) { CacheInfo magick_restrict cache_info; assert(cache != (Cache) NULL); cache_info=(CacheInfo ) cache; assert(cache_info->signature == MagickCoreSignature); if (cache_info->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s", cache_info->filename); LockSemaphoreInfo(cache_info->semaphore); cache_info->reference_count--; if (cache_info->reference_count != 0) { UnlockSemaphoreInfo(cache_info->semaphore); return((Cache) NULL); } UnlockSemaphoreInfo(cache_info->semaphore); if (cache_info->debug != MagickFalse) { char message[MagickPathExtent]; (void) FormatLocaleString(message,MagickPathExtent,"destroy %s", cache_info->filename); (void) LogMagickEvent(CacheEvent,GetMagickModule(),"%s",message); } RelinquishPixelCachePixels(cache_info); if (cache_info->server_info != (DistributeCacheInfo ) NULL) cache_info->server_info=DestroyDistributeCacheInfo((DistributeCacheInfo ) cache_info->server_info); if (cache_info->nexus_info != (NexusInfo ) NULL) cache_info->nexus_info=DestroyPixelCacheNexus(cache_info->nexus_info, cache_info->number_threads); if (cache_info->random_info != (RandomInfo ) NULL) cache_info->random_info=DestroyRandomInfo(cache_info->random_info); if (cache_info->file_semaphore != (SemaphoreInfo ) NULL) RelinquishSemaphoreInfo(&cache_info->file_semaphore); if (cache_info->semaphore != (SemaphoreInfo ) NULL) RelinquishSemaphoreInfo(&cache_info->semaphore); cache_info->signature=(~MagickCoreSignature); cache_info=(CacheInfo ) RelinquishMagickMemory(cache_info); cache=(Cache) NULL; return(cache); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + D e s t r o y P i x e l C a c h e N e x u s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % DestroyPixelCacheNexus() destroys a pixel cache nexus. % % The format of the DestroyPixelCacheNexus() method is: % % NexusInfo *DestroyPixelCacheNexus(NexusInfo nexus_info, % const size_t number_threads) % % A description of each parameter follows: % % o nexus_info: the nexus to destroy. % % o number_threads: the number of nexus threads. % / static inline void RelinquishCacheNexusPixels(NexusInfo nexus_info) { if (nexus_info->mapped == MagickFalse) (void) RelinquishAlignedMemory(nexus_info->cache); else (void) UnmapBlob(nexus_info->cache,(size_t) nexus_info->length); nexus_info->cache=(Quantum ) NULL; nexus_info->pixels=(Quantum ) NULL; nexus_info->metacontent=(void ) NULL; nexus_info->length=0; nexus_info->mapped=MagickFalse; } MagickPrivate NexusInfo DestroyPixelCacheNexus(NexusInfo nexus_info, const size_t number_threads) { register ssize_t i; assert(nexus_info != (NexusInfo ) NULL); for (i=0; i < (ssize_t) number_threads; i++) { if (nexus_info[i]->cache != (Quantum ) NULL) RelinquishCacheNexusPixels(nexus_info[i]); nexus_info[i]->signature=(~MagickCoreSignature); } nexus_info[0]=(NexusInfo ) RelinquishMagickMemory(nexus_info[0]); nexus_info=(NexusInfo ) RelinquishAlignedMemory(nexus_info); return(nexus_info); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % G e t A u t h e n t i c M e t a c o n t e n t % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetAuthenticMetacontent() returns the authentic metacontent corresponding % with the last call to QueueAuthenticPixels() or GetVirtualPixels(). NULL is % returned if the associated pixels are not available. % % The format of the GetAuthenticMetacontent() method is: % % void GetAuthenticMetacontent(const Image image) % % A description of each parameter follows: % % o image: the image. % / MagickExport void GetAuthenticMetacontent(const Image image) { CacheInfo magick_restrict cache_info; const int id = GetOpenMPThreadId(); assert(image != (const Image ) NULL); assert(image->signature == MagickCoreSignature); assert(image->cache != (Cache) NULL); cache_info=(CacheInfo ) image->cache; assert(cache_info->signature == MagickCoreSignature); if (cache_info->methods.get_authentic_metacontent_from_handler != (GetAuthenticMetacontentFromHandler) NULL) { void metacontent; metacontent=cache_info->methods. get_authentic_metacontent_from_handler(image); return(metacontent); } assert(id < (int) cache_info->number_threads); return(cache_info->nexus_info[id]->metacontent); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + G e t A u t h e n t i c M e t a c o n t e n t F r o m C a c h e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetAuthenticMetacontentFromCache() returns the meta-content corresponding % with the last call to QueueAuthenticPixelsCache() or % GetAuthenticPixelsCache(). % % The format of the GetAuthenticMetacontentFromCache() method is: % % void GetAuthenticMetacontentFromCache(const Image image) % % A description of each parameter follows: % % o image: the image. % / static void GetAuthenticMetacontentFromCache(const Image image) { CacheInfo magick_restrict cache_info; const int id = GetOpenMPThreadId(); assert(image != (const Image ) NULL); assert(image->signature == MagickCoreSignature); assert(image->cache != (Cache) NULL); cache_info=(CacheInfo ) image->cache; assert(cache_info->signature == MagickCoreSignature); assert(id < (int) cache_info->number_threads); return(cache_info->nexus_info[id]->metacontent); } #if defined(MAGICKCORE_OPENCL_SUPPORT) /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + G e t A u t h e n t i c O p e n C L B u f f e r % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetAuthenticOpenCLBuffer() returns an OpenCL buffer used to execute OpenCL % operations. % % The format of the GetAuthenticOpenCLBuffer() method is: % % cl_mem GetAuthenticOpenCLBuffer(const Image image, % MagickCLDevice device,ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o device: the device to use. % % o exception: return any errors or warnings in this structure. % / MagickPrivate cl_mem GetAuthenticOpenCLBuffer(const Image image, MagickCLDevice device,ExceptionInfo exception) { CacheInfo magick_restrict cache_info; assert(image != (const Image ) NULL); assert(device != (const MagickCLDevice) NULL); cache_info=(CacheInfo ) image->cache; if ((cache_info->type == UndefinedCache) \|\| (cache_info->reference_count > 1)) { SyncImagePixelCache((Image ) image,exception); cache_info=(CacheInfo ) image->cache; } if ((cache_info->type != MemoryCache) \|\| (cache_info->mapped != MagickFalse)) return((cl_mem) NULL); LockSemaphoreInfo(cache_info->semaphore); if ((cache_info->opencl != (MagickCLCacheInfo) NULL) && (cache_info->opencl->device->context != device->context)) cache_info->opencl=CopyMagickCLCacheInfo(cache_info->opencl); if (cache_info->opencl == (MagickCLCacheInfo) NULL) { assert(cache_info->pixels != (Quantum ) NULL); cache_info->opencl=AcquireMagickCLCacheInfo(device,cache_info->pixels, cache_info->length); } if (cache_info->opencl != (MagickCLCacheInfo) NULL) RetainOpenCLMemObject(cache_info->opencl->buffer); UnlockSemaphoreInfo(cache_info->semaphore); if (cache_info->opencl == (MagickCLCacheInfo) NULL) return((cl_mem) NULL); assert(cache_info->opencl->pixels == cache_info->pixels); return(cache_info->opencl->buffer); } #endif / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + G e t A u t h e n t i c P i x e l C a c h e N e x u s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetAuthenticPixelCacheNexus() gets authentic pixels from the in-memory or % disk pixel cache as defined by the geometry parameters. A pointer to the % pixels is returned if the pixels are transferred, otherwise a NULL is % returned. % % The format of the GetAuthenticPixelCacheNexus() method is: % % Quantum GetAuthenticPixelCacheNexus(Image image,const ssize_t x, % const ssize_t y,const size_t columns,const size_t rows, % NexusInfo nexus_info,ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o x,y,columns,rows: These values define the perimeter of a region of % pixels. % % o nexus_info: the cache nexus to return. % % o exception: return any errors or warnings in this structure. % / MagickPrivate Quantum GetAuthenticPixelCacheNexus(Image image,const ssize_t x, const ssize_t y,const size_t columns,const size_t rows,NexusInfo nexus_info, ExceptionInfo exception) { CacheInfo magick_restrict cache_info; Quantum magick_restrict pixels; / Transfer pixels from the cache. / assert(image != (Image ) NULL); assert(image->signature == MagickCoreSignature); pixels=QueueAuthenticPixelCacheNexus(image,x,y,columns,rows,MagickTrue, nexus_info,exception); if (pixels == (Quantum ) NULL) return((Quantum ) NULL); cache_info=(CacheInfo ) image->cache; assert(cache_info->signature == MagickCoreSignature); if (nexus_info->authentic_pixel_cache != MagickFalse) return(pixels); if (ReadPixelCachePixels(cache_info,nexus_info,exception) == MagickFalse) return((Quantum ) NULL); if (cache_info->metacontent_extent != 0) if (ReadPixelCacheMetacontent(cache_info,nexus_info,exception) == MagickFalse) return((Quantum ) NULL); return(pixels); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + G e t A u t h e n t i c P i x e l s F r o m C a c h e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetAuthenticPixelsFromCache() returns the pixels associated with the last % call to the QueueAuthenticPixelsCache() or GetAuthenticPixelsCache() methods. % % The format of the GetAuthenticPixelsFromCache() method is: % % Quantum GetAuthenticPixelsFromCache(const Image image) % % A description of each parameter follows: % % o image: the image. % / static Quantum GetAuthenticPixelsFromCache(const Image image) { CacheInfo magick_restrict cache_info; const int id = GetOpenMPThreadId(); assert(image != (const Image ) NULL); assert(image->signature == MagickCoreSignature); assert(image->cache != (Cache) NULL); cache_info=(CacheInfo ) image->cache; assert(cache_info->signature == MagickCoreSignature); assert(id < (int) cache_info->number_threads); return(cache_info->nexus_info[id]->pixels); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % G e t A u t h e n t i c P i x e l Q u e u e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetAuthenticPixelQueue() returns the authentic pixels associated % corresponding with the last call to QueueAuthenticPixels() or % GetAuthenticPixels(). % % The format of the GetAuthenticPixelQueue() method is: % % Quantum GetAuthenticPixelQueue(const Image image) % % A description of each parameter follows: % % o image: the image. % / MagickExport Quantum GetAuthenticPixelQueue(const Image image) { CacheInfo magick_restrict cache_info; const int id = GetOpenMPThreadId(); assert(image != (const Image ) NULL); assert(image->signature == MagickCoreSignature); assert(image->cache != (Cache) NULL); cache_info=(CacheInfo ) image->cache; assert(cache_info->signature == MagickCoreSignature); if (cache_info->methods.get_authentic_pixels_from_handler != (GetAuthenticPixelsFromHandler) NULL) return(cache_info->methods.get_authentic_pixels_from_handler(image)); assert(id < (int) cache_info->number_threads); return(cache_info->nexus_info[id]->pixels); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % G e t A u t h e n t i c P i x e l s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetAuthenticPixels() obtains a pixel region for read/write access. If the % region is successfully accessed, a pointer to a Quantum array % representing the region is returned, otherwise NULL is returned. % % The returned pointer may point to a temporary working copy of the pixels % or it may point to the original pixels in memory. Performance is maximized % if the selected region is part of one row, or one or more full rows, since % then there is opportunity to access the pixels in-place (without a copy) % if the image is in memory, or in a memory-mapped file. The returned pointer % must never be deallocated by the user. % % Pixels accessed via the returned pointer represent a simple array of type % Quantum. If the image has corresponding metacontent,call % GetAuthenticMetacontent() after invoking GetAuthenticPixels() to obtain the % meta-content corresponding to the region. Once the Quantum array has % been updated, the changes must be saved back to the underlying image using % SyncAuthenticPixels() or they may be lost. % % The format of the GetAuthenticPixels() method is: % % Quantum GetAuthenticPixels(Image image,const ssize_t x, % const ssize_t y,const size_t columns,const size_t rows, % ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o x,y,columns,rows: These values define the perimeter of a region of % pixels. % % o exception: return any errors or warnings in this structure. % / MagickExport Quantum GetAuthenticPixels(Image image,const ssize_t x, const ssize_t y,const size_t columns,const size_t rows, ExceptionInfo exception) { CacheInfo magick_restrict cache_info; const int id = GetOpenMPThreadId(); Quantum pixels; assert(image != (Image ) NULL); assert(image->signature == MagickCoreSignature); assert(image->cache != (Cache) NULL); cache_info=(CacheInfo ) image->cache; assert(cache_info->signature == MagickCoreSignature); if (cache_info->methods.get_authentic_pixels_handler != (GetAuthenticPixelsHandler) NULL) { pixels=cache_info->methods.get_authentic_pixels_handler(image,x,y,columns, rows,exception); return(pixels); } assert(id < (int) cache_info->number_threads); pixels=GetAuthenticPixelCacheNexus(image,x,y,columns,rows, cache_info->nexus_info[id],exception); return(pixels); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + G e t A u t h e n t i c P i x e l s C a c h e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetAuthenticPixelsCache() gets pixels from the in-memory or disk pixel cache % as defined by the geometry parameters. A pointer to the pixels is returned % if the pixels are transferred, otherwise a NULL is returned. % % The format of the GetAuthenticPixelsCache() method is: % % Quantum GetAuthenticPixelsCache(Image image,const ssize_t x, % const ssize_t y,const size_t columns,const size_t rows, % ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o x,y,columns,rows: These values define the perimeter of a region of % pixels. % % o exception: return any errors or warnings in this structure. % / static Quantum GetAuthenticPixelsCache(Image image,const ssize_t x, const ssize_t y,const size_t columns,const size_t rows, ExceptionInfo exception) { CacheInfo magick_restrict cache_info; const int id = GetOpenMPThreadId(); Quantum magick_restrict pixels; assert(image != (const Image ) NULL); assert(image->signature == MagickCoreSignature); assert(image->cache != (Cache) NULL); cache_info=(CacheInfo ) image->cache; if (cache_info == (Cache) NULL) return((Quantum ) NULL); assert(cache_info->signature == MagickCoreSignature); assert(id < (int) cache_info->number_threads); pixels=GetAuthenticPixelCacheNexus(image,x,y,columns,rows, cache_info->nexus_info[id],exception); return(pixels); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + G e t I m a g e E x t e n t % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetImageExtent() returns the extent of the pixels associated corresponding % with the last call to QueueAuthenticPixels() or GetAuthenticPixels(). % % The format of the GetImageExtent() method is: % % MagickSizeType GetImageExtent(const Image image) % % A description of each parameter follows: % % o image: the image. % / MagickExport MagickSizeType GetImageExtent(const Image image) { CacheInfo magick_restrict cache_info; const int id = GetOpenMPThreadId(); assert(image != (Image ) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(image->cache != (Cache) NULL); cache_info=(CacheInfo ) image->cache; assert(cache_info->signature == MagickCoreSignature); assert(id < (int) cache_info->number_threads); return(GetPixelCacheNexusExtent(cache_info,cache_info->nexus_info[id])); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + G e t I m a g e P i x e l C a c h e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetImagePixelCache() ensures that there is only a single reference to the % pixel cache to be modified, updating the provided cache pointer to point to % a clone of the original pixel cache if necessary. % % The format of the GetImagePixelCache method is: % % Cache GetImagePixelCache(Image image,const MagickBooleanType clone, % ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o clone: any value other than MagickFalse clones the cache pixels. % % o exception: return any errors or warnings in this structure. % / static inline MagickBooleanType ValidatePixelCacheMorphology( const Image magick_restrict image) { const CacheInfo magick_restrict cache_info; const PixelChannelMap magick_restrict p, magick_restrict q; / Does the image match the pixel cache morphology? / cache_info=(CacheInfo ) image->cache; p=image->channel_map; q=cache_info->channel_map; if ((image->storage_class != cache_info->storage_class) \|\| (image->colorspace != cache_info->colorspace) \|\| (image->alpha_trait != cache_info->alpha_trait) \|\| (image->channels != cache_info->channels) \|\| (image->columns != cache_info->columns) \|\| (image->rows != cache_info->rows) \|\| (image->number_channels != cache_info->number_channels) \|\| (memcmp(p,q,image->number_channelssizeof(p)) != 0) \|\| (image->metacontent_extent != cache_info->metacontent_extent) \|\| (cache_info->nexus_info == (NexusInfo *) NULL)) return(MagickFalse); return(MagickTrue); } static Cache GetImagePixelCache(Image image,const MagickBooleanType clone, ExceptionInfo exception) { CacheInfo magick_restrict cache_info; MagickBooleanType destroy, status; static MagickSizeType cache_timelimit = MagickResourceInfinity, cpu_throttle = MagickResourceInfinity, cycles = 0; status=MagickTrue; if (cpu_throttle == MagickResourceInfinity) cpu_throttle=GetMagickResourceLimit(ThrottleResource); if ((cpu_throttle != 0) && ((cycles++ % 32) == 0)) MagickDelay(cpu_throttle); if (cache_epoch == 0) { /* Set the expire time in seconds. / cache_timelimit=GetMagickResourceLimit(TimeResource); cache_epoch=time((time_t ) NULL); } if ((cache_timelimit != MagickResourceInfinity) && ((MagickSizeType) (time((time_t ) NULL)-cache_epoch) >= cache_timelimit)) { #if defined(ECANCELED) errno=ECANCELED; #endif cache_info=(CacheInfo ) image->cache; if (cache_info->file != -1) (void) ClosePixelCacheOnDisk(cache_info); ThrowFatalException(ResourceLimitFatalError,"TimeLimitExceeded"); } LockSemaphoreInfo(image->semaphore); assert(image->cache != (Cache) NULL); cache_info=(CacheInfo ) image->cache; #if defined(MAGICKCORE_OPENCL_SUPPORT) CopyOpenCLBuffer(cache_info); #endif destroy=MagickFalse; if ((cache_info->reference_count > 1) \|\| (cache_info->mode == ReadMode)) { LockSemaphoreInfo(cache_info->semaphore); if ((cache_info->reference_count > 1) \|\| (cache_info->mode == ReadMode)) { CacheInfo clone_info; Image clone_image; /* Clone pixel cache. / clone_image=(image); clone_image.semaphore=AcquireSemaphoreInfo(); clone_image.reference_count=1; clone_image.cache=ClonePixelCache(cache_info); clone_info=(CacheInfo ) clone_image.cache; status=OpenPixelCache(&clone_image,IOMode,exception); if (status == MagickFalse) clone_info=(CacheInfo ) DestroyPixelCache(clone_info); else { if (clone != MagickFalse) status=ClonePixelCacheRepository(clone_info,cache_info, exception); if (status == MagickFalse) clone_info=(CacheInfo ) DestroyPixelCache(clone_info); else { destroy=MagickTrue; image->cache=clone_info; } } RelinquishSemaphoreInfo(&clone_image.semaphore); } UnlockSemaphoreInfo(cache_info->semaphore); } if (destroy != MagickFalse) cache_info=(CacheInfo ) DestroyPixelCache(cache_info); if (status != MagickFalse) { /* Ensure the image matches the pixel cache morphology. / image->type=UndefinedType; if (ValidatePixelCacheMorphology(image) == MagickFalse) { status=OpenPixelCache(image,IOMode,exception); cache_info=(CacheInfo ) image->cache; if (cache_info->file != -1) (void) ClosePixelCacheOnDisk(cache_info); } } UnlockSemaphoreInfo(image->semaphore); if (status == MagickFalse) return((Cache) NULL); return(image->cache); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + G e t I m a g e P i x e l C a c h e T y p e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetImagePixelCacheType() returns the pixel cache type: UndefinedCache, % DiskCache, MemoryCache, MapCache, or PingCache. % % The format of the GetImagePixelCacheType() method is: % % CacheType GetImagePixelCacheType(const Image image) % % A description of each parameter follows: % % o image: the image. % / MagickExport CacheType GetImagePixelCacheType(const Image image) { CacheInfo magick_restrict cache_info; assert(image != (Image ) NULL); assert(image->signature == MagickCoreSignature); assert(image->cache != (Cache) NULL); cache_info=(CacheInfo ) image->cache; assert(cache_info->signature == MagickCoreSignature); return(cache_info->type); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % G e t O n e A u t h e n t i c P i x e l % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetOneAuthenticPixel() returns a single pixel at the specified (x,y) % location. The image background color is returned if an error occurs. % % The format of the GetOneAuthenticPixel() method is: % % MagickBooleanType GetOneAuthenticPixel(const Image image,const ssize_t x, % const ssize_t y,Quantum pixel,ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o x,y: These values define the location of the pixel to return. % % o pixel: return a pixel at the specified (x,y) location. % % o exception: return any errors or warnings in this structure. % / static inline MagickBooleanType CopyPixel(const Image image, const Quantum source,Quantum destination) { register ssize_t i; if (source == (const Quantum ) NULL) { destination[RedPixelChannel]=ClampToQuantum(image->background_color.red); destination[GreenPixelChannel]=ClampToQuantum( image->background_color.green); destination[BluePixelChannel]=ClampToQuantum( image->background_color.blue); destination[BlackPixelChannel]=ClampToQuantum( image->background_color.black); destination[AlphaPixelChannel]=ClampToQuantum( image->background_color.alpha); return(MagickFalse); } for (i=0; i < (ssize_t) GetPixelChannels(image); i++) { PixelChannel channel = GetPixelChannelChannel(image,i); destination[channel]=source[i]; } return(MagickTrue); } MagickExport MagickBooleanType GetOneAuthenticPixel(Image image, const ssize_t x,const ssize_t y,Quantum pixel,ExceptionInfo exception) { CacheInfo magick_restrict cache_info; register Quantum magick_restrict q; assert(image != (Image ) NULL); assert(image->signature == MagickCoreSignature); assert(image->cache != (Cache) NULL); cache_info=(CacheInfo ) image->cache; assert(cache_info->signature == MagickCoreSignature); (void) memset(pixel,0,MaxPixelChannelssizeof(pixel)); if (cache_info->methods.get_one_authentic_pixel_from_handler != (GetOneAuthenticPixelFromHandler) NULL) return(cache_info->methods.get_one_authentic_pixel_from_handler(image,x,y,pixel,exception)); q=GetAuthenticPixelsCache(image,x,y,1UL,1UL,exception); return(CopyPixel(image,q,pixel)); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + G e t O n e A u t h e n t i c P i x e l F r o m C a c h e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetOneAuthenticPixelFromCache() returns a single pixel at the specified (x,y) % location. The image background color is returned if an error occurs. % % The format of the GetOneAuthenticPixelFromCache() method is: % % MagickBooleanType GetOneAuthenticPixelFromCache(const Image image, % const ssize_t x,const ssize_t y,Quantum pixel, % ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o x,y: These values define the location of the pixel to return. % % o pixel: return a pixel at the specified (x,y) location. % % o exception: return any errors or warnings in this structure. % / static MagickBooleanType GetOneAuthenticPixelFromCache(Image image, const ssize_t x,const ssize_t y,Quantum pixel,ExceptionInfo exception) { CacheInfo magick_restrict cache_info; const int id = GetOpenMPThreadId(); register Quantum magick_restrict q; assert(image != (const Image ) NULL); assert(image->signature == MagickCoreSignature); assert(image->cache != (Cache) NULL); cache_info=(CacheInfo ) image->cache; assert(cache_info->signature == MagickCoreSignature); assert(id < (int) cache_info->number_threads); (void) memset(pixel,0,MaxPixelChannelssizeof(pixel)); q=GetAuthenticPixelCacheNexus(image,x,y,1UL,1UL,cache_info->nexus_info[id], exception); return(CopyPixel(image,q,pixel)); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % G e t O n e V i r t u a l P i x e l % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetOneVirtualPixel() returns a single virtual pixel at the specified % (x,y) location. The image background color is returned if an error occurs. % If you plan to modify the pixel, use GetOneAuthenticPixel() instead. % % The format of the GetOneVirtualPixel() method is: % % MagickBooleanType GetOneVirtualPixel(const Image image,const ssize_t x, % const ssize_t y,Quantum pixel,ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o x,y: These values define the location of the pixel to return. % % o pixel: return a pixel at the specified (x,y) location. % % o exception: return any errors or warnings in this structure. % / MagickExport MagickBooleanType GetOneVirtualPixel(const Image image, const ssize_t x,const ssize_t y,Quantum pixel,ExceptionInfo exception) { CacheInfo magick_restrict cache_info; const int id = GetOpenMPThreadId(); const Quantum p; assert(image != (const Image ) NULL); assert(image->signature == MagickCoreSignature); assert(image->cache != (Cache) NULL); cache_info=(CacheInfo ) image->cache; assert(cache_info->signature == MagickCoreSignature); (void) memset(pixel,0,MaxPixelChannelssizeof(pixel)); if (cache_info->methods.get_one_virtual_pixel_from_handler != (GetOneVirtualPixelFromHandler) NULL) return(cache_info->methods.get_one_virtual_pixel_from_handler(image, GetPixelCacheVirtualMethod(image),x,y,pixel,exception)); assert(id < (int) cache_info->number_threads); p=GetVirtualPixelCacheNexus(image,GetPixelCacheVirtualMethod(image),x,y, 1UL,1UL,cache_info->nexus_info[id],exception); return(CopyPixel(image,p,pixel)); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + G e t O n e V i r t u a l P i x e l F r o m C a c h e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetOneVirtualPixelFromCache() returns a single virtual pixel at the % specified (x,y) location. The image background color is returned if an % error occurs. % % The format of the GetOneVirtualPixelFromCache() method is: % % MagickBooleanType GetOneVirtualPixelFromCache(const Image image, % const VirtualPixelMethod method,const ssize_t x,const ssize_t y, % Quantum pixel,ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o virtual_pixel_method: the virtual pixel method. % % o x,y: These values define the location of the pixel to return. % % o pixel: return a pixel at the specified (x,y) location. % % o exception: return any errors or warnings in this structure. % / static MagickBooleanType GetOneVirtualPixelFromCache(const Image image, const VirtualPixelMethod virtual_pixel_method,const ssize_t x,const ssize_t y, Quantum pixel,ExceptionInfo exception) { CacheInfo magick_restrict cache_info; const int id = GetOpenMPThreadId(); const Quantum p; assert(image != (const Image ) NULL); assert(image->signature == MagickCoreSignature); assert(image->cache != (Cache) NULL); cache_info=(CacheInfo ) image->cache; assert(cache_info->signature == MagickCoreSignature); assert(id < (int) cache_info->number_threads); (void) memset(pixel,0,MaxPixelChannelssizeof(pixel)); p=GetVirtualPixelCacheNexus(image,virtual_pixel_method,x,y,1UL,1UL, cache_info->nexus_info[id],exception); return(CopyPixel(image,p,pixel)); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % G e t O n e V i r t u a l P i x e l I n f o % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetOneVirtualPixelInfo() returns a single pixel at the specified (x,y) % location. The image background color is returned if an error occurs. If % you plan to modify the pixel, use GetOneAuthenticPixel() instead. % % The format of the GetOneVirtualPixelInfo() method is: % % MagickBooleanType GetOneVirtualPixelInfo(const Image image, % const VirtualPixelMethod virtual_pixel_method,const ssize_t x, % const ssize_t y,PixelInfo pixel,ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o virtual_pixel_method: the virtual pixel method. % % o x,y: these values define the location of the pixel to return. % % o pixel: return a pixel at the specified (x,y) location. % % o exception: return any errors or warnings in this structure. % / MagickExport MagickBooleanType GetOneVirtualPixelInfo(const Image image, const VirtualPixelMethod virtual_pixel_method,const ssize_t x,const ssize_t y, PixelInfo pixel,ExceptionInfo exception) { CacheInfo magick_restrict cache_info; const int id = GetOpenMPThreadId(); register const Quantum magick_restrict p; assert(image != (const Image ) NULL); assert(image->signature == MagickCoreSignature); assert(image->cache != (Cache) NULL); cache_info=(CacheInfo ) image->cache; assert(cache_info->signature == MagickCoreSignature); assert(id < (int) cache_info->number_threads); GetPixelInfo(image,pixel); p=GetVirtualPixelCacheNexus(image,virtual_pixel_method,x,y,1UL,1UL, cache_info->nexus_info[id],exception); if (p == (const Quantum ) NULL) return(MagickFalse); GetPixelInfoPixel(image,p,pixel); return(MagickTrue); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + G e t P i x e l C a c h e C o l o r s p a c e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetPixelCacheColorspace() returns the class type of the pixel cache. % % The format of the GetPixelCacheColorspace() method is: % % Colorspace GetPixelCacheColorspace(Cache cache) % % A description of each parameter follows: % % o cache: the pixel cache. % / MagickPrivate ColorspaceType GetPixelCacheColorspace(const Cache cache) { CacheInfo magick_restrict cache_info; assert(cache != (Cache) NULL); cache_info=(CacheInfo ) cache; assert(cache_info->signature == MagickCoreSignature); if (cache_info->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s", cache_info->filename); return(cache_info->colorspace); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + G e t P i x e l C a c h e F i l e n a m e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetPixelCacheFilename() returns the filename associated with the pixel % cache. % % The format of the GetPixelCacheFilename() method is: % % const char GetPixelCacheFilename(const Image image) % % A description of each parameter follows: % % o image: the image. % / MagickExport const char GetPixelCacheFilename(const Image image) { CacheInfo magick_restrict cache_info; assert(image != (const Image ) NULL); assert(image->signature == MagickCoreSignature); assert(image->cache != (Cache) NULL); cache_info=(CacheInfo ) image->cache; assert(cache_info->signature == MagickCoreSignature); return(cache_info->cache_filename); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + G e t P i x e l C a c h e M e t h o d s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetPixelCacheMethods() initializes the CacheMethods structure. % % The format of the GetPixelCacheMethods() method is: % % void GetPixelCacheMethods(CacheMethods cache_methods) % % A description of each parameter follows: % % o cache_methods: Specifies a pointer to a CacheMethods structure. % / MagickPrivate void GetPixelCacheMethods(CacheMethods cache_methods) { assert(cache_methods != (CacheMethods ) NULL); (void) memset(cache_methods,0,sizeof(cache_methods)); cache_methods->get_virtual_pixel_handler=GetVirtualPixelCache; cache_methods->get_virtual_pixels_handler=GetVirtualPixelsCache; cache_methods->get_virtual_metacontent_from_handler= GetVirtualMetacontentFromCache; cache_methods->get_one_virtual_pixel_from_handler=GetOneVirtualPixelFromCache; cache_methods->get_authentic_pixels_handler=GetAuthenticPixelsCache; cache_methods->get_authentic_metacontent_from_handler= GetAuthenticMetacontentFromCache; cache_methods->get_authentic_pixels_from_handler=GetAuthenticPixelsFromCache; cache_methods->get_one_authentic_pixel_from_handler= GetOneAuthenticPixelFromCache; cache_methods->queue_authentic_pixels_handler=QueueAuthenticPixelsCache; cache_methods->sync_authentic_pixels_handler=SyncAuthenticPixelsCache; cache_methods->destroy_pixel_handler=DestroyImagePixelCache; } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + G e t P i x e l C a c h e N e x u s E x t e n t % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetPixelCacheNexusExtent() returns the extent of the pixels associated % corresponding with the last call to SetPixelCacheNexusPixels() or % GetPixelCacheNexusPixels(). % % The format of the GetPixelCacheNexusExtent() method is: % % MagickSizeType GetPixelCacheNexusExtent(const Cache cache, % NexusInfo nexus_info) % % A description of each parameter follows: % % o nexus_info: the nexus info. % / MagickPrivate MagickSizeType GetPixelCacheNexusExtent(const Cache cache, NexusInfo magick_restrict nexus_info) { CacheInfo magick_restrict cache_info; MagickSizeType extent; assert(cache != NULL); cache_info=(CacheInfo ) cache; assert(cache_info->signature == MagickCoreSignature); extent=(MagickSizeType) nexus_info->region.widthnexus_info->region.height; if (extent == 0) return((MagickSizeType) cache_info->columnscache_info->rows); return(extent); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + G e t P i x e l C a c h e P i x e l s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetPixelCachePixels() returns the pixels associated with the specified image. % % The format of the GetPixelCachePixels() method is: % % void GetPixelCachePixels(Image image,MagickSizeType length, % ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o length: the pixel cache length. % % o exception: return any errors or warnings in this structure. % / MagickExport void GetPixelCachePixels(Image image,MagickSizeType length, ExceptionInfo exception) { CacheInfo magick_restrict cache_info; assert(image != (const Image ) NULL); assert(image->signature == MagickCoreSignature); assert(image->cache != (Cache) NULL); assert(length != (MagickSizeType ) NULL); assert(exception != (ExceptionInfo ) NULL); assert(exception->signature == MagickCoreSignature); cache_info=(CacheInfo ) image->cache; assert(cache_info->signature == MagickCoreSignature); length=cache_info->length; if ((cache_info->type != MemoryCache) && (cache_info->type != MapCache)) return((void ) NULL); return((void ) cache_info->pixels); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + G e t P i x e l C a c h e S t o r a g e C l a s s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetPixelCacheStorageClass() returns the class type of the pixel cache. % % The format of the GetPixelCacheStorageClass() method is: % % ClassType GetPixelCacheStorageClass(Cache cache) % % A description of each parameter follows: % % o type: GetPixelCacheStorageClass returns DirectClass or PseudoClass. % % o cache: the pixel cache. % / MagickPrivate ClassType GetPixelCacheStorageClass(const Cache cache) { CacheInfo magick_restrict cache_info; assert(cache != (Cache) NULL); cache_info=(CacheInfo ) cache; assert(cache_info->signature == MagickCoreSignature); if (cache_info->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s", cache_info->filename); return(cache_info->storage_class); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + G e t P i x e l C a c h e T i l e S i z e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetPixelCacheTileSize() returns the pixel cache tile size. % % The format of the GetPixelCacheTileSize() method is: % % void GetPixelCacheTileSize(const Image image,size_t width, % size_t height) % % A description of each parameter follows: % % o image: the image. % % o width: the optimized cache tile width in pixels. % % o height: the optimized cache tile height in pixels. % / MagickPrivate void GetPixelCacheTileSize(const Image image,size_t width, size_t height) { CacheInfo magick_restrict cache_info; assert(image != (Image ) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); cache_info=(CacheInfo ) image->cache; assert(cache_info->signature == MagickCoreSignature); width=2048UL/(cache_info->number_channelssizeof(Quantum)); if (GetImagePixelCacheType(image) == DiskCache) width=8192UL/(cache_info->number_channelssizeof(Quantum)); height=(width); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + G e t P i x e l C a c h e V i r t u a l M e t h o d % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetPixelCacheVirtualMethod() gets the "virtual pixels" method for the % pixel cache. A virtual pixel is any pixel access that is outside the % boundaries of the image cache. % % The format of the GetPixelCacheVirtualMethod() method is: % % VirtualPixelMethod GetPixelCacheVirtualMethod(const Image image) % % A description of each parameter follows: % % o image: the image. % / MagickPrivate VirtualPixelMethod GetPixelCacheVirtualMethod(const Image image) { CacheInfo magick_restrict cache_info; assert(image != (Image ) NULL); assert(image->signature == MagickCoreSignature); assert(image->cache != (Cache) NULL); cache_info=(CacheInfo ) image->cache; assert(cache_info->signature == MagickCoreSignature); return(cache_info->virtual_pixel_method); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + G e t V i r t u a l M e t a c o n t e n t F r o m C a c h e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetVirtualMetacontentFromCache() returns the meta-content corresponding with % the last call to QueueAuthenticPixelsCache() or GetVirtualPixelCache(). % % The format of the GetVirtualMetacontentFromCache() method is: % % void GetVirtualMetacontentFromCache(const Image image) % % A description of each parameter follows: % % o image: the image. % / static const void GetVirtualMetacontentFromCache(const Image image) { CacheInfo magick_restrict cache_info; const int id = GetOpenMPThreadId(); const void magick_restrict metacontent; assert(image != (const Image ) NULL); assert(image->signature == MagickCoreSignature); assert(image->cache != (Cache) NULL); cache_info=(CacheInfo ) image->cache; assert(cache_info->signature == MagickCoreSignature); assert(id < (int) cache_info->number_threads); metacontent=GetVirtualMetacontentFromNexus(cache_info, cache_info->nexus_info[id]); return(metacontent); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + G e t V i r t u a l M e t a c o n t e n t F r o m N e x u s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetVirtualMetacontentFromNexus() returns the meta-content for the specified % cache nexus. % % The format of the GetVirtualMetacontentFromNexus() method is: % % const void GetVirtualMetacontentFromNexus(const Cache cache, % NexusInfo nexus_info) % % A description of each parameter follows: % % o cache: the pixel cache. % % o nexus_info: the cache nexus to return the meta-content. % / MagickPrivate const void GetVirtualMetacontentFromNexus(const Cache cache, NexusInfo magick_restrict nexus_info) { CacheInfo magick_restrict cache_info; assert(cache != (Cache) NULL); cache_info=(CacheInfo ) cache; assert(cache_info->signature == MagickCoreSignature); if (cache_info->storage_class == UndefinedClass) return((void ) NULL); return(nexus_info->metacontent); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % G e t V i r t u a l M e t a c o n t e n t % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetVirtualMetacontent() returns the virtual metacontent corresponding with % the last call to QueueAuthenticPixels() or GetVirtualPixels(). NULL is % returned if the meta-content are not available. % % The format of the GetVirtualMetacontent() method is: % % const void GetVirtualMetacontent(const Image image) % % A description of each parameter follows: % % o image: the image. % / MagickExport const void GetVirtualMetacontent(const Image image) { CacheInfo magick_restrict cache_info; const int id = GetOpenMPThreadId(); const void magick_restrict metacontent; assert(image != (const Image ) NULL); assert(image->signature == MagickCoreSignature); assert(image->cache != (Cache) NULL); cache_info=(CacheInfo ) image->cache; assert(cache_info->signature == MagickCoreSignature); metacontent=cache_info->methods.get_virtual_metacontent_from_handler(image); if (metacontent != (void ) NULL) return(metacontent); assert(id < (int) cache_info->number_threads); metacontent=GetVirtualMetacontentFromNexus(cache_info, cache_info->nexus_info[id]); return(metacontent); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + G e t V i r t u a l P i x e l C a c h e N e x u s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetVirtualPixelCacheNexus() gets virtual pixels from the in-memory or disk % pixel cache as defined by the geometry parameters. A pointer to the pixels % is returned if the pixels are transferred, otherwise a NULL is returned. % % The format of the GetVirtualPixelCacheNexus() method is: % % Quantum GetVirtualPixelCacheNexus(const Image image, % const VirtualPixelMethod method,const ssize_t x,const ssize_t y, % const size_t columns,const size_t rows,NexusInfo nexus_info, % ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o virtual_pixel_method: the virtual pixel method. % % o x,y,columns,rows: These values define the perimeter of a region of % pixels. % % o nexus_info: the cache nexus to acquire. % % o exception: return any errors or warnings in this structure. % / static ssize_t DitherMatrix[64] = { 0, 48, 12, 60, 3, 51, 15, 63, 32, 16, 44, 28, 35, 19, 47, 31, 8, 56, 4, 52, 11, 59, 7, 55, 40, 24, 36, 20, 43, 27, 39, 23, 2, 50, 14, 62, 1, 49, 13, 61, 34, 18, 46, 30, 33, 17, 45, 29, 10, 58, 6, 54, 9, 57, 5, 53, 42, 26, 38, 22, 41, 25, 37, 21 }; static inline ssize_t DitherX(const ssize_t x,const size_t columns) { ssize_t index; index=x+DitherMatrix[x & 0x07]-32L; if (index < 0L) return(0L); if (index >= (ssize_t) columns) return((ssize_t) columns-1L); return(index); } static inline ssize_t DitherY(const ssize_t y,const size_t rows) { ssize_t index; index=y+DitherMatrix[y & 0x07]-32L; if (index < 0L) return(0L); if (index >= (ssize_t) rows) return((ssize_t) rows-1L); return(index); } 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 ssize_t RandomX(RandomInfo random_info,const size_t columns) { return((ssize_t) (columnsGetPseudoRandomValue(random_info))); } static inline ssize_t RandomY(RandomInfo random_info,const size_t rows) { return((ssize_t) (rowsGetPseudoRandomValue(random_info))); } static inline MagickModulo VirtualPixelModulo(const ssize_t offset, const size_t extent) { MagickModulo modulo; / Compute the remainder of dividing offset by extent. It returns not only the quotient (tile the offset falls in) but also the positive remainer within that tile such that 0 <= remainder < extent. This method is essentially a ldiv() using a floored modulo division rather than the normal default truncated modulo division. / modulo.quotient=offset/(ssize_t) extent; if (offset < 0L) modulo.quotient--; modulo.remainder=(ssize_t) (offset-(MagickOffsetType) modulo.quotient (ssize_t) extent); return(modulo); } MagickPrivate const Quantum GetVirtualPixelCacheNexus(const Image image, const VirtualPixelMethod virtual_pixel_method,const ssize_t x,const ssize_t y, const size_t columns,const size_t rows,NexusInfo nexus_info, ExceptionInfo exception) { CacheInfo magick_restrict cache_info; MagickOffsetType offset; MagickSizeType length, number_pixels; NexusInfo magick_restrict virtual_nexus; Quantum magick_restrict pixels, virtual_pixel[MaxPixelChannels]; RectangleInfo region; register const Quantum magick_restrict p; register const void magick_restrict r; register Quantum magick_restrict q; register ssize_t i, u; register unsigned char magick_restrict s; ssize_t v; void magick_restrict virtual_metacontent; / Acquire pixels. / assert(image != (const Image ) NULL); assert(image->signature == MagickCoreSignature); assert(image->cache != (Cache) NULL); cache_info=(CacheInfo ) image->cache; assert(cache_info->signature == MagickCoreSignature); if (cache_info->type == UndefinedCache) return((const Quantum ) NULL); #if defined(MAGICKCORE_OPENCL_SUPPORT) CopyOpenCLBuffer(cache_info); #endif region.x=x; region.y=y; region.width=columns; region.height=rows; pixels=SetPixelCacheNexusPixels(cache_info,ReadMode,&region, ((image->channels & WriteMaskChannel) != 0) \|\| ((image->channels & CompositeMaskChannel) != 0) ? MagickTrue : MagickFalse, nexus_info,exception); if (pixels == (Quantum ) NULL) return((const Quantum ) NULL); q=pixels; offset=(MagickOffsetType) nexus_info->region.ycache_info->columns+ nexus_info->region.x; length=(MagickSizeType) (nexus_info->region.height-1L)cache_info->columns+ nexus_info->region.width-1L; number_pixels=(MagickSizeType) cache_info->columnscache_info->rows; if ((offset >= 0) && (((MagickSizeType) offset+length) < number_pixels)) if ((x >= 0) && ((ssize_t) (x+columns) <= (ssize_t) cache_info->columns) && (y >= 0) && ((ssize_t) (y+rows) <= (ssize_t) cache_info->rows)) { MagickBooleanType status; / Pixel request is inside cache extents. / if (nexus_info->authentic_pixel_cache != MagickFalse) return(q); status=ReadPixelCachePixels(cache_info,nexus_info,exception); if (status == MagickFalse) return((const Quantum ) NULL); if (cache_info->metacontent_extent != 0) { status=ReadPixelCacheMetacontent(cache_info,nexus_info,exception); if (status == MagickFalse) return((const Quantum ) NULL); } return(q); } / Pixel request is outside cache extents. / s=(unsigned char ) nexus_info->metacontent; virtual_nexus=AcquirePixelCacheNexus(1); (void) memset(virtual_pixel,0,cache_info->number_channels* sizeof(virtual_pixel)); virtual_metacontent=(void ) NULL; switch (virtual_pixel_method) { case BackgroundVirtualPixelMethod: case BlackVirtualPixelMethod: case GrayVirtualPixelMethod: case TransparentVirtualPixelMethod: case MaskVirtualPixelMethod: case WhiteVirtualPixelMethod: case EdgeVirtualPixelMethod: case CheckerTileVirtualPixelMethod: case HorizontalTileVirtualPixelMethod: case VerticalTileVirtualPixelMethod: { if (cache_info->metacontent_extent != 0) { /* Acquire a metacontent buffer. / virtual_metacontent=(void ) AcquireQuantumMemory(1, cache_info->metacontent_extent); if (virtual_metacontent == (void ) NULL) { virtual_nexus=DestroyPixelCacheNexus(virtual_nexus,1); (void) ThrowMagickException(exception,GetMagickModule(), CacheError,"UnableToGetCacheNexus","`%s'",image->filename); return((const Quantum ) NULL); } (void) memset(virtual_metacontent,0,cache_info->metacontent_extent); } switch (virtual_pixel_method) { case BlackVirtualPixelMethod: { for (i=0; i < (ssize_t) cache_info->number_channels; i++) SetPixelChannel(image,(PixelChannel) i,(Quantum) 0,virtual_pixel); SetPixelAlpha(image,OpaqueAlpha,virtual_pixel); break; } case GrayVirtualPixelMethod: { for (i=0; i < (ssize_t) cache_info->number_channels; i++) SetPixelChannel(image,(PixelChannel) i,QuantumRange/2, virtual_pixel); SetPixelAlpha(image,OpaqueAlpha,virtual_pixel); break; } case TransparentVirtualPixelMethod: { for (i=0; i < (ssize_t) cache_info->number_channels; i++) SetPixelChannel(image,(PixelChannel) i,(Quantum) 0,virtual_pixel); SetPixelAlpha(image,TransparentAlpha,virtual_pixel); break; } case MaskVirtualPixelMethod: case WhiteVirtualPixelMethod: { for (i=0; i < (ssize_t) cache_info->number_channels; i++) SetPixelChannel(image,(PixelChannel) i,QuantumRange,virtual_pixel); SetPixelAlpha(image,OpaqueAlpha,virtual_pixel); break; } default: { SetPixelRed(image,ClampToQuantum(image->background_color.red), virtual_pixel); SetPixelGreen(image,ClampToQuantum(image->background_color.green), virtual_pixel); SetPixelBlue(image,ClampToQuantum(image->background_color.blue), virtual_pixel); SetPixelBlack(image,ClampToQuantum(image->background_color.black), virtual_pixel); SetPixelAlpha(image,ClampToQuantum(image->background_color.alpha), virtual_pixel); break; } } break; } default: break; } for (v=0; v < (ssize_t) rows; v++) { ssize_t y_offset; y_offset=y+v; if ((virtual_pixel_method == EdgeVirtualPixelMethod) \|\| (virtual_pixel_method == UndefinedVirtualPixelMethod)) y_offset=EdgeY(y_offset,cache_info->rows); for (u=0; u < (ssize_t) columns; u+=length) { ssize_t x_offset; x_offset=x+u; length=(MagickSizeType) MagickMin(cache_info->columns-x_offset,columns-u); if (((x_offset < 0) \|\| (x_offset >= (ssize_t) cache_info->columns)) \|\| ((y_offset < 0) \|\| (y_offset >= (ssize_t) cache_info->rows)) \|\| (length == 0)) { MagickModulo x_modulo, y_modulo; /* Transfer a single pixel. / length=(MagickSizeType) 1; switch (virtual_pixel_method) { case EdgeVirtualPixelMethod: default: { p=GetVirtualPixelCacheNexus(image,virtual_pixel_method, EdgeX(x_offset,cache_info->columns), EdgeY(y_offset,cache_info->rows),1UL,1UL,virtual_nexus, exception); r=GetVirtualMetacontentFromNexus(cache_info,virtual_nexus); break; } case RandomVirtualPixelMethod: { if (cache_info->random_info == (RandomInfo ) NULL) cache_info->random_info=AcquireRandomInfo(); p=GetVirtualPixelCacheNexus(image,virtual_pixel_method, RandomX(cache_info->random_info,cache_info->columns), RandomY(cache_info->random_info,cache_info->rows),1UL,1UL, virtual_nexus,exception); r=GetVirtualMetacontentFromNexus(cache_info,virtual_nexus); break; } case DitherVirtualPixelMethod: { p=GetVirtualPixelCacheNexus(image,virtual_pixel_method, DitherX(x_offset,cache_info->columns), DitherY(y_offset,cache_info->rows),1UL,1UL,virtual_nexus, exception); r=GetVirtualMetacontentFromNexus(cache_info,virtual_nexus); break; } case TileVirtualPixelMethod: { x_modulo=VirtualPixelModulo(x_offset,cache_info->columns); y_modulo=VirtualPixelModulo(y_offset,cache_info->rows); p=GetVirtualPixelCacheNexus(image,virtual_pixel_method, x_modulo.remainder,y_modulo.remainder,1UL,1UL,virtual_nexus, exception); r=GetVirtualMetacontentFromNexus(cache_info,virtual_nexus); break; } case MirrorVirtualPixelMethod: { x_modulo=VirtualPixelModulo(x_offset,cache_info->columns); if ((x_modulo.quotient & 0x01) == 1L) x_modulo.remainder=(ssize_t) cache_info->columns- x_modulo.remainder-1L; y_modulo=VirtualPixelModulo(y_offset,cache_info->rows); if ((y_modulo.quotient & 0x01) == 1L) y_modulo.remainder=(ssize_t) cache_info->rows- y_modulo.remainder-1L; p=GetVirtualPixelCacheNexus(image,virtual_pixel_method, x_modulo.remainder,y_modulo.remainder,1UL,1UL,virtual_nexus, exception); r=GetVirtualMetacontentFromNexus(cache_info,virtual_nexus); break; } case HorizontalTileEdgeVirtualPixelMethod: { x_modulo=VirtualPixelModulo(x_offset,cache_info->columns); p=GetVirtualPixelCacheNexus(image,virtual_pixel_method, x_modulo.remainder,EdgeY(y_offset,cache_info->rows),1UL,1UL, virtual_nexus,exception); r=GetVirtualMetacontentFromNexus(cache_info,virtual_nexus); break; } case VerticalTileEdgeVirtualPixelMethod: { y_modulo=VirtualPixelModulo(y_offset,cache_info->rows); p=GetVirtualPixelCacheNexus(image,virtual_pixel_method, EdgeX(x_offset,cache_info->columns),y_modulo.remainder,1UL,1UL, virtual_nexus,exception); r=GetVirtualMetacontentFromNexus(cache_info,virtual_nexus); break; } case BackgroundVirtualPixelMethod: case BlackVirtualPixelMethod: case GrayVirtualPixelMethod: case TransparentVirtualPixelMethod: case MaskVirtualPixelMethod: case WhiteVirtualPixelMethod: { p=virtual_pixel; r=virtual_metacontent; break; } case CheckerTileVirtualPixelMethod: { x_modulo=VirtualPixelModulo(x_offset,cache_info->columns); y_modulo=VirtualPixelModulo(y_offset,cache_info->rows); if (((x_modulo.quotient ^ y_modulo.quotient) & 0x01) != 0L) { p=virtual_pixel; r=virtual_metacontent; break; } p=GetVirtualPixelCacheNexus(image,virtual_pixel_method, x_modulo.remainder,y_modulo.remainder,1UL,1UL,virtual_nexus, exception); r=GetVirtualMetacontentFromNexus(cache_info,virtual_nexus); break; } case HorizontalTileVirtualPixelMethod: { if ((y_offset < 0) \|\| (y_offset >= (ssize_t) cache_info->rows)) { p=virtual_pixel; r=virtual_metacontent; break; } x_modulo=VirtualPixelModulo(x_offset,cache_info->columns); y_modulo=VirtualPixelModulo(y_offset,cache_info->rows); p=GetVirtualPixelCacheNexus(image,virtual_pixel_method, x_modulo.remainder,y_modulo.remainder,1UL,1UL,virtual_nexus, exception); r=GetVirtualMetacontentFromNexus(cache_info,virtual_nexus); break; } case VerticalTileVirtualPixelMethod: { if ((x_offset < 0) \|\| (x_offset >= (ssize_t) cache_info->columns)) { p=virtual_pixel; r=virtual_metacontent; break; } x_modulo=VirtualPixelModulo(x_offset,cache_info->columns); y_modulo=VirtualPixelModulo(y_offset,cache_info->rows); p=GetVirtualPixelCacheNexus(image,virtual_pixel_method, x_modulo.remainder,y_modulo.remainder,1UL,1UL,virtual_nexus, exception); r=GetVirtualMetacontentFromNexus(cache_info,virtual_nexus); break; } } if (p == (const Quantum ) NULL) break; (void) memcpy(q,p,(size_t) lengthcache_info->number_channels* sizeof(p)); q+=cache_info->number_channels; if ((s != (void ) NULL) && (r != (const void ) NULL)) { (void) memcpy(s,r,(size_t) cache_info->metacontent_extent); s+=cache_info->metacontent_extent; } continue; } / Transfer a run of pixels. / p=GetVirtualPixelCacheNexus(image,virtual_pixel_method,x_offset,y_offset, (size_t) length,1UL,virtual_nexus,exception); if (p == (const Quantum ) NULL) break; r=GetVirtualMetacontentFromNexus(cache_info,virtual_nexus); (void) memcpy(q,p,(size_t) lengthcache_info->number_channelssizeof(p)); q+=lengthcache_info->number_channels; if ((r != (void ) NULL) && (s != (const void ) NULL)) { (void) memcpy(s,r,(size_t) length); s+=lengthcache_info->metacontent_extent; } } if (u < (ssize_t) columns) break; } / Free resources. / if (virtual_metacontent != (void ) NULL) virtual_metacontent=(void ) RelinquishMagickMemory(virtual_metacontent); virtual_nexus=DestroyPixelCacheNexus(virtual_nexus,1); if (v < (ssize_t) rows) return((const Quantum ) NULL); return(pixels); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + G e t V i r t u a l P i x e l C a c h e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetVirtualPixelCache() get virtual pixels from the in-memory or disk pixel % cache as defined by the geometry parameters. A pointer to the pixels % is returned if the pixels are transferred, otherwise a NULL is returned. % % The format of the GetVirtualPixelCache() method is: % % const Quantum GetVirtualPixelCache(const Image image, % const VirtualPixelMethod virtual_pixel_method,const ssize_t x, % const ssize_t y,const size_t columns,const size_t rows, % ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o virtual_pixel_method: the virtual pixel method. % % o x,y,columns,rows: These values define the perimeter of a region of % pixels. % % o exception: return any errors or warnings in this structure. % / static const Quantum GetVirtualPixelCache(const Image image, const VirtualPixelMethod virtual_pixel_method,const ssize_t x,const ssize_t y, const size_t columns,const size_t rows,ExceptionInfo exception) { CacheInfo magick_restrict cache_info; const int id = GetOpenMPThreadId(); const Quantum magick_restrict p; assert(image != (const Image ) NULL); assert(image->signature == MagickCoreSignature); assert(image->cache != (Cache) NULL); cache_info=(CacheInfo ) image->cache; assert(cache_info->signature == MagickCoreSignature); assert(id < (int) cache_info->number_threads); p=GetVirtualPixelCacheNexus(image,virtual_pixel_method,x,y,columns,rows, cache_info->nexus_info[id],exception); return(p); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % G e t V i r t u a l P i x e l Q u e u e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetVirtualPixelQueue() returns the virtual pixels associated corresponding % with the last call to QueueAuthenticPixels() or GetVirtualPixels(). % % The format of the GetVirtualPixelQueue() method is: % % const Quantum GetVirtualPixelQueue(const Image image) % % A description of each parameter follows: % % o image: the image. % / MagickExport const Quantum GetVirtualPixelQueue(const Image image) { CacheInfo magick_restrict cache_info; const int id = GetOpenMPThreadId(); assert(image != (const Image ) NULL); assert(image->signature == MagickCoreSignature); assert(image->cache != (Cache) NULL); cache_info=(CacheInfo ) image->cache; assert(cache_info->signature == MagickCoreSignature); if (cache_info->methods.get_virtual_pixels_handler != (GetVirtualPixelsHandler) NULL) return(cache_info->methods.get_virtual_pixels_handler(image)); assert(id < (int) cache_info->number_threads); return(GetVirtualPixelsNexus(cache_info,cache_info->nexus_info[id])); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % G e t V i r t u a l P i x e l s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetVirtualPixels() returns an immutable pixel region. If the % region is successfully accessed, a pointer to it is returned, otherwise % NULL is returned. The returned pointer may point to a temporary working % copy of the pixels or it may point to the original pixels in memory. % Performance is maximized if the selected region is part of one row, or one % or more full rows, since there is opportunity to access the pixels in-place % (without a copy) if the image is in memory, or in a memory-mapped file. The % returned pointer must never be deallocated by the user. % % Pixels accessed via the returned pointer represent a simple array of type % Quantum. If the image type is CMYK or the storage class is PseudoClass, % call GetAuthenticMetacontent() after invoking GetAuthenticPixels() to % access the meta-content (of type void) corresponding to the the % region. % % If you plan to modify the pixels, use GetAuthenticPixels() instead. % % Note, the GetVirtualPixels() and GetAuthenticPixels() methods are not thread- % safe. In a threaded environment, use GetCacheViewVirtualPixels() or % GetCacheViewAuthenticPixels() instead. % % The format of the GetVirtualPixels() method is: % % const Quantum GetVirtualPixels(const Image image,const ssize_t x, % const ssize_t y,const size_t columns,const size_t rows, % ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o x,y,columns,rows: These values define the perimeter of a region of % pixels. % % o exception: return any errors or warnings in this structure. % / MagickExport const Quantum GetVirtualPixels(const Image image, const ssize_t x,const ssize_t y,const size_t columns,const size_t rows, ExceptionInfo exception) { CacheInfo magick_restrict cache_info; const int id = GetOpenMPThreadId(); const Quantum magick_restrict p; assert(image != (const Image ) NULL); assert(image->signature == MagickCoreSignature); assert(image->cache != (Cache) NULL); cache_info=(CacheInfo ) image->cache; assert(cache_info->signature == MagickCoreSignature); if (cache_info->methods.get_virtual_pixel_handler != (GetVirtualPixelHandler) NULL) return(cache_info->methods.get_virtual_pixel_handler(image, GetPixelCacheVirtualMethod(image),x,y,columns,rows,exception)); assert(id < (int) cache_info->number_threads); p=GetVirtualPixelCacheNexus(image,GetPixelCacheVirtualMethod(image),x,y, columns,rows,cache_info->nexus_info[id],exception); return(p); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + G e t V i r t u a l P i x e l s F r o m C a c h e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetVirtualPixelsCache() returns the pixels associated corresponding with the % last call to QueueAuthenticPixelsCache() or GetVirtualPixelCache(). % % The format of the GetVirtualPixelsCache() method is: % % Quantum GetVirtualPixelsCache(const Image image) % % A description of each parameter follows: % % o image: the image. % / static const Quantum GetVirtualPixelsCache(const Image image) { CacheInfo magick_restrict cache_info; const int id = GetOpenMPThreadId(); assert(image != (const Image ) NULL); assert(image->signature == MagickCoreSignature); assert(image->cache != (Cache) NULL); cache_info=(CacheInfo ) image->cache; assert(cache_info->signature == MagickCoreSignature); assert(id < (int) cache_info->number_threads); return(GetVirtualPixelsNexus(image->cache,cache_info->nexus_info[id])); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + G e t V i r t u a l P i x e l s N e x u s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetVirtualPixelsNexus() returns the pixels associated with the specified % cache nexus. % % The format of the GetVirtualPixelsNexus() method is: % % const Quantum GetVirtualPixelsNexus(const Cache cache, % NexusInfo nexus_info) % % A description of each parameter follows: % % o cache: the pixel cache. % % o nexus_info: the cache nexus to return the colormap pixels. % / MagickPrivate const Quantum GetVirtualPixelsNexus(const Cache cache, NexusInfo magick_restrict nexus_info) { CacheInfo magick_restrict cache_info; assert(cache != (Cache) NULL); cache_info=(CacheInfo ) cache; assert(cache_info->signature == MagickCoreSignature); if (cache_info->storage_class == UndefinedClass) return((Quantum ) NULL); return((const Quantum ) nexus_info->pixels); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + M a s k P i x e l C a c h e N e x u s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % MaskPixelCacheNexus() masks the cache nexus as defined by the image mask. % The method returns MagickTrue if the pixel region is masked, otherwise % MagickFalse. % % The format of the MaskPixelCacheNexus() method is: % % MagickBooleanType MaskPixelCacheNexus(Image image, % NexusInfo nexus_info,ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o nexus_info: the cache nexus to clip. % % o exception: return any errors or warnings in this structure. % / static inline Quantum ApplyPixelCompositeMask(const Quantum p, const MagickRealType alpha,const Quantum q,const MagickRealType beta) { double mask_alpha; if (fabs(alpha-OpaqueAlpha) < MagickEpsilon) return(p); mask_alpha=1.0-QuantumScaleQuantumScalealphabeta; mask_alpha=PerceptibleReciprocal(mask_alpha); return(ClampToQuantum(mask_alphaMagickOver_((double) p,alpha,(double) q,beta))); } static MagickBooleanType MaskPixelCacheNexus(Image image,NexusInfo nexus_info, ExceptionInfo exception) { CacheInfo magick_restrict cache_info; MagickSizeType number_pixels; NexusInfo *magick_restrict image_nexus; register Quantum magick_restrict p, magick_restrict q; register ssize_t n; / Apply clip mask. / if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); if ((image->channels & CompositeMaskChannel) == 0) return(MagickTrue); cache_info=(CacheInfo ) image->cache; if (cache_info == (Cache) NULL) return(MagickFalse); image_nexus=AcquirePixelCacheNexus(1); p=GetAuthenticPixelCacheNexus(image,nexus_info->region.x,nexus_info->region.y, nexus_info->region.width,nexus_info->region.height,image_nexus[0], exception); q=nexus_info->pixels; number_pixels=(MagickSizeType) nexus_info->region.width* nexus_info->region.height; for (n=0; n < (ssize_t) number_pixels; n++) { double mask_alpha; register ssize_t i; if (p == (Quantum ) NULL) break; mask_alpha=(double) GetPixelCompositeMask(image,p); for (i=0; i < (ssize_t) image->number_channels; i++) { PixelChannel channel = GetPixelChannelChannel(image,i); PixelTrait traits = GetPixelChannelTraits(image,channel); if ((traits & UpdatePixelTrait) == 0) continue; q[i]=ApplyPixelCompositeMask(p[i],mask_alpha,q[i], (MagickRealType) GetPixelAlpha(image,q)); } p+=GetPixelChannels(image); q+=GetPixelChannels(image); } image_nexus=DestroyPixelCacheNexus(image_nexus,1); if (n < (ssize_t) number_pixels) return(MagickFalse); return(MagickTrue); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + O p e n P i x e l C a c h e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % OpenPixelCache() allocates the pixel cache. This includes defining the cache % dimensions, allocating space for the image pixels and optionally the % metacontent, and memory mapping the cache if it is disk based. The cache % nexus array is initialized as well. % % The format of the OpenPixelCache() method is: % % MagickBooleanType OpenPixelCache(Image image,const MapMode mode, % ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o mode: ReadMode, WriteMode, or IOMode. % % o exception: return any errors or warnings in this structure. % / static MagickBooleanType OpenPixelCacheOnDisk(CacheInfo cache_info, const MapMode mode) { int file; /* Open pixel cache on disk. / if ((cache_info->file != -1) && (cache_info->disk_mode == mode)) return(MagickTrue); / cache already open and in the proper mode / if (cache_info->cache_filename == '\0') file=AcquireUniqueFileResource(cache_info->cache_filename); else switch (mode) { case ReadMode: { file=open_utf8(cache_info->cache_filename,O_RDONLY \| O_BINARY,0); break; } case WriteMode: { file=open_utf8(cache_info->cache_filename,O_WRONLY \| O_CREAT \| O_BINARY \| O_EXCL,S_MODE); if (file == -1) file=open_utf8(cache_info->cache_filename,O_WRONLY \| O_BINARY,S_MODE); break; } case IOMode: default: { file=open_utf8(cache_info->cache_filename,O_RDWR \| O_CREAT \| O_BINARY \| O_EXCL,S_MODE); if (file == -1) file=open_utf8(cache_info->cache_filename,O_RDWR \| O_BINARY,S_MODE); break; } } if (file == -1) return(MagickFalse); (void) AcquireMagickResource(FileResource,1); if (cache_info->file != -1) (void) ClosePixelCacheOnDisk(cache_info); cache_info->file=file; cache_info->disk_mode=mode; return(MagickTrue); } static inline MagickOffsetType WritePixelCacheRegion( const CacheInfo magick_restrict cache_info,const MagickOffsetType offset, const MagickSizeType length,const unsigned char magick_restrict buffer) { register MagickOffsetType i; ssize_t count; #if !defined(MAGICKCORE_HAVE_PWRITE) if (lseek(cache_info->file,offset,SEEK_SET) < 0) return((MagickOffsetType) -1); #endif count=0; for (i=0; i < (MagickOffsetType) length; i+=count) { #if !defined(MAGICKCORE_HAVE_PWRITE) count=write(cache_info->file,buffer+i,(size_t) MagickMin(length-i,(size_t) SSIZE_MAX)); #else count=pwrite(cache_info->file,buffer+i,(size_t) MagickMin(length-i,(size_t) SSIZE_MAX),(off_t) (offset+i)); #endif if (count <= 0) { count=0; if (errno != EINTR) break; } } return(i); } static MagickBooleanType SetPixelCacheExtent(Image image,MagickSizeType length) { CacheInfo magick_restrict cache_info; MagickOffsetType count, extent, offset; cache_info=(CacheInfo ) image->cache; if (image->debug != MagickFalse) { char format[MagickPathExtent], message[MagickPathExtent]; (void) FormatMagickSize(length,MagickFalse,"B",MagickPathExtent,format); (void) FormatLocaleString(message,MagickPathExtent, "extend %s (%s[%d], disk, %s)",cache_info->filename, cache_info->cache_filename,cache_info->file,format); (void) LogMagickEvent(CacheEvent,GetMagickModule(),"%s",message); } if (length != (MagickSizeType) ((MagickOffsetType) length)) return(MagickFalse); offset=(MagickOffsetType) lseek(cache_info->file,0,SEEK_END); if (offset < 0) return(MagickFalse); if ((MagickSizeType) offset >= length) count=(MagickOffsetType) 1; else { extent=(MagickOffsetType) length-1; count=WritePixelCacheRegion(cache_info,extent,1,(const unsigned char ) ""); if (count != 1) return(MagickFalse); #if defined(MAGICKCORE_HAVE_POSIX_FALLOCATE) if (cache_info->synchronize != MagickFalse) (void) posix_fallocate(cache_info->file,offset+1,extent-offset); #endif } offset=(MagickOffsetType) lseek(cache_info->file,0,SEEK_SET); if (offset < 0) return(MagickFalse); return(MagickTrue); } static MagickBooleanType OpenPixelCache(Image image,const MapMode mode, ExceptionInfo exception) { CacheInfo magick_restrict cache_info, source_info; char format[MagickPathExtent], message[MagickPathExtent]; const char hosts, type; MagickBooleanType status; MagickSizeType length, number_pixels; size_t columns, packet_size; assert(image != (const Image ) NULL); assert(image->signature == MagickCoreSignature); assert(image->cache != (Cache) NULL); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); if (cache_anonymous_memory < 0) { char value; / Does the security policy require anonymous mapping for pixel cache? / cache_anonymous_memory=0; value=GetPolicyValue("pixel-cache-memory"); if (value == (char ) NULL) value=GetPolicyValue("cache:memory-map"); if (LocaleCompare(value,"anonymous") == 0) { #if defined(MAGICKCORE_HAVE_MMAP) && defined(MAP_ANONYMOUS) cache_anonymous_memory=1; #else (void) ThrowMagickException(exception,GetMagickModule(), MissingDelegateError,"DelegateLibrarySupportNotBuiltIn", "'%s' (policy requires anonymous memory mapping)",image->filename); #endif } value=DestroyString(value); } if ((image->columns == 0) \|\| (image->rows == 0)) ThrowBinaryException(CacheError,"NoPixelsDefinedInCache",image->filename); cache_info=(CacheInfo ) image->cache; assert(cache_info->signature == MagickCoreSignature); if ((AcquireMagickResource(WidthResource,image->columns) == MagickFalse) \|\| (AcquireMagickResource(HeightResource,image->rows) == MagickFalse)) ThrowBinaryException(ImageError,"WidthOrHeightExceedsLimit", image->filename); length=GetImageListLength(image); if (AcquireMagickResource(ListLengthResource,length) == MagickFalse) ThrowBinaryException(ResourceLimitError,"ListLengthExceedsLimit", image->filename); source_info=(cache_info); source_info.file=(-1); (void) FormatLocaleString(cache_info->filename,MagickPathExtent,"%s[%.20g]", image->filename,(double) image->scene); cache_info->storage_class=image->storage_class; cache_info->colorspace=image->colorspace; cache_info->alpha_trait=image->alpha_trait; cache_info->channels=image->channels; cache_info->rows=image->rows; cache_info->columns=image->columns; InitializePixelChannelMap(image); cache_info->number_channels=GetPixelChannels(image); (void) memcpy(cache_info->channel_map,image->channel_map,MaxPixelChannels* sizeof(image->channel_map)); cache_info->metacontent_extent=image->metacontent_extent; cache_info->mode=mode; number_pixels=(MagickSizeType) cache_info->columnscache_info->rows; packet_size=cache_info->number_channelssizeof(Quantum); if (image->metacontent_extent != 0) packet_size+=cache_info->metacontent_extent; length=number_pixelspacket_size; columns=(size_t) (length/cache_info->rows/packet_size); if ((cache_info->columns != columns) \|\| ((ssize_t) cache_info->columns < 0) \|\| ((ssize_t) cache_info->rows < 0)) ThrowBinaryException(ResourceLimitError,"PixelCacheAllocationFailed", image->filename); cache_info->length=length; if (image->ping != MagickFalse) { cache_info->storage_class=image->storage_class; cache_info->colorspace=image->colorspace; cache_info->type=PingCache; return(MagickTrue); } status=AcquireMagickResource(AreaResource,(MagickSizeType) cache_info->columnscache_info->rows); if (cache_info->mode == PersistMode) status=MagickFalse; length=number_pixels(cache_info->number_channelssizeof(Quantum)+ cache_info->metacontent_extent); if ((status != MagickFalse) && (length == (MagickSizeType) ((size_t) length)) && ((cache_info->type == UndefinedCache) \|\| (cache_info->type == MemoryCache))) { status=AcquireMagickResource(MemoryResource,cache_info->length); if (status != MagickFalse) { status=MagickTrue; if (cache_anonymous_memory <= 0) { cache_info->mapped=MagickFalse; cache_info->pixels=(Quantum ) MagickAssumeAligned( AcquireAlignedMemory(1,(size_t) cache_info->length)); } else { cache_info->mapped=MagickTrue; cache_info->pixels=(Quantum ) MapBlob(-1,IOMode,0,(size_t) cache_info->length); } if (cache_info->pixels == (Quantum ) NULL) cache_info->pixels=source_info.pixels; else { /* Create memory pixel cache. / cache_info->type=MemoryCache; cache_info->metacontent=(void ) NULL; if (cache_info->metacontent_extent != 0) cache_info->metacontent=(void ) (cache_info->pixels+ number_pixelscache_info->number_channels); if ((source_info.storage_class != UndefinedClass) && (mode != ReadMode)) { status=ClonePixelCacheRepository(cache_info,&source_info, exception); RelinquishPixelCachePixels(&source_info); } if (image->debug != MagickFalse) { (void) FormatMagickSize(cache_info->length,MagickTrue,"B", MagickPathExtent,format); type=CommandOptionToMnemonic(MagickCacheOptions,(ssize_t) cache_info->type); (void) FormatLocaleString(message,MagickPathExtent, "open %s (%s %s, %.20gx%.20gx%.20g %s)", cache_info->filename,cache_info->mapped != MagickFalse ? "Anonymous" : "Heap",type,(double) cache_info->columns, (double) cache_info->rows,(double) cache_info->number_channels,format); (void) LogMagickEvent(CacheEvent,GetMagickModule(),"%s", message); } return(status == 0 ? MagickFalse : MagickTrue); } } } status=AcquireMagickResource(DiskResource,cache_info->length); hosts=(const char ) GetImageRegistry(StringRegistryType,"cache:hosts", exception); if ((status == MagickFalse) && (hosts != (const char ) NULL)) { DistributeCacheInfo server_info; / Distribute the pixel cache to a remote server. / server_info=AcquireDistributeCacheInfo(exception); if (server_info != (DistributeCacheInfo ) NULL) { status=OpenDistributePixelCache(server_info,image); if (status == MagickFalse) { ThrowFileException(exception,CacheError,"UnableToOpenPixelCache", GetDistributeCacheHostname(server_info)); server_info=DestroyDistributeCacheInfo(server_info); } else { /* Create a distributed pixel cache. / status=MagickTrue; cache_info->type=DistributedCache; cache_info->server_info=server_info; (void) FormatLocaleString(cache_info->cache_filename, MagickPathExtent,"%s:%d",GetDistributeCacheHostname( (DistributeCacheInfo ) cache_info->server_info), GetDistributeCachePort((DistributeCacheInfo ) cache_info->server_info)); if ((source_info.storage_class != UndefinedClass) && (mode != ReadMode)) { status=ClonePixelCacheRepository(cache_info,&source_info, exception); RelinquishPixelCachePixels(&source_info); } if (image->debug != MagickFalse) { (void) FormatMagickSize(cache_info->length,MagickFalse,"B", MagickPathExtent,format); type=CommandOptionToMnemonic(MagickCacheOptions,(ssize_t) cache_info->type); (void) FormatLocaleString(message,MagickPathExtent, "open %s (%s[%d], %s, %.20gx%.20gx%.20g %s)", cache_info->filename,cache_info->cache_filename, GetDistributeCacheFile((DistributeCacheInfo ) cache_info->server_info),type,(double) cache_info->columns, (double) cache_info->rows,(double) cache_info->number_channels,format); (void) LogMagickEvent(CacheEvent,GetMagickModule(),"%s", message); } return(status == 0 ? MagickFalse : MagickTrue); } } cache_info->type=UndefinedCache; (void) ThrowMagickException(exception,GetMagickModule(),CacheError, "CacheResourcesExhausted","`%s'",image->filename); return(MagickFalse); } /* Create pixel cache on disk. / if (status == MagickFalse) { cache_info->type=UndefinedCache; (void) ThrowMagickException(exception,GetMagickModule(),CacheError, "CacheResourcesExhausted","`%s'",image->filename); return(MagickFalse); } if ((source_info.storage_class != UndefinedClass) && (mode != ReadMode) && (cache_info->mode != PersistMode)) { (void) ClosePixelCacheOnDisk(cache_info); cache_info->cache_filename='\0'; } if (OpenPixelCacheOnDisk(cache_info,mode) == MagickFalse) { ThrowFileException(exception,CacheError,"UnableToOpenPixelCache", image->filename); return(MagickFalse); } status=SetPixelCacheExtent(image,(MagickSizeType) cache_info->offset+ cache_info->length); if (status == MagickFalse) { ThrowFileException(exception,CacheError,"UnableToExtendCache", image->filename); return(MagickFalse); } length=number_pixels(cache_info->number_channelssizeof(Quantum)+ cache_info->metacontent_extent); if (length != (MagickSizeType) ((size_t) length)) cache_info->type=DiskCache; else { status=AcquireMagickResource(MapResource,cache_info->length); if (status == MagickFalse) cache_info->type=DiskCache; else if ((cache_info->type != MapCache) && (cache_info->type != MemoryCache)) { cache_info->type=DiskCache; RelinquishMagickResource(MapResource,cache_info->length); } else { cache_info->pixels=(Quantum ) MapBlob(cache_info->file,mode, cache_info->offset,(size_t) cache_info->length); if (cache_info->pixels == (Quantum ) NULL) { cache_info->type=DiskCache; cache_info->pixels=source_info.pixels; RelinquishMagickResource(MapResource,cache_info->length); } else { /* Create file-backed memory-mapped pixel cache. / (void) ClosePixelCacheOnDisk(cache_info); cache_info->type=MapCache; cache_info->mapped=MagickTrue; cache_info->metacontent=(void ) NULL; if (cache_info->metacontent_extent != 0) cache_info->metacontent=(void ) (cache_info->pixels+ number_pixelscache_info->number_channels); if ((source_info.storage_class != UndefinedClass) && (mode != ReadMode)) { status=ClonePixelCacheRepository(cache_info,&source_info, exception); RelinquishPixelCachePixels(&source_info); } if (image->debug != MagickFalse) { (void) FormatMagickSize(cache_info->length,MagickTrue,"B", MagickPathExtent,format); type=CommandOptionToMnemonic(MagickCacheOptions,(ssize_t) cache_info->type); (void) FormatLocaleString(message,MagickPathExtent, "open %s (%s[%d], %s, %.20gx%.20gx%.20g %s)", cache_info->filename,cache_info->cache_filename, cache_info->file,type,(double) cache_info->columns, (double) cache_info->rows,(double) cache_info->number_channels,format); (void) LogMagickEvent(CacheEvent,GetMagickModule(),"%s", message); } return(status == 0 ? MagickFalse : MagickTrue); } } } status=MagickTrue; if ((source_info.storage_class != UndefinedClass) && (mode != ReadMode)) { status=ClonePixelCacheRepository(cache_info,&source_info,exception); RelinquishPixelCachePixels(&source_info); } if (image->debug != MagickFalse) { (void) FormatMagickSize(cache_info->length,MagickFalse,"B", MagickPathExtent,format); type=CommandOptionToMnemonic(MagickCacheOptions,(ssize_t) cache_info->type); (void) FormatLocaleString(message,MagickPathExtent, "open %s (%s[%d], %s, %.20gx%.20gx%.20g %s)",cache_info->filename, cache_info->cache_filename,cache_info->file,type,(double) cache_info->columns,(double) cache_info->rows,(double) cache_info->number_channels,format); (void) LogMagickEvent(CacheEvent,GetMagickModule(),"%s",message); } return(status == 0 ? MagickFalse : MagickTrue); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + P e r s i s t P i x e l C a c h e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % PersistPixelCache() attaches to or initializes a persistent pixel cache. A % persistent pixel cache is one that resides on disk and is not destroyed % when the program exits. % % The format of the PersistPixelCache() method is: % % MagickBooleanType PersistPixelCache(Image image,const char filename, % const MagickBooleanType attach,MagickOffsetType offset, % ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o filename: the persistent pixel cache filename. % % o attach: A value other than zero initializes the persistent pixel cache. % % o initialize: A value other than zero initializes the persistent pixel % cache. % % o offset: the offset in the persistent cache to store pixels. % % o exception: return any errors or warnings in this structure. % / MagickExport MagickBooleanType PersistPixelCache(Image image, const char filename,const MagickBooleanType attach,MagickOffsetType offset, ExceptionInfo exception) { CacheInfo magick_restrict cache_info, magick_restrict clone_info; MagickBooleanType status; ssize_t page_size; assert(image != (Image ) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(image->cache != (void ) NULL); assert(filename != (const char ) NULL); assert(offset != (MagickOffsetType ) NULL); page_size=GetMagickPageSize(); cache_info=(CacheInfo ) image->cache; assert(cache_info->signature == MagickCoreSignature); #if defined(MAGICKCORE_OPENCL_SUPPORT) CopyOpenCLBuffer(cache_info); #endif if (attach != MagickFalse) { /* Attach existing persistent pixel cache. / if (image->debug != MagickFalse) (void) LogMagickEvent(CacheEvent,GetMagickModule(), "attach persistent cache"); (void) CopyMagickString(cache_info->cache_filename,filename, MagickPathExtent); cache_info->type=DiskCache; cache_info->offset=(offset); if (OpenPixelCache(image,ReadMode,exception) == MagickFalse) return(MagickFalse); offset+=cache_info->length+page_size-(cache_info->length % page_size); return(SyncImagePixelCache(image,exception)); } / Clone persistent pixel cache. / status=AcquireMagickResource(DiskResource,cache_info->length); if (status == MagickFalse) { (void) ThrowMagickException(exception,GetMagickModule(),CacheError, "CacheResourcesExhausted","`%s'",image->filename); return(MagickFalse); } clone_info=(CacheInfo ) ClonePixelCache(cache_info); clone_info->type=DiskCache; (void) CopyMagickString(clone_info->cache_filename,filename,MagickPathExtent); clone_info->file=(-1); clone_info->storage_class=cache_info->storage_class; clone_info->colorspace=cache_info->colorspace; clone_info->alpha_trait=cache_info->alpha_trait; clone_info->channels=cache_info->channels; clone_info->columns=cache_info->columns; clone_info->rows=cache_info->rows; clone_info->number_channels=cache_info->number_channels; clone_info->metacontent_extent=cache_info->metacontent_extent; clone_info->mode=PersistMode; clone_info->length=cache_info->length; (void) memcpy(clone_info->channel_map,cache_info->channel_map, MaxPixelChannelssizeof(cache_info->channel_map)); clone_info->offset=(offset); status=ClonePixelCacheRepository(clone_info,cache_info,exception); offset+=cache_info->length+page_size-(cache_info->length % page_size); clone_info=(CacheInfo ) DestroyPixelCache(clone_info); return(status); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + Q u e u e A u t h e n t i c P i x e l C a c h e N e x u s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % QueueAuthenticPixelCacheNexus() allocates an region to store image pixels as % defined by the region rectangle and returns a pointer to the region. This % region is subsequently transferred from the pixel cache with % SyncAuthenticPixelsCache(). A pointer to the pixels is returned if the % pixels are transferred, otherwise a NULL is returned. % % The format of the QueueAuthenticPixelCacheNexus() method is: % % Quantum QueueAuthenticPixelCacheNexus(Image image,const ssize_t x, % const ssize_t y,const size_t columns,const size_t rows, % const MagickBooleanType clone,NexusInfo nexus_info, % ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o x,y,columns,rows: These values define the perimeter of a region of % pixels. % % o nexus_info: the cache nexus to set. % % o clone: clone the pixel cache. % % o exception: return any errors or warnings in this structure. % / MagickPrivate Quantum QueueAuthenticPixelCacheNexus(Image image, const ssize_t x,const ssize_t y,const size_t columns,const size_t rows, const MagickBooleanType clone,NexusInfo nexus_info,ExceptionInfo exception) { CacheInfo magick_restrict cache_info; MagickOffsetType offset; MagickSizeType number_pixels; Quantum magick_restrict pixels; RectangleInfo region; / Validate pixel cache geometry. / assert(image != (const Image ) NULL); assert(image->signature == MagickCoreSignature); assert(image->cache != (Cache) NULL); cache_info=(CacheInfo ) GetImagePixelCache(image,clone,exception); if (cache_info == (Cache) NULL) return((Quantum ) NULL); assert(cache_info->signature == MagickCoreSignature); if ((cache_info->columns == 0) \|\| (cache_info->rows == 0) \|\| (x < 0) \|\| (y < 0) \|\| (x >= (ssize_t) cache_info->columns) \|\| (y >= (ssize_t) cache_info->rows)) { (void) ThrowMagickException(exception,GetMagickModule(),CacheError, "PixelsAreNotAuthentic","`%s'",image->filename); return((Quantum ) NULL); } offset=(MagickOffsetType) ycache_info->columns+x; if (offset < 0) return((Quantum ) NULL); number_pixels=(MagickSizeType) cache_info->columnscache_info->rows; offset+=(MagickOffsetType) (rows-1)cache_info->columns+columns-1; if ((MagickSizeType) offset >= number_pixels) return((Quantum ) NULL); /* Return pixel cache. / region.x=x; region.y=y; region.width=columns; region.height=rows; pixels=SetPixelCacheNexusPixels(cache_info,WriteMode,&region, ((image->channels & WriteMaskChannel) != 0) \|\| ((image->channels & CompositeMaskChannel) != 0) ? MagickTrue : MagickFalse, nexus_info,exception); return(pixels); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + Q u e u e A u t h e n t i c P i x e l s C a c h e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % QueueAuthenticPixelsCache() allocates an region to store image pixels as % defined by the region rectangle and returns a pointer to the region. This % region is subsequently transferred from the pixel cache with % SyncAuthenticPixelsCache(). A pointer to the pixels is returned if the % pixels are transferred, otherwise a NULL is returned. % % The format of the QueueAuthenticPixelsCache() method is: % % Quantum QueueAuthenticPixelsCache(Image image,const ssize_t x, % const ssize_t y,const size_t columns,const size_t rows, % ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o x,y,columns,rows: These values define the perimeter of a region of % pixels. % % o exception: return any errors or warnings in this structure. % / static Quantum QueueAuthenticPixelsCache(Image image,const ssize_t x, const ssize_t y,const size_t columns,const size_t rows, ExceptionInfo exception) { CacheInfo magick_restrict cache_info; const int id = GetOpenMPThreadId(); Quantum magick_restrict pixels; assert(image != (const Image ) NULL); assert(image->signature == MagickCoreSignature); assert(image->cache != (Cache) NULL); cache_info=(CacheInfo ) image->cache; assert(cache_info->signature == MagickCoreSignature); assert(id < (int) cache_info->number_threads); pixels=QueueAuthenticPixelCacheNexus(image,x,y,columns,rows,MagickFalse, cache_info->nexus_info[id],exception); return(pixels); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % Q u e u e A u t h e n t i c P i x e l s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % QueueAuthenticPixels() queues a mutable pixel region. If the region is % successfully initialized a pointer to a Quantum array representing the % region is returned, otherwise NULL is returned. The returned pointer may % point to a temporary working buffer for the pixels or it may point to the % final location of the pixels in memory. % % Write-only access means that any existing pixel values corresponding to % the region are ignored. This is useful if the initial image is being % created from scratch, or if the existing pixel values are to be % completely replaced without need to refer to their pre-existing values. % The application is free to read and write the pixel buffer returned by % QueueAuthenticPixels() any way it pleases. QueueAuthenticPixels() does not % initialize the pixel array values. Initializing pixel array values is the % application's responsibility. % % Performance is maximized if the selected region is part of one row, or % one or more full rows, since then there is opportunity to access the % pixels in-place (without a copy) if the image is in memory, or in a % memory-mapped file. The returned pointer must never be deallocated % by the user. % % Pixels accessed via the returned pointer represent a simple array of type % Quantum. If the image type is CMYK or the storage class is PseudoClass, % call GetAuthenticMetacontent() after invoking GetAuthenticPixels() to % obtain the meta-content (of type void) corresponding to the region. % Once the Quantum (and/or Quantum) array has been updated, the % changes must be saved back to the underlying image using % SyncAuthenticPixels() or they may be lost. % % The format of the QueueAuthenticPixels() method is: % % Quantum QueueAuthenticPixels(Image image,const ssize_t x, % const ssize_t y,const size_t columns,const size_t rows, % ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o x,y,columns,rows: These values define the perimeter of a region of % pixels. % % o exception: return any errors or warnings in this structure. % / MagickExport Quantum QueueAuthenticPixels(Image image,const ssize_t x, const ssize_t y,const size_t columns,const size_t rows, ExceptionInfo exception) { CacheInfo magick_restrict cache_info; const int id = GetOpenMPThreadId(); Quantum magick_restrict pixels; assert(image != (Image ) NULL); assert(image->signature == MagickCoreSignature); assert(image->cache != (Cache) NULL); cache_info=(CacheInfo ) image->cache; assert(cache_info->signature == MagickCoreSignature); if (cache_info->methods.queue_authentic_pixels_handler != (QueueAuthenticPixelsHandler) NULL) { pixels=cache_info->methods.queue_authentic_pixels_handler(image,x,y, columns,rows,exception); return(pixels); } assert(id < (int) cache_info->number_threads); pixels=QueueAuthenticPixelCacheNexus(image,x,y,columns,rows,MagickFalse, cache_info->nexus_info[id],exception); return(pixels); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + R e a d P i x e l C a c h e M e t a c o n t e n t % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % ReadPixelCacheMetacontent() reads metacontent from the specified region of % the pixel cache. % % The format of the ReadPixelCacheMetacontent() method is: % % MagickBooleanType ReadPixelCacheMetacontent(CacheInfo cache_info, % NexusInfo nexus_info,ExceptionInfo exception) % % A description of each parameter follows: % % o cache_info: the pixel cache. % % o nexus_info: the cache nexus to read the metacontent. % % o exception: return any errors or warnings in this structure. % / static inline MagickOffsetType ReadPixelCacheRegion( const CacheInfo magick_restrict cache_info,const MagickOffsetType offset, const MagickSizeType length,unsigned char magick_restrict buffer) { register MagickOffsetType i; ssize_t count; #if !defined(MAGICKCORE_HAVE_PREAD) if (lseek(cache_info->file,offset,SEEK_SET) < 0) return((MagickOffsetType) -1); #endif count=0; for (i=0; i < (MagickOffsetType) length; i+=count) { #if !defined(MAGICKCORE_HAVE_PREAD) count=read(cache_info->file,buffer+i,(size_t) MagickMin(length-i,(size_t) SSIZE_MAX)); #else count=pread(cache_info->file,buffer+i,(size_t) MagickMin(length-i,(size_t) SSIZE_MAX),(off_t) (offset+i)); #endif if (count <= 0) { count=0; if (errno != EINTR) break; } } return(i); } static MagickBooleanType ReadPixelCacheMetacontent( CacheInfo magick_restrict cache_info,NexusInfo magick_restrict nexus_info, ExceptionInfo exception) { MagickOffsetType count, offset; MagickSizeType extent, length; register ssize_t y; register unsigned char magick_restrict q; size_t rows; if (cache_info->metacontent_extent == 0) return(MagickFalse); if (nexus_info->authentic_pixel_cache != MagickFalse) return(MagickTrue); offset=(MagickOffsetType) nexus_info->region.ycache_info->columns+ nexus_info->region.x; length=(MagickSizeType) nexus_info->region.width cache_info->metacontent_extent; extent=lengthnexus_info->region.height; rows=nexus_info->region.height; y=0; q=(unsigned char ) nexus_info->metacontent; switch (cache_info->type) { case MemoryCache: case MapCache: { register unsigned char magick_restrict p; / Read meta-content from memory. / if ((cache_info->columns == nexus_info->region.width) && (extent == (MagickSizeType) ((size_t) extent))) { length=extent; rows=1UL; } p=(unsigned char ) cache_info->metacontent+offset* cache_info->metacontent_extent; for (y=0; y < (ssize_t) rows; y++) { (void) memcpy(q,p,(size_t) length); p+=cache_info->metacontent_extentcache_info->columns; q+=cache_info->metacontent_extentnexus_info->region.width; } break; } case DiskCache: { /* Read meta content from disk. / LockSemaphoreInfo(cache_info->file_semaphore); if (OpenPixelCacheOnDisk(cache_info,IOMode) == MagickFalse) { ThrowFileException(exception,FileOpenError,"UnableToOpenFile", cache_info->cache_filename); UnlockSemaphoreInfo(cache_info->file_semaphore); return(MagickFalse); } if ((cache_info->columns == nexus_info->region.width) && (extent <= MagickMaxBufferExtent)) { length=extent; rows=1UL; } extent=(MagickSizeType) cache_info->columnscache_info->rows; for (y=0; y < (ssize_t) rows; y++) { count=ReadPixelCacheRegion(cache_info,cache_info->offset+extent* cache_info->number_channelssizeof(Quantum)+offset cache_info->metacontent_extent,length,(unsigned char ) q); if (count != (MagickOffsetType) length) break; offset+=cache_info->columns; q+=cache_info->metacontent_extentnexus_info->region.width; } if (IsFileDescriptorLimitExceeded() != MagickFalse) (void) ClosePixelCacheOnDisk(cache_info); UnlockSemaphoreInfo(cache_info->file_semaphore); break; } case DistributedCache: { RectangleInfo region; /* Read metacontent from distributed cache. / LockSemaphoreInfo(cache_info->file_semaphore); region=nexus_info->region; if ((cache_info->columns != nexus_info->region.width) \|\| (extent > MagickMaxBufferExtent)) region.height=1UL; else { length=extent; rows=1UL; } for (y=0; y < (ssize_t) rows; y++) { count=ReadDistributePixelCacheMetacontent((DistributeCacheInfo ) cache_info->server_info,&region,length,(unsigned char ) q); if (count != (MagickOffsetType) length) break; q+=cache_info->metacontent_extentnexus_info->region.width; region.y++; } UnlockSemaphoreInfo(cache_info->file_semaphore); break; } default: break; } if (y < (ssize_t) rows) { ThrowFileException(exception,CacheError,"UnableToReadPixelCache", cache_info->cache_filename); return(MagickFalse); } if ((cache_info->debug != MagickFalse) && (CacheTick(nexus_info->region.y,cache_info->rows) != MagickFalse)) (void) LogMagickEvent(CacheEvent,GetMagickModule(), "%s[%.20gx%.20g%+.20g%+.20g]",cache_info->filename,(double) nexus_info->region.width,(double) nexus_info->region.height,(double) nexus_info->region.x,(double) nexus_info->region.y); return(MagickTrue); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + R e a d P i x e l C a c h e P i x e l s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % ReadPixelCachePixels() reads pixels from the specified region of the pixel % cache. % % The format of the ReadPixelCachePixels() method is: % % MagickBooleanType ReadPixelCachePixels(CacheInfo cache_info, % NexusInfo nexus_info,ExceptionInfo exception) % % A description of each parameter follows: % % o cache_info: the pixel cache. % % o nexus_info: the cache nexus to read the pixels. % % o exception: return any errors or warnings in this structure. % / static MagickBooleanType ReadPixelCachePixels( CacheInfo magick_restrict cache_info,NexusInfo magick_restrict nexus_info, ExceptionInfo exception) { MagickOffsetType count, offset; MagickSizeType extent, length; register Quantum magick_restrict q; register ssize_t y; size_t number_channels, rows; if (nexus_info->authentic_pixel_cache != MagickFalse) return(MagickTrue); offset=(MagickOffsetType) nexus_info->region.ycache_info->columns; if ((ssize_t) (offset/cache_info->columns) != nexus_info->region.y) return(MagickFalse); offset+=nexus_info->region.x; number_channels=cache_info->number_channels; length=(MagickSizeType) number_channelsnexus_info->region.width* sizeof(Quantum); if ((length/number_channels/sizeof(Quantum)) != nexus_info->region.width) return(MagickFalse); rows=nexus_info->region.height; extent=lengthrows; if ((extent == 0) \|\| ((extent/length) != rows)) return(MagickFalse); y=0; q=nexus_info->pixels; switch (cache_info->type) { case MemoryCache: case MapCache: { register Quantum magick_restrict p; /* Read pixels from memory. / if ((cache_info->columns == nexus_info->region.width) && (extent == (MagickSizeType) ((size_t) extent))) { length=extent; rows=1UL; } p=cache_info->pixels+offsetcache_info->number_channels; for (y=0; y < (ssize_t) rows; y++) { (void) memcpy(q,p,(size_t) length); p+=cache_info->number_channelscache_info->columns; q+=cache_info->number_channelsnexus_info->region.width; } break; } case DiskCache: { /* Read pixels from disk. / LockSemaphoreInfo(cache_info->file_semaphore); if (OpenPixelCacheOnDisk(cache_info,IOMode) == MagickFalse) { ThrowFileException(exception,FileOpenError,"UnableToOpenFile", cache_info->cache_filename); UnlockSemaphoreInfo(cache_info->file_semaphore); return(MagickFalse); } if ((cache_info->columns == nexus_info->region.width) && (extent <= MagickMaxBufferExtent)) { length=extent; rows=1UL; } for (y=0; y < (ssize_t) rows; y++) { count=ReadPixelCacheRegion(cache_info,cache_info->offset+offset cache_info->number_channelssizeof(q),length,(unsigned char ) q); if (count != (MagickOffsetType) length) break; offset+=cache_info->columns; q+=cache_info->number_channelsnexus_info->region.width; } if (IsFileDescriptorLimitExceeded() != MagickFalse) (void) ClosePixelCacheOnDisk(cache_info); UnlockSemaphoreInfo(cache_info->file_semaphore); break; } case DistributedCache: { RectangleInfo region; /* Read pixels from distributed cache. / LockSemaphoreInfo(cache_info->file_semaphore); region=nexus_info->region; if ((cache_info->columns != nexus_info->region.width) \|\| (extent > MagickMaxBufferExtent)) region.height=1UL; else { length=extent; rows=1UL; } for (y=0; y < (ssize_t) rows; y++) { count=ReadDistributePixelCachePixels((DistributeCacheInfo ) cache_info->server_info,&region,length,(unsigned char ) q); if (count != (MagickOffsetType) length) break; q+=cache_info->number_channelsnexus_info->region.width; region.y++; } UnlockSemaphoreInfo(cache_info->file_semaphore); break; } default: break; } if (y < (ssize_t) rows) { ThrowFileException(exception,CacheError,"UnableToReadPixelCache", cache_info->cache_filename); return(MagickFalse); } if ((cache_info->debug != MagickFalse) && (CacheTick(nexus_info->region.y,cache_info->rows) != MagickFalse)) (void) LogMagickEvent(CacheEvent,GetMagickModule(), "%s[%.20gx%.20g%+.20g%+.20g]",cache_info->filename,(double) nexus_info->region.width,(double) nexus_info->region.height,(double) nexus_info->region.x,(double) nexus_info->region.y); return(MagickTrue); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + R e f e r e n c e P i x e l C a c h e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % ReferencePixelCache() increments the reference count associated with the % pixel cache returning a pointer to the cache. % % The format of the ReferencePixelCache method is: % % Cache ReferencePixelCache(Cache cache_info) % % A description of each parameter follows: % % o cache_info: the pixel cache. % / MagickPrivate Cache ReferencePixelCache(Cache cache) { CacheInfo magick_restrict cache_info; assert(cache != (Cache ) NULL); cache_info=(CacheInfo ) cache; assert(cache_info->signature == MagickCoreSignature); LockSemaphoreInfo(cache_info->semaphore); cache_info->reference_count++; UnlockSemaphoreInfo(cache_info->semaphore); return(cache_info); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + R e s e t P i x e l C a c h e C h a n n e l s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % ResetPixelCacheChannels() resets the pixel cache channels. % % The format of the ResetPixelCacheChannels method is: % % void ResetPixelCacheChannels(Image ) % % A description of each parameter follows: % % o image: the image. % / MagickPrivate void ResetPixelCacheChannels(Image image) { CacheInfo magick_restrict cache_info; assert(image != (const Image ) NULL); assert(image->signature == MagickCoreSignature); assert(image->cache != (Cache) NULL); cache_info=(CacheInfo ) image->cache; assert(cache_info->signature == MagickCoreSignature); cache_info->number_channels=GetPixelChannels(image); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + R e s e t C a c h e A n o n y m o u s M e m o r y % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % ResetCacheAnonymousMemory() resets the anonymous_memory value. % % The format of the ResetCacheAnonymousMemory method is: % % void ResetCacheAnonymousMemory(void) % / MagickPrivate void ResetCacheAnonymousMemory(void) { cache_anonymous_memory=0; } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + R e s e t P i x e l C a c h e E p o c h % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % ResetPixelCacheEpoch() resets the pixel cache epoch. % % The format of the ResetPixelCacheEpoch method is: % % void ResetPixelCacheEpoch(void) % / MagickPrivate void ResetPixelCacheEpoch(void) { cache_epoch=0; } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + S e t P i x e l C a c h e M e t h o d s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % SetPixelCacheMethods() sets the image pixel methods to the specified ones. % % The format of the SetPixelCacheMethods() method is: % % SetPixelCacheMethods(Cache ,CacheMethods cache_methods) % % A description of each parameter follows: % % o cache: the pixel cache. % % o cache_methods: Specifies a pointer to a CacheMethods structure. % / MagickPrivate void SetPixelCacheMethods(Cache cache,CacheMethods cache_methods) { CacheInfo magick_restrict cache_info; GetOneAuthenticPixelFromHandler get_one_authentic_pixel_from_handler; GetOneVirtualPixelFromHandler get_one_virtual_pixel_from_handler; / Set cache pixel methods. / assert(cache != (Cache) NULL); assert(cache_methods != (CacheMethods ) NULL); cache_info=(CacheInfo ) cache; assert(cache_info->signature == MagickCoreSignature); if (cache_info->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s", cache_info->filename); if (cache_methods->get_virtual_pixel_handler != (GetVirtualPixelHandler) NULL) cache_info->methods.get_virtual_pixel_handler= cache_methods->get_virtual_pixel_handler; if (cache_methods->destroy_pixel_handler != (DestroyPixelHandler) NULL) cache_info->methods.destroy_pixel_handler= cache_methods->destroy_pixel_handler; if (cache_methods->get_virtual_metacontent_from_handler != (GetVirtualMetacontentFromHandler) NULL) cache_info->methods.get_virtual_metacontent_from_handler= cache_methods->get_virtual_metacontent_from_handler; if (cache_methods->get_authentic_pixels_handler != (GetAuthenticPixelsHandler) NULL) cache_info->methods.get_authentic_pixels_handler= cache_methods->get_authentic_pixels_handler; if (cache_methods->queue_authentic_pixels_handler != (QueueAuthenticPixelsHandler) NULL) cache_info->methods.queue_authentic_pixels_handler= cache_methods->queue_authentic_pixels_handler; if (cache_methods->sync_authentic_pixels_handler != (SyncAuthenticPixelsHandler) NULL) cache_info->methods.sync_authentic_pixels_handler= cache_methods->sync_authentic_pixels_handler; if (cache_methods->get_authentic_pixels_from_handler != (GetAuthenticPixelsFromHandler) NULL) cache_info->methods.get_authentic_pixels_from_handler= cache_methods->get_authentic_pixels_from_handler; if (cache_methods->get_authentic_metacontent_from_handler != (GetAuthenticMetacontentFromHandler) NULL) cache_info->methods.get_authentic_metacontent_from_handler= cache_methods->get_authentic_metacontent_from_handler; get_one_virtual_pixel_from_handler= cache_info->methods.get_one_virtual_pixel_from_handler; if (get_one_virtual_pixel_from_handler != (GetOneVirtualPixelFromHandler) NULL) cache_info->methods.get_one_virtual_pixel_from_handler= cache_methods->get_one_virtual_pixel_from_handler; get_one_authentic_pixel_from_handler= cache_methods->get_one_authentic_pixel_from_handler; if (get_one_authentic_pixel_from_handler != (GetOneAuthenticPixelFromHandler) NULL) cache_info->methods.get_one_authentic_pixel_from_handler= cache_methods->get_one_authentic_pixel_from_handler; } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + S e t P i x e l C a c h e N e x u s P i x e l s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % SetPixelCacheNexusPixels() defines the region of the cache for the % specified cache nexus. % % The format of the SetPixelCacheNexusPixels() method is: % % Quantum SetPixelCacheNexusPixels(const CacheInfo cache_info, % const MapMode mode,const RectangleInfo region, % const MagickBooleanType buffered,NexusInfo nexus_info, % ExceptionInfo exception) % % A description of each parameter follows: % % o cache_info: the pixel cache. % % o mode: ReadMode, WriteMode, or IOMode. % % o region: A pointer to the RectangleInfo structure that defines the % region of this particular cache nexus. % % o buffered: if true, nexus pixels are buffered. % % o nexus_info: the cache nexus to set. % % o exception: return any errors or warnings in this structure. % / static inline MagickBooleanType AcquireCacheNexusPixels( const CacheInfo magick_restrict cache_info,NexusInfo nexus_info, ExceptionInfo exception) { if (nexus_info->length != (MagickSizeType) ((size_t) nexus_info->length)) return(MagickFalse); if (cache_anonymous_memory <= 0) { nexus_info->mapped=MagickFalse; nexus_info->cache=(Quantum ) MagickAssumeAligned(AcquireAlignedMemory(1, (size_t) nexus_info->length)); if (nexus_info->cache != (Quantum ) NULL) (void) memset(nexus_info->cache,0,(size_t) nexus_info->length); } else { nexus_info->mapped=MagickTrue; nexus_info->cache=(Quantum ) MapBlob(-1,IOMode,0,(size_t) nexus_info->length); } if (nexus_info->cache == (Quantum ) NULL) { (void) ThrowMagickException(exception,GetMagickModule(), ResourceLimitError,"MemoryAllocationFailed","`%s'", cache_info->filename); return(MagickFalse); } return(MagickTrue); } static inline MagickBooleanType IsPixelCacheAuthentic( const CacheInfo magick_restrict cache_info, const NexusInfo magick_restrict nexus_info) { MagickBooleanType status; MagickOffsetType offset; /* Does nexus pixels point directly to in-core cache pixels or is it buffered? / if (cache_info->type == PingCache) return(MagickTrue); offset=(MagickOffsetType) nexus_info->region.ycache_info->columns+ nexus_info->region.x; status=nexus_info->pixels == (cache_info->pixels+offset* cache_info->number_channels) ? MagickTrue : MagickFalse; return(status); } static inline void PrefetchPixelCacheNexusPixels(const NexusInfo nexus_info, const MapMode mode) { if (mode == ReadMode) { MagickCachePrefetch((unsigned char ) nexus_info->pixels,0,1); return; } MagickCachePrefetch((unsigned char ) nexus_info->pixels,1,1); } static Quantum SetPixelCacheNexusPixels(const CacheInfo cache_info, const MapMode mode,const RectangleInfo region, const MagickBooleanType buffered,NexusInfo nexus_info, ExceptionInfo exception) { MagickBooleanType status; MagickSizeType length, number_pixels; assert(cache_info != (const CacheInfo ) NULL); assert(cache_info->signature == MagickCoreSignature); if (cache_info->type == UndefinedCache) return((Quantum ) NULL); if ((region->width == 0) \|\| (region->height == 0)) return((Quantum ) NULL); nexus_info->region=(region); number_pixels=(MagickSizeType) nexus_info->region.width* nexus_info->region.height; if (number_pixels == 0) return((Quantum ) NULL); if (((cache_info->type == MemoryCache) \|\| (cache_info->type == MapCache)) && (buffered == MagickFalse)) { ssize_t x, y; x=nexus_info->region.x+(ssize_t) nexus_info->region.width-1; y=nexus_info->region.y+(ssize_t) nexus_info->region.height-1; if (((nexus_info->region.x >= 0) && (nexus_info->region.y >= 0) && (y < (ssize_t) cache_info->rows)) && (((nexus_info->region.x == 0) && (nexus_info->region.width == cache_info->columns)) \|\| ((nexus_info->region.height == 1) && (x < (ssize_t) cache_info->columns)))) { MagickOffsetType offset; / Pixels are accessed directly from memory. / offset=(MagickOffsetType) nexus_info->region.ycache_info->columns+ nexus_info->region.x; nexus_info->pixels=cache_info->pixels+cache_info->number_channels* offset; nexus_info->metacontent=(void ) NULL; if (cache_info->metacontent_extent != 0) nexus_info->metacontent=(unsigned char ) cache_info->metacontent+ offsetcache_info->metacontent_extent; PrefetchPixelCacheNexusPixels(nexus_info,mode); nexus_info->authentic_pixel_cache=IsPixelCacheAuthentic(cache_info, nexus_info); return(nexus_info->pixels); } } / Pixels are stored in a staging region until they are synced to the cache. / length=number_pixelscache_info->number_channelssizeof(Quantum); if (cache_info->metacontent_extent != 0) length+=number_pixelscache_info->metacontent_extent; if (nexus_info->cache == (Quantum ) NULL) { nexus_info->length=length; status=AcquireCacheNexusPixels(cache_info,nexus_info,exception); if (status == MagickFalse) { nexus_info->length=0; return((Quantum ) NULL); } } else if (nexus_info->length < length) { RelinquishCacheNexusPixels(nexus_info); nexus_info->length=length; status=AcquireCacheNexusPixels(cache_info,nexus_info,exception); if (status == MagickFalse) { nexus_info->length=0; return((Quantum ) NULL); } } nexus_info->pixels=nexus_info->cache; nexus_info->metacontent=(void ) NULL; if (cache_info->metacontent_extent != 0) nexus_info->metacontent=(void ) (nexus_info->pixels+number_pixels cache_info->number_channels); PrefetchPixelCacheNexusPixels(nexus_info,mode); nexus_info->authentic_pixel_cache=IsPixelCacheAuthentic(cache_info, nexus_info); return(nexus_info->pixels); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % S e t P i x e l C a c h e V i r t u a l M e t h o d % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % SetPixelCacheVirtualMethod() sets the "virtual pixels" method for the % pixel cache 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 SetPixelCacheVirtualMethod() method is: % % VirtualPixelMethod SetPixelCacheVirtualMethod(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. % / static MagickBooleanType SetCacheAlphaChannel(Image image,const Quantum alpha, ExceptionInfo exception) { CacheInfo magick_restrict cache_info; CacheView magick_restrict 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); assert(image->cache != (Cache) NULL); cache_info=(CacheInfo ) image->cache; assert(cache_info->signature == MagickCoreSignature); image->alpha_trait=BlendPixelTrait; status=MagickTrue; image_view=AcquireVirtualCacheView(image,exception); / must be virtual / #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); } status=SyncCacheViewAuthenticPixels(image_view,exception); } image_view=DestroyCacheView(image_view); return(status); } MagickPrivate VirtualPixelMethod SetPixelCacheVirtualMethod(Image image, const VirtualPixelMethod virtual_pixel_method,ExceptionInfo exception) { CacheInfo magick_restrict cache_info; VirtualPixelMethod method; assert(image != (Image ) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(image->cache != (Cache) NULL); cache_info=(CacheInfo ) image->cache; assert(cache_info->signature == MagickCoreSignature); method=cache_info->virtual_pixel_method; cache_info->virtual_pixel_method=virtual_pixel_method; if ((image->columns != 0) && (image->rows != 0)) switch (virtual_pixel_method) { case BackgroundVirtualPixelMethod: { if ((image->background_color.alpha_trait != UndefinedPixelTrait) && (image->alpha_trait == UndefinedPixelTrait)) (void) SetCacheAlphaChannel(image,OpaqueAlpha,exception); if ((IsPixelInfoGray(&image->background_color) == MagickFalse) && (IsGrayColorspace(image->colorspace) != MagickFalse)) (void) SetImageColorspace(image,sRGBColorspace,exception); break; } case TransparentVirtualPixelMethod: { if (image->alpha_trait == UndefinedPixelTrait) (void) SetCacheAlphaChannel(image,OpaqueAlpha,exception); break; } default: break; } return(method); } #if defined(MAGICKCORE_OPENCL_SUPPORT) /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + S y n c A u t h e n t i c O p e n C L B u f f e r % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % SyncAuthenticOpenCLBuffer() makes sure that all the OpenCL operations have % been completed and updates the host memory. % % The format of the SyncAuthenticOpenCLBuffer() method is: % % void SyncAuthenticOpenCLBuffer(const Image image) % % A description of each parameter follows: % % o image: the image. % / static void CopyOpenCLBuffer(CacheInfo magick_restrict cache_info) { assert(cache_info != (CacheInfo ) NULL); assert(cache_info->signature == MagickCoreSignature); if ((cache_info->type != MemoryCache) \|\| (cache_info->opencl == (MagickCLCacheInfo) NULL)) return; /* Ensure single threaded access to OpenCL environment. / LockSemaphoreInfo(cache_info->semaphore); cache_info->opencl=CopyMagickCLCacheInfo(cache_info->opencl); UnlockSemaphoreInfo(cache_info->semaphore); } MagickPrivate void SyncAuthenticOpenCLBuffer(const Image image) { CacheInfo magick_restrict cache_info; assert(image != (const Image ) NULL); cache_info=(CacheInfo ) image->cache; CopyOpenCLBuffer(cache_info); } #endif / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + S y n c A u t h e n t i c P i x e l C a c h e N e x u s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % SyncAuthenticPixelCacheNexus() saves the authentic image pixels to the % in-memory or disk cache. The method returns MagickTrue if the pixel region % is synced, otherwise MagickFalse. % % The format of the SyncAuthenticPixelCacheNexus() method is: % % MagickBooleanType SyncAuthenticPixelCacheNexus(Image image, % NexusInfo nexus_info,ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o nexus_info: the cache nexus to sync. % % o exception: return any errors or warnings in this structure. % / MagickPrivate MagickBooleanType SyncAuthenticPixelCacheNexus(Image image, NexusInfo magick_restrict nexus_info,ExceptionInfo exception) { CacheInfo magick_restrict cache_info; MagickBooleanType status; /* Transfer pixels to the cache. / assert(image != (Image ) NULL); assert(image->signature == MagickCoreSignature); if (image->cache == (Cache) NULL) ThrowBinaryException(CacheError,"PixelCacheIsNotOpen",image->filename); cache_info=(CacheInfo ) image->cache; assert(cache_info->signature == MagickCoreSignature); if (cache_info->type == UndefinedCache) return(MagickFalse); if (image->mask_trait != UpdatePixelTrait) { if (((image->channels & WriteMaskChannel) != 0) && (ClipPixelCacheNexus(image,nexus_info,exception) == MagickFalse)) return(MagickFalse); if (((image->channels & CompositeMaskChannel) != 0) && (MaskPixelCacheNexus(image,nexus_info,exception) == MagickFalse)) return(MagickFalse); } if (nexus_info->authentic_pixel_cache != MagickFalse) { image->taint=MagickTrue; return(MagickTrue); } assert(cache_info->signature == MagickCoreSignature); status=WritePixelCachePixels(cache_info,nexus_info,exception); if ((cache_info->metacontent_extent != 0) && (WritePixelCacheMetacontent(cache_info,nexus_info,exception) == MagickFalse)) return(MagickFalse); if (status != MagickFalse) image->taint=MagickTrue; return(status); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + S y n c A u t h e n t i c P i x e l C a c h e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % SyncAuthenticPixelsCache() saves the authentic image pixels to the in-memory % or disk cache. The method returns MagickTrue if the pixel region is synced, % otherwise MagickFalse. % % The format of the SyncAuthenticPixelsCache() method is: % % MagickBooleanType SyncAuthenticPixelsCache(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 MagickBooleanType SyncAuthenticPixelsCache(Image image, ExceptionInfo exception) { CacheInfo magick_restrict cache_info; const int id = GetOpenMPThreadId(); MagickBooleanType status; assert(image != (Image ) NULL); assert(image->signature == MagickCoreSignature); assert(image->cache != (Cache) NULL); cache_info=(CacheInfo ) image->cache; assert(cache_info->signature == MagickCoreSignature); assert(id < (int) cache_info->number_threads); status=SyncAuthenticPixelCacheNexus(image,cache_info->nexus_info[id], exception); return(status); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % S y n c A u t h e n t i c P i x e l s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % SyncAuthenticPixels() saves the image pixels to the in-memory or disk cache. % The method returns MagickTrue if the pixel region is flushed, otherwise % MagickFalse. % % The format of the SyncAuthenticPixels() method is: % % MagickBooleanType SyncAuthenticPixels(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 SyncAuthenticPixels(Image image, ExceptionInfo exception) { CacheInfo magick_restrict cache_info; const int id = GetOpenMPThreadId(); MagickBooleanType status; assert(image != (Image ) NULL); assert(image->signature == MagickCoreSignature); assert(image->cache != (Cache) NULL); cache_info=(CacheInfo ) image->cache; assert(cache_info->signature == MagickCoreSignature); if (cache_info->methods.sync_authentic_pixels_handler != (SyncAuthenticPixelsHandler) NULL) { status=cache_info->methods.sync_authentic_pixels_handler(image, exception); return(status); } assert(id < (int) cache_info->number_threads); status=SyncAuthenticPixelCacheNexus(image,cache_info->nexus_info[id], exception); return(status); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + S y n c I m a g e P i x e l C a c h e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % SyncImagePixelCache() saves the image pixels to the in-memory or disk cache. % The method returns MagickTrue if the pixel region is flushed, otherwise % MagickFalse. % % The format of the SyncImagePixelCache() method is: % % MagickBooleanType SyncImagePixelCache(Image image, % ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o exception: return any errors or warnings in this structure. % / MagickPrivate MagickBooleanType SyncImagePixelCache(Image image, ExceptionInfo exception) { CacheInfo magick_restrict cache_info; assert(image != (Image ) NULL); assert(exception != (ExceptionInfo ) NULL); cache_info=(CacheInfo ) GetImagePixelCache(image,MagickTrue,exception); return(cache_info == (CacheInfo ) NULL ? MagickFalse : MagickTrue); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + W r i t e P i x e l C a c h e M e t a c o n t e n t % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % WritePixelCacheMetacontent() writes the meta-content to the specified region % of the pixel cache. % % The format of the WritePixelCacheMetacontent() method is: % % MagickBooleanType WritePixelCacheMetacontent(CacheInfo cache_info, % NexusInfo nexus_info,ExceptionInfo exception) % % A description of each parameter follows: % % o cache_info: the pixel cache. % % o nexus_info: the cache nexus to write the meta-content. % % o exception: return any errors or warnings in this structure. % / static MagickBooleanType WritePixelCacheMetacontent(CacheInfo cache_info, NexusInfo magick_restrict nexus_info,ExceptionInfo exception) { MagickOffsetType count, offset; MagickSizeType extent, length; register const unsigned char magick_restrict p; register ssize_t y; size_t rows; if (cache_info->metacontent_extent == 0) return(MagickFalse); if (nexus_info->authentic_pixel_cache != MagickFalse) return(MagickTrue); offset=(MagickOffsetType) nexus_info->region.ycache_info->columns+ nexus_info->region.x; length=(MagickSizeType) nexus_info->region.width cache_info->metacontent_extent; extent=(MagickSizeType) lengthnexus_info->region.height; rows=nexus_info->region.height; y=0; p=(unsigned char ) nexus_info->metacontent; switch (cache_info->type) { case MemoryCache: case MapCache: { register unsigned char magick_restrict q; / Write associated pixels to memory. / if ((cache_info->columns == nexus_info->region.width) && (extent == (MagickSizeType) ((size_t) extent))) { length=extent; rows=1UL; } q=(unsigned char ) cache_info->metacontent+offset* cache_info->metacontent_extent; for (y=0; y < (ssize_t) rows; y++) { (void) memcpy(q,p,(size_t) length); p+=nexus_info->region.widthcache_info->metacontent_extent; q+=cache_info->columnscache_info->metacontent_extent; } break; } case DiskCache: { /* Write associated pixels to disk. / LockSemaphoreInfo(cache_info->file_semaphore); if (OpenPixelCacheOnDisk(cache_info,IOMode) == MagickFalse) { ThrowFileException(exception,FileOpenError,"UnableToOpenFile", cache_info->cache_filename); UnlockSemaphoreInfo(cache_info->file_semaphore); return(MagickFalse); } if ((cache_info->columns == nexus_info->region.width) && (extent <= MagickMaxBufferExtent)) { length=extent; rows=1UL; } extent=(MagickSizeType) cache_info->columnscache_info->rows; for (y=0; y < (ssize_t) rows; y++) { count=WritePixelCacheRegion(cache_info,cache_info->offset+extent* cache_info->number_channelssizeof(Quantum)+offset cache_info->metacontent_extent,length,(const unsigned char ) p); if (count != (MagickOffsetType) length) break; p+=cache_info->metacontent_extentnexus_info->region.width; offset+=cache_info->columns; } if (IsFileDescriptorLimitExceeded() != MagickFalse) (void) ClosePixelCacheOnDisk(cache_info); UnlockSemaphoreInfo(cache_info->file_semaphore); break; } case DistributedCache: { RectangleInfo region; /* Write metacontent to distributed cache. / LockSemaphoreInfo(cache_info->file_semaphore); region=nexus_info->region; if ((cache_info->columns != nexus_info->region.width) \|\| (extent > MagickMaxBufferExtent)) region.height=1UL; else { length=extent; rows=1UL; } for (y=0; y < (ssize_t) rows; y++) { count=WriteDistributePixelCacheMetacontent((DistributeCacheInfo ) cache_info->server_info,&region,length,(const unsigned char ) p); if (count != (MagickOffsetType) length) break; p+=cache_info->metacontent_extentnexus_info->region.width; region.y++; } UnlockSemaphoreInfo(cache_info->file_semaphore); break; } default: break; } if (y < (ssize_t) rows) { ThrowFileException(exception,CacheError,"UnableToWritePixelCache", cache_info->cache_filename); return(MagickFalse); } if ((cache_info->debug != MagickFalse) && (CacheTick(nexus_info->region.y,cache_info->rows) != MagickFalse)) (void) LogMagickEvent(CacheEvent,GetMagickModule(), "%s[%.20gx%.20g%+.20g%+.20g]",cache_info->filename,(double) nexus_info->region.width,(double) nexus_info->region.height,(double) nexus_info->region.x,(double) nexus_info->region.y); return(MagickTrue); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + W r i t e C a c h e P i x e l s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % WritePixelCachePixels() writes image pixels to the specified region of the % pixel cache. % % The format of the WritePixelCachePixels() method is: % % MagickBooleanType WritePixelCachePixels(CacheInfo cache_info, % NexusInfo nexus_info,ExceptionInfo exception) % % A description of each parameter follows: % % o cache_info: the pixel cache. % % o nexus_info: the cache nexus to write the pixels. % % o exception: return any errors or warnings in this structure. % / static MagickBooleanType WritePixelCachePixels( CacheInfo magick_restrict cache_info,NexusInfo magick_restrict nexus_info, ExceptionInfo exception) { MagickOffsetType count, offset; MagickSizeType extent, length; register const Quantum magick_restrict p; register ssize_t y; size_t rows; if (nexus_info->authentic_pixel_cache != MagickFalse) return(MagickTrue); offset=(MagickOffsetType) nexus_info->region.ycache_info->columns+ nexus_info->region.x; length=(MagickSizeType) cache_info->number_channelsnexus_info->region.width* sizeof(Quantum); extent=lengthnexus_info->region.height; rows=nexus_info->region.height; y=0; p=nexus_info->pixels; switch (cache_info->type) { case MemoryCache: case MapCache: { register Quantum magick_restrict q; /* Write pixels to memory. / if ((cache_info->columns == nexus_info->region.width) && (extent == (MagickSizeType) ((size_t) extent))) { length=extent; rows=1UL; } q=cache_info->pixels+offsetcache_info->number_channels; for (y=0; y < (ssize_t) rows; y++) { (void) memcpy(q,p,(size_t) length); p+=cache_info->number_channelsnexus_info->region.width; q+=cache_info->number_channelscache_info->columns; } break; } case DiskCache: { /* Write pixels to disk. / LockSemaphoreInfo(cache_info->file_semaphore); if (OpenPixelCacheOnDisk(cache_info,IOMode) == MagickFalse) { ThrowFileException(exception,FileOpenError,"UnableToOpenFile", cache_info->cache_filename); UnlockSemaphoreInfo(cache_info->file_semaphore); return(MagickFalse); } if ((cache_info->columns == nexus_info->region.width) && (extent <= MagickMaxBufferExtent)) { length=extent; rows=1UL; } for (y=0; y < (ssize_t) rows; y++) { count=WritePixelCacheRegion(cache_info,cache_info->offset+offset cache_info->number_channelssizeof(p),length,(const unsigned char ) p); if (count != (MagickOffsetType) length) break; p+=cache_info->number_channelsnexus_info->region.width; offset+=cache_info->columns; } if (IsFileDescriptorLimitExceeded() != MagickFalse) (void) ClosePixelCacheOnDisk(cache_info); UnlockSemaphoreInfo(cache_info->file_semaphore); break; } case DistributedCache: { RectangleInfo region; /* Write pixels to distributed cache. / LockSemaphoreInfo(cache_info->file_semaphore); region=nexus_info->region; if ((cache_info->columns != nexus_info->region.width) \|\| (extent > MagickMaxBufferExtent)) region.height=1UL; else { length=extent; rows=1UL; } for (y=0; y < (ssize_t) rows; y++) { count=WriteDistributePixelCachePixels((DistributeCacheInfo ) cache_info->server_info,&region,length,(const unsigned char ) p); if (count != (MagickOffsetType) length) break; p+=cache_info->number_channelsnexus_info->region.width; region.y++; } UnlockSemaphoreInfo(cache_info->file_semaphore); break; } default: break; } if (y < (ssize_t) rows) { ThrowFileException(exception,CacheError,"UnableToWritePixelCache", cache_info->cache_filename); return(MagickFalse); } if ((cache_info->debug != MagickFalse) && (CacheTick(nexus_info->region.y,cache_info->rows) != MagickFalse)) (void) LogMagickEvent(CacheEvent,GetMagickModule(), "%s[%.20gx%.20g%+.20g%+.20g]",cache_info->filename,(double) nexus_info->region.width,(double) nexus_info->region.height,(double) nexus_info->region.x,(double) nexus_info->region.y); return(MagickTrue); }
task_multiple_producer_omp.c	/* -- Mode: C; c-basic-offset:4 ; indent-tabs-mode:nil ; -- / / * See LICENSE.txt in top-level directory. / #include <assert.h> #include <omp.h> #include <stdio.h> #include <stdlib.h> #include <unistd.h> #define NUM_TASKS 5000000 #define NUM_REPS 1 #define USLEEP usleep(100); / Pragma omp task directive evaluation * Output: avg time / void sscal(float value, float a) { a = a * value; } int main(int argc, char argv[]) { int i, r, nthreads; double time, avg_time = 0.0; char str, endptr; float a; #pragma omp parallel { #pragma omp master { nthreads = omp_get_num_threads(); } } if (argc > 1) { str = argv[1]; } int ntasks = argc > 1 ? strtoll(str, &endptr, 10) : NUM_TASKS; if (ntasks < nthreads) { ntasks = nthreads; } int rep = (argc > 2) ? atoi(argv[2]) : NUM_REPS; time = malloc(sizeof(double) (rep + 1)); a = malloc(sizeof(float) * ntasks); for (i = 0; i < ntasks; i++) { a[i] = i + 100.0f; } for (r = 0; r < rep; r++) { time[r] = omp_get_wtime(); #pragma omp parallel { time[1] = omp_get_wtime(); #pragma omp for for (i = 0; i < ntasks; i++) { #pragma omp task firstprivate(i) { sscal(0.9f, &a[i]); } } time[1] = (omp_get_wtime() - time[1]); } time[r] = omp_get_wtime() - time[r]; avg_time += time[r]; } for (i = 0; i < ntasks; i++) { if (a[i] != (i + 100.0f) * 0.9f) { printf("error: a[%d]=%.2f expected %.2f\n", i, a[i], (i + 100.0f) * 0.9f); } } avg_time /= rep; printf("nthreads: %d\nntasks: %d\nTime(s):%f\nCreation Time: %f\n", nthreads, ntasks, avg_time, time[1]); return EXIT_SUCCESS; }
flowinfo_ipv4_dst.c	/* * Copyright 2014-2017 Nippon Telegraph and Telephone Corporation. * * 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. / /* * @file flowinfo_ipv4_dst.c * @brief Optimized flow database for dataplane, for ipv4_dst / #include <stdlib.h> #include "openflow.h" #include "lagopus_apis.h" #include "lagopus/flowdb.h" #include "pktbuf.h" #include "packet.h" #include "lagopus/flowinfo.h" #define OXM_FIELD_TYPE(field) ((field) >> 1) #define IPV4_DST_BITLEN (32) static lagopus_result_t add_flow_ipv4_dst_mask(struct flowinfo , struct flow ); static lagopus_result_t del_flow_ipv4_dst_mask(struct flowinfo , struct flow ); static struct flow match_flow_ipv4_dst_mask(struct flowinfo , struct lagopus_packet , int32_t ); static struct flow find_flow_ipv4_dst_mask(struct flowinfo , struct flow ); static void destroy_flowinfo_ipv4_dst_mask(struct flowinfo ); static lagopus_result_t add_flow_ipv4_dst(struct flowinfo , struct flow ); static lagopus_result_t del_flow_ipv4_dst(struct flowinfo , struct flow ); static struct flow match_flow_ipv4_dst(struct flowinfo , struct lagopus_packet , int32_t ); static struct flow find_flow_ipv4_dst(struct flowinfo , struct flow ); static void destroy_flowinfo_ipv4_dst(struct flowinfo ); static lagopus_result_t get_match_ipv4_dst(const struct match_list match_list, uint32_t ipv4_dst, uint32_t mask) { const struct match match; TAILQ_FOREACH(match, match_list, entry) { if (match->oxm_field == (OFPXMT_OFB_IPV4_DST << 1) + 1) { OS_MEMCPY(ipv4_dst, match->oxm_value, sizeof(ipv4_dst)); OS_MEMCPY(mask, &match->oxm_value[4], sizeof(mask)); break; } if (OXM_FIELD_TYPE(match->oxm_field) == OFPXMT_OFB_IPV4_DST) { OS_MEMCPY(ipv4_dst, match->oxm_value, sizeof(ipv4_dst)); mask = 0xffffffff; break; } } if (match == NULL) { return LAGOPUS_RESULT_NOT_FOUND; } return LAGOPUS_RESULT_OK; } struct flowinfo new_flowinfo_ipv4_dst_mask(void) { struct flowinfo self; self = calloc(1, sizeof(struct flowinfo)); if (self != NULL) { self->nflow = 0; self->nnext = 0; self->next = malloc(1); self->misc = new_flowinfo_ipv4_src_mask(); self->add_func = add_flow_ipv4_dst_mask; self->del_func = del_flow_ipv4_dst_mask; self->match_func = match_flow_ipv4_dst_mask; self->find_func = find_flow_ipv4_dst_mask; self->destroy_func = destroy_flowinfo_ipv4_dst_mask; } return self; } static void destroy_flowinfo_ipv4_dst_mask(struct flowinfo self) { struct flowinfo flowinfo; unsigned int i; for (i = 0; i < self->nnext; i++) { flowinfo = self->next[i]; flowinfo->destroy_func(flowinfo); } free(self->next); free(self); } static void freeup_flowinfo(void val) { struct flowinfo flowinfo; flowinfo = val; flowinfo->destroy_func(flowinfo); } struct flowinfo new_flowinfo_ipv4_dst(void) { struct flowinfo self; self = calloc(1, sizeof(struct flowinfo)); if (self != NULL) { lagopus_hashmap_create(&self->hashmap, LAGOPUS_HASHMAP_TYPE_ONE_WORD, freeup_flowinfo); / misc is not used / self->add_func = add_flow_ipv4_dst; self->del_func = del_flow_ipv4_dst; self->match_func = match_flow_ipv4_dst; self->find_func = find_flow_ipv4_dst; self->destroy_func = destroy_flowinfo_ipv4_dst; } return self; } static void destroy_flowinfo_ipv4_dst(struct flowinfo self) { lagopus_hashmap_destroy(&self->hashmap, true); free(self); } static lagopus_result_t add_flow_ipv4_dst_mask(struct flowinfo self, struct flow flow) { struct flowinfo flowinfo; uint32_t ipv4_dst, mask; lagopus_result_t rv; unsigned int i; rv = get_match_ipv4_dst(&flow->match_list, &ipv4_dst, &mask); if (rv == LAGOPUS_RESULT_OK) { rv = LAGOPUS_RESULT_NOT_FOUND; for (i = 0; i < self->nnext; i++) { if (self->next[i]->userdata == mask) { flowinfo = self->next[i]; rv = LAGOPUS_RESULT_OK; break; } } if (rv == LAGOPUS_RESULT_NOT_FOUND) { / new node. / flowinfo = new_flowinfo_ipv4_dst(); flowinfo->userdata = mask; self->next = realloc(self->next, (unsigned long)(self->nnext + 1) sizeof(struct flowinfo )); self->next[self->nnext] = flowinfo; self->nnext++; } rv = flowinfo->add_func(flowinfo, flow); } else { rv = self->misc->add_func(self->misc, flow); } if (rv == LAGOPUS_RESULT_OK) { self->nflow++; } return rv; } static lagopus_result_t del_flow_ipv4_dst_mask(struct flowinfo self, struct flow flow) { struct flowinfo flowinfo; uint32_t ipv4_dst, mask; lagopus_result_t rv; unsigned int i; rv = get_match_ipv4_dst(&flow->match_list, &ipv4_dst, &mask); if (rv == LAGOPUS_RESULT_OK) { rv = LAGOPUS_RESULT_NOT_FOUND; for (i = 0; i < self->nnext; i++) { if (self->next[i]->userdata == mask) { flowinfo = self->next[i]; rv = LAGOPUS_RESULT_OK; break; } } if (rv == LAGOPUS_RESULT_NOT_FOUND) { return LAGOPUS_RESULT_NOT_FOUND; } rv = flowinfo->del_func(flowinfo, flow); if (flowinfo->nflow == 0) { flowinfo->destroy_func(flowinfo); self->nnext--; memmove(&self->next[i], &self->next[i + 1], (self->nnext - i) * sizeof(struct flowinfo *)); } } else { rv = self->misc->del_func(self->misc, flow); } if (rv == LAGOPUS_RESULT_OK) { self->nflow--; } return rv; } static struct flow match_flow_ipv4_dst_mask(struct flowinfo self, struct lagopus_packet pkt, int32_t pri) { struct flowinfo flowinfo; struct flow flow[self->nnext], matched, alt_flow; struct flow mismatched = { .priority = 0, .flags = 0, .idle_timeout = 0, .hard_timeout = 0, .match_list = {NULL, NULL}, .instruction_list = {NULL, NULL}, .field_bits = 0 }; unsigned int i; matched = &mismatched; //#pragma omp parallel for for (i = 0; i < self->nnext; i++) { flowinfo = self->next[i]; flow[i] = flowinfo->match_func(flowinfo, pkt, pri); } for (i = 0; i < self->nnext; i++) { if (flow[i] != NULL && flow[i]->priority > matched->priority) { matched = flow[i]; } } alt_flow = self->misc->match_func(self->misc, pkt, pri); if (alt_flow != NULL) { matched = alt_flow; } if (matched == &mismatched) { matched = NULL; } return matched; } static struct flow find_flow_ipv4_dst_mask(struct flowinfo self, struct flow flow) { struct flowinfo flowinfo; uint32_t ipv4_dst, mask; lagopus_result_t rv; unsigned int i; rv = get_match_ipv4_dst(&flow->match_list, &ipv4_dst, &mask); if (rv == LAGOPUS_RESULT_OK) { rv = LAGOPUS_RESULT_NOT_FOUND; for (i = 0; i < self->nnext; i++) { if (self->next[i]->userdata == mask) { flowinfo = self->next[i]; rv = LAGOPUS_RESULT_OK; break; } } if (rv == LAGOPUS_RESULT_NOT_FOUND) { return NULL; } } else { flowinfo = self->misc; } return flowinfo->find_func(flowinfo, flow); } static lagopus_result_t add_flow_ipv4_dst(struct flowinfo self, struct flow flow) { struct flowinfo flowinfo; uint32_t ipv4_dst, mask; lagopus_result_t rv; rv = get_match_ipv4_dst(&flow->match_list, &ipv4_dst, &mask); if (rv == LAGOPUS_RESULT_OK) { rv = lagopus_hashmap_find_no_lock(&self->hashmap, (void )ipv4_dst, (void )&flowinfo); if (rv != LAGOPUS_RESULT_OK) { void val; flowinfo = new_flowinfo_ipv4(); val = flowinfo; lagopus_hashmap_add_no_lock(&self->hashmap, (void )ipv4_dst, (void )&val, false); } rv = flowinfo->add_func(flowinfo, flow); if (rv == LAGOPUS_RESULT_OK) { self->nflow++; } } return rv; } static lagopus_result_t del_flow_ipv4_dst(struct flowinfo self, struct flow flow) { uint32_t ipv4_dst, mask; lagopus_result_t rv; rv = get_match_ipv4_dst(&flow->match_list, &ipv4_dst, &mask); if (rv == LAGOPUS_RESULT_OK) { struct flowinfo flowinfo; rv = lagopus_hashmap_find_no_lock(&self->hashmap, (void )ipv4_dst, (void )&flowinfo); if (rv == LAGOPUS_RESULT_OK) { flowinfo->del_func(flowinfo, flow); } if (rv == LAGOPUS_RESULT_OK) { self->nflow--; } } return rv; } static struct flow * match_flow_ipv4_dst(struct flowinfo self, struct lagopus_packet pkt, int32_t pri) { struct flowinfo flowinfo; uint32_t ipv4_dst; struct flow flow; lagopus_result_t rv; flow = NULL; ipv4_dst = (pkt->ipv4->ip_dst.s_addr & (uint32_t)self->userdata); rv = lagopus_hashmap_find_no_lock(&self->hashmap, (void )ipv4_dst, (void )&flowinfo); if (rv == LAGOPUS_RESULT_OK) { flow = flowinfo->match_func(flowinfo, pkt, pri); } return flow; } static struct flow find_flow_ipv4_dst(struct flowinfo self, struct flow flow) { struct flowinfo flowinfo; uint32_t ipv4_dst, mask; lagopus_result_t rv; rv = get_match_ipv4_dst(&flow->match_list, &ipv4_dst, &mask); if (rv == LAGOPUS_RESULT_OK) { rv = lagopus_hashmap_find_no_lock(&self->hashmap, (void )ipv4_dst, (void *)&flowinfo); if (rv != LAGOPUS_RESULT_OK) { return NULL; } return flowinfo->find_func(flowinfo, flow); } else { return self->misc->find_func(self->misc, flow); } }
Functions.h	// // smarties // Copyright (c) 2018 CSE-Lab, ETH Zurich, Switzerland. All rights reserved. // Distributed under the terms of the MIT license. // // Created by Guido Novati (novatig@ethz.ch). // #ifndef smarties_Function_h #define smarties_Function_h #include "../../Utils/FunctionUtilities.h" #include "../../Utils/Warnings.h" #include <memory> #ifndef PRELU_FAC #define PRELU_FAC 0.1 #endif //List of non-linearities for neural networks //- eval return f(in), also present as array in / array out //- evalDiff returns f'(x) //- initFactor: some prefer fan in fan out, some only fan-in dependency //If adding a new function, edit function readFunction at end of file namespace smarties { struct Function { //weights are initialized with uniform distrib [-weightsInitFactor, weightsInitFactor] virtual Real initFactor(const Uint inps, const Uint outs) const = 0; virtual void eval(const nnRealconst in, nnRealconst out, const Uint N) const = 0; // f(in) virtual nnReal eval(const nnReal in) const = 0; virtual nnReal inverse(const nnReal in) const = 0; // f(in) virtual nnReal evalDiff(const nnReal in, const nnReal out) const = 0; // f'(in) virtual std::string name() const = 0; virtual ~Function() {} }; struct Linear : public Function { std::string name() const override { return "Linear";} Real initFactor(const Uint inps, const Uint outs) const override { return std::sqrt(1./inps); } static Real _initFactor(const Uint inps, const Uint outs) { return std::sqrt(1./inps); } void eval(const nnRealconst in, nnRealconst out, const Uint N) const override { memcpy(out, in, Nsizeof(nnReal)); } static void _eval(const nnRealconst in, nnRealconst out, const Uint N) { memcpy(out, in, Nsizeof(nnReal)); } template <typename T> static T _eval(const T in) { return in; } template <typename T> static T _evalDiff(const T in, const T out) { return 1; } nnReal eval(const nnReal in) const override { return in; } nnReal inverse(const nnReal in) const override { return in; } nnReal evalDiff(const nnReal in, const nnReal out) const override { return 1; } }; struct Tanh : public Function { std::string name() const override { return "Tanh"; } Real initFactor(const Uint inps, const Uint outs) const override { return std::sqrt(6./(inps + outs)); } static Real _initFactor(const Uint inps, const Uint outs) { return std::sqrt(6./(inps + outs)); } template <typename T> static T _eval(const T in) { if(in > 0) { const T e2x = std::exp(-2in); return (1-e2x)/(1+e2x); } else { const T e2x = std::exp( 2in); return (e2x-1)/(1+e2x); } } template <typename T> static T _evalDiff(const T in, const T out) { return 1 - outout; } static void _eval(const nnRealconst in, nnRealconst out, const Uint N) { for(Uint i=0; i<N; ++i) out[i] = _eval(in[i]); } void eval(const nnRealconst in, nnRealconst out, const Uint N) const override { for(Uint i=0; i<N; ++i) out[i] = _eval(in[i]); } nnReal eval(const nnReal in) const override { return _eval(in); } nnReal inverse(const nnReal in) const override { assert(std::fabs(in)<1); return std::log((1+in)/(1-in)) / 2; } nnReal evalDiff(const nnReal in, const nnReal out) const override { return _evalDiff(in, out); } }; struct Sigm : public Function { std::string name() const override { return "Sigm";} Real initFactor(const Uint inps, const Uint outs) const override { return std::sqrt(6./(inps + outs)); } static Real _initFactor(const Uint inps, const Uint outs) { return std::sqrt(6./(inps + outs)); } template <typename T> static T _eval(const T in) { if(in > 0) return 1/(1+Utilities::safeExp(-in)); else { const T ex = Utilities::safeExp(in); return ex/(1+ex); } } template <typename T> static T _inv(const T in) { assert(in > 0 && in < 1); return - std::log(1/in - 1); } template <typename T> static T _evalDiff(const T in) { const T expx = Utilities::safeExp(in); return expx / std::pow(expx+1, 2); } template <typename T> static T _evalDiff(const T in, const T out) { return out(1-out); } static void _eval(const nnRealconst in, nnRealconst out, const Uint N) { for(Uint i=0; i<N; ++i) out[i] = _eval(in[i]); } void eval(const nnRealconst in, nnRealconst out, const Uint N) const override { for(Uint i=0; i<N; ++i) out[i] = _eval(in[i]); } nnReal eval(const nnReal in) const override { return _eval(in); } nnReal inverse(const nnReal in) const override { return _inv(in); } nnReal evalDiff(const nnReal in, const nnReal out) const override { return _evalDiff(in, out); } }; struct HardSign : public Function { std::string name() const override { return "HardSign";} Real initFactor(const Uint inps, const Uint outs) const override { return std::sqrt(6./(inps + outs)); } static Real _initFactor(const Uint inps, const Uint outs) { return std::sqrt(6./(inps + outs)); } template <typename T> static T _eval(const T in) { return in/std::sqrt(1+inin); } template <typename T> static T _evalDiff(const T in, const T out) { const T denom = std::sqrt(1+inin); return 1/(denomdenomdenom); } static void _eval(const nnRealconst in, nnRealconst out, const Uint N) { #pragma omp simd aligned(in,out : VEC_WIDTH) for (Uint i=0; i<N; ++i) out[i] = in[i]/std::sqrt(1+in[i]in[i]); } void eval(const nnRealconst in, nnRealconst out, const Uint N) const override { return _eval(in, out, N); } nnReal eval(const nnReal in) const override { return _eval(in); } nnReal inverse(const nnReal in) const override { assert(in > 0 && in < 1); return in/std::sqrt(1 -inin); } nnReal evalDiff(const nnReal in, const nnReal out) const override { return _evalDiff(in, out); } }; struct HardSigmoid : public Function { std::string name() const override { return "HardSigmoid";} Real initFactor(const Uint inps, const Uint outs) const override { return std::sqrt(6./(inps + outs)); } static Real _initFactor(const Uint inps, const Uint outs) { return std::sqrt(6./(inps + outs)); } template <typename T> static T _eval(const T x) { return 0.5 * (1 + x/std::sqrt(1+xx)); } template <typename T> static T _evalDiff(const T x, const T y) { const T denom = std::sqrt(1+xx); return 0.5/(denomdenomdenom); } template <typename T> static T _evalDiff(const T x) { const T denom = std::sqrt(1+xx); return 0.5/(denomdenomdenom); } template <typename T> static T _inv(const T y) { assert(y > 0 && y < 1); const Real map = 2 y - 1; return map/std::sqrt(1 -mapmap); } static void _eval(const nnRealconst in, nnRealconst out, const Uint N) { #pragma omp simd aligned(in,out : VEC_WIDTH) for (Uint i=0; i<N; ++i) out[i] = _eval(in[i]); } void eval(const nnRealconst in, nnRealconst out, const Uint N) const override { return _eval(in, out, N); } nnReal eval(const nnReal in) const override { return _eval(in); } nnReal inverse(const nnReal y) const override { return _inv(y); } nnReal evalDiff(const nnReal in, const nnReal out) const override { return _evalDiff(in, out); } }; struct SoftSign : public Function { std::string name() const override { return "SoftSign";} Real initFactor(const Uint inps, const Uint outs) const override { return std::sqrt(6.0/(inps + outs)); } static Real _initFactor(const Uint inps, const Uint outs) { return std::sqrt(6.0/(inps + outs)); } template <typename T> static T _eval(const T in) { return in/(1 + std::fabs(in)); } template <typename T> static T _evalDiff(const T in, const T out) { const T denom = 1 + std::fabs(in); return 1/(denomdenom); } static void _eval(const nnRealconst in, nnRealconst out, const Uint N) { #pragma omp simd aligned(in,out : VEC_WIDTH) for (Uint i=0;i<N; ++i) out[i] = _eval(in[i]); } void eval(const nnRealconst in, nnRealconst out, const Uint N) const override { return _eval(in, out, N); } nnReal eval(const nnReal in) const override { return _eval(in); } nnReal inverse(const nnReal in) const override { assert(in > 0 && in < 1); return in / (1 - std::fabs(in)); } nnReal evalDiff(const nnReal in, const nnReal out) const override { return _evalDiff(in, out); } }; struct SoftRBF : public Function { std::string name() const override { return "SoftRBF";} Real initFactor(const Uint inps, const Uint outs) const override { return std::sqrt(6.0/(inps + outs)); } static Real _initFactor(const Uint inps, const Uint outs) { return std::sqrt(6.0/(inps + outs)); } template <typename T> static T _eval(const T in) { return 1/(1 + in * in); } template <typename T> static T _evalDiff(const T in, const T out) { const T denom = 1 + in * in; return - 2 * in / (denom * denom); } static void _eval(const nnRealconst in, nnRealconst out, const Uint N) { #pragma omp simd aligned(in,out : VEC_WIDTH) for (Uint i=0;i<N; ++i) out[i] = _eval(in[i]); } void eval(const nnRealconst in, nnRealconst out, const Uint N) const override { return _eval(in, out, N); } nnReal eval(const nnReal in) const override { return _eval(in); } nnReal inverse(const nnReal in) const override { die("Not supported"); return in / (1 - std::fabs(in)); } nnReal evalDiff(const nnReal in, const nnReal out) const override { return _evalDiff(in, out); } }; struct Relu : public Function { std::string name() const override { return "Relu";} Real initFactor(const Uint inps, const Uint outs) const override { return std::sqrt(2./inps); } static Real _initFactor(const Uint inps, const Uint outs) { return std::sqrt(2./inps); } template <typename T> static T _eval(const T in) { return in>0 ? in : 0; } template <typename T> static T _evalDiff(const T in, const T out) { return in>0 ? 1 : 0; } static void _eval(const nnRealconst in, nnRealconst out, const Uint N) { #pragma omp simd aligned(in,out : VEC_WIDTH) for (Uint i=0;i<N; ++i) out[i] = in[i]>0 ? in[i] : 0; } void eval(const nnRealconst in, nnRealconst out, const Uint N) const override { return _eval(in, out, N); } nnReal eval(const nnReal in) const override { return _eval(in); } nnReal inverse(const nnReal in) const override { assert(in>=0); return in; } nnReal evalDiff(const nnReal in, const nnReal out) const override { return _evalDiff(in, out); } }; struct LRelu : public Function { std::string name() const override { return "LRelu";} Real initFactor(const Uint inps, const Uint outs) const override { return std::sqrt(1.0/inps); } static Real _initFactor(const Uint inps, const Uint outs) { return std::sqrt(1.0/inps); } template <typename T> static T _eval(const T in) { return in>0 ? in : PRELU_FACin; } template <typename T> static T _evalDiff(const T in, const T out) { return in>0 ? 1 : PRELU_FAC; } static void _eval(const nnRealconst in, nnRealconst out, const Uint N) { #pragma omp simd aligned(in,out : VEC_WIDTH) for (Uint i=0;i<N; ++i) out[i] = in[i]>0 ? in[i] : PRELU_FACin[i]; } void eval(const nnRealconst in, nnRealconst out, const Uint N) const override { return _eval(in, out, N); } nnReal eval(const nnReal in) const override { return _eval(in); } nnReal inverse(const nnReal in) const override { if(in >= 0) return in; else return in / PRELU_FAC; } nnReal evalDiff(const nnReal in, const nnReal out) const override { return _evalDiff(in, out); } }; struct ExpPlus : public Function { std::string name() const override { return "ExpPlus";} Real initFactor(const Uint inps, const Uint outs) const override { return std::sqrt(2./inps); } static Real _initFactor(const Uint inps, const Uint outs) { return std::sqrt(2./inps); } template <typename T> static T _inv(const T in) { return std::log(Utilities::safeExp(in) - 1); } // Used here, std::exp is trigger happy with nans, therefore we clip it // between exp(-32) and exp(16). template <typename T> static T _eval(const T in) { return std::log(1 + Utilities::safeExp(in)); } template <typename T> static T _evalDiff(const T in) { return 1/(1 + Utilities::safeExp(-in)); } template <typename T> static T _evalDiff(const T in, const T out) { return 1/(1 + Utilities::safeExp(-in)); } static void _eval(const nnRealconst in, nnRealconst out, const Uint N) { for(Uint i=0; i<N; ++i) out[i] = _eval(in[i]); } void eval(const nnRealconst in, nnRealconst out, const Uint N) const override { return _eval(in, out, N); } nnReal eval(const nnReal in) const override { return _eval(in); } nnReal inverse(const nnReal in) const override { return _inv(in); } nnReal evalDiff(const nnReal in, const nnReal out) const override { return _evalDiff(in, out); } }; struct SoftPlus : public Function { std::string name() const override { return "SoftPlus";} Real initFactor(const Uint inps, const Uint outs) const override { return std::sqrt(2./inps); } static Real _initFactor(const Uint inps, const Uint outs) { return std::sqrt(2./inps); } template <typename T> static T _eval(const T in) { return (in + std::sqrt(1+inin)) / 2; } template <typename T> static T _evalDiff(const T in) { return (1 + in/std::sqrt(1+inin)) / 2; } template <typename T> static T _evalDiff(const T in, const T out) { return (1 + in/std::sqrt(1+inin)) / 2; } template <typename T> static T _inv(const T in) { assert(in > 0); return (inin - (T)0.25)/in; } static void _eval(const nnRealconst in, nnRealconst out, const Uint N) { #pragma omp simd aligned(in,out : VEC_WIDTH) for (Uint i=0;i<N; ++i) out[i] = (in[i] + std::sqrt(1+in[i]in[i])) / 2; } void eval(const nnRealconst in, nnRealconst out, const Uint N) const override { return _eval(in, out, N); } nnReal eval(const nnReal in) const override { return _eval(in); } nnReal inverse(const nnReal in) const override { return _inv(in); } nnReal evalDiff(const nnReal in, const nnReal out) const override { return _evalDiff(in, out); } }; struct Exp : public Function { std::string name() const override { return "Exp";} Real initFactor(const Uint inps, const Uint outs) const override { return std::sqrt(2./inps); } static Real _initFactor(const Uint inps, const Uint outs) { return std::sqrt(2./inps); } template <typename T> static T _inv(const T in) { return std::log(in); } template <typename T> static T _eval(const T in) { return Utilities::nnSafeExp(in); } template <typename T> static T _evalDiff(const T in) { return Utilities::nnSafeExp(in); } template <typename T> static T _evalDiff(const T in, const T out) { return out; } static void _eval(const nnRealconst in, nnRealconst out, const Uint N) { for(Uint i=0; i<N; ++i) out[i] = Utilities::nnSafeExp(in[i]); } void eval(const nnRealconst in, nnReal*const out, const Uint N) const override { return _eval(in, out, N); } nnReal eval(const nnReal in) const override { return _eval(in); } nnReal inverse(const nnReal in) const override { assert(in > 0); return std::log(in); } nnReal evalDiff(const nnReal in, const nnReal out) const override { return _evalDiff(in, out); } }; inline std::unique_ptr<Function> makeFunction(const std::string name, const bool bOutput=false) { if (bOutput \|\| name == "Linear") return std::make_unique<Linear>(); else if (name == "Tanh") return std::make_unique<Tanh>(); else if (name == "Sigm") return std::make_unique<Sigm>(); else if (name == "HardSign") return std::make_unique<HardSign>(); else if (name == "SoftSign") return std::make_unique<SoftSign>(); else if (name == "Relu") return std::make_unique<Relu>(); else if (name == "LRelu") return std::make_unique<LRelu>(); else if (name == "ExpPlus") return std::make_unique<ExpPlus>(); else if (name == "SoftPlus") return std::make_unique<SoftPlus>(); else if (name == "Exp") return std::make_unique<Exp>(); else die("Activation function not recognized"); return std::make_unique<Linear>(); } } // end namespace smarties #endif // smarties_Quadratic_term_h
parser.c	/* C++ Parser. Copyright (C) 2000, 2001, 2002, 2003, 2004, 2005 Free Software Foundation, Inc. Written by Mark Mitchell <mark@codesourcery.com>. This file is part of GCC. GCC 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, or (at your option) any later version. GCC 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 GCC; see the file COPYING. If not, write to the Free Software Foundation, 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA. / #include "config.h" #include "system.h" #include "coretypes.h" #include "tm.h" #include "dyn-string.h" #include "varray.h" #include "cpplib.h" #include "tree.h" #include "cp-tree.h" #include "c-pragma.h" #include "decl.h" #include "flags.h" #include "diagnostic.h" #include "toplev.h" #include "output.h" #include "target.h" #include "cgraph.h" #include "c-common.h" / The lexer. / / The cp_lexer_* routines mediate between the lexer proper (in libcpp and c-lex.c) and the C++ parser. / / A token's value and its associated deferred access checks and qualifying scope. / struct tree_check GTY(()) { / The value associated with the token. / tree value; / The checks that have been associated with value. / VEC (deferred_access_check, gc) checks; /* The token's qualifying scope (used when it is a CPP_NESTED_NAME_SPECIFIER). / tree qualifying_scope; }; / A C++ token. / typedef struct cp_token GTY (()) { / The kind of token. / ENUM_BITFIELD (cpp_ttype) type : 8; / If this token is a keyword, this value indicates which keyword. Otherwise, this value is RID_MAX. / ENUM_BITFIELD (rid) keyword : 8; / Token flags. / unsigned char flags; / Identifier for the pragma. / ENUM_BITFIELD (pragma_kind) pragma_kind : 6; / True if this token is from a system header. / BOOL_BITFIELD in_system_header : 1; / True if this token is from a context where it is implicitly extern "C" / BOOL_BITFIELD implicit_extern_c : 1; / True for a CPP_NAME token that is not a keyword (i.e., for which KEYWORD is RID_MAX) iff this name was looked up and found to be ambiguous. An error has already been reported. / BOOL_BITFIELD ambiguous_p : 1; / The input file stack index at which this token was found. / unsigned input_file_stack_index : INPUT_FILE_STACK_BITS; / The value associated with this token, if any. / union cp_token_value { / Used for CPP_NESTED_NAME_SPECIFIER and CPP_TEMPLATE_ID. / struct tree_check GTY((tag ("1"))) tree_check_value; /* Use for all other tokens. / tree GTY((tag ("0"))) value; } GTY((desc ("(%1.type == CPP_TEMPLATE_ID) \|\| (%1.type == CPP_NESTED_NAME_SPECIFIER)"))) u; / The location at which this token was found. / location_t location; } cp_token; / We use a stack of token pointer for saving token sets. / typedef struct cp_token cp_token_position; DEF_VEC_P (cp_token_position); DEF_VEC_ALLOC_P (cp_token_position,heap); static const cp_token eof_token = { CPP_EOF, RID_MAX, 0, PRAGMA_NONE, 0, 0, false, 0, { NULL }, #if USE_MAPPED_LOCATION 0 #else {0, 0} #endif }; /* The cp_lexer structure represents the C++ lexer. It is responsible for managing the token stream from the preprocessor and supplying it to the parser. Tokens are never added to the cp_lexer after it is created. / typedef struct cp_lexer GTY (()) { / The memory allocated for the buffer. NULL if this lexer does not own the token buffer. / cp_token GTY ((length ("%h.buffer_length"))) buffer; /* If the lexer owns the buffer, this is the number of tokens in the buffer. / size_t buffer_length; / A pointer just past the last available token. The tokens in this lexer are [buffer, last_token). / cp_token_position GTY ((skip)) last_token; / The next available token. If NEXT_TOKEN is &eof_token, then there are no more available tokens. / cp_token_position GTY ((skip)) next_token; / A stack indicating positions at which cp_lexer_save_tokens was called. The top entry is the most recent position at which we began saving tokens. If the stack is non-empty, we are saving tokens. / VEC(cp_token_position,heap) GTY ((skip)) saved_tokens; /* The next lexer in a linked list of lexers. / struct cp_lexer next; /* True if we should output debugging information. / bool debugging_p; / True if we're in the context of parsing a pragma, and should not increment past the end-of-line marker. / bool in_pragma; } cp_lexer; / cp_token_cache is a range of tokens. There is no need to represent allocate heap memory for it, since tokens are never removed from the lexer's array. There is also no need for the GC to walk through a cp_token_cache, since everything in here is referenced through a lexer. / typedef struct cp_token_cache GTY(()) { / The beginning of the token range. / cp_token GTY((skip)) first; /* Points immediately after the last token in the range. / cp_token GTY ((skip)) last; } cp_token_cache; /* Prototypes. / static cp_lexer cp_lexer_new_main (void); static cp_lexer cp_lexer_new_from_tokens (cp_token_cache tokens); static void cp_lexer_destroy (cp_lexer ); static int cp_lexer_saving_tokens (const cp_lexer ); static cp_token_position cp_lexer_token_position (cp_lexer , bool); static cp_token cp_lexer_token_at (cp_lexer , cp_token_position); static void cp_lexer_get_preprocessor_token (cp_lexer , cp_token ); static inline cp_token cp_lexer_peek_token (cp_lexer ); static cp_token cp_lexer_peek_nth_token (cp_lexer , size_t); static inline bool cp_lexer_next_token_is (cp_lexer , enum cpp_ttype); static bool cp_lexer_next_token_is_not (cp_lexer , enum cpp_ttype); static bool cp_lexer_next_token_is_keyword (cp_lexer , enum rid); static cp_token cp_lexer_consume_token (cp_lexer ); static void cp_lexer_purge_token (cp_lexer ); static void cp_lexer_purge_tokens_after (cp_lexer , cp_token_position); static void cp_lexer_save_tokens (cp_lexer ); static void cp_lexer_commit_tokens (cp_lexer ); static void cp_lexer_rollback_tokens (cp_lexer ); #ifdef ENABLE_CHECKING static void cp_lexer_print_token (FILE , cp_token ); static inline bool cp_lexer_debugging_p (cp_lexer ); static void cp_lexer_start_debugging (cp_lexer ) ATTRIBUTE_UNUSED; static void cp_lexer_stop_debugging (cp_lexer ) ATTRIBUTE_UNUSED; #else /* If we define cp_lexer_debug_stream to NULL it will provoke warnings about passing NULL to functions that require non-NULL arguments (fputs, fprintf). It will never be used, so all we need is a value of the right type that's guaranteed not to be NULL. / #define cp_lexer_debug_stream stdout #define cp_lexer_print_token(str, tok) (void) 0 #define cp_lexer_debugging_p(lexer) 0 #endif / ENABLE_CHECKING / static cp_token_cache cp_token_cache_new (cp_token , cp_token ); static void cp_parser_initial_pragma (cp_token ); / Manifest constants. / #define CP_LEXER_BUFFER_SIZE ((256 1024) / sizeof (cp_token)) #define CP_SAVED_TOKEN_STACK 5 /* A token type for keywords, as opposed to ordinary identifiers. / #define CPP_KEYWORD ((enum cpp_ttype) (N_TTYPES + 1)) / A token type for template-ids. If a template-id is processed while parsing tentatively, it is replaced with a CPP_TEMPLATE_ID token; the value of the CPP_TEMPLATE_ID is whatever was returned by cp_parser_template_id. / #define CPP_TEMPLATE_ID ((enum cpp_ttype) (CPP_KEYWORD + 1)) / A token type for nested-name-specifiers. If a nested-name-specifier is processed while parsing tentatively, it is replaced with a CPP_NESTED_NAME_SPECIFIER token; the value of the CPP_NESTED_NAME_SPECIFIER is whatever was returned by cp_parser_nested_name_specifier_opt. / #define CPP_NESTED_NAME_SPECIFIER ((enum cpp_ttype) (CPP_TEMPLATE_ID + 1)) / A token type for tokens that are not tokens at all; these are used to represent slots in the array where there used to be a token that has now been deleted. / #define CPP_PURGED ((enum cpp_ttype) (CPP_NESTED_NAME_SPECIFIER + 1)) / The number of token types, including C++-specific ones. / #define N_CP_TTYPES ((int) (CPP_PURGED + 1)) / Variables. / #ifdef ENABLE_CHECKING / The stream to which debugging output should be written. / static FILE cp_lexer_debug_stream; #endif /* ENABLE_CHECKING / / Create a new main C++ lexer, the lexer that gets tokens from the preprocessor. / static cp_lexer cp_lexer_new_main (void) { cp_token first_token; cp_lexer lexer; cp_token pos; size_t alloc; size_t space; cp_token buffer; / It's possible that parsing the first pragma will load a PCH file, which is a GC collection point. So we have to do that before allocating any memory. / cp_parser_initial_pragma (&first_token); / Tell c_lex_with_flags not to merge string constants. / c_lex_return_raw_strings = true; c_common_no_more_pch (); / Allocate the memory. / lexer = GGC_CNEW (cp_lexer); #ifdef ENABLE_CHECKING / Initially we are not debugging. / lexer->debugging_p = false; #endif / ENABLE_CHECKING / lexer->saved_tokens = VEC_alloc (cp_token_position, heap, CP_SAVED_TOKEN_STACK); / Create the buffer. / alloc = CP_LEXER_BUFFER_SIZE; buffer = GGC_NEWVEC (cp_token, alloc); / Put the first token in the buffer. / space = alloc; pos = buffer; pos = first_token; /* Get the remaining tokens from the preprocessor. / while (pos->type != CPP_EOF) { pos++; if (!--space) { space = alloc; alloc = 2; buffer = GGC_RESIZEVEC (cp_token, buffer, alloc); pos = buffer + space; } cp_lexer_get_preprocessor_token (lexer, pos); } lexer->buffer = buffer; lexer->buffer_length = alloc - space; lexer->last_token = pos; lexer->next_token = lexer->buffer_length ? buffer : (cp_token )&eof_token; / Subsequent preprocessor diagnostics should use compiler diagnostic functions to get the compiler source location. / cpp_get_options (parse_in)->client_diagnostic = true; cpp_get_callbacks (parse_in)->error = cp_cpp_error; gcc_assert (lexer->next_token->type != CPP_PURGED); return lexer; } / Create a new lexer whose token stream is primed with the tokens in CACHE. When these tokens are exhausted, no new tokens will be read. / static cp_lexer cp_lexer_new_from_tokens (cp_token_cache cache) { cp_token first = cache->first; cp_token last = cache->last; cp_lexer lexer = GGC_CNEW (cp_lexer); /* We do not own the buffer. / lexer->buffer = NULL; lexer->buffer_length = 0; lexer->next_token = first == last ? (cp_token )&eof_token : first; lexer->last_token = last; lexer->saved_tokens = VEC_alloc (cp_token_position, heap, CP_SAVED_TOKEN_STACK); #ifdef ENABLE_CHECKING /* Initially we are not debugging. / lexer->debugging_p = false; #endif gcc_assert (lexer->next_token->type != CPP_PURGED); return lexer; } / Frees all resources associated with LEXER. / static void cp_lexer_destroy (cp_lexer lexer) { if (lexer->buffer) ggc_free (lexer->buffer); VEC_free (cp_token_position, heap, lexer->saved_tokens); ggc_free (lexer); } /* Returns nonzero if debugging information should be output. / #ifdef ENABLE_CHECKING static inline bool cp_lexer_debugging_p (cp_lexer lexer) { return lexer->debugging_p; } #endif /* ENABLE_CHECKING / static inline cp_token_position cp_lexer_token_position (cp_lexer lexer, bool previous_p) { gcc_assert (!previous_p \|\| lexer->next_token != &eof_token); return lexer->next_token - previous_p; } static inline cp_token * cp_lexer_token_at (cp_lexer lexer ATTRIBUTE_UNUSED, cp_token_position pos) { return pos; } / nonzero if we are presently saving tokens. / static inline int cp_lexer_saving_tokens (const cp_lexer lexer) { return VEC_length (cp_token_position, lexer->saved_tokens) != 0; } /* Store the next token from the preprocessor in TOKEN. Return true if we reach EOF. / static void cp_lexer_get_preprocessor_token (cp_lexer lexer ATTRIBUTE_UNUSED , cp_token token) { static int is_extern_c = 0; /* Get a new token from the preprocessor. / token->type = c_lex_with_flags (&token->u.value, &token->location, &token->flags); token->input_file_stack_index = input_file_stack_tick; token->keyword = RID_MAX; token->pragma_kind = PRAGMA_NONE; token->in_system_header = in_system_header; / On some systems, some header files are surrounded by an implicit extern "C" block. Set a flag in the token if it comes from such a header. / is_extern_c += pending_lang_change; pending_lang_change = 0; token->implicit_extern_c = is_extern_c > 0; / Check to see if this token is a keyword. / if (token->type == CPP_NAME) { if (C_IS_RESERVED_WORD (token->u.value)) { / Mark this token as a keyword. / token->type = CPP_KEYWORD; / Record which keyword. / token->keyword = C_RID_CODE (token->u.value); / Update the value. Some keywords are mapped to particular entities, rather than simply having the value of the corresponding IDENTIFIER_NODE. For example, `__const' is mapped to `const'. / token->u.value = ridpointers[token->keyword]; } else { token->ambiguous_p = false; token->keyword = RID_MAX; } } / Handle Objective-C++ keywords. / else if (token->type == CPP_AT_NAME) { token->type = CPP_KEYWORD; switch (C_RID_CODE (token->u.value)) { / Map 'class' to '@class', 'private' to '@private', etc. / case RID_CLASS: token->keyword = RID_AT_CLASS; break; case RID_PRIVATE: token->keyword = RID_AT_PRIVATE; break; case RID_PROTECTED: token->keyword = RID_AT_PROTECTED; break; case RID_PUBLIC: token->keyword = RID_AT_PUBLIC; break; case RID_THROW: token->keyword = RID_AT_THROW; break; case RID_TRY: token->keyword = RID_AT_TRY; break; case RID_CATCH: token->keyword = RID_AT_CATCH; break; default: token->keyword = C_RID_CODE (token->u.value); } } else if (token->type == CPP_PRAGMA) { / We smuggled the cpp_token->u.pragma value in an INTEGER_CST. / token->pragma_kind = TREE_INT_CST_LOW (token->u.value); token->u.value = NULL_TREE; } } / Update the globals input_location and in_system_header and the input file stack from TOKEN. / static inline void cp_lexer_set_source_position_from_token (cp_token token) { if (token->type != CPP_EOF) { input_location = token->location; in_system_header = token->in_system_header; restore_input_file_stack (token->input_file_stack_index); } } /* Return a pointer to the next token in the token stream, but do not consume it. / static inline cp_token cp_lexer_peek_token (cp_lexer lexer) { if (cp_lexer_debugging_p (lexer)) { fputs ("cp_lexer: peeking at token: ", cp_lexer_debug_stream); cp_lexer_print_token (cp_lexer_debug_stream, lexer->next_token); putc ('\n', cp_lexer_debug_stream); } return lexer->next_token; } / Return true if the next token has the indicated TYPE. / static inline bool cp_lexer_next_token_is (cp_lexer lexer, enum cpp_ttype type) { return cp_lexer_peek_token (lexer)->type == type; } /* Return true if the next token does not have the indicated TYPE. / static inline bool cp_lexer_next_token_is_not (cp_lexer lexer, enum cpp_ttype type) { return !cp_lexer_next_token_is (lexer, type); } /* Return true if the next token is the indicated KEYWORD. / static inline bool cp_lexer_next_token_is_keyword (cp_lexer lexer, enum rid keyword) { return cp_lexer_peek_token (lexer)->keyword == keyword; } /* Return true if the next token is a keyword for a decl-specifier. / static bool cp_lexer_next_token_is_decl_specifier_keyword (cp_lexer lexer) { cp_token token; token = cp_lexer_peek_token (lexer); switch (token->keyword) { / Storage classes. / case RID_AUTO: case RID_REGISTER: case RID_STATIC: case RID_EXTERN: case RID_MUTABLE: case RID_THREAD: / Elaborated type specifiers. / case RID_ENUM: case RID_CLASS: case RID_STRUCT: case RID_UNION: case RID_TYPENAME: / Simple type specifiers. / case RID_CHAR: case RID_WCHAR: case RID_BOOL: case RID_SHORT: case RID_INT: case RID_LONG: case RID_SIGNED: case RID_UNSIGNED: case RID_FLOAT: case RID_DOUBLE: case RID_VOID: / GNU extensions. / case RID_ATTRIBUTE: case RID_TYPEOF: return true; default: return false; } } / Return a pointer to the Nth token in the token stream. If N is 1, then this is precisely equivalent to cp_lexer_peek_token (except that it is not inline). One would like to disallow that case, but there is one case (cp_parser_nth_token_starts_template_id) where the caller passes a variable for N and it might be 1. / static cp_token cp_lexer_peek_nth_token (cp_lexer* lexer, size_t n) { cp_token token; / N is 1-based, not zero-based. / gcc_assert (n > 0); if (cp_lexer_debugging_p (lexer)) fprintf (cp_lexer_debug_stream, "cp_lexer: peeking ahead %ld at token: ", (long)n); --n; token = lexer->next_token; gcc_assert (!n \|\| token != &eof_token); while (n != 0) { ++token; if (token == lexer->last_token) { token = (cp_token )&eof_token; break; } if (token->type != CPP_PURGED) --n; } if (cp_lexer_debugging_p (lexer)) { cp_lexer_print_token (cp_lexer_debug_stream, token); putc ('\n', cp_lexer_debug_stream); } return token; } /* Return the next token, and advance the lexer's next_token pointer to point to the next non-purged token. / static cp_token cp_lexer_consume_token (cp_lexer* lexer) { cp_token token = lexer->next_token; gcc_assert (token != &eof_token); gcc_assert (!lexer->in_pragma \|\| token->type != CPP_PRAGMA_EOL); do { lexer->next_token++; if (lexer->next_token == lexer->last_token) { lexer->next_token = (cp_token )&eof_token; break; } } while (lexer->next_token->type == CPP_PURGED); cp_lexer_set_source_position_from_token (token); /* Provide debugging output. / if (cp_lexer_debugging_p (lexer)) { fputs ("cp_lexer: consuming token: ", cp_lexer_debug_stream); cp_lexer_print_token (cp_lexer_debug_stream, token); putc ('\n', cp_lexer_debug_stream); } return token; } / Permanently remove the next token from the token stream, and advance the next_token pointer to refer to the next non-purged token. / static void cp_lexer_purge_token (cp_lexer lexer) { cp_token tok = lexer->next_token; gcc_assert (tok != &eof_token); tok->type = CPP_PURGED; tok->location = UNKNOWN_LOCATION; tok->u.value = NULL_TREE; tok->keyword = RID_MAX; do { tok++; if (tok == lexer->last_token) { tok = (cp_token )&eof_token; break; } } while (tok->type == CPP_PURGED); lexer->next_token = tok; } /* Permanently remove all tokens after TOK, up to, but not including, the token that will be returned next by cp_lexer_peek_token. / static void cp_lexer_purge_tokens_after (cp_lexer lexer, cp_token tok) { cp_token peek = lexer->next_token; if (peek == &eof_token) peek = lexer->last_token; gcc_assert (tok < peek); for ( tok += 1; tok != peek; tok += 1) { tok->type = CPP_PURGED; tok->location = UNKNOWN_LOCATION; tok->u.value = NULL_TREE; tok->keyword = RID_MAX; } } /* Begin saving tokens. All tokens consumed after this point will be preserved. / static void cp_lexer_save_tokens (cp_lexer lexer) { /* Provide debugging output. / if (cp_lexer_debugging_p (lexer)) fprintf (cp_lexer_debug_stream, "cp_lexer: saving tokens\n"); VEC_safe_push (cp_token_position, heap, lexer->saved_tokens, lexer->next_token); } / Commit to the portion of the token stream most recently saved. / static void cp_lexer_commit_tokens (cp_lexer lexer) { /* Provide debugging output. / if (cp_lexer_debugging_p (lexer)) fprintf (cp_lexer_debug_stream, "cp_lexer: committing tokens\n"); VEC_pop (cp_token_position, lexer->saved_tokens); } / Return all tokens saved since the last call to cp_lexer_save_tokens to the token stream. Stop saving tokens. / static void cp_lexer_rollback_tokens (cp_lexer lexer) { /* Provide debugging output. / if (cp_lexer_debugging_p (lexer)) fprintf (cp_lexer_debug_stream, "cp_lexer: restoring tokens\n"); lexer->next_token = VEC_pop (cp_token_position, lexer->saved_tokens); } / Print a representation of the TOKEN on the STREAM. / #ifdef ENABLE_CHECKING static void cp_lexer_print_token (FILE stream, cp_token token) { / We don't use cpp_type2name here because the parser defines a few tokens of its own. / static const char const token_names[] = { /* cpplib-defined token types / #define OP(e, s) #e, #define TK(e, s) #e, TTYPE_TABLE #undef OP #undef TK / C++ parser token types - see "Manifest constants", above. / "KEYWORD", "TEMPLATE_ID", "NESTED_NAME_SPECIFIER", "PURGED" }; / If we have a name for the token, print it out. Otherwise, we simply give the numeric code. / gcc_assert (token->type < ARRAY_SIZE(token_names)); fputs (token_names[token->type], stream); / For some tokens, print the associated data. / switch (token->type) { case CPP_KEYWORD: / Some keywords have a value that is not an IDENTIFIER_NODE. For example, `struct' is mapped to an INTEGER_CST. / if (TREE_CODE (token->u.value) != IDENTIFIER_NODE) break; / else fall through / case CPP_NAME: fputs (IDENTIFIER_POINTER (token->u.value), stream); break; case CPP_STRING: case CPP_WSTRING: fprintf (stream, " \"%s\"", TREE_STRING_POINTER (token->u.value)); break; default: break; } } / Start emitting debugging information. / static void cp_lexer_start_debugging (cp_lexer lexer) { lexer->debugging_p = true; } /* Stop emitting debugging information. / static void cp_lexer_stop_debugging (cp_lexer lexer) { lexer->debugging_p = false; } #endif /* ENABLE_CHECKING / / Create a new cp_token_cache, representing a range of tokens. / static cp_token_cache cp_token_cache_new (cp_token first, cp_token last) { cp_token_cache cache = GGC_NEW (cp_token_cache); cache->first = first; cache->last = last; return cache; } / Decl-specifiers. / / Set DECL_SPECS to represent an empty decl-specifier-seq. / static void clear_decl_specs (cp_decl_specifier_seq decl_specs) { memset (decl_specs, 0, sizeof (cp_decl_specifier_seq)); } / Declarators. / / Nothing other than the parser should be creating declarators; declarators are a semi-syntactic representation of C++ entities. Other parts of the front end that need to create entities (like VAR_DECLs or FUNCTION_DECLs) should do that directly. / static cp_declarator make_call_declarator (cp_declarator , cp_parameter_declarator , cp_cv_quals, tree); static cp_declarator make_array_declarator (cp_declarator , tree); static cp_declarator make_pointer_declarator (cp_cv_quals, cp_declarator ); static cp_declarator make_reference_declarator (cp_cv_quals, cp_declarator ); static cp_parameter_declarator make_parameter_declarator (cp_decl_specifier_seq , cp_declarator , tree); static cp_declarator make_ptrmem_declarator (cp_cv_quals, tree, cp_declarator ); / An erroneous declarator. / static cp_declarator cp_error_declarator; /* The obstack on which declarators and related data structures are allocated. / static struct obstack declarator_obstack; / Alloc BYTES from the declarator memory pool. / static inline void alloc_declarator (size_t bytes) { return obstack_alloc (&declarator_obstack, bytes); } /* Allocate a declarator of the indicated KIND. Clear fields that are common to all declarators. / static cp_declarator make_declarator (cp_declarator_kind kind) { cp_declarator declarator; declarator = (cp_declarator ) alloc_declarator (sizeof (cp_declarator)); declarator->kind = kind; declarator->attributes = NULL_TREE; declarator->declarator = NULL; return declarator; } /* Make a declarator for a generalized identifier. If QUALIFYING_SCOPE is non-NULL, the identifier is QUALIFYING_SCOPE::UNQUALIFIED_NAME; otherwise, it is just UNQUALIFIED_NAME. SFK indicates the kind of special function this is, if any. / static cp_declarator make_id_declarator (tree qualifying_scope, tree unqualified_name, special_function_kind sfk) { cp_declarator declarator; / It is valid to write: class C { void f(); }; typedef C D; void D::f(); The standard is not clear about whether `typedef const C D' is legal; as of 2002-09-15 the committee is considering that question. EDG 3.0 allows that syntax. Therefore, we do as well. / if (qualifying_scope && TYPE_P (qualifying_scope)) qualifying_scope = TYPE_MAIN_VARIANT (qualifying_scope); gcc_assert (TREE_CODE (unqualified_name) == IDENTIFIER_NODE \|\| TREE_CODE (unqualified_name) == BIT_NOT_EXPR \|\| TREE_CODE (unqualified_name) == TEMPLATE_ID_EXPR); declarator = make_declarator (cdk_id); declarator->u.id.qualifying_scope = qualifying_scope; declarator->u.id.unqualified_name = unqualified_name; declarator->u.id.sfk = sfk; return declarator; } / Make a declarator for a pointer to TARGET. CV_QUALIFIERS is a list of modifiers such as const or volatile to apply to the pointer type, represented as identifiers. / cp_declarator make_pointer_declarator (cp_cv_quals cv_qualifiers, cp_declarator target) { cp_declarator declarator; declarator = make_declarator (cdk_pointer); declarator->declarator = target; declarator->u.pointer.qualifiers = cv_qualifiers; declarator->u.pointer.class_type = NULL_TREE; return declarator; } /* Like make_pointer_declarator -- but for references. / cp_declarator make_reference_declarator (cp_cv_quals cv_qualifiers, cp_declarator target) { cp_declarator declarator; declarator = make_declarator (cdk_reference); declarator->declarator = target; declarator->u.pointer.qualifiers = cv_qualifiers; declarator->u.pointer.class_type = NULL_TREE; return declarator; } /* Like make_pointer_declarator -- but for a pointer to a non-static member of CLASS_TYPE. / cp_declarator make_ptrmem_declarator (cp_cv_quals cv_qualifiers, tree class_type, cp_declarator pointee) { cp_declarator declarator; declarator = make_declarator (cdk_ptrmem); declarator->declarator = pointee; declarator->u.pointer.qualifiers = cv_qualifiers; declarator->u.pointer.class_type = class_type; return declarator; } /* Make a declarator for the function given by TARGET, with the indicated PARMS. The CV_QUALIFIERS aply to the function, as in "const"-qualified member function. The EXCEPTION_SPECIFICATION indicates what exceptions can be thrown. / cp_declarator make_call_declarator (cp_declarator target, cp_parameter_declarator parms, cp_cv_quals cv_qualifiers, tree exception_specification) { cp_declarator declarator; declarator = make_declarator (cdk_function); declarator->declarator = target; declarator->u.function.parameters = parms; declarator->u.function.qualifiers = cv_qualifiers; declarator->u.function.exception_specification = exception_specification; return declarator; } / Make a declarator for an array of BOUNDS elements, each of which is defined by ELEMENT. / cp_declarator make_array_declarator (cp_declarator element, tree bounds) { cp_declarator declarator; declarator = make_declarator (cdk_array); declarator->declarator = element; declarator->u.array.bounds = bounds; return declarator; } cp_parameter_declarator no_parameters; / Create a parameter declarator with the indicated DECL_SPECIFIERS, DECLARATOR and DEFAULT_ARGUMENT. / cp_parameter_declarator make_parameter_declarator (cp_decl_specifier_seq decl_specifiers, cp_declarator declarator, tree default_argument) { cp_parameter_declarator parameter; parameter = ((cp_parameter_declarator ) alloc_declarator (sizeof (cp_parameter_declarator))); parameter->next = NULL; if (decl_specifiers) parameter->decl_specifiers = decl_specifiers; else clear_decl_specs (&parameter->decl_specifiers); parameter->declarator = declarator; parameter->default_argument = default_argument; parameter->ellipsis_p = false; return parameter; } / Returns true iff DECLARATOR is a declaration for a function. / static bool function_declarator_p (const cp_declarator declarator) { while (declarator) { if (declarator->kind == cdk_function && declarator->declarator->kind == cdk_id) return true; if (declarator->kind == cdk_id \|\| declarator->kind == cdk_error) return false; declarator = declarator->declarator; } return false; } /* The parser. / / Overview -------- A cp_parser parses the token stream as specified by the C++ grammar. Its job is purely parsing, not semantic analysis. For example, the parser breaks the token stream into declarators, expressions, statements, and other similar syntactic constructs. It does not check that the types of the expressions on either side of an assignment-statement are compatible, or that a function is not declared with a parameter of type `void'. The parser invokes routines elsewhere in the compiler to perform semantic analysis and to build up the abstract syntax tree for the code processed. The parser (and the template instantiation code, which is, in a way, a close relative of parsing) are the only parts of the compiler that should be calling push_scope and pop_scope, or related functions. The parser (and template instantiation code) keeps track of what scope is presently active; everything else should simply honor that. (The code that generates static initializers may also need to set the scope, in order to check access control correctly when emitting the initializers.) Methodology ----------- The parser is of the standard recursive-descent variety. Upcoming tokens in the token stream are examined in order to determine which production to use when parsing a non-terminal. Some C++ constructs require arbitrary look ahead to disambiguate. For example, it is impossible, in the general case, to tell whether a statement is an expression or declaration without scanning the entire statement. Therefore, the parser is capable of "parsing tentatively." When the parser is not sure what construct comes next, it enters this mode. Then, while we attempt to parse the construct, the parser queues up error messages, rather than issuing them immediately, and saves the tokens it consumes. If the construct is parsed successfully, the parser "commits", i.e., it issues any queued error messages and the tokens that were being preserved are permanently discarded. If, however, the construct is not parsed successfully, the parser rolls back its state completely so that it can resume parsing using a different alternative. Future Improvements ------------------- The performance of the parser could probably be improved substantially. We could often eliminate the need to parse tentatively by looking ahead a little bit. In some places, this approach might not entirely eliminate the need to parse tentatively, but it might still speed up the average case. / / Flags that are passed to some parsing functions. These values can be bitwise-ored together. / typedef enum cp_parser_flags { / No flags. / CP_PARSER_FLAGS_NONE = 0x0, / The construct is optional. If it is not present, then no error should be issued. / CP_PARSER_FLAGS_OPTIONAL = 0x1, / When parsing a type-specifier, do not allow user-defined types. / CP_PARSER_FLAGS_NO_USER_DEFINED_TYPES = 0x2 } cp_parser_flags; / The different kinds of declarators we want to parse. / typedef enum cp_parser_declarator_kind { / We want an abstract declarator. / CP_PARSER_DECLARATOR_ABSTRACT, / We want a named declarator. / CP_PARSER_DECLARATOR_NAMED, / We don't mind, but the name must be an unqualified-id. / CP_PARSER_DECLARATOR_EITHER } cp_parser_declarator_kind; / The precedence values used to parse binary expressions. The minimum value of PREC must be 1, because zero is reserved to quickly discriminate binary operators from other tokens. / enum cp_parser_prec { PREC_NOT_OPERATOR, PREC_LOGICAL_OR_EXPRESSION, PREC_LOGICAL_AND_EXPRESSION, PREC_INCLUSIVE_OR_EXPRESSION, PREC_EXCLUSIVE_OR_EXPRESSION, PREC_AND_EXPRESSION, PREC_EQUALITY_EXPRESSION, PREC_RELATIONAL_EXPRESSION, PREC_SHIFT_EXPRESSION, PREC_ADDITIVE_EXPRESSION, PREC_MULTIPLICATIVE_EXPRESSION, PREC_PM_EXPRESSION, NUM_PREC_VALUES = PREC_PM_EXPRESSION }; / A mapping from a token type to a corresponding tree node type, with a precedence value. / typedef struct cp_parser_binary_operations_map_node { / The token type. / enum cpp_ttype token_type; / The corresponding tree code. / enum tree_code tree_type; / The precedence of this operator. / enum cp_parser_prec prec; } cp_parser_binary_operations_map_node; / The status of a tentative parse. / typedef enum cp_parser_status_kind { / No errors have occurred. / CP_PARSER_STATUS_KIND_NO_ERROR, / An error has occurred. / CP_PARSER_STATUS_KIND_ERROR, / We are committed to this tentative parse, whether or not an error has occurred. / CP_PARSER_STATUS_KIND_COMMITTED } cp_parser_status_kind; typedef struct cp_parser_expression_stack_entry { tree lhs; enum tree_code tree_type; int prec; } cp_parser_expression_stack_entry; / The stack for storing partial expressions. We only need NUM_PREC_VALUES entries because precedence levels on the stack are monotonically increasing. / typedef struct cp_parser_expression_stack_entry cp_parser_expression_stack[NUM_PREC_VALUES]; / Context that is saved and restored when parsing tentatively. / typedef struct cp_parser_context GTY (()) { / If this is a tentative parsing context, the status of the tentative parse. / enum cp_parser_status_kind status; / If non-NULL, we have just seen a `x->' or `x.' expression. Names that are looked up in this context must be looked up both in the scope given by OBJECT_TYPE (the type of `x' or `x') and also in the context of the containing expression. / tree object_type; /* The next parsing context in the stack. / struct cp_parser_context next; } cp_parser_context; /* Prototypes. / / Constructors and destructors. / static cp_parser_context cp_parser_context_new (cp_parser_context ); / Class variables. / static GTY((deletable)) cp_parser_context cp_parser_context_free_list; /* The operator-precedence table used by cp_parser_binary_expression. Transformed into an associative array (binops_by_token) by cp_parser_new. / static const cp_parser_binary_operations_map_node binops[] = { { CPP_DEREF_STAR, MEMBER_REF, PREC_PM_EXPRESSION }, { CPP_DOT_STAR, DOTSTAR_EXPR, PREC_PM_EXPRESSION }, { CPP_MULT, MULT_EXPR, PREC_MULTIPLICATIVE_EXPRESSION }, { CPP_DIV, TRUNC_DIV_EXPR, PREC_MULTIPLICATIVE_EXPRESSION }, { CPP_MOD, TRUNC_MOD_EXPR, PREC_MULTIPLICATIVE_EXPRESSION }, { CPP_PLUS, PLUS_EXPR, PREC_ADDITIVE_EXPRESSION }, { CPP_MINUS, MINUS_EXPR, PREC_ADDITIVE_EXPRESSION }, { CPP_LSHIFT, LSHIFT_EXPR, PREC_SHIFT_EXPRESSION }, { CPP_RSHIFT, RSHIFT_EXPR, PREC_SHIFT_EXPRESSION }, { CPP_LESS, LT_EXPR, PREC_RELATIONAL_EXPRESSION }, { CPP_GREATER, GT_EXPR, PREC_RELATIONAL_EXPRESSION }, { CPP_LESS_EQ, LE_EXPR, PREC_RELATIONAL_EXPRESSION }, { CPP_GREATER_EQ, GE_EXPR, PREC_RELATIONAL_EXPRESSION }, { CPP_EQ_EQ, EQ_EXPR, PREC_EQUALITY_EXPRESSION }, { CPP_NOT_EQ, NE_EXPR, PREC_EQUALITY_EXPRESSION }, { CPP_AND, BIT_AND_EXPR, PREC_AND_EXPRESSION }, { CPP_XOR, BIT_XOR_EXPR, PREC_EXCLUSIVE_OR_EXPRESSION }, { CPP_OR, BIT_IOR_EXPR, PREC_INCLUSIVE_OR_EXPRESSION }, { CPP_AND_AND, TRUTH_ANDIF_EXPR, PREC_LOGICAL_AND_EXPRESSION }, { CPP_OR_OR, TRUTH_ORIF_EXPR, PREC_LOGICAL_OR_EXPRESSION } }; / The same as binops, but initialized by cp_parser_new so that binops_by_token[N].token_type == N. Used in cp_parser_binary_expression for speed. / static cp_parser_binary_operations_map_node binops_by_token[N_CP_TTYPES]; / Constructors and destructors. / / Construct a new context. The context below this one on the stack is given by NEXT. / static cp_parser_context cp_parser_context_new (cp_parser_context* next) { cp_parser_context context; / Allocate the storage. / if (cp_parser_context_free_list != NULL) { / Pull the first entry from the free list. / context = cp_parser_context_free_list; cp_parser_context_free_list = context->next; memset (context, 0, sizeof (context)); } else context = GGC_CNEW (cp_parser_context); /* No errors have occurred yet in this context. / context->status = CP_PARSER_STATUS_KIND_NO_ERROR; / If this is not the bottomost context, copy information that we need from the previous context. / if (next) { / If, in the NEXT context, we are parsing an `x->' or `x.' expression, then we are parsing one in this context, too. / context->object_type = next->object_type; / Thread the stack. / context->next = next; } return context; } / The cp_parser structure represents the C++ parser. / typedef struct cp_parser GTY(()) { / The lexer from which we are obtaining tokens. / cp_lexer lexer; /* The scope in which names should be looked up. If NULL_TREE, then we look up names in the scope that is currently open in the source program. If non-NULL, this is either a TYPE or NAMESPACE_DECL for the scope in which we should look. It can also be ERROR_MARK, when we've parsed a bogus scope. This value is not cleared automatically after a name is looked up, so we must be careful to clear it before starting a new look up sequence. (If it is not cleared, then `X::Y' followed by `Z' will look up `Z' in the scope of `X', rather than the current scope.) Unfortunately, it is difficult to tell when name lookup is complete, because we sometimes peek at a token, look it up, and then decide not to consume it. / tree scope; / OBJECT_SCOPE and QUALIFYING_SCOPE give the scopes in which the last lookup took place. OBJECT_SCOPE is used if an expression like "x->y" or "x.y" was used; it gives the type of "x" or "x", respectively. QUALIFYING_SCOPE is used for an expression of the form "X::Y"; it refers to X. / tree object_scope; tree qualifying_scope; /* A stack of parsing contexts. All but the bottom entry on the stack will be tentative contexts. We parse tentatively in order to determine which construct is in use in some situations. For example, in order to determine whether a statement is an expression-statement or a declaration-statement we parse it tentatively as a declaration-statement. If that fails, we then reparse the same token stream as an expression-statement. / cp_parser_context context; /* True if we are parsing GNU C++. If this flag is not set, then GNU extensions are not recognized. / bool allow_gnu_extensions_p; / TRUE if the `>' token should be interpreted as the greater-than operator. FALSE if it is the end of a template-id or template-parameter-list. / bool greater_than_is_operator_p; / TRUE if default arguments are allowed within a parameter list that starts at this point. FALSE if only a gnu extension makes them permissible. / bool default_arg_ok_p; / TRUE if we are parsing an integral constant-expression. See [expr.const] for a precise definition. / bool integral_constant_expression_p; / TRUE if we are parsing an integral constant-expression -- but a non-constant expression should be permitted as well. This flag is used when parsing an array bound so that GNU variable-length arrays are tolerated. / bool allow_non_integral_constant_expression_p; / TRUE if ALLOW_NON_CONSTANT_EXPRESSION_P is TRUE and something has been seen that makes the expression non-constant. / bool non_integral_constant_expression_p; / TRUE if local variable names and `this' are forbidden in the current context. / bool local_variables_forbidden_p; / TRUE if the declaration we are parsing is part of a linkage-specification of the form `extern string-literal declaration'. / bool in_unbraced_linkage_specification_p; / TRUE if we are presently parsing a declarator, after the direct-declarator. / bool in_declarator_p; / TRUE if we are presently parsing a template-argument-list. / bool in_template_argument_list_p; / Set to IN_ITERATION_STMT if parsing an iteration-statement, to IN_OMP_BLOCK if parsing OpenMP structured block and IN_OMP_FOR if parsing OpenMP loop. If parsing a switch statement, this is bitwise ORed with IN_SWITCH_STMT, unless parsing an iteration-statement, OpenMP block or loop within that switch. / #define IN_SWITCH_STMT 1 #define IN_ITERATION_STMT 2 #define IN_OMP_BLOCK 4 #define IN_OMP_FOR 8 unsigned char in_statement; / TRUE if we are presently parsing the body of a switch statement. Note that this doesn't quite overlap with in_statement above. The difference relates to giving the right sets of error messages: "case not in switch" vs "break statement used with OpenMP...". / bool in_switch_statement_p; / TRUE if we are parsing a type-id in an expression context. In such a situation, both "type (expr)" and "type (type)" are valid alternatives. / bool in_type_id_in_expr_p; / TRUE if we are currently in a header file where declarations are implicitly extern "C". / bool implicit_extern_c; / TRUE if strings in expressions should be translated to the execution character set. / bool translate_strings_p; / TRUE if we are presently parsing the body of a function, but not a local class. / bool in_function_body; / If non-NULL, then we are parsing a construct where new type definitions are not permitted. The string stored here will be issued as an error message if a type is defined. / const char type_definition_forbidden_message; /* A list of lists. The outer list is a stack, used for member functions of local classes. At each level there are two sub-list, one on TREE_VALUE and one on TREE_PURPOSE. Each of those sub-lists has a FUNCTION_DECL or TEMPLATE_DECL on their TREE_VALUE's. The functions are chained in reverse declaration order. The TREE_PURPOSE sublist contains those functions with default arguments that need post processing, and the TREE_VALUE sublist contains those functions with definitions that need post processing. These lists can only be processed once the outermost class being defined is complete. / tree unparsed_functions_queues; / The number of classes whose definitions are currently in progress. / unsigned num_classes_being_defined; / The number of template parameter lists that apply directly to the current declaration. / unsigned num_template_parameter_lists; } cp_parser; / Prototypes. / / Constructors and destructors. / static cp_parser cp_parser_new (void); /* Routines to parse various constructs. Those that return `tree' will return the error_mark_node (rather than NULL_TREE) if a parse error occurs, unless otherwise noted. Sometimes, they will return an ordinary node if error-recovery was attempted, even though a parse error occurred. So, to check whether or not a parse error occurred, you should always use cp_parser_error_occurred. If the construct is optional (indicated either by an `_opt' in the name of the function that does the parsing or via a FLAGS parameter), then NULL_TREE is returned if the construct is not present. / / Lexical conventions [gram.lex] / static tree cp_parser_identifier (cp_parser ); static tree cp_parser_string_literal (cp_parser , bool, bool); / Basic concepts [gram.basic] / static bool cp_parser_translation_unit (cp_parser ); /* Expressions [gram.expr] / static tree cp_parser_primary_expression (cp_parser , bool, bool, bool, cp_id_kind ); static tree cp_parser_id_expression (cp_parser , bool, bool, bool , bool, bool); static tree cp_parser_unqualified_id (cp_parser , bool, bool, bool, bool); static tree cp_parser_nested_name_specifier_opt (cp_parser , bool, bool, bool, bool); static tree cp_parser_nested_name_specifier (cp_parser , bool, bool, bool, bool); static tree cp_parser_class_or_namespace_name (cp_parser , bool, bool, bool, bool, bool); static tree cp_parser_postfix_expression (cp_parser , bool, bool); static tree cp_parser_postfix_open_square_expression (cp_parser , tree, bool); static tree cp_parser_postfix_dot_deref_expression (cp_parser , enum cpp_ttype, tree, bool, cp_id_kind ); static tree cp_parser_parenthesized_expression_list (cp_parser , bool, bool, bool ); static void cp_parser_pseudo_destructor_name (cp_parser , tree , tree ); static tree cp_parser_unary_expression (cp_parser , bool, bool); static enum tree_code cp_parser_unary_operator (cp_token ); static tree cp_parser_new_expression (cp_parser ); static tree cp_parser_new_placement (cp_parser ); static tree cp_parser_new_type_id (cp_parser , tree ); static cp_declarator cp_parser_new_declarator_opt (cp_parser ); static cp_declarator cp_parser_direct_new_declarator (cp_parser ); static tree cp_parser_new_initializer (cp_parser ); static tree cp_parser_delete_expression (cp_parser ); static tree cp_parser_cast_expression (cp_parser , bool, bool); static tree cp_parser_binary_expression (cp_parser , bool); static tree cp_parser_question_colon_clause (cp_parser , tree); static tree cp_parser_assignment_expression (cp_parser , bool); static enum tree_code cp_parser_assignment_operator_opt (cp_parser ); static tree cp_parser_expression (cp_parser , bool); static tree cp_parser_constant_expression (cp_parser , bool, bool ); static tree cp_parser_builtin_offsetof (cp_parser ); / Statements [gram.stmt.stmt] / static void cp_parser_statement (cp_parser , tree, bool); static void cp_parser_label_for_labeled_statement (cp_parser ); static tree cp_parser_expression_statement (cp_parser , tree); static tree cp_parser_compound_statement (cp_parser , tree, bool); static void cp_parser_statement_seq_opt (cp_parser , tree); static tree cp_parser_selection_statement (cp_parser ); static tree cp_parser_condition (cp_parser ); static tree cp_parser_iteration_statement (cp_parser ); static void cp_parser_for_init_statement (cp_parser ); static tree cp_parser_jump_statement (cp_parser ); static void cp_parser_declaration_statement (cp_parser ); static tree cp_parser_implicitly_scoped_statement (cp_parser ); static void cp_parser_already_scoped_statement (cp_parser ); /* Declarations [gram.dcl.dcl] / static void cp_parser_declaration_seq_opt (cp_parser ); static void cp_parser_declaration (cp_parser ); static void cp_parser_block_declaration (cp_parser , bool); static void cp_parser_simple_declaration (cp_parser , bool); static void cp_parser_decl_specifier_seq (cp_parser , cp_parser_flags, cp_decl_specifier_seq , int ); static tree cp_parser_storage_class_specifier_opt (cp_parser ); static tree cp_parser_function_specifier_opt (cp_parser , cp_decl_specifier_seq ); static tree cp_parser_type_specifier (cp_parser , cp_parser_flags, cp_decl_specifier_seq , bool, int , bool ); static tree cp_parser_simple_type_specifier (cp_parser , cp_decl_specifier_seq , cp_parser_flags); static tree cp_parser_type_name (cp_parser ); static tree cp_parser_elaborated_type_specifier (cp_parser , bool, bool); static tree cp_parser_enum_specifier (cp_parser ); static void cp_parser_enumerator_list (cp_parser , tree); static void cp_parser_enumerator_definition (cp_parser , tree); static tree cp_parser_namespace_name (cp_parser ); static void cp_parser_namespace_definition (cp_parser ); static void cp_parser_namespace_body (cp_parser ); static tree cp_parser_qualified_namespace_specifier (cp_parser ); static void cp_parser_namespace_alias_definition (cp_parser ); static bool cp_parser_using_declaration (cp_parser , bool); static void cp_parser_using_directive (cp_parser ); static void cp_parser_asm_definition (cp_parser ); static void cp_parser_linkage_specification (cp_parser ); / Declarators [gram.dcl.decl] / static tree cp_parser_init_declarator (cp_parser , cp_decl_specifier_seq , VEC (deferred_access_check,gc), bool, bool, int, bool ); static cp_declarator cp_parser_declarator (cp_parser , cp_parser_declarator_kind, int , bool , bool); static cp_declarator cp_parser_direct_declarator (cp_parser , cp_parser_declarator_kind, int , bool); static enum tree_code cp_parser_ptr_operator (cp_parser , tree , cp_cv_quals ); static cp_cv_quals cp_parser_cv_qualifier_seq_opt (cp_parser ); static tree cp_parser_declarator_id (cp_parser , bool); static tree cp_parser_type_id (cp_parser ); static void cp_parser_type_specifier_seq (cp_parser , bool, cp_decl_specifier_seq ); static cp_parameter_declarator cp_parser_parameter_declaration_clause (cp_parser ); static cp_parameter_declarator cp_parser_parameter_declaration_list (cp_parser , bool ); static cp_parameter_declarator cp_parser_parameter_declaration (cp_parser , bool, bool ); static void cp_parser_function_body (cp_parser ); static tree cp_parser_initializer (cp_parser , bool , bool ); static tree cp_parser_initializer_clause (cp_parser , bool ); static VEC(constructor_elt,gc) cp_parser_initializer_list (cp_parser , bool ); static bool cp_parser_ctor_initializer_opt_and_function_body (cp_parser ); /* Classes [gram.class] / static tree cp_parser_class_name (cp_parser , bool, bool, enum tag_types, bool, bool, bool); static tree cp_parser_class_specifier (cp_parser ); static tree cp_parser_class_head (cp_parser , bool , tree , tree ); static enum tag_types cp_parser_class_key (cp_parser ); static void cp_parser_member_specification_opt (cp_parser ); static void cp_parser_member_declaration (cp_parser ); static tree cp_parser_pure_specifier (cp_parser ); static tree cp_parser_constant_initializer (cp_parser ); /* Derived classes [gram.class.derived] / static tree cp_parser_base_clause (cp_parser ); static tree cp_parser_base_specifier (cp_parser ); / Special member functions [gram.special] / static tree cp_parser_conversion_function_id (cp_parser ); static tree cp_parser_conversion_type_id (cp_parser ); static cp_declarator cp_parser_conversion_declarator_opt (cp_parser ); static bool cp_parser_ctor_initializer_opt (cp_parser ); static void cp_parser_mem_initializer_list (cp_parser ); static tree cp_parser_mem_initializer (cp_parser ); static tree cp_parser_mem_initializer_id (cp_parser ); / Overloading [gram.over] / static tree cp_parser_operator_function_id (cp_parser ); static tree cp_parser_operator (cp_parser ); / Templates [gram.temp] / static void cp_parser_template_declaration (cp_parser , bool); static tree cp_parser_template_parameter_list (cp_parser ); static tree cp_parser_template_parameter (cp_parser , bool ); static tree cp_parser_type_parameter (cp_parser ); static tree cp_parser_template_id (cp_parser , bool, bool, bool); static tree cp_parser_template_name (cp_parser , bool, bool, bool, bool ); static tree cp_parser_template_argument_list (cp_parser ); static tree cp_parser_template_argument (cp_parser ); static void cp_parser_explicit_instantiation (cp_parser ); static void cp_parser_explicit_specialization (cp_parser ); / Exception handling [gram.exception] / static tree cp_parser_try_block (cp_parser ); static bool cp_parser_function_try_block (cp_parser ); static void cp_parser_handler_seq (cp_parser ); static void cp_parser_handler (cp_parser ); static tree cp_parser_exception_declaration (cp_parser ); static tree cp_parser_throw_expression (cp_parser ); static tree cp_parser_exception_specification_opt (cp_parser ); static tree cp_parser_type_id_list (cp_parser ); / GNU Extensions / static tree cp_parser_asm_specification_opt (cp_parser ); static tree cp_parser_asm_operand_list (cp_parser ); static tree cp_parser_asm_clobber_list (cp_parser ); static tree cp_parser_attributes_opt (cp_parser ); static tree cp_parser_attribute_list (cp_parser ); static bool cp_parser_extension_opt (cp_parser , int ); static void cp_parser_label_declaration (cp_parser ); enum pragma_context { pragma_external, pragma_stmt, pragma_compound }; static bool cp_parser_pragma (cp_parser , enum pragma_context); /* Objective-C++ Productions / static tree cp_parser_objc_message_receiver (cp_parser ); static tree cp_parser_objc_message_args (cp_parser ); static tree cp_parser_objc_message_expression (cp_parser ); static tree cp_parser_objc_encode_expression (cp_parser ); static tree cp_parser_objc_defs_expression (cp_parser ); static tree cp_parser_objc_protocol_expression (cp_parser ); static tree cp_parser_objc_selector_expression (cp_parser ); static tree cp_parser_objc_expression (cp_parser ); static bool cp_parser_objc_selector_p (enum cpp_ttype); static tree cp_parser_objc_selector (cp_parser ); static tree cp_parser_objc_protocol_refs_opt (cp_parser ); static void cp_parser_objc_declaration (cp_parser ); static tree cp_parser_objc_statement (cp_parser ); / Utility Routines / static tree cp_parser_lookup_name (cp_parser , tree, enum tag_types, bool, bool, bool, tree ); static tree cp_parser_lookup_name_simple (cp_parser , tree); static tree cp_parser_maybe_treat_template_as_class (tree, bool); static bool cp_parser_check_declarator_template_parameters (cp_parser , cp_declarator ); static bool cp_parser_check_template_parameters (cp_parser , unsigned); static tree cp_parser_simple_cast_expression (cp_parser ); static tree cp_parser_global_scope_opt (cp_parser , bool); static bool cp_parser_constructor_declarator_p (cp_parser , bool); static tree cp_parser_function_definition_from_specifiers_and_declarator (cp_parser , cp_decl_specifier_seq , tree, const cp_declarator ); static tree cp_parser_function_definition_after_declarator (cp_parser , bool); static void cp_parser_template_declaration_after_export (cp_parser , bool); static void cp_parser_perform_template_parameter_access_checks (VEC (deferred_access_check,gc)); static tree cp_parser_single_declaration (cp_parser , VEC (deferred_access_check,gc), bool, bool ); static tree cp_parser_functional_cast (cp_parser , tree); static tree cp_parser_save_member_function_body (cp_parser , cp_decl_specifier_seq , cp_declarator , tree); static tree cp_parser_enclosed_template_argument_list (cp_parser ); static void cp_parser_save_default_args (cp_parser , tree); static void cp_parser_late_parsing_for_member (cp_parser , tree); static void cp_parser_late_parsing_default_args (cp_parser , tree); static tree cp_parser_sizeof_operand (cp_parser , enum rid); static bool cp_parser_declares_only_class_p (cp_parser ); static void cp_parser_set_storage_class (cp_parser , cp_decl_specifier_seq , enum rid); static void cp_parser_set_decl_spec_type (cp_decl_specifier_seq , tree, bool); static bool cp_parser_friend_p (const cp_decl_specifier_seq ); static cp_token cp_parser_require (cp_parser , enum cpp_ttype, const char ); static cp_token cp_parser_require_keyword (cp_parser , enum rid, const char ); static bool cp_parser_token_starts_function_definition_p (cp_token ); static bool cp_parser_next_token_starts_class_definition_p (cp_parser ); static bool cp_parser_next_token_ends_template_argument_p (cp_parser ); static bool cp_parser_nth_token_starts_template_argument_list_p (cp_parser , size_t); static enum tag_types cp_parser_token_is_class_key (cp_token ); static void cp_parser_check_class_key (enum tag_types, tree type); static void cp_parser_check_access_in_redeclaration (tree type); static bool cp_parser_optional_template_keyword (cp_parser ); static void cp_parser_pre_parsed_nested_name_specifier (cp_parser ); static void cp_parser_cache_group (cp_parser , enum cpp_ttype, unsigned); static void cp_parser_parse_tentatively (cp_parser ); static void cp_parser_commit_to_tentative_parse (cp_parser ); static void cp_parser_abort_tentative_parse (cp_parser ); static bool cp_parser_parse_definitely (cp_parser ); static inline bool cp_parser_parsing_tentatively (cp_parser ); static bool cp_parser_uncommitted_to_tentative_parse_p (cp_parser ); static void cp_parser_error (cp_parser , const char ); static void cp_parser_name_lookup_error (cp_parser , tree, tree, const char ); static bool cp_parser_simulate_error (cp_parser ); static bool cp_parser_check_type_definition (cp_parser ); static void cp_parser_check_for_definition_in_return_type (cp_declarator , tree); static void cp_parser_check_for_invalid_template_id (cp_parser , tree); static bool cp_parser_non_integral_constant_expression (cp_parser , const char ); static void cp_parser_diagnose_invalid_type_name (cp_parser , tree, tree); static bool cp_parser_parse_and_diagnose_invalid_type_name (cp_parser ); static int cp_parser_skip_to_closing_parenthesis (cp_parser , bool, bool, bool); static void cp_parser_skip_to_end_of_statement (cp_parser ); static void cp_parser_consume_semicolon_at_end_of_statement (cp_parser ); static void cp_parser_skip_to_end_of_block_or_statement (cp_parser ); static void cp_parser_skip_to_closing_brace (cp_parser ); static void cp_parser_skip_to_end_of_template_parameter_list (cp_parser ); static void cp_parser_skip_to_pragma_eol (cp_parser, cp_token ); static bool cp_parser_error_occurred (cp_parser ); static bool cp_parser_allow_gnu_extensions_p (cp_parser ); static bool cp_parser_is_string_literal (cp_token ); static bool cp_parser_is_keyword (cp_token , enum rid); static tree cp_parser_make_typename_type (cp_parser , tree, tree); /* Returns nonzero if we are parsing tentatively. / static inline bool cp_parser_parsing_tentatively (cp_parser parser) { return parser->context->next != NULL; } /* Returns nonzero if TOKEN is a string literal. / static bool cp_parser_is_string_literal (cp_token token) { return (token->type == CPP_STRING \|\| token->type == CPP_WSTRING); } /* Returns nonzero if TOKEN is the indicated KEYWORD. / static bool cp_parser_is_keyword (cp_token token, enum rid keyword) { return token->keyword == keyword; } /* If not parsing tentatively, issue a diagnostic of the form FILE:LINE: MESSAGE before TOKEN where TOKEN is the next token in the input stream. MESSAGE (specified by the caller) is usually of the form "expected OTHER-TOKEN". / static void cp_parser_error (cp_parser parser, const char* message) { if (!cp_parser_simulate_error (parser)) { cp_token token = cp_lexer_peek_token (parser->lexer); / This diagnostic makes more sense if it is tagged to the line of the token we just peeked at. / cp_lexer_set_source_position_from_token (token); if (token->type == CPP_PRAGMA) { error ("%<#pragma%> is not allowed here"); cp_parser_skip_to_pragma_eol (parser, token); return; } c_parse_error (message, / Because c_parser_error does not understand CPP_KEYWORD, keywords are treated like identifiers. / (token->type == CPP_KEYWORD ? CPP_NAME : token->type), token->u.value); } } / Issue an error about name-lookup failing. NAME is the IDENTIFIER_NODE DECL is the result of the lookup (as returned from cp_parser_lookup_name). DESIRED is the thing that we hoped to find. / static void cp_parser_name_lookup_error (cp_parser parser, tree name, tree decl, const char* desired) { /* If name lookup completely failed, tell the user that NAME was not declared. / if (decl == error_mark_node) { if (parser->scope && parser->scope != global_namespace) error ("%<%D::%D%> has not been declared", parser->scope, name); else if (parser->scope == global_namespace) error ("%<::%D%> has not been declared", name); else if (parser->object_scope && !CLASS_TYPE_P (parser->object_scope)) error ("request for member %qD in non-class type %qT", name, parser->object_scope); else if (parser->object_scope) error ("%<%T::%D%> has not been declared", parser->object_scope, name); else error ("%qD has not been declared", name); } else if (parser->scope && parser->scope != global_namespace) error ("%<%D::%D%> %s", parser->scope, name, desired); else if (parser->scope == global_namespace) error ("%<::%D%> %s", name, desired); else error ("%qD %s", name, desired); } / If we are parsing tentatively, remember that an error has occurred during this tentative parse. Returns true if the error was simulated; false if a message should be issued by the caller. / static bool cp_parser_simulate_error (cp_parser parser) { if (cp_parser_uncommitted_to_tentative_parse_p (parser)) { parser->context->status = CP_PARSER_STATUS_KIND_ERROR; return true; } return false; } /* Check for repeated decl-specifiers. / static void cp_parser_check_decl_spec (cp_decl_specifier_seq decl_specs) { cp_decl_spec ds; for (ds = ds_first; ds != ds_last; ++ds) { unsigned count = decl_specs->specs[(int)ds]; if (count < 2) continue; /* The "long" specifier is a special case because of "long long". / if (ds == ds_long) { if (count > 2) error ("%<long long long%> is too long for GCC"); else if (pedantic && !in_system_header && warn_long_long) pedwarn ("ISO C++ does not support %<long long%>"); } else if (count > 1) { static const char const decl_spec_names[] = { "signed", "unsigned", "short", "long", "const", "volatile", "restrict", "inline", "virtual", "explicit", "friend", "typedef", "__complex", "__thread" }; error ("duplicate %qs", decl_spec_names[(int)ds]); } } } /* This function is called when a type is defined. If type definitions are forbidden at this point, an error message is issued. / static bool cp_parser_check_type_definition (cp_parser parser) { /* If types are forbidden here, issue a message. / if (parser->type_definition_forbidden_message) { / Use `%s' to print the string in case there are any escape characters in the message. / error ("%s", parser->type_definition_forbidden_message); return false; } return true; } / This function is called when the DECLARATOR is processed. The TYPE was a type defined in the decl-specifiers. If it is invalid to define a type in the decl-specifiers for DECLARATOR, an error is issued. / static void cp_parser_check_for_definition_in_return_type (cp_declarator declarator, tree type) { /* [dcl.fct] forbids type definitions in return types. Unfortunately, it's not easy to know whether or not we are processing a return type until after the fact. / while (declarator && (declarator->kind == cdk_pointer \|\| declarator->kind == cdk_reference \|\| declarator->kind == cdk_ptrmem)) declarator = declarator->declarator; if (declarator && declarator->kind == cdk_function) { error ("new types may not be defined in a return type"); inform ("(perhaps a semicolon is missing after the definition of %qT)", type); } } / A type-specifier (TYPE) has been parsed which cannot be followed by "<" in any valid C++ program. If the next token is indeed "<", issue a message warning the user about what appears to be an invalid attempt to form a template-id. / static void cp_parser_check_for_invalid_template_id (cp_parser parser, tree type) { cp_token_position start = 0; if (cp_lexer_next_token_is (parser->lexer, CPP_LESS)) { if (TYPE_P (type)) error ("%qT is not a template", type); else if (TREE_CODE (type) == IDENTIFIER_NODE) error ("%qE is not a template", type); else error ("invalid template-id"); /* Remember the location of the invalid "<". / if (cp_parser_uncommitted_to_tentative_parse_p (parser)) start = cp_lexer_token_position (parser->lexer, true); / Consume the "<". / cp_lexer_consume_token (parser->lexer); / Parse the template arguments. / cp_parser_enclosed_template_argument_list (parser); / Permanently remove the invalid template arguments so that this error message is not issued again. / if (start) cp_lexer_purge_tokens_after (parser->lexer, start); } } / If parsing an integral constant-expression, issue an error message about the fact that THING appeared and return true. Otherwise, return false. In either case, set PARSER->NON_INTEGRAL_CONSTANT_EXPRESSION_P. / static bool cp_parser_non_integral_constant_expression (cp_parser parser, const char thing) { parser->non_integral_constant_expression_p = true; if (parser->integral_constant_expression_p) { if (!parser->allow_non_integral_constant_expression_p) { error ("%s cannot appear in a constant-expression", thing); return true; } } return false; } / Emit a diagnostic for an invalid type name. SCOPE is the qualifying scope (or NULL, if none) for ID. This function commits to the current active tentative parse, if any. (Otherwise, the problematic construct might be encountered again later, resulting in duplicate error messages.) / static void cp_parser_diagnose_invalid_type_name (cp_parser parser, tree scope, tree id) { tree decl, old_scope; /* Try to lookup the identifier. / old_scope = parser->scope; parser->scope = scope; decl = cp_parser_lookup_name_simple (parser, id); parser->scope = old_scope; / If the lookup found a template-name, it means that the user forgot to specify an argument list. Emit a useful error message. / if (TREE_CODE (decl) == TEMPLATE_DECL) error ("invalid use of template-name %qE without an argument list", decl); else if (TREE_CODE (id) == BIT_NOT_EXPR) error ("invalid use of destructor %qD as a type", id); else if (TREE_CODE (decl) == TYPE_DECL) / Something like 'unsigned A a;' / error ("invalid combination of multiple type-specifiers"); else if (!parser->scope) { / Issue an error message. / error ("%qE does not name a type", id); / If we're in a template class, it's possible that the user was referring to a type from a base class. For example: template <typename T> struct A { typedef T X; }; template <typename T> struct B : public A<T> { X x; }; The user should have said "typename A<T>::X". / if (processing_template_decl && current_class_type && TYPE_BINFO (current_class_type)) { tree b; for (b = TREE_CHAIN (TYPE_BINFO (current_class_type)); b; b = TREE_CHAIN (b)) { tree base_type = BINFO_TYPE (b); if (CLASS_TYPE_P (base_type) && dependent_type_p (base_type)) { tree field; / Go from a particular instantiation of the template (which will have an empty TYPE_FIELDs), to the main version. / base_type = CLASSTYPE_PRIMARY_TEMPLATE_TYPE (base_type); for (field = TYPE_FIELDS (base_type); field; field = TREE_CHAIN (field)) if (TREE_CODE (field) == TYPE_DECL && DECL_NAME (field) == id) { inform ("(perhaps %<typename %T::%E%> was intended)", BINFO_TYPE (b), id); break; } if (field) break; } } } } / Here we diagnose qualified-ids where the scope is actually correct, but the identifier does not resolve to a valid type name. / else if (parser->scope != error_mark_node) { if (TREE_CODE (parser->scope) == NAMESPACE_DECL) error ("%qE in namespace %qE does not name a type", id, parser->scope); else if (TYPE_P (parser->scope)) error ("%qE in class %qT does not name a type", id, parser->scope); else gcc_unreachable (); } cp_parser_commit_to_tentative_parse (parser); } / Check for a common situation where a type-name should be present, but is not, and issue a sensible error message. Returns true if an invalid type-name was detected. The situation handled by this function are variable declarations of the form `ID a', where `ID' is an id-expression and `a' is a plain identifier. Usually, `ID' should name a type, but if we got here it means that it does not. We try to emit the best possible error message depending on how exactly the id-expression looks like. / static bool cp_parser_parse_and_diagnose_invalid_type_name (cp_parser parser) { tree id; cp_parser_parse_tentatively (parser); id = cp_parser_id_expression (parser, /template_keyword_p=/false, /check_dependency_p=/true, /template_p=/NULL, /declarator_p=/true, /optional_p=/false); /* After the id-expression, there should be a plain identifier, otherwise this is not a simple variable declaration. Also, if the scope is dependent, we cannot do much. / if (!cp_lexer_next_token_is (parser->lexer, CPP_NAME) \|\| (parser->scope && TYPE_P (parser->scope) && dependent_type_p (parser->scope)) \|\| TREE_CODE (id) == TYPE_DECL) { cp_parser_abort_tentative_parse (parser); return false; } if (!cp_parser_parse_definitely (parser)) return false; / Emit a diagnostic for the invalid type. / cp_parser_diagnose_invalid_type_name (parser, parser->scope, id); / Skip to the end of the declaration; there's no point in trying to process it. / cp_parser_skip_to_end_of_block_or_statement (parser); return true; } / Consume tokens up to, and including, the next non-nested closing `)'. Returns 1 iff we found a closing `)'. RECOVERING is true, if we are doing error recovery. Returns -1 if OR_COMMA is true and we found an unnested comma. / static int cp_parser_skip_to_closing_parenthesis (cp_parser parser, bool recovering, bool or_comma, bool consume_paren) { unsigned paren_depth = 0; unsigned brace_depth = 0; if (recovering && !or_comma && cp_parser_uncommitted_to_tentative_parse_p (parser)) return 0; while (true) { cp_token * token = cp_lexer_peek_token (parser->lexer); switch (token->type) { case CPP_EOF: case CPP_PRAGMA_EOL: /* If we've run out of tokens, then there is no closing `)'. / return 0; case CPP_SEMICOLON: / This matches the processing in skip_to_end_of_statement. / if (!brace_depth) return 0; break; case CPP_OPEN_BRACE: ++brace_depth; break; case CPP_CLOSE_BRACE: if (!brace_depth--) return 0; break; case CPP_COMMA: if (recovering && or_comma && !brace_depth && !paren_depth) return -1; break; case CPP_OPEN_PAREN: if (!brace_depth) ++paren_depth; break; case CPP_CLOSE_PAREN: if (!brace_depth && !paren_depth--) { if (consume_paren) cp_lexer_consume_token (parser->lexer); return 1; } break; default: break; } / Consume the token. / cp_lexer_consume_token (parser->lexer); } } / Consume tokens until we reach the end of the current statement. Normally, that will be just before consuming a `;'. However, if a non-nested `}' comes first, then we stop before consuming that. / static void cp_parser_skip_to_end_of_statement (cp_parser parser) { unsigned nesting_depth = 0; while (true) { cp_token token = cp_lexer_peek_token (parser->lexer); switch (token->type) { case CPP_EOF: case CPP_PRAGMA_EOL: / If we've run out of tokens, stop. / return; case CPP_SEMICOLON: / If the next token is a `;', we have reached the end of the statement. / if (!nesting_depth) return; break; case CPP_CLOSE_BRACE: / If this is a non-nested '}', stop before consuming it. That way, when confronted with something like: { 3 + } we stop before consuming the closing '}', even though we have not yet reached a `;'. / if (nesting_depth == 0) return; / If it is the closing '}' for a block that we have scanned, stop -- but only after consuming the token. That way given: void f g () { ... } typedef int I; we will stop after the body of the erroneously declared function, but before consuming the following `typedef' declaration. / if (--nesting_depth == 0) { cp_lexer_consume_token (parser->lexer); return; } case CPP_OPEN_BRACE: ++nesting_depth; break; default: break; } / Consume the token. / cp_lexer_consume_token (parser->lexer); } } / This function is called at the end of a statement or declaration. If the next token is a semicolon, it is consumed; otherwise, error recovery is attempted. / static void cp_parser_consume_semicolon_at_end_of_statement (cp_parser parser) { /* Look for the trailing `;'. / if (!cp_parser_require (parser, CPP_SEMICOLON, "`;'")) { / If there is additional (erroneous) input, skip to the end of the statement. / cp_parser_skip_to_end_of_statement (parser); / If the next token is now a `;', consume it. / if (cp_lexer_next_token_is (parser->lexer, CPP_SEMICOLON)) cp_lexer_consume_token (parser->lexer); } } / Skip tokens until we have consumed an entire block, or until we have consumed a non-nested `;'. / static void cp_parser_skip_to_end_of_block_or_statement (cp_parser parser) { int nesting_depth = 0; while (nesting_depth >= 0) { cp_token token = cp_lexer_peek_token (parser->lexer); switch (token->type) { case CPP_EOF: case CPP_PRAGMA_EOL: / If we've run out of tokens, stop. / return; case CPP_SEMICOLON: / Stop if this is an unnested ';'. / if (!nesting_depth) nesting_depth = -1; break; case CPP_CLOSE_BRACE: / Stop if this is an unnested '}', or closes the outermost nesting level. / nesting_depth--; if (!nesting_depth) nesting_depth = -1; break; case CPP_OPEN_BRACE: / Nest. / nesting_depth++; break; default: break; } / Consume the token. / cp_lexer_consume_token (parser->lexer); } } / Skip tokens until a non-nested closing curly brace is the next token. / static void cp_parser_skip_to_closing_brace (cp_parser parser) { unsigned nesting_depth = 0; while (true) { cp_token token = cp_lexer_peek_token (parser->lexer); switch (token->type) { case CPP_EOF: case CPP_PRAGMA_EOL: / If we've run out of tokens, stop. / return; case CPP_CLOSE_BRACE: / If the next token is a non-nested `}', then we have reached the end of the current block. / if (nesting_depth-- == 0) return; break; case CPP_OPEN_BRACE: / If it the next token is a `{', then we are entering a new block. Consume the entire block. / ++nesting_depth; break; default: break; } / Consume the token. / cp_lexer_consume_token (parser->lexer); } } / Consume tokens until we reach the end of the pragma. The PRAGMA_TOK parameter is the PRAGMA token, allowing us to purge the entire pragma sequence. / static void cp_parser_skip_to_pragma_eol (cp_parser parser, cp_token pragma_tok) { cp_token token; parser->lexer->in_pragma = false; do token = cp_lexer_consume_token (parser->lexer); while (token->type != CPP_PRAGMA_EOL && token->type != CPP_EOF); /* Ensure that the pragma is not parsed again. / cp_lexer_purge_tokens_after (parser->lexer, pragma_tok); } / Require pragma end of line, resyncing with it as necessary. The arguments are as for cp_parser_skip_to_pragma_eol. / static void cp_parser_require_pragma_eol (cp_parser parser, cp_token pragma_tok) { parser->lexer->in_pragma = false; if (!cp_parser_require (parser, CPP_PRAGMA_EOL, "end of line")) cp_parser_skip_to_pragma_eol (parser, pragma_tok); } / This is a simple wrapper around make_typename_type. When the id is an unresolved identifier node, we can provide a superior diagnostic using cp_parser_diagnose_invalid_type_name. / static tree cp_parser_make_typename_type (cp_parser parser, tree scope, tree id) { tree result; if (TREE_CODE (id) == IDENTIFIER_NODE) { result = make_typename_type (scope, id, typename_type, /complain=/tf_none); if (result == error_mark_node) cp_parser_diagnose_invalid_type_name (parser, scope, id); return result; } return make_typename_type (scope, id, typename_type, tf_error); } /* Create a new C++ parser. / static cp_parser cp_parser_new (void) { cp_parser parser; cp_lexer lexer; unsigned i; /* cp_lexer_new_main is called before calling ggc_alloc because cp_lexer_new_main might load a PCH file. / lexer = cp_lexer_new_main (); / Initialize the binops_by_token so that we can get the tree directly from the token. / for (i = 0; i < sizeof (binops) / sizeof (binops[0]); i++) binops_by_token[binops[i].token_type] = binops[i]; parser = GGC_CNEW (cp_parser); parser->lexer = lexer; parser->context = cp_parser_context_new (NULL); / For now, we always accept GNU extensions. / parser->allow_gnu_extensions_p = 1; / The `>' token is a greater-than operator, not the end of a template-id. / parser->greater_than_is_operator_p = true; parser->default_arg_ok_p = true; / We are not parsing a constant-expression. / parser->integral_constant_expression_p = false; parser->allow_non_integral_constant_expression_p = false; parser->non_integral_constant_expression_p = false; / Local variable names are not forbidden. / parser->local_variables_forbidden_p = false; / We are not processing an `extern "C"' declaration. / parser->in_unbraced_linkage_specification_p = false; / We are not processing a declarator. / parser->in_declarator_p = false; / We are not processing a template-argument-list. / parser->in_template_argument_list_p = false; / We are not in an iteration statement. / parser->in_statement = 0; / We are not in a switch statement. / parser->in_switch_statement_p = false; / We are not parsing a type-id inside an expression. / parser->in_type_id_in_expr_p = false; / Declarations aren't implicitly extern "C". / parser->implicit_extern_c = false; / String literals should be translated to the execution character set. / parser->translate_strings_p = true; / We are not parsing a function body. / parser->in_function_body = false; / The unparsed function queue is empty. / parser->unparsed_functions_queues = build_tree_list (NULL_TREE, NULL_TREE); / There are no classes being defined. / parser->num_classes_being_defined = 0; / No template parameters apply. / parser->num_template_parameter_lists = 0; return parser; } / Create a cp_lexer structure which will emit the tokens in CACHE and push it onto the parser's lexer stack. This is used for delayed parsing of in-class method bodies and default arguments, and should not be confused with tentative parsing. / static void cp_parser_push_lexer_for_tokens (cp_parser parser, cp_token_cache cache) { cp_lexer lexer = cp_lexer_new_from_tokens (cache); lexer->next = parser->lexer; parser->lexer = lexer; /* Move the current source position to that of the first token in the new lexer. / cp_lexer_set_source_position_from_token (lexer->next_token); } / Pop the top lexer off the parser stack. This is never used for the "main" lexer, only for those pushed by cp_parser_push_lexer_for_tokens. / static void cp_parser_pop_lexer (cp_parser parser) { cp_lexer lexer = parser->lexer; parser->lexer = lexer->next; cp_lexer_destroy (lexer); / Put the current source position back where it was before this lexer was pushed. / cp_lexer_set_source_position_from_token (parser->lexer->next_token); } / Lexical conventions [gram.lex] / / Parse an identifier. Returns an IDENTIFIER_NODE representing the identifier. / static tree cp_parser_identifier (cp_parser parser) { cp_token token; / Look for the identifier. / token = cp_parser_require (parser, CPP_NAME, "identifier"); / Return the value. / return token ? token->u.value : error_mark_node; } / Parse a sequence of adjacent string constants. Returns a TREE_STRING representing the combined, nul-terminated string constant. If TRANSLATE is true, translate the string to the execution character set. If WIDE_OK is true, a wide string is invalid here. C++98 [lex.string] says that if a narrow string literal token is adjacent to a wide string literal token, the behavior is undefined. However, C99 6.4.5p4 says that this results in a wide string literal. We follow C99 here, for consistency with the C front end. This code is largely lifted from lex_string() in c-lex.c. FUTURE: ObjC++ will need to handle @-strings here. / static tree cp_parser_string_literal (cp_parser parser, bool translate, bool wide_ok) { tree value; bool wide = false; size_t count; struct obstack str_ob; cpp_string str, istr, strs; cp_token tok; tok = cp_lexer_peek_token (parser->lexer); if (!cp_parser_is_string_literal (tok)) { cp_parser_error (parser, "expected string-literal"); return error_mark_node; } /* Try to avoid the overhead of creating and destroying an obstack for the common case of just one string. / if (!cp_parser_is_string_literal (cp_lexer_peek_nth_token (parser->lexer, 2))) { cp_lexer_consume_token (parser->lexer); str.text = (const unsigned char )TREE_STRING_POINTER (tok->u.value); str.len = TREE_STRING_LENGTH (tok->u.value); count = 1; if (tok->type == CPP_WSTRING) wide = true; strs = &str; } else { gcc_obstack_init (&str_ob); count = 0; do { cp_lexer_consume_token (parser->lexer); count++; str.text = (unsigned char )TREE_STRING_POINTER (tok->u.value); str.len = TREE_STRING_LENGTH (tok->u.value); if (tok->type == CPP_WSTRING) wide = true; obstack_grow (&str_ob, &str, sizeof (cpp_string)); tok = cp_lexer_peek_token (parser->lexer); } while (cp_parser_is_string_literal (tok)); strs = (cpp_string ) obstack_finish (&str_ob); } if (wide && !wide_ok) { cp_parser_error (parser, "a wide string is invalid in this context"); wide = false; } if ((translate ? cpp_interpret_string : cpp_interpret_string_notranslate) (parse_in, strs, count, &istr, wide)) { value = build_string (istr.len, (char )istr.text); free ((void )istr.text); TREE_TYPE (value) = wide ? wchar_array_type_node : char_array_type_node; value = fix_string_type (value); } else /* cpp_interpret_string has issued an error. / value = error_mark_node; if (count > 1) obstack_free (&str_ob, 0); return value; } / Basic concepts [gram.basic] / / Parse a translation-unit. translation-unit: declaration-seq [opt] Returns TRUE if all went well. / static bool cp_parser_translation_unit (cp_parser parser) { /* The address of the first non-permanent object on the declarator obstack. / static void declarator_obstack_base; bool success; /* Create the declarator obstack, if necessary. / if (!cp_error_declarator) { gcc_obstack_init (&declarator_obstack); / Create the error declarator. / cp_error_declarator = make_declarator (cdk_error); / Create the empty parameter list. / no_parameters = make_parameter_declarator (NULL, NULL, NULL_TREE); / Remember where the base of the declarator obstack lies. / declarator_obstack_base = obstack_next_free (&declarator_obstack); } cp_parser_declaration_seq_opt (parser); / If there are no tokens left then all went well. / if (cp_lexer_next_token_is (parser->lexer, CPP_EOF)) { / Get rid of the token array; we don't need it any more. / cp_lexer_destroy (parser->lexer); parser->lexer = NULL; / This file might have been a context that's implicitly extern "C". If so, pop the lang context. (Only relevant for PCH.) / if (parser->implicit_extern_c) { pop_lang_context (); parser->implicit_extern_c = false; } / Finish up. / finish_translation_unit (); success = true; } else { cp_parser_error (parser, "expected declaration"); success = false; } / Make sure the declarator obstack was fully cleaned up. / gcc_assert (obstack_next_free (&declarator_obstack) == declarator_obstack_base); / All went well. / return success; } / Expressions [gram.expr] / / Parse a primary-expression. primary-expression: literal this ( expression ) id-expression GNU Extensions: primary-expression: ( compound-statement ) __builtin_va_arg ( assignment-expression , type-id ) __builtin_offsetof ( type-id , offsetof-expression ) Objective-C++ Extension: primary-expression: objc-expression literal: __null ADDRESS_P is true iff this expression was immediately preceded by "&" and therefore might denote a pointer-to-member. CAST_P is true iff this expression is the target of a cast. TEMPLATE_ARG_P is true iff this expression is a template argument. Returns a representation of the expression. Upon return, IDK indicates what kind of id-expression (if any) was present. / static tree cp_parser_primary_expression (cp_parser parser, bool address_p, bool cast_p, bool template_arg_p, cp_id_kind idk) { cp_token token; / Assume the primary expression is not an id-expression. / idk = CP_ID_KIND_NONE; /* Peek at the next token. / token = cp_lexer_peek_token (parser->lexer); switch (token->type) { / literal: integer-literal character-literal floating-literal string-literal boolean-literal / case CPP_CHAR: case CPP_WCHAR: case CPP_NUMBER: token = cp_lexer_consume_token (parser->lexer); / Floating-point literals are only allowed in an integral constant expression if they are cast to an integral or enumeration type. / if (TREE_CODE (token->u.value) == REAL_CST && parser->integral_constant_expression_p && pedantic) { / CAST_P will be set even in invalid code like "int(2.7 + ...)". Therefore, we have to check that the next token is sure to end the cast. / if (cast_p) { cp_token next_token; next_token = cp_lexer_peek_token (parser->lexer); if (/* The comma at the end of an enumerator-definition. / next_token->type != CPP_COMMA / The curly brace at the end of an enum-specifier. / && next_token->type != CPP_CLOSE_BRACE / The end of a statement. / && next_token->type != CPP_SEMICOLON / The end of the cast-expression. / && next_token->type != CPP_CLOSE_PAREN / The end of an array bound. / && next_token->type != CPP_CLOSE_SQUARE / The closing ">" in a template-argument-list. / && (next_token->type != CPP_GREATER \|\| parser->greater_than_is_operator_p)) cast_p = false; } / If we are within a cast, then the constraint that the cast is to an integral or enumeration type will be checked at that point. If we are not within a cast, then this code is invalid. / if (!cast_p) cp_parser_non_integral_constant_expression (parser, "floating-point literal"); } return token->u.value; case CPP_STRING: case CPP_WSTRING: / ??? Should wide strings be allowed when parser->translate_strings_p is false (i.e. in attributes)? If not, we can kill the third argument to cp_parser_string_literal. / return cp_parser_string_literal (parser, parser->translate_strings_p, true); case CPP_OPEN_PAREN: { tree expr; bool saved_greater_than_is_operator_p; / Consume the `('. / cp_lexer_consume_token (parser->lexer); / Within a parenthesized expression, a `>' token is always the greater-than operator. / saved_greater_than_is_operator_p = parser->greater_than_is_operator_p; parser->greater_than_is_operator_p = true; / If we see `( { ' then we are looking at the beginning of a GNU statement-expression. / if (cp_parser_allow_gnu_extensions_p (parser) && cp_lexer_next_token_is (parser->lexer, CPP_OPEN_BRACE)) { / Statement-expressions are not allowed by the standard. / if (pedantic) pedwarn ("ISO C++ forbids braced-groups within expressions"); / And they're not allowed outside of a function-body; you cannot, for example, write: int i = ({ int j = 3; j + 1; }); at class or namespace scope. / if (!parser->in_function_body) error ("statement-expressions are allowed only inside functions"); / Start the statement-expression. / expr = begin_stmt_expr (); / Parse the compound-statement. / cp_parser_compound_statement (parser, expr, false); / Finish up. / expr = finish_stmt_expr (expr, false); } else { / Parse the parenthesized expression. / expr = cp_parser_expression (parser, cast_p); / Let the front end know that this expression was enclosed in parentheses. This matters in case, for example, the expression is of the form `A::B', since `&A::B' might be a pointer-to-member, but `&(A::B)' is not. / finish_parenthesized_expr (expr); } / The `>' token might be the end of a template-id or template-parameter-list now. / parser->greater_than_is_operator_p = saved_greater_than_is_operator_p; / Consume the `)'. / if (!cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'")) cp_parser_skip_to_end_of_statement (parser); return expr; } case CPP_KEYWORD: switch (token->keyword) { / These two are the boolean literals. / case RID_TRUE: cp_lexer_consume_token (parser->lexer); return boolean_true_node; case RID_FALSE: cp_lexer_consume_token (parser->lexer); return boolean_false_node; / The `__null' literal. / case RID_NULL: cp_lexer_consume_token (parser->lexer); return null_node; / Recognize the `this' keyword. / case RID_THIS: cp_lexer_consume_token (parser->lexer); if (parser->local_variables_forbidden_p) { error ("%<this%> may not be used in this context"); return error_mark_node; } / Pointers cannot appear in constant-expressions. / if (cp_parser_non_integral_constant_expression (parser, "`this'")) return error_mark_node; return finish_this_expr (); / The `operator' keyword can be the beginning of an id-expression. / case RID_OPERATOR: goto id_expression; case RID_FUNCTION_NAME: case RID_PRETTY_FUNCTION_NAME: case RID_C99_FUNCTION_NAME: / The symbols __FUNCTION__, __PRETTY_FUNCTION__, and __func__ are the names of variables -- but they are treated specially. Therefore, they are handled here, rather than relying on the generic id-expression logic below. Grammatically, these names are id-expressions. Consume the token. / token = cp_lexer_consume_token (parser->lexer); / Look up the name. / return finish_fname (token->u.value); case RID_VA_ARG: { tree expression; tree type; / The `__builtin_va_arg' construct is used to handle `va_arg'. Consume the `__builtin_va_arg' token. / cp_lexer_consume_token (parser->lexer); / Look for the opening `('. / cp_parser_require (parser, CPP_OPEN_PAREN, "`('"); / Now, parse the assignment-expression. / expression = cp_parser_assignment_expression (parser, /cast_p=/false); / Look for the `,'. / cp_parser_require (parser, CPP_COMMA, "`,'"); / Parse the type-id. / type = cp_parser_type_id (parser); / Look for the closing `)'. / cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'"); / Using `va_arg' in a constant-expression is not allowed. / if (cp_parser_non_integral_constant_expression (parser, "`va_arg'")) return error_mark_node; return build_x_va_arg (expression, type); } case RID_OFFSETOF: return cp_parser_builtin_offsetof (parser); / Objective-C++ expressions. / case RID_AT_ENCODE: case RID_AT_PROTOCOL: case RID_AT_SELECTOR: return cp_parser_objc_expression (parser); default: cp_parser_error (parser, "expected primary-expression"); return error_mark_node; } / An id-expression can start with either an identifier, a `::' as the beginning of a qualified-id, or the "operator" keyword. / case CPP_NAME: case CPP_SCOPE: case CPP_TEMPLATE_ID: case CPP_NESTED_NAME_SPECIFIER: { tree id_expression; tree decl; const char error_msg; bool template_p; bool done; id_expression: /* Parse the id-expression. / id_expression = cp_parser_id_expression (parser, /template_keyword_p=/false, /check_dependency_p=/true, &template_p, /declarator_p=/false, /optional_p=/false); if (id_expression == error_mark_node) return error_mark_node; token = cp_lexer_peek_token (parser->lexer); done = (token->type != CPP_OPEN_SQUARE && token->type != CPP_OPEN_PAREN && token->type != CPP_DOT && token->type != CPP_DEREF && token->type != CPP_PLUS_PLUS && token->type != CPP_MINUS_MINUS); / If we have a template-id, then no further lookup is required. If the template-id was for a template-class, we will sometimes have a TYPE_DECL at this point. / if (TREE_CODE (id_expression) == TEMPLATE_ID_EXPR \|\| TREE_CODE (id_expression) == TYPE_DECL) decl = id_expression; / Look up the name. / else { tree ambiguous_decls; decl = cp_parser_lookup_name (parser, id_expression, none_type, template_p, /is_namespace=/false, /check_dependency=/true, &ambiguous_decls); / If the lookup was ambiguous, an error will already have been issued. / if (ambiguous_decls) return error_mark_node; / In Objective-C++, an instance variable (ivar) may be preferred to whatever cp_parser_lookup_name() found. / decl = objc_lookup_ivar (decl, id_expression); / If name lookup gives us a SCOPE_REF, then the qualifying scope was dependent. / if (TREE_CODE (decl) == SCOPE_REF) { / At this point, we do not know if DECL is a valid integral constant expression. We assume that it is in fact such an expression, so that code like: template <int N> struct A { int a[B<N>::i]; }; is accepted. At template-instantiation time, we will check that B<N>::i is actually a constant. / return decl; } / Check to see if DECL is a local variable in a context where that is forbidden. / if (parser->local_variables_forbidden_p && local_variable_p (decl)) { / It might be that we only found DECL because we are trying to be generous with pre-ISO scoping rules. For example, consider: int i; void g() { for (int i = 0; i < 10; ++i) {} extern void f(int j = i); } Here, name look up will originally find the out of scope `i'. We need to issue a warning message, but then use the global `i'. / decl = check_for_out_of_scope_variable (decl); if (local_variable_p (decl)) { error ("local variable %qD may not appear in this context", decl); return error_mark_node; } } } decl = (finish_id_expression (id_expression, decl, parser->scope, idk, parser->integral_constant_expression_p, parser->allow_non_integral_constant_expression_p, &parser->non_integral_constant_expression_p, template_p, done, address_p, template_arg_p, &error_msg)); if (error_msg) cp_parser_error (parser, error_msg); return decl; } / Anything else is an error. / default: / ...unless we have an Objective-C++ message or string literal, that is. / if (c_dialect_objc () && (token->type == CPP_OPEN_SQUARE \|\| token->type == CPP_OBJC_STRING)) return cp_parser_objc_expression (parser); cp_parser_error (parser, "expected primary-expression"); return error_mark_node; } } / Parse an id-expression. id-expression: unqualified-id qualified-id qualified-id: :: [opt] nested-name-specifier template [opt] unqualified-id :: identifier :: operator-function-id :: template-id Return a representation of the unqualified portion of the identifier. Sets PARSER->SCOPE to the qualifying scope if there is a `::' or nested-name-specifier. Often, if the id-expression was a qualified-id, the caller will want to make a SCOPE_REF to represent the qualified-id. This function does not do this in order to avoid wastefully creating SCOPE_REFs when they are not required. If TEMPLATE_KEYWORD_P is true, then we have just seen the `template' keyword. If CHECK_DEPENDENCY_P is false, then names are looked up inside uninstantiated templates. If TEMPLATE_P is non-NULL, it is set to true iff the `template' keyword is used to explicitly indicate that the entity named is a template. If DECLARATOR_P is true, the id-expression is appearing as part of a declarator, rather than as part of an expression. / static tree cp_parser_id_expression (cp_parser parser, bool template_keyword_p, bool check_dependency_p, bool template_p, bool declarator_p, bool optional_p) { bool global_scope_p; bool nested_name_specifier_p; /* Assume the `template' keyword was not used. / if (template_p) template_p = template_keyword_p; /* Look for the optional `::' operator. / global_scope_p = (cp_parser_global_scope_opt (parser, /current_scope_valid_p=/false) != NULL_TREE); / Look for the optional nested-name-specifier. / nested_name_specifier_p = (cp_parser_nested_name_specifier_opt (parser, /typename_keyword_p=/false, check_dependency_p, /type_p=/false, declarator_p) != NULL_TREE); / If there is a nested-name-specifier, then we are looking at the first qualified-id production. / if (nested_name_specifier_p) { tree saved_scope; tree saved_object_scope; tree saved_qualifying_scope; tree unqualified_id; bool is_template; / See if the next token is the `template' keyword. / if (!template_p) template_p = &is_template; template_p = cp_parser_optional_template_keyword (parser); /* Name lookup we do during the processing of the unqualified-id might obliterate SCOPE. / saved_scope = parser->scope; saved_object_scope = parser->object_scope; saved_qualifying_scope = parser->qualifying_scope; / Process the final unqualified-id. / unqualified_id = cp_parser_unqualified_id (parser, template_p, check_dependency_p, declarator_p, /optional_p=/false); /* Restore the SAVED_SCOPE for our caller. / parser->scope = saved_scope; parser->object_scope = saved_object_scope; parser->qualifying_scope = saved_qualifying_scope; return unqualified_id; } / Otherwise, if we are in global scope, then we are looking at one of the other qualified-id productions. / else if (global_scope_p) { cp_token token; tree id; /* Peek at the next token. / token = cp_lexer_peek_token (parser->lexer); / If it's an identifier, and the next token is not a "<", then we can avoid the template-id case. This is an optimization for this common case. / if (token->type == CPP_NAME && !cp_parser_nth_token_starts_template_argument_list_p (parser, 2)) return cp_parser_identifier (parser); cp_parser_parse_tentatively (parser); / Try a template-id. / id = cp_parser_template_id (parser, /template_keyword_p=/false, /check_dependency_p=/true, declarator_p); / If that worked, we're done. / if (cp_parser_parse_definitely (parser)) return id; / Peek at the next token. (Changes in the token buffer may have invalidated the pointer obtained above.) / token = cp_lexer_peek_token (parser->lexer); switch (token->type) { case CPP_NAME: return cp_parser_identifier (parser); case CPP_KEYWORD: if (token->keyword == RID_OPERATOR) return cp_parser_operator_function_id (parser); / Fall through. / default: cp_parser_error (parser, "expected id-expression"); return error_mark_node; } } else return cp_parser_unqualified_id (parser, template_keyword_p, /check_dependency_p=/true, declarator_p, optional_p); } / Parse an unqualified-id. unqualified-id: identifier operator-function-id conversion-function-id ~ class-name template-id If TEMPLATE_KEYWORD_P is TRUE, we have just seen the `template' keyword, in a construct like `A::template ...'. Returns a representation of unqualified-id. For the `identifier' production, an IDENTIFIER_NODE is returned. For the `~ class-name' production a BIT_NOT_EXPR is returned; the operand of the BIT_NOT_EXPR is an IDENTIFIER_NODE for the class-name. For the other productions, see the documentation accompanying the corresponding parsing functions. If CHECK_DEPENDENCY_P is false, names are looked up in uninstantiated templates. If DECLARATOR_P is true, the unqualified-id is appearing as part of a declarator, rather than as part of an expression. / static tree cp_parser_unqualified_id (cp_parser parser, bool template_keyword_p, bool check_dependency_p, bool declarator_p, bool optional_p) { cp_token token; / Peek at the next token. / token = cp_lexer_peek_token (parser->lexer); switch (token->type) { case CPP_NAME: { tree id; / We don't know yet whether or not this will be a template-id. / cp_parser_parse_tentatively (parser); / Try a template-id. / id = cp_parser_template_id (parser, template_keyword_p, check_dependency_p, declarator_p); / If it worked, we're done. / if (cp_parser_parse_definitely (parser)) return id; / Otherwise, it's an ordinary identifier. / return cp_parser_identifier (parser); } case CPP_TEMPLATE_ID: return cp_parser_template_id (parser, template_keyword_p, check_dependency_p, declarator_p); case CPP_COMPL: { tree type_decl; tree qualifying_scope; tree object_scope; tree scope; bool done; / Consume the `~' token. / cp_lexer_consume_token (parser->lexer); / Parse the class-name. The standard, as written, seems to say that: template <typename T> struct S { ~S (); }; template <typename T> S<T>::~S() {} is invalid, since `~' must be followed by a class-name, but `S<T>' is dependent, and so not known to be a class. That's not right; we need to look in uninstantiated templates. A further complication arises from: template <typename T> void f(T t) { t.T::~T(); } Here, it is not possible to look up `T' in the scope of `T' itself. We must look in both the current scope, and the scope of the containing complete expression. Yet another issue is: struct S { int S; ~S(); }; S::~S() {} The standard does not seem to say that the `S' in `~S' should refer to the type `S' and not the data member `S::S'. / / DR 244 says that we look up the name after the "~" in the same scope as we looked up the qualifying name. That idea isn't fully worked out; it's more complicated than that. / scope = parser->scope; object_scope = parser->object_scope; qualifying_scope = parser->qualifying_scope; / Check for invalid scopes. / if (scope == error_mark_node) { if (cp_lexer_next_token_is (parser->lexer, CPP_NAME)) cp_lexer_consume_token (parser->lexer); return error_mark_node; } if (scope && TREE_CODE (scope) == NAMESPACE_DECL) { if (!cp_parser_uncommitted_to_tentative_parse_p (parser)) error ("scope %qT before %<~%> is not a class-name", scope); cp_parser_simulate_error (parser); if (cp_lexer_next_token_is (parser->lexer, CPP_NAME)) cp_lexer_consume_token (parser->lexer); return error_mark_node; } gcc_assert (!scope \|\| TYPE_P (scope)); / If the name is of the form "X::~X" it's OK. / token = cp_lexer_peek_token (parser->lexer); if (scope && token->type == CPP_NAME && (cp_lexer_peek_nth_token (parser->lexer, 2)->type == CPP_OPEN_PAREN) && constructor_name_p (token->u.value, scope)) { cp_lexer_consume_token (parser->lexer); return build_nt (BIT_NOT_EXPR, scope); } / If there was an explicit qualification (S::~T), first look in the scope given by the qualification (i.e., S). / done = false; type_decl = NULL_TREE; if (scope) { cp_parser_parse_tentatively (parser); type_decl = cp_parser_class_name (parser, /typename_keyword_p=/false, /template_keyword_p=/false, none_type, /check_dependency=/false, /class_head_p=/false, declarator_p); if (cp_parser_parse_definitely (parser)) done = true; } / In "N::S::~S", look in "N" as well. / if (!done && scope && qualifying_scope) { cp_parser_parse_tentatively (parser); parser->scope = qualifying_scope; parser->object_scope = NULL_TREE; parser->qualifying_scope = NULL_TREE; type_decl = cp_parser_class_name (parser, /typename_keyword_p=/false, /template_keyword_p=/false, none_type, /check_dependency=/false, /class_head_p=/false, declarator_p); if (cp_parser_parse_definitely (parser)) done = true; } / In "p->S::~T", look in the scope given by "p" as well. / else if (!done && object_scope) { cp_parser_parse_tentatively (parser); parser->scope = object_scope; parser->object_scope = NULL_TREE; parser->qualifying_scope = NULL_TREE; type_decl = cp_parser_class_name (parser, /typename_keyword_p=/false, /template_keyword_p=/false, none_type, /check_dependency=/false, /class_head_p=/false, declarator_p); if (cp_parser_parse_definitely (parser)) done = true; } /* Look in the surrounding context. / if (!done) { parser->scope = NULL_TREE; parser->object_scope = NULL_TREE; parser->qualifying_scope = NULL_TREE; type_decl = cp_parser_class_name (parser, /typename_keyword_p=/false, /template_keyword_p=/false, none_type, /check_dependency=/false, /class_head_p=/false, declarator_p); } / If an error occurred, assume that the name of the destructor is the same as the name of the qualifying class. That allows us to keep parsing after running into ill-formed destructor names. / if (type_decl == error_mark_node && scope) return build_nt (BIT_NOT_EXPR, scope); else if (type_decl == error_mark_node) return error_mark_node; / Check that destructor name and scope match. / if (declarator_p && scope && !check_dtor_name (scope, type_decl)) { if (!cp_parser_uncommitted_to_tentative_parse_p (parser)) error ("declaration of %<~%T%> as member of %qT", type_decl, scope); cp_parser_simulate_error (parser); return error_mark_node; } / [class.dtor] A typedef-name that names a class shall not be used as the identifier in the declarator for a destructor declaration. / if (declarator_p && !DECL_IMPLICIT_TYPEDEF_P (type_decl) && !DECL_SELF_REFERENCE_P (type_decl) && !cp_parser_uncommitted_to_tentative_parse_p (parser)) error ("typedef-name %qD used as destructor declarator", type_decl); return build_nt (BIT_NOT_EXPR, TREE_TYPE (type_decl)); } case CPP_KEYWORD: if (token->keyword == RID_OPERATOR) { tree id; / This could be a template-id, so we try that first. / cp_parser_parse_tentatively (parser); / Try a template-id. / id = cp_parser_template_id (parser, template_keyword_p, /check_dependency_p=/true, declarator_p); / If that worked, we're done. / if (cp_parser_parse_definitely (parser)) return id; / We still don't know whether we're looking at an operator-function-id or a conversion-function-id. / cp_parser_parse_tentatively (parser); / Try an operator-function-id. / id = cp_parser_operator_function_id (parser); / If that didn't work, try a conversion-function-id. / if (!cp_parser_parse_definitely (parser)) id = cp_parser_conversion_function_id (parser); return id; } / Fall through. / default: if (optional_p) return NULL_TREE; cp_parser_error (parser, "expected unqualified-id"); return error_mark_node; } } / Parse an (optional) nested-name-specifier. nested-name-specifier: class-or-namespace-name :: nested-name-specifier [opt] class-or-namespace-name :: template nested-name-specifier [opt] PARSER->SCOPE should be set appropriately before this function is called. TYPENAME_KEYWORD_P is TRUE if the `typename' keyword is in effect. TYPE_P is TRUE if we non-type bindings should be ignored in name lookups. Sets PARSER->SCOPE to the class (TYPE) or namespace (NAMESPACE_DECL) specified by the nested-name-specifier, or leaves it unchanged if there is no nested-name-specifier. Returns the new scope iff there is a nested-name-specifier, or NULL_TREE otherwise. If IS_DECLARATION is TRUE, the nested-name-specifier is known to be part of a declaration and/or decl-specifier. / static tree cp_parser_nested_name_specifier_opt (cp_parser parser, bool typename_keyword_p, bool check_dependency_p, bool type_p, bool is_declaration) { bool success = false; cp_token_position start = 0; cp_token token; / Remember where the nested-name-specifier starts. / if (cp_parser_uncommitted_to_tentative_parse_p (parser)) { start = cp_lexer_token_position (parser->lexer, false); push_deferring_access_checks (dk_deferred); } while (true) { tree new_scope; tree old_scope; tree saved_qualifying_scope; bool template_keyword_p; / Spot cases that cannot be the beginning of a nested-name-specifier. / token = cp_lexer_peek_token (parser->lexer); / If the next token is CPP_NESTED_NAME_SPECIFIER, just process the already parsed nested-name-specifier. / if (token->type == CPP_NESTED_NAME_SPECIFIER) { / Grab the nested-name-specifier and continue the loop. / cp_parser_pre_parsed_nested_name_specifier (parser); / If we originally encountered this nested-name-specifier with IS_DECLARATION set to false, we will not have resolved TYPENAME_TYPEs, so we must do so here. / if (is_declaration && TREE_CODE (parser->scope) == TYPENAME_TYPE) { new_scope = resolve_typename_type (parser->scope, /only_current_p=/false); if (new_scope != error_mark_node) parser->scope = new_scope; } success = true; continue; } / Spot cases that cannot be the beginning of a nested-name-specifier. On the second and subsequent times through the loop, we look for the `template' keyword. / if (success && token->keyword == RID_TEMPLATE) ; / A template-id can start a nested-name-specifier. / else if (token->type == CPP_TEMPLATE_ID) ; else { / If the next token is not an identifier, then it is definitely not a class-or-namespace-name. / if (token->type != CPP_NAME) break; / If the following token is neither a `<' (to begin a template-id), nor a `::', then we are not looking at a nested-name-specifier. / token = cp_lexer_peek_nth_token (parser->lexer, 2); if (token->type != CPP_SCOPE && !cp_parser_nth_token_starts_template_argument_list_p (parser, 2)) break; } / The nested-name-specifier is optional, so we parse tentatively. / cp_parser_parse_tentatively (parser); / Look for the optional `template' keyword, if this isn't the first time through the loop. / if (success) template_keyword_p = cp_parser_optional_template_keyword (parser); else template_keyword_p = false; / Save the old scope since the name lookup we are about to do might destroy it. / old_scope = parser->scope; saved_qualifying_scope = parser->qualifying_scope; / In a declarator-id like "X<T>::I::Y<T>" we must be able to look up names in "X<T>::I" in order to determine that "Y" is a template. So, if we have a typename at this point, we make an effort to look through it. / if (is_declaration && !typename_keyword_p && parser->scope && TREE_CODE (parser->scope) == TYPENAME_TYPE) parser->scope = resolve_typename_type (parser->scope, /only_current_p=/false); / Parse the qualifying entity. / new_scope = cp_parser_class_or_namespace_name (parser, typename_keyword_p, template_keyword_p, check_dependency_p, type_p, is_declaration); / Look for the `::' token. / cp_parser_require (parser, CPP_SCOPE, "`::'"); / If we found what we wanted, we keep going; otherwise, we're done. / if (!cp_parser_parse_definitely (parser)) { bool error_p = false; / Restore the OLD_SCOPE since it was valid before the failed attempt at finding the last class-or-namespace-name. / parser->scope = old_scope; parser->qualifying_scope = saved_qualifying_scope; if (cp_parser_uncommitted_to_tentative_parse_p (parser)) break; / If the next token is an identifier, and the one after that is a `::', then any valid interpretation would have found a class-or-namespace-name. / while (cp_lexer_next_token_is (parser->lexer, CPP_NAME) && (cp_lexer_peek_nth_token (parser->lexer, 2)->type == CPP_SCOPE) && (cp_lexer_peek_nth_token (parser->lexer, 3)->type != CPP_COMPL)) { token = cp_lexer_consume_token (parser->lexer); if (!error_p) { if (!token->ambiguous_p) { tree decl; tree ambiguous_decls; decl = cp_parser_lookup_name (parser, token->u.value, none_type, /is_template=/false, /is_namespace=/false, /check_dependency=/true, &ambiguous_decls); if (TREE_CODE (decl) == TEMPLATE_DECL) error ("%qD used without template parameters", decl); else if (ambiguous_decls) { error ("reference to %qD is ambiguous", token->u.value); print_candidates (ambiguous_decls); decl = error_mark_node; } else cp_parser_name_lookup_error (parser, token->u.value, decl, "is not a class or namespace"); } parser->scope = error_mark_node; error_p = true; / Treat this as a successful nested-name-specifier due to: [basic.lookup.qual] If the name found is not a class-name (clause _class_) or namespace-name (_namespace.def_), the program is ill-formed. / success = true; } cp_lexer_consume_token (parser->lexer); } break; } / We've found one valid nested-name-specifier. / success = true; / Name lookup always gives us a DECL. / if (TREE_CODE (new_scope) == TYPE_DECL) new_scope = TREE_TYPE (new_scope); / Uses of "template" must be followed by actual templates. / if (template_keyword_p && !(CLASS_TYPE_P (new_scope) && ((CLASSTYPE_USE_TEMPLATE (new_scope) && PRIMARY_TEMPLATE_P (CLASSTYPE_TI_TEMPLATE (new_scope))) \|\| CLASSTYPE_IS_TEMPLATE (new_scope))) && !(TREE_CODE (new_scope) == TYPENAME_TYPE && (TREE_CODE (TYPENAME_TYPE_FULLNAME (new_scope)) == TEMPLATE_ID_EXPR))) pedwarn (TYPE_P (new_scope) ? "%qT is not a template" : "%qD is not a template", new_scope); / If it is a class scope, try to complete it; we are about to be looking up names inside the class. / if (TYPE_P (new_scope) / Since checking types for dependency can be expensive, avoid doing it if the type is already complete. / && !COMPLETE_TYPE_P (new_scope) / Do not try to complete dependent types. / && !dependent_type_p (new_scope)) new_scope = complete_type (new_scope); / Make sure we look in the right scope the next time through the loop. / parser->scope = new_scope; } / If parsing tentatively, replace the sequence of tokens that makes up the nested-name-specifier with a CPP_NESTED_NAME_SPECIFIER token. That way, should we re-parse the token stream, we will not have to repeat the effort required to do the parse, nor will we issue duplicate error messages. / if (success && start) { cp_token token; token = cp_lexer_token_at (parser->lexer, start); /* Reset the contents of the START token. / token->type = CPP_NESTED_NAME_SPECIFIER; / Retrieve any deferred checks. Do not pop this access checks yet so the memory will not be reclaimed during token replacing below. / token->u.tree_check_value = GGC_CNEW (struct tree_check); token->u.tree_check_value->value = parser->scope; token->u.tree_check_value->checks = get_deferred_access_checks (); token->u.tree_check_value->qualifying_scope = parser->qualifying_scope; token->keyword = RID_MAX; / Purge all subsequent tokens. / cp_lexer_purge_tokens_after (parser->lexer, start); } if (start) pop_to_parent_deferring_access_checks (); return success ? parser->scope : NULL_TREE; } / Parse a nested-name-specifier. See cp_parser_nested_name_specifier_opt for details. This function behaves identically, except that it will an issue an error if no nested-name-specifier is present. / static tree cp_parser_nested_name_specifier (cp_parser parser, bool typename_keyword_p, bool check_dependency_p, bool type_p, bool is_declaration) { tree scope; /* Look for the nested-name-specifier. / scope = cp_parser_nested_name_specifier_opt (parser, typename_keyword_p, check_dependency_p, type_p, is_declaration); / If it was not present, issue an error message. / if (!scope) { cp_parser_error (parser, "expected nested-name-specifier"); parser->scope = NULL_TREE; } return scope; } / Parse a class-or-namespace-name. class-or-namespace-name: class-name namespace-name TYPENAME_KEYWORD_P is TRUE iff the `typename' keyword is in effect. TEMPLATE_KEYWORD_P is TRUE iff the `template' keyword is in effect. CHECK_DEPENDENCY_P is FALSE iff dependent names should be looked up. TYPE_P is TRUE iff the next name should be taken as a class-name, even the same name is declared to be another entity in the same scope. Returns the class (TYPE_DECL) or namespace (NAMESPACE_DECL) specified by the class-or-namespace-name. If neither is found the ERROR_MARK_NODE is returned. / static tree cp_parser_class_or_namespace_name (cp_parser parser, bool typename_keyword_p, bool template_keyword_p, bool check_dependency_p, bool type_p, bool is_declaration) { tree saved_scope; tree saved_qualifying_scope; tree saved_object_scope; tree scope; bool only_class_p; /* Before we try to parse the class-name, we must save away the current PARSER->SCOPE since cp_parser_class_name will destroy it. / saved_scope = parser->scope; saved_qualifying_scope = parser->qualifying_scope; saved_object_scope = parser->object_scope; / Try for a class-name first. If the SAVED_SCOPE is a type, then there is no need to look for a namespace-name. / only_class_p = template_keyword_p \|\| (saved_scope && TYPE_P (saved_scope)); if (!only_class_p) cp_parser_parse_tentatively (parser); scope = cp_parser_class_name (parser, typename_keyword_p, template_keyword_p, type_p ? class_type : none_type, check_dependency_p, /class_head_p=/false, is_declaration); / If that didn't work, try for a namespace-name. / if (!only_class_p && !cp_parser_parse_definitely (parser)) { / Restore the saved scope. / parser->scope = saved_scope; parser->qualifying_scope = saved_qualifying_scope; parser->object_scope = saved_object_scope; / If we are not looking at an identifier followed by the scope resolution operator, then this is not part of a nested-name-specifier. (Note that this function is only used to parse the components of a nested-name-specifier.) / if (cp_lexer_next_token_is_not (parser->lexer, CPP_NAME) \|\| cp_lexer_peek_nth_token (parser->lexer, 2)->type != CPP_SCOPE) return error_mark_node; scope = cp_parser_namespace_name (parser); } return scope; } / Parse a postfix-expression. postfix-expression: primary-expression postfix-expression [ expression ] postfix-expression ( expression-list [opt] ) simple-type-specifier ( expression-list [opt] ) typename :: [opt] nested-name-specifier identifier ( expression-list [opt] ) typename :: [opt] nested-name-specifier template [opt] template-id ( expression-list [opt] ) postfix-expression . template [opt] id-expression postfix-expression -> template [opt] id-expression postfix-expression . pseudo-destructor-name postfix-expression -> pseudo-destructor-name postfix-expression ++ postfix-expression -- dynamic_cast < type-id > ( expression ) static_cast < type-id > ( expression ) reinterpret_cast < type-id > ( expression ) const_cast < type-id > ( expression ) typeid ( expression ) typeid ( type-id ) GNU Extension: postfix-expression: ( type-id ) { initializer-list , [opt] } This extension is a GNU version of the C99 compound-literal construct. (The C99 grammar uses `type-name' instead of `type-id', but they are essentially the same concept.) If ADDRESS_P is true, the postfix expression is the operand of the `&' operator. CAST_P is true if this expression is the target of a cast. Returns a representation of the expression. / static tree cp_parser_postfix_expression (cp_parser parser, bool address_p, bool cast_p) { cp_token token; enum rid keyword; cp_id_kind idk = CP_ID_KIND_NONE; tree postfix_expression = NULL_TREE; / Peek at the next token. / token = cp_lexer_peek_token (parser->lexer); / Some of the productions are determined by keywords. / keyword = token->keyword; switch (keyword) { case RID_DYNCAST: case RID_STATCAST: case RID_REINTCAST: case RID_CONSTCAST: { tree type; tree expression; const char saved_message; /* All of these can be handled in the same way from the point of view of parsing. Begin by consuming the token identifying the cast. / cp_lexer_consume_token (parser->lexer); / New types cannot be defined in the cast. / saved_message = parser->type_definition_forbidden_message; parser->type_definition_forbidden_message = "types may not be defined in casts"; / Look for the opening `<'. / cp_parser_require (parser, CPP_LESS, "`<'"); / Parse the type to which we are casting. / type = cp_parser_type_id (parser); / Look for the closing `>'. / cp_parser_require (parser, CPP_GREATER, "`>'"); / Restore the old message. / parser->type_definition_forbidden_message = saved_message; / And the expression which is being cast. / cp_parser_require (parser, CPP_OPEN_PAREN, "`('"); expression = cp_parser_expression (parser, /cast_p=/true); cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'"); / Only type conversions to integral or enumeration types can be used in constant-expressions. / if (!cast_valid_in_integral_constant_expression_p (type) && (cp_parser_non_integral_constant_expression (parser, "a cast to a type other than an integral or " "enumeration type"))) return error_mark_node; switch (keyword) { case RID_DYNCAST: postfix_expression = build_dynamic_cast (type, expression); break; case RID_STATCAST: postfix_expression = build_static_cast (type, expression); break; case RID_REINTCAST: postfix_expression = build_reinterpret_cast (type, expression); break; case RID_CONSTCAST: postfix_expression = build_const_cast (type, expression); break; default: gcc_unreachable (); } } break; case RID_TYPEID: { tree type; const char saved_message; bool saved_in_type_id_in_expr_p; /* Consume the `typeid' token. / cp_lexer_consume_token (parser->lexer); / Look for the `(' token. / cp_parser_require (parser, CPP_OPEN_PAREN, "`('"); / Types cannot be defined in a `typeid' expression. / saved_message = parser->type_definition_forbidden_message; parser->type_definition_forbidden_message = "types may not be defined in a `typeid\' expression"; / We can't be sure yet whether we're looking at a type-id or an expression. / cp_parser_parse_tentatively (parser); / Try a type-id first. / saved_in_type_id_in_expr_p = parser->in_type_id_in_expr_p; parser->in_type_id_in_expr_p = true; type = cp_parser_type_id (parser); parser->in_type_id_in_expr_p = saved_in_type_id_in_expr_p; / Look for the `)' token. Otherwise, we can't be sure that we're not looking at an expression: consider `typeid (int (3))', for example. / cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'"); / If all went well, simply lookup the type-id. / if (cp_parser_parse_definitely (parser)) postfix_expression = get_typeid (type); / Otherwise, fall back to the expression variant. / else { tree expression; / Look for an expression. / expression = cp_parser_expression (parser, /cast_p=/false); / Compute its typeid. / postfix_expression = build_typeid (expression); / Look for the `)' token. / cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'"); } / Restore the saved message. / parser->type_definition_forbidden_message = saved_message; / `typeid' may not appear in an integral constant expression. / if (cp_parser_non_integral_constant_expression(parser, "`typeid' operator")) return error_mark_node; } break; case RID_TYPENAME: { tree type; / The syntax permitted here is the same permitted for an elaborated-type-specifier. / type = cp_parser_elaborated_type_specifier (parser, /is_friend=/false, /is_declaration=/false); postfix_expression = cp_parser_functional_cast (parser, type); } break; default: { tree type; / If the next thing is a simple-type-specifier, we may be looking at a functional cast. We could also be looking at an id-expression. So, we try the functional cast, and if that doesn't work we fall back to the primary-expression. / cp_parser_parse_tentatively (parser); / Look for the simple-type-specifier. / type = cp_parser_simple_type_specifier (parser, /decl_specs=/NULL, CP_PARSER_FLAGS_NONE); / Parse the cast itself. / if (!cp_parser_error_occurred (parser)) postfix_expression = cp_parser_functional_cast (parser, type); / If that worked, we're done. / if (cp_parser_parse_definitely (parser)) break; / If the functional-cast didn't work out, try a compound-literal. / if (cp_parser_allow_gnu_extensions_p (parser) && cp_lexer_next_token_is (parser->lexer, CPP_OPEN_PAREN)) { VEC(constructor_elt,gc) initializer_list = NULL; bool saved_in_type_id_in_expr_p; cp_parser_parse_tentatively (parser); /* Consume the `('. / cp_lexer_consume_token (parser->lexer); / Parse the type. / saved_in_type_id_in_expr_p = parser->in_type_id_in_expr_p; parser->in_type_id_in_expr_p = true; type = cp_parser_type_id (parser); parser->in_type_id_in_expr_p = saved_in_type_id_in_expr_p; / Look for the `)'. / cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'"); / Look for the `{'. / cp_parser_require (parser, CPP_OPEN_BRACE, "`{'"); / If things aren't going well, there's no need to keep going. / if (!cp_parser_error_occurred (parser)) { bool non_constant_p; / Parse the initializer-list. / initializer_list = cp_parser_initializer_list (parser, &non_constant_p); / Allow a trailing `,'. / if (cp_lexer_next_token_is (parser->lexer, CPP_COMMA)) cp_lexer_consume_token (parser->lexer); / Look for the final `}'. / cp_parser_require (parser, CPP_CLOSE_BRACE, "`}'"); } / If that worked, we're definitely looking at a compound-literal expression. / if (cp_parser_parse_definitely (parser)) { / Warn the user that a compound literal is not allowed in standard C++. / if (pedantic) pedwarn ("ISO C++ forbids compound-literals"); / For simplicitly, we disallow compound literals in constant-expressions for simpliicitly. We could allow compound literals of integer type, whose initializer was a constant, in constant expressions. Permitting that usage, as a further extension, would not change the meaning of any currently accepted programs. (Of course, as compound literals are not part of ISO C++, the standard has nothing to say.) / if (cp_parser_non_integral_constant_expression (parser, "non-constant compound literals")) { postfix_expression = error_mark_node; break; } / Form the representation of the compound-literal. / postfix_expression = finish_compound_literal (type, initializer_list); break; } } / It must be a primary-expression. / postfix_expression = cp_parser_primary_expression (parser, address_p, cast_p, /template_arg_p=/false, &idk); } break; } / Keep looping until the postfix-expression is complete. / while (true) { if (idk == CP_ID_KIND_UNQUALIFIED && TREE_CODE (postfix_expression) == IDENTIFIER_NODE && cp_lexer_next_token_is_not (parser->lexer, CPP_OPEN_PAREN)) / It is not a Koenig lookup function call. / postfix_expression = unqualified_name_lookup_error (postfix_expression); / Peek at the next token. / token = cp_lexer_peek_token (parser->lexer); switch (token->type) { case CPP_OPEN_SQUARE: postfix_expression = cp_parser_postfix_open_square_expression (parser, postfix_expression, false); idk = CP_ID_KIND_NONE; break; case CPP_OPEN_PAREN: / postfix-expression ( expression-list [opt] ) / { bool koenig_p; bool is_builtin_constant_p; bool saved_integral_constant_expression_p = false; bool saved_non_integral_constant_expression_p = false; tree args; is_builtin_constant_p = DECL_IS_BUILTIN_CONSTANT_P (postfix_expression); if (is_builtin_constant_p) { / The whole point of __builtin_constant_p is to allow non-constant expressions to appear as arguments. / saved_integral_constant_expression_p = parser->integral_constant_expression_p; saved_non_integral_constant_expression_p = parser->non_integral_constant_expression_p; parser->integral_constant_expression_p = false; } args = (cp_parser_parenthesized_expression_list (parser, /is_attribute_list=/false, /cast_p=/false, /non_constant_p=/NULL)); if (is_builtin_constant_p) { parser->integral_constant_expression_p = saved_integral_constant_expression_p; parser->non_integral_constant_expression_p = saved_non_integral_constant_expression_p; } if (args == error_mark_node) { postfix_expression = error_mark_node; break; } / Function calls are not permitted in constant-expressions. / if (! builtin_valid_in_constant_expr_p (postfix_expression) && cp_parser_non_integral_constant_expression (parser, "a function call")) { postfix_expression = error_mark_node; break; } koenig_p = false; if (idk == CP_ID_KIND_UNQUALIFIED) { if (TREE_CODE (postfix_expression) == IDENTIFIER_NODE) { if (args) { koenig_p = true; postfix_expression = perform_koenig_lookup (postfix_expression, args); } else postfix_expression = unqualified_fn_lookup_error (postfix_expression); } / We do not perform argument-dependent lookup if normal lookup finds a non-function, in accordance with the expected resolution of DR 218. / else if (args && is_overloaded_fn (postfix_expression)) { tree fn = get_first_fn (postfix_expression); if (TREE_CODE (fn) == TEMPLATE_ID_EXPR) fn = OVL_CURRENT (TREE_OPERAND (fn, 0)); / Only do argument dependent lookup if regular lookup does not find a set of member functions. [basic.lookup.koenig]/2a / if (!DECL_FUNCTION_MEMBER_P (fn)) { koenig_p = true; postfix_expression = perform_koenig_lookup (postfix_expression, args); } } } if (TREE_CODE (postfix_expression) == COMPONENT_REF) { tree instance = TREE_OPERAND (postfix_expression, 0); tree fn = TREE_OPERAND (postfix_expression, 1); if (processing_template_decl && (type_dependent_expression_p (instance) \|\| (!BASELINK_P (fn) && TREE_CODE (fn) != FIELD_DECL) \|\| type_dependent_expression_p (fn) \|\| any_type_dependent_arguments_p (args))) { postfix_expression = build_min_nt (CALL_EXPR, postfix_expression, args, NULL_TREE); break; } if (BASELINK_P (fn)) postfix_expression = (build_new_method_call (instance, fn, args, NULL_TREE, (idk == CP_ID_KIND_QUALIFIED ? LOOKUP_NONVIRTUAL : LOOKUP_NORMAL), /fn_p=/NULL)); else postfix_expression = finish_call_expr (postfix_expression, args, /disallow_virtual=/false, /koenig_p=/false); } else if (TREE_CODE (postfix_expression) == OFFSET_REF \|\| TREE_CODE (postfix_expression) == MEMBER_REF \|\| TREE_CODE (postfix_expression) == DOTSTAR_EXPR) postfix_expression = (build_offset_ref_call_from_tree (postfix_expression, args)); else if (idk == CP_ID_KIND_QUALIFIED) / A call to a static class member, or a namespace-scope function. / postfix_expression = finish_call_expr (postfix_expression, args, /disallow_virtual=/true, koenig_p); else / All other function calls. / postfix_expression = finish_call_expr (postfix_expression, args, /disallow_virtual=/false, koenig_p); / The POSTFIX_EXPRESSION is certainly no longer an id. / idk = CP_ID_KIND_NONE; } break; case CPP_DOT: case CPP_DEREF: / postfix-expression . template [opt] id-expression postfix-expression . pseudo-destructor-name postfix-expression -> template [opt] id-expression postfix-expression -> pseudo-destructor-name / / Consume the `.' or `->' operator. / cp_lexer_consume_token (parser->lexer); postfix_expression = cp_parser_postfix_dot_deref_expression (parser, token->type, postfix_expression, false, &idk); break; case CPP_PLUS_PLUS: / postfix-expression ++ / / Consume the `++' token. / cp_lexer_consume_token (parser->lexer); / Generate a representation for the complete expression. / postfix_expression = finish_increment_expr (postfix_expression, POSTINCREMENT_EXPR); / Increments may not appear in constant-expressions. / if (cp_parser_non_integral_constant_expression (parser, "an increment")) postfix_expression = error_mark_node; idk = CP_ID_KIND_NONE; break; case CPP_MINUS_MINUS: / postfix-expression -- / / Consume the `--' token. / cp_lexer_consume_token (parser->lexer); / Generate a representation for the complete expression. / postfix_expression = finish_increment_expr (postfix_expression, POSTDECREMENT_EXPR); / Decrements may not appear in constant-expressions. / if (cp_parser_non_integral_constant_expression (parser, "a decrement")) postfix_expression = error_mark_node; idk = CP_ID_KIND_NONE; break; default: return postfix_expression; } } / We should never get here. / gcc_unreachable (); return error_mark_node; } / A subroutine of cp_parser_postfix_expression that also gets hijacked by cp_parser_builtin_offsetof. We're looking for postfix-expression [ expression ] FOR_OFFSETOF is set if we're being called in that context, which changes how we deal with integer constant expressions. / static tree cp_parser_postfix_open_square_expression (cp_parser parser, tree postfix_expression, bool for_offsetof) { tree index; /* Consume the `[' token. / cp_lexer_consume_token (parser->lexer); / Parse the index expression. / / ??? For offsetof, there is a question of what to allow here. If offsetof is not being used in an integral constant expression context, then we could get the right answer by computing the value at runtime. If we are in an integral constant expression context, then we might could accept any constant expression; hard to say without analysis. Rather than open the barn door too wide right away, allow only integer constant expressions here. / if (for_offsetof) index = cp_parser_constant_expression (parser, false, NULL); else index = cp_parser_expression (parser, /cast_p=/false); / Look for the closing `]'. / cp_parser_require (parser, CPP_CLOSE_SQUARE, "`]'"); / Build the ARRAY_REF. / postfix_expression = grok_array_decl (postfix_expression, index); / When not doing offsetof, array references are not permitted in constant-expressions. / if (!for_offsetof && (cp_parser_non_integral_constant_expression (parser, "an array reference"))) postfix_expression = error_mark_node; return postfix_expression; } / A subroutine of cp_parser_postfix_expression that also gets hijacked by cp_parser_builtin_offsetof. We're looking for postfix-expression . template [opt] id-expression postfix-expression . pseudo-destructor-name postfix-expression -> template [opt] id-expression postfix-expression -> pseudo-destructor-name FOR_OFFSETOF is set if we're being called in that context. That sorta limits what of the above we'll actually accept, but nevermind. TOKEN_TYPE is the "." or "->" token, which will already have been removed from the stream. / static tree cp_parser_postfix_dot_deref_expression (cp_parser parser, enum cpp_ttype token_type, tree postfix_expression, bool for_offsetof, cp_id_kind idk) { tree name; bool dependent_p; bool pseudo_destructor_p; tree scope = NULL_TREE; / If this is a `->' operator, dereference the pointer. / if (token_type == CPP_DEREF) postfix_expression = build_x_arrow (postfix_expression); / Check to see whether or not the expression is type-dependent. / dependent_p = type_dependent_expression_p (postfix_expression); / The identifier following the `->' or `.' is not qualified. / parser->scope = NULL_TREE; parser->qualifying_scope = NULL_TREE; parser->object_scope = NULL_TREE; idk = CP_ID_KIND_NONE; /* Enter the scope corresponding to the type of the object given by the POSTFIX_EXPRESSION. / if (!dependent_p && TREE_TYPE (postfix_expression) != NULL_TREE) { scope = TREE_TYPE (postfix_expression); / According to the standard, no expression should ever have reference type. Unfortunately, we do not currently match the standard in this respect in that our internal representation of an expression may have reference type even when the standard says it does not. Therefore, we have to manually obtain the underlying type here. / scope = non_reference (scope); / The type of the POSTFIX_EXPRESSION must be complete. / if (scope == unknown_type_node) { error ("%qE does not have class type", postfix_expression); scope = NULL_TREE; } else scope = complete_type_or_else (scope, NULL_TREE); / Let the name lookup machinery know that we are processing a class member access expression. / parser->context->object_type = scope; / If something went wrong, we want to be able to discern that case, as opposed to the case where there was no SCOPE due to the type of expression being dependent. / if (!scope) scope = error_mark_node; / If the SCOPE was erroneous, make the various semantic analysis functions exit quickly -- and without issuing additional error messages. / if (scope == error_mark_node) postfix_expression = error_mark_node; } / Assume this expression is not a pseudo-destructor access. / pseudo_destructor_p = false; / If the SCOPE is a scalar type, then, if this is a valid program, we must be looking at a pseudo-destructor-name. / if (scope && SCALAR_TYPE_P (scope)) { tree s; tree type; cp_parser_parse_tentatively (parser); / Parse the pseudo-destructor-name. / s = NULL_TREE; cp_parser_pseudo_destructor_name (parser, &s, &type); if (cp_parser_parse_definitely (parser)) { pseudo_destructor_p = true; postfix_expression = finish_pseudo_destructor_expr (postfix_expression, s, TREE_TYPE (type)); } } if (!pseudo_destructor_p) { / If the SCOPE is not a scalar type, we are looking at an ordinary class member access expression, rather than a pseudo-destructor-name. / bool template_p; / Parse the id-expression. / name = (cp_parser_id_expression (parser, cp_parser_optional_template_keyword (parser), /check_dependency_p=/true, &template_p, /declarator_p=/false, /optional_p=/false)); / In general, build a SCOPE_REF if the member name is qualified. However, if the name was not dependent and has already been resolved; there is no need to build the SCOPE_REF. For example; struct X { void f(); }; template <typename T> void f(T* t) { t->X::f(); } Even though "t" is dependent, "X::f" is not and has been resolved to a BASELINK; there is no need to include scope information. / / But we do need to remember that there was an explicit scope for virtual function calls. / if (parser->scope) idk = CP_ID_KIND_QUALIFIED; /* If the name is a template-id that names a type, we will get a TYPE_DECL here. That is invalid code. / if (TREE_CODE (name) == TYPE_DECL) { error ("invalid use of %qD", name); postfix_expression = error_mark_node; } else { if (name != error_mark_node && !BASELINK_P (name) && parser->scope) { name = build_qualified_name (/type=/NULL_TREE, parser->scope, name, template_p); parser->scope = NULL_TREE; parser->qualifying_scope = NULL_TREE; parser->object_scope = NULL_TREE; } if (scope && name && BASELINK_P (name)) adjust_result_of_qualified_name_lookup (name, BINFO_TYPE (BASELINK_ACCESS_BINFO (name)), scope); postfix_expression = finish_class_member_access_expr (postfix_expression, name, template_p); } } / We no longer need to look up names in the scope of the object on the left-hand side of the `.' or `->' operator. / parser->context->object_type = NULL_TREE; / Outside of offsetof, these operators may not appear in constant-expressions. / if (!for_offsetof && (cp_parser_non_integral_constant_expression (parser, token_type == CPP_DEREF ? "'->'" : "`.'"))) postfix_expression = error_mark_node; return postfix_expression; } / Parse a parenthesized expression-list. expression-list: assignment-expression expression-list, assignment-expression attribute-list: expression-list identifier identifier, expression-list CAST_P is true if this expression is the target of a cast. Returns a TREE_LIST. The TREE_VALUE of each node is a representation of an assignment-expression. Note that a TREE_LIST is returned even if there is only a single expression in the list. error_mark_node is returned if the ( and or ) are missing. NULL_TREE is returned on no expressions. The parentheses are eaten. IS_ATTRIBUTE_LIST is true if this is really an attribute list being parsed. If NON_CONSTANT_P is non-NULL, NON_CONSTANT_P indicates whether or not all of the expressions in the list were constant. / static tree cp_parser_parenthesized_expression_list (cp_parser* parser, bool is_attribute_list, bool cast_p, bool non_constant_p) { tree expression_list = NULL_TREE; bool fold_expr_p = is_attribute_list; tree identifier = NULL_TREE; / Assume all the expressions will be constant. / if (non_constant_p) non_constant_p = false; if (!cp_parser_require (parser, CPP_OPEN_PAREN, "`('")) return error_mark_node; /* Consume expressions until there are no more. / if (cp_lexer_next_token_is_not (parser->lexer, CPP_CLOSE_PAREN)) while (true) { tree expr; / At the beginning of attribute lists, check to see if the next token is an identifier. / if (is_attribute_list && cp_lexer_peek_token (parser->lexer)->type == CPP_NAME) { cp_token token; /* Consume the identifier. / token = cp_lexer_consume_token (parser->lexer); / Save the identifier. / identifier = token->u.value; } else { / Parse the next assignment-expression. / if (non_constant_p) { bool expr_non_constant_p; expr = (cp_parser_constant_expression (parser, /allow_non_constant_p=/true, &expr_non_constant_p)); if (expr_non_constant_p) non_constant_p = true; } else expr = cp_parser_assignment_expression (parser, cast_p); if (fold_expr_p) expr = fold_non_dependent_expr (expr); /* Add it to the list. We add error_mark_node expressions to the list, so that we can still tell if the correct form for a parenthesized expression-list is found. That gives better errors. / expression_list = tree_cons (NULL_TREE, expr, expression_list); if (expr == error_mark_node) goto skip_comma; } / After the first item, attribute lists look the same as expression lists. / is_attribute_list = false; get_comma:; / If the next token isn't a `,', then we are done. / if (cp_lexer_next_token_is_not (parser->lexer, CPP_COMMA)) break; / Otherwise, consume the `,' and keep going. / cp_lexer_consume_token (parser->lexer); } if (!cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'")) { int ending; skip_comma:; / We try and resync to an unnested comma, as that will give the user better diagnostics. / ending = cp_parser_skip_to_closing_parenthesis (parser, /recovering=/true, /or_comma=/true, /consume_paren=/true); if (ending < 0) goto get_comma; if (!ending) return error_mark_node; } / We built up the list in reverse order so we must reverse it now. / expression_list = nreverse (expression_list); if (identifier) expression_list = tree_cons (NULL_TREE, identifier, expression_list); return expression_list; } / Parse a pseudo-destructor-name. pseudo-destructor-name: :: [opt] nested-name-specifier [opt] type-name :: ~ type-name :: [opt] nested-name-specifier template template-id :: ~ type-name :: [opt] nested-name-specifier [opt] ~ type-name If either of the first two productions is used, sets SCOPE to the TYPE specified before the final `::'. Otherwise, SCOPE is set to NULL_TREE. TYPE is set to the TYPE_DECL for the final type-name, or ERROR_MARK_NODE if the parse fails. / static void cp_parser_pseudo_destructor_name (cp_parser* parser, tree* scope, tree* type) { bool nested_name_specifier_p; /* Assume that things will not work out. / type = error_mark_node; /* Look for the optional `::' operator. / cp_parser_global_scope_opt (parser, /current_scope_valid_p=/true); / Look for the optional nested-name-specifier. / nested_name_specifier_p = (cp_parser_nested_name_specifier_opt (parser, /typename_keyword_p=/false, /check_dependency_p=/true, /type_p=/false, /is_declaration=/true) != NULL_TREE); / Now, if we saw a nested-name-specifier, we might be doing the second production. / if (nested_name_specifier_p && cp_lexer_next_token_is_keyword (parser->lexer, RID_TEMPLATE)) { / Consume the `template' keyword. / cp_lexer_consume_token (parser->lexer); / Parse the template-id. / cp_parser_template_id (parser, /template_keyword_p=/true, /check_dependency_p=/false, /is_declaration=/true); / Look for the `::' token. / cp_parser_require (parser, CPP_SCOPE, "`::'"); } / If the next token is not a `~', then there might be some additional qualification. / else if (cp_lexer_next_token_is_not (parser->lexer, CPP_COMPL)) { / Look for the type-name. / scope = TREE_TYPE (cp_parser_type_name (parser)); if (scope == error_mark_node) return; / If we don't have ::~, then something has gone wrong. Since the only caller of this function is looking for something after `.' or `->' after a scalar type, most likely the program is trying to get a member of a non-aggregate type. / if (cp_lexer_next_token_is_not (parser->lexer, CPP_SCOPE) \|\| cp_lexer_peek_nth_token (parser->lexer, 2)->type != CPP_COMPL) { cp_parser_error (parser, "request for member of non-aggregate type"); return; } / Look for the `::' token. / cp_parser_require (parser, CPP_SCOPE, "`::'"); } else scope = NULL_TREE; /* Look for the `~'. / cp_parser_require (parser, CPP_COMPL, "`~'"); / Look for the type-name again. We are not responsible for checking that it matches the first type-name. / type = cp_parser_type_name (parser); } /* Parse a unary-expression. unary-expression: postfix-expression ++ cast-expression -- cast-expression unary-operator cast-expression sizeof unary-expression sizeof ( type-id ) new-expression delete-expression GNU Extensions: unary-expression: __extension__ cast-expression __alignof__ unary-expression __alignof__ ( type-id ) __real__ cast-expression __imag__ cast-expression && identifier ADDRESS_P is true iff the unary-expression is appearing as the operand of the `&' operator. CAST_P is true if this expression is the target of a cast. Returns a representation of the expression. / static tree cp_parser_unary_expression (cp_parser parser, bool address_p, bool cast_p) { cp_token token; enum tree_code unary_operator; / Peek at the next token. / token = cp_lexer_peek_token (parser->lexer); / Some keywords give away the kind of expression. / if (token->type == CPP_KEYWORD) { enum rid keyword = token->keyword; switch (keyword) { case RID_ALIGNOF: case RID_SIZEOF: { tree operand; enum tree_code op; op = keyword == RID_ALIGNOF ? ALIGNOF_EXPR : SIZEOF_EXPR; / Consume the token. / cp_lexer_consume_token (parser->lexer); / Parse the operand. / operand = cp_parser_sizeof_operand (parser, keyword); if (TYPE_P (operand)) return cxx_sizeof_or_alignof_type (operand, op, true); else return cxx_sizeof_or_alignof_expr (operand, op); } case RID_NEW: return cp_parser_new_expression (parser); case RID_DELETE: return cp_parser_delete_expression (parser); case RID_EXTENSION: { / The saved value of the PEDANTIC flag. / int saved_pedantic; tree expr; / Save away the PEDANTIC flag. / cp_parser_extension_opt (parser, &saved_pedantic); / Parse the cast-expression. / expr = cp_parser_simple_cast_expression (parser); / Restore the PEDANTIC flag. / pedantic = saved_pedantic; return expr; } case RID_REALPART: case RID_IMAGPART: { tree expression; / Consume the `__real__' or `__imag__' token. / cp_lexer_consume_token (parser->lexer); / Parse the cast-expression. / expression = cp_parser_simple_cast_expression (parser); / Create the complete representation. / return build_x_unary_op ((keyword == RID_REALPART ? REALPART_EXPR : IMAGPART_EXPR), expression); } break; default: break; } } / Look for the `:: new' and `:: delete', which also signal the beginning of a new-expression, or delete-expression, respectively. If the next token is `::', then it might be one of these. / if (cp_lexer_next_token_is (parser->lexer, CPP_SCOPE)) { enum rid keyword; / See if the token after the `::' is one of the keywords in which we're interested. / keyword = cp_lexer_peek_nth_token (parser->lexer, 2)->keyword; / If it's `new', we have a new-expression. / if (keyword == RID_NEW) return cp_parser_new_expression (parser); / Similarly, for `delete'. / else if (keyword == RID_DELETE) return cp_parser_delete_expression (parser); } / Look for a unary operator. / unary_operator = cp_parser_unary_operator (token); / The `++' and `--' operators can be handled similarly, even though they are not technically unary-operators in the grammar. / if (unary_operator == ERROR_MARK) { if (token->type == CPP_PLUS_PLUS) unary_operator = PREINCREMENT_EXPR; else if (token->type == CPP_MINUS_MINUS) unary_operator = PREDECREMENT_EXPR; / Handle the GNU address-of-label extension. / else if (cp_parser_allow_gnu_extensions_p (parser) && token->type == CPP_AND_AND) { tree identifier; / Consume the '&&' token. / cp_lexer_consume_token (parser->lexer); / Look for the identifier. / identifier = cp_parser_identifier (parser); / Create an expression representing the address. / return finish_label_address_expr (identifier); } } if (unary_operator != ERROR_MARK) { tree cast_expression; tree expression = error_mark_node; const char non_constant_p = NULL; /* Consume the operator token. / token = cp_lexer_consume_token (parser->lexer); / Parse the cast-expression. / cast_expression = cp_parser_cast_expression (parser, unary_operator == ADDR_EXPR, /cast_p=/false); / Now, build an appropriate representation. / switch (unary_operator) { case INDIRECT_REF: non_constant_p = "`'"; expression = build_x_indirect_ref (cast_expression, "unary "); break; case ADDR_EXPR: non_constant_p = "`&'"; / Fall through. / case BIT_NOT_EXPR: expression = build_x_unary_op (unary_operator, cast_expression); break; case PREINCREMENT_EXPR: case PREDECREMENT_EXPR: non_constant_p = (unary_operator == PREINCREMENT_EXPR ? "`++'" : "`--'"); / Fall through. / case UNARY_PLUS_EXPR: case NEGATE_EXPR: case TRUTH_NOT_EXPR: expression = finish_unary_op_expr (unary_operator, cast_expression); break; default: gcc_unreachable (); } if (non_constant_p && cp_parser_non_integral_constant_expression (parser, non_constant_p)) expression = error_mark_node; return expression; } return cp_parser_postfix_expression (parser, address_p, cast_p); } / Returns ERROR_MARK if TOKEN is not a unary-operator. If TOKEN is a unary-operator, the corresponding tree code is returned. / static enum tree_code cp_parser_unary_operator (cp_token token) { switch (token->type) { case CPP_MULT: return INDIRECT_REF; case CPP_AND: return ADDR_EXPR; case CPP_PLUS: return UNARY_PLUS_EXPR; case CPP_MINUS: return NEGATE_EXPR; case CPP_NOT: return TRUTH_NOT_EXPR; case CPP_COMPL: return BIT_NOT_EXPR; default: return ERROR_MARK; } } /* Parse a new-expression. new-expression: :: [opt] new new-placement [opt] new-type-id new-initializer [opt] :: [opt] new new-placement [opt] ( type-id ) new-initializer [opt] Returns a representation of the expression. / static tree cp_parser_new_expression (cp_parser parser) { bool global_scope_p; tree placement; tree type; tree initializer; tree nelts; /* Look for the optional `::' operator. / global_scope_p = (cp_parser_global_scope_opt (parser, /current_scope_valid_p=/false) != NULL_TREE); / Look for the `new' operator. / cp_parser_require_keyword (parser, RID_NEW, "`new'"); / There's no easy way to tell a new-placement from the `( type-id )' construct. / cp_parser_parse_tentatively (parser); / Look for a new-placement. / placement = cp_parser_new_placement (parser); / If that didn't work out, there's no new-placement. / if (!cp_parser_parse_definitely (parser)) placement = NULL_TREE; / If the next token is a `(', then we have a parenthesized type-id. / if (cp_lexer_next_token_is (parser->lexer, CPP_OPEN_PAREN)) { / Consume the `('. / cp_lexer_consume_token (parser->lexer); / Parse the type-id. / type = cp_parser_type_id (parser); / Look for the closing `)'. / cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'"); / There should not be a direct-new-declarator in this production, but GCC used to allowed this, so we check and emit a sensible error message for this case. / if (cp_lexer_next_token_is (parser->lexer, CPP_OPEN_SQUARE)) { error ("array bound forbidden after parenthesized type-id"); inform ("try removing the parentheses around the type-id"); cp_parser_direct_new_declarator (parser); } nelts = NULL_TREE; } / Otherwise, there must be a new-type-id. / else type = cp_parser_new_type_id (parser, &nelts); / If the next token is a `(', then we have a new-initializer. / if (cp_lexer_next_token_is (parser->lexer, CPP_OPEN_PAREN)) initializer = cp_parser_new_initializer (parser); else initializer = NULL_TREE; / A new-expression may not appear in an integral constant expression. / if (cp_parser_non_integral_constant_expression (parser, "`new'")) return error_mark_node; / Create a representation of the new-expression. / return build_new (placement, type, nelts, initializer, global_scope_p); } / Parse a new-placement. new-placement: ( expression-list ) Returns the same representation as for an expression-list. / static tree cp_parser_new_placement (cp_parser parser) { tree expression_list; /* Parse the expression-list. / expression_list = (cp_parser_parenthesized_expression_list (parser, false, /cast_p=/false, /non_constant_p=/NULL)); return expression_list; } / Parse a new-type-id. new-type-id: type-specifier-seq new-declarator [opt] Returns the TYPE allocated. If the new-type-id indicates an array type, NELTS is set to the number of elements in the last array bound; the TYPE will not include the last array bound. / static tree cp_parser_new_type_id (cp_parser* parser, tree nelts) { cp_decl_specifier_seq type_specifier_seq; cp_declarator new_declarator; cp_declarator declarator; cp_declarator outer_declarator; const char saved_message; tree type; / The type-specifier sequence must not contain type definitions. (It cannot contain declarations of new types either, but if they are not definitions we will catch that because they are not complete.) / saved_message = parser->type_definition_forbidden_message; parser->type_definition_forbidden_message = "types may not be defined in a new-type-id"; / Parse the type-specifier-seq. / cp_parser_type_specifier_seq (parser, /is_condition=/false, &type_specifier_seq); / Restore the old message. / parser->type_definition_forbidden_message = saved_message; / Parse the new-declarator. / new_declarator = cp_parser_new_declarator_opt (parser); / Determine the number of elements in the last array dimension, if any. / nelts = NULL_TREE; /* Skip down to the last array dimension. / declarator = new_declarator; outer_declarator = NULL; while (declarator && (declarator->kind == cdk_pointer \|\| declarator->kind == cdk_ptrmem)) { outer_declarator = declarator; declarator = declarator->declarator; } while (declarator && declarator->kind == cdk_array && declarator->declarator && declarator->declarator->kind == cdk_array) { outer_declarator = declarator; declarator = declarator->declarator; } if (declarator && declarator->kind == cdk_array) { nelts = declarator->u.array.bounds; if (nelts == error_mark_node) nelts = integer_one_node; if (outer_declarator) outer_declarator->declarator = declarator->declarator; else new_declarator = NULL; } type = groktypename (&type_specifier_seq, new_declarator); if (TREE_CODE (type) == ARRAY_TYPE && nelts == NULL_TREE) { nelts = array_type_nelts_top (type); type = TREE_TYPE (type); } return type; } /* Parse an (optional) new-declarator. new-declarator: ptr-operator new-declarator [opt] direct-new-declarator Returns the declarator. / static cp_declarator cp_parser_new_declarator_opt (cp_parser* parser) { enum tree_code code; tree type; cp_cv_quals cv_quals; /* We don't know if there's a ptr-operator next, or not. / cp_parser_parse_tentatively (parser); / Look for a ptr-operator. / code = cp_parser_ptr_operator (parser, &type, &cv_quals); / If that worked, look for more new-declarators. / if (cp_parser_parse_definitely (parser)) { cp_declarator declarator; /* Parse another optional declarator. / declarator = cp_parser_new_declarator_opt (parser); / Create the representation of the declarator. / if (type) declarator = make_ptrmem_declarator (cv_quals, type, declarator); else if (code == INDIRECT_REF) declarator = make_pointer_declarator (cv_quals, declarator); else declarator = make_reference_declarator (cv_quals, declarator); return declarator; } / If the next token is a `[', there is a direct-new-declarator. / if (cp_lexer_next_token_is (parser->lexer, CPP_OPEN_SQUARE)) return cp_parser_direct_new_declarator (parser); return NULL; } / Parse a direct-new-declarator. direct-new-declarator: [ expression ] direct-new-declarator [constant-expression] / static cp_declarator cp_parser_direct_new_declarator (cp_parser* parser) { cp_declarator declarator = NULL; while (true) { tree expression; / Look for the opening `['. / cp_parser_require (parser, CPP_OPEN_SQUARE, "`['"); / The first expression is not required to be constant. / if (!declarator) { expression = cp_parser_expression (parser, /cast_p=/false); / The standard requires that the expression have integral type. DR 74 adds enumeration types. We believe that the real intent is that these expressions be handled like the expression in a `switch' condition, which also allows classes with a single conversion to integral or enumeration type. / if (!processing_template_decl) { expression = build_expr_type_conversion (WANT_INT \| WANT_ENUM, expression, /complain=/true); if (!expression) { error ("expression in new-declarator must have integral " "or enumeration type"); expression = error_mark_node; } } } / But all the other expressions must be. / else expression = cp_parser_constant_expression (parser, /allow_non_constant=/false, NULL); / Look for the closing `]'. / cp_parser_require (parser, CPP_CLOSE_SQUARE, "`]'"); / Add this bound to the declarator. / declarator = make_array_declarator (declarator, expression); / If the next token is not a `[', then there are no more bounds. / if (cp_lexer_next_token_is_not (parser->lexer, CPP_OPEN_SQUARE)) break; } return declarator; } / Parse a new-initializer. new-initializer: ( expression-list [opt] ) Returns a representation of the expression-list. If there is no expression-list, VOID_ZERO_NODE is returned. / static tree cp_parser_new_initializer (cp_parser parser) { tree expression_list; expression_list = (cp_parser_parenthesized_expression_list (parser, false, /cast_p=/false, /non_constant_p=/NULL)); if (!expression_list) expression_list = void_zero_node; return expression_list; } /* Parse a delete-expression. delete-expression: :: [opt] delete cast-expression :: [opt] delete [ ] cast-expression Returns a representation of the expression. / static tree cp_parser_delete_expression (cp_parser parser) { bool global_scope_p; bool array_p; tree expression; /* Look for the optional `::' operator. / global_scope_p = (cp_parser_global_scope_opt (parser, /current_scope_valid_p=/false) != NULL_TREE); / Look for the `delete' keyword. / cp_parser_require_keyword (parser, RID_DELETE, "`delete'"); / See if the array syntax is in use. / if (cp_lexer_next_token_is (parser->lexer, CPP_OPEN_SQUARE)) { / Consume the `[' token. / cp_lexer_consume_token (parser->lexer); / Look for the `]' token. / cp_parser_require (parser, CPP_CLOSE_SQUARE, "`]'"); / Remember that this is the `[]' construct. / array_p = true; } else array_p = false; / Parse the cast-expression. / expression = cp_parser_simple_cast_expression (parser); / A delete-expression may not appear in an integral constant expression. / if (cp_parser_non_integral_constant_expression (parser, "`delete'")) return error_mark_node; return delete_sanity (expression, NULL_TREE, array_p, global_scope_p); } / Parse a cast-expression. cast-expression: unary-expression ( type-id ) cast-expression ADDRESS_P is true iff the unary-expression is appearing as the operand of the `&' operator. CAST_P is true if this expression is the target of a cast. Returns a representation of the expression. / static tree cp_parser_cast_expression (cp_parser parser, bool address_p, bool cast_p) { /* If it's a `(', then we might be looking at a cast. / if (cp_lexer_next_token_is (parser->lexer, CPP_OPEN_PAREN)) { tree type = NULL_TREE; tree expr = NULL_TREE; bool compound_literal_p; const char saved_message; /* There's no way to know yet whether or not this is a cast. For example, `(int (3))' is a unary-expression, while `(int) 3' is a cast. So, we resort to parsing tentatively. / cp_parser_parse_tentatively (parser); / Types may not be defined in a cast. / saved_message = parser->type_definition_forbidden_message; parser->type_definition_forbidden_message = "types may not be defined in casts"; / Consume the `('. / cp_lexer_consume_token (parser->lexer); / A very tricky bit is that `(struct S) { 3 }' is a compound-literal (which we permit in C++ as an extension). But, that construct is not a cast-expression -- it is a postfix-expression. (The reason is that `(struct S) { 3 }.i' is legal; if the compound-literal were a cast-expression, you'd need an extra set of parentheses.) But, if we parse the type-id, and it happens to be a class-specifier, then we will commit to the parse at that point, because we cannot undo the action that is done when creating a new class. So, then we cannot back up and do a postfix-expression. Therefore, we scan ahead to the closing `)', and check to see if the token after the `)' is a `{'. If so, we are not looking at a cast-expression. Save tokens so that we can put them back. / cp_lexer_save_tokens (parser->lexer); / Skip tokens until the next token is a closing parenthesis. If we find the closing `)', and the next token is a `{', then we are looking at a compound-literal. / compound_literal_p = (cp_parser_skip_to_closing_parenthesis (parser, false, false, /consume_paren=/true) && cp_lexer_next_token_is (parser->lexer, CPP_OPEN_BRACE)); / Roll back the tokens we skipped. / cp_lexer_rollback_tokens (parser->lexer); / If we were looking at a compound-literal, simulate an error so that the call to cp_parser_parse_definitely below will fail. / if (compound_literal_p) cp_parser_simulate_error (parser); else { bool saved_in_type_id_in_expr_p = parser->in_type_id_in_expr_p; parser->in_type_id_in_expr_p = true; / Look for the type-id. / type = cp_parser_type_id (parser); / Look for the closing `)'. / cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'"); parser->in_type_id_in_expr_p = saved_in_type_id_in_expr_p; } / Restore the saved message. / parser->type_definition_forbidden_message = saved_message; / If ok so far, parse the dependent expression. We cannot be sure it is a cast. Consider `(T ())'. It is a parenthesized ctor of T, but looks like a cast to function returning T without a dependent expression. / if (!cp_parser_error_occurred (parser)) expr = cp_parser_cast_expression (parser, /address_p=/false, /cast_p=/true); if (cp_parser_parse_definitely (parser)) { / Warn about old-style casts, if so requested. / if (warn_old_style_cast && !in_system_header && !VOID_TYPE_P (type) && current_lang_name != lang_name_c) warning (OPT_Wold_style_cast, "use of old-style cast"); / Only type conversions to integral or enumeration types can be used in constant-expressions. / if (!cast_valid_in_integral_constant_expression_p (type) && (cp_parser_non_integral_constant_expression (parser, "a cast to a type other than an integral or " "enumeration type"))) return error_mark_node; / Perform the cast. / expr = build_c_cast (type, expr); return expr; } } / If we get here, then it's not a cast, so it must be a unary-expression. / return cp_parser_unary_expression (parser, address_p, cast_p); } / Parse a binary expression of the general form: pm-expression: cast-expression pm-expression .* cast-expression pm-expression ->* cast-expression multiplicative-expression: pm-expression multiplicative-expression * pm-expression multiplicative-expression / pm-expression multiplicative-expression % pm-expression additive-expression: multiplicative-expression additive-expression + multiplicative-expression additive-expression - multiplicative-expression shift-expression: additive-expression shift-expression << additive-expression shift-expression >> additive-expression relational-expression: shift-expression relational-expression < shift-expression relational-expression > shift-expression relational-expression <= shift-expression relational-expression >= shift-expression GNU Extension: relational-expression: relational-expression <? shift-expression relational-expression >? shift-expression equality-expression: relational-expression equality-expression == relational-expression equality-expression != relational-expression and-expression: equality-expression and-expression & equality-expression exclusive-or-expression: and-expression exclusive-or-expression ^ and-expression inclusive-or-expression: exclusive-or-expression inclusive-or-expression \| exclusive-or-expression logical-and-expression: inclusive-or-expression logical-and-expression && inclusive-or-expression logical-or-expression: logical-and-expression logical-or-expression \|\| logical-and-expression All these are implemented with a single function like: binary-expression: simple-cast-expression binary-expression <token> binary-expression CAST_P is true if this expression is the target of a cast. The binops_by_token map is used to get the tree codes for each <token> type. binary-expressions are associated according to a precedence table. / #define TOKEN_PRECEDENCE(token) \ ((token->type == CPP_GREATER && !parser->greater_than_is_operator_p) \ ? PREC_NOT_OPERATOR \ : binops_by_token[token->type].prec) static tree cp_parser_binary_expression (cp_parser parser, bool cast_p) { cp_parser_expression_stack stack; cp_parser_expression_stack_entry sp = &stack[0]; tree lhs, rhs; cp_token token; enum tree_code tree_type; enum cp_parser_prec prec = PREC_NOT_OPERATOR, new_prec, lookahead_prec; bool overloaded_p; /* Parse the first expression. / lhs = cp_parser_cast_expression (parser, /address_p=/false, cast_p); for (;;) { / Get an operator token. / token = cp_lexer_peek_token (parser->lexer); new_prec = TOKEN_PRECEDENCE (token); / Popping an entry off the stack means we completed a subexpression: - either we found a token which is not an operator (`>' where it is not an operator, or prec == PREC_NOT_OPERATOR), in which case popping will happen repeatedly; - or, we found an operator which has lower priority. This is the case where the recursive descent ascends, as in `3 * 4 + 5' after parsing `3 * 4'. / if (new_prec <= prec) { if (sp == stack) break; else goto pop; } get_rhs: tree_type = binops_by_token[token->type].tree_type; / We used the operator token. / cp_lexer_consume_token (parser->lexer); / Extract another operand. It may be the RHS of this expression or the LHS of a new, higher priority expression. / rhs = cp_parser_simple_cast_expression (parser); / Get another operator token. Look up its precedence to avoid building a useless (immediately popped) stack entry for common cases such as 3 + 4 + 5 or 3 * 4 + 5. / token = cp_lexer_peek_token (parser->lexer); lookahead_prec = TOKEN_PRECEDENCE (token); if (lookahead_prec > new_prec) { / ... and prepare to parse the RHS of the new, higher priority expression. Since precedence levels on the stack are monotonically increasing, we do not have to care about stack overflows. / sp->prec = prec; sp->tree_type = tree_type; sp->lhs = lhs; sp++; lhs = rhs; prec = new_prec; new_prec = lookahead_prec; goto get_rhs; pop: / If the stack is not empty, we have parsed into LHS the right side (`4' in the example above) of an expression we had suspended. We can use the information on the stack to recover the LHS (`3') from the stack together with the tree code (`MULT_EXPR'), and the precedence of the higher level subexpression (`PREC_ADDITIVE_EXPRESSION'). TOKEN is the CPP_PLUS token, which will be used to actually build the additive expression. / --sp; prec = sp->prec; tree_type = sp->tree_type; rhs = lhs; lhs = sp->lhs; } overloaded_p = false; lhs = build_x_binary_op (tree_type, lhs, rhs, &overloaded_p); / If the binary operator required the use of an overloaded operator, then this expression cannot be an integral constant-expression. An overloaded operator can be used even if both operands are otherwise permissible in an integral constant-expression if at least one of the operands is of enumeration type. / if (overloaded_p && (cp_parser_non_integral_constant_expression (parser, "calls to overloaded operators"))) return error_mark_node; } return lhs; } / Parse the `? expression : assignment-expression' part of a conditional-expression. The LOGICAL_OR_EXPR is the logical-or-expression that started the conditional-expression. Returns a representation of the entire conditional-expression. This routine is used by cp_parser_assignment_expression. ? expression : assignment-expression GNU Extensions: ? : assignment-expression / static tree cp_parser_question_colon_clause (cp_parser parser, tree logical_or_expr) { tree expr; tree assignment_expr; /* Consume the `?' token. / cp_lexer_consume_token (parser->lexer); if (cp_parser_allow_gnu_extensions_p (parser) && cp_lexer_next_token_is (parser->lexer, CPP_COLON)) / Implicit true clause. / expr = NULL_TREE; else / Parse the expression. / expr = cp_parser_expression (parser, /cast_p=/false); / The next token should be a `:'. / cp_parser_require (parser, CPP_COLON, "`:'"); / Parse the assignment-expression. / assignment_expr = cp_parser_assignment_expression (parser, /cast_p=/false); / Build the conditional-expression. / return build_x_conditional_expr (logical_or_expr, expr, assignment_expr); } / Parse an assignment-expression. assignment-expression: conditional-expression logical-or-expression assignment-operator assignment_expression throw-expression CAST_P is true if this expression is the target of a cast. Returns a representation for the expression. / static tree cp_parser_assignment_expression (cp_parser parser, bool cast_p) { tree expr; /* If the next token is the `throw' keyword, then we're looking at a throw-expression. / if (cp_lexer_next_token_is_keyword (parser->lexer, RID_THROW)) expr = cp_parser_throw_expression (parser); / Otherwise, it must be that we are looking at a logical-or-expression. / else { / Parse the binary expressions (logical-or-expression). / expr = cp_parser_binary_expression (parser, cast_p); / If the next token is a `?' then we're actually looking at a conditional-expression. / if (cp_lexer_next_token_is (parser->lexer, CPP_QUERY)) return cp_parser_question_colon_clause (parser, expr); else { enum tree_code assignment_operator; / If it's an assignment-operator, we're using the second production. / assignment_operator = cp_parser_assignment_operator_opt (parser); if (assignment_operator != ERROR_MARK) { tree rhs; / Parse the right-hand side of the assignment. / rhs = cp_parser_assignment_expression (parser, cast_p); / An assignment may not appear in a constant-expression. / if (cp_parser_non_integral_constant_expression (parser, "an assignment")) return error_mark_node; / Build the assignment expression. / expr = build_x_modify_expr (expr, assignment_operator, rhs); } } } return expr; } / Parse an (optional) assignment-operator. assignment-operator: one of = = /= %= += -= >>= <<= &= ^= \|= GNU Extension: assignment-operator: one of <?= >?= If the next token is an assignment operator, the corresponding tree code is returned, and the token is consumed. For example, for `+=', PLUS_EXPR is returned. For `=' itself, the code returned is NOP_EXPR. For `/', TRUNC_DIV_EXPR is returned; for `%', TRUNC_MOD_EXPR is returned. If TOKEN is not an assignment operator, ERROR_MARK is returned. / static enum tree_code cp_parser_assignment_operator_opt (cp_parser* parser) { enum tree_code op; cp_token token; / Peek at the next toen. / token = cp_lexer_peek_token (parser->lexer); switch (token->type) { case CPP_EQ: op = NOP_EXPR; break; case CPP_MULT_EQ: op = MULT_EXPR; break; case CPP_DIV_EQ: op = TRUNC_DIV_EXPR; break; case CPP_MOD_EQ: op = TRUNC_MOD_EXPR; break; case CPP_PLUS_EQ: op = PLUS_EXPR; break; case CPP_MINUS_EQ: op = MINUS_EXPR; break; case CPP_RSHIFT_EQ: op = RSHIFT_EXPR; break; case CPP_LSHIFT_EQ: op = LSHIFT_EXPR; break; case CPP_AND_EQ: op = BIT_AND_EXPR; break; case CPP_XOR_EQ: op = BIT_XOR_EXPR; break; case CPP_OR_EQ: op = BIT_IOR_EXPR; break; default: / Nothing else is an assignment operator. / op = ERROR_MARK; } / If it was an assignment operator, consume it. / if (op != ERROR_MARK) cp_lexer_consume_token (parser->lexer); return op; } / Parse an expression. expression: assignment-expression expression , assignment-expression CAST_P is true if this expression is the target of a cast. Returns a representation of the expression. / static tree cp_parser_expression (cp_parser parser, bool cast_p) { tree expression = NULL_TREE; while (true) { tree assignment_expression; /* Parse the next assignment-expression. / assignment_expression = cp_parser_assignment_expression (parser, cast_p); / If this is the first assignment-expression, we can just save it away. / if (!expression) expression = assignment_expression; else expression = build_x_compound_expr (expression, assignment_expression); / If the next token is not a comma, then we are done with the expression. / if (cp_lexer_next_token_is_not (parser->lexer, CPP_COMMA)) break; / Consume the `,'. / cp_lexer_consume_token (parser->lexer); / A comma operator cannot appear in a constant-expression. / if (cp_parser_non_integral_constant_expression (parser, "a comma operator")) expression = error_mark_node; } return expression; } / Parse a constant-expression. constant-expression: conditional-expression If ALLOW_NON_CONSTANT_P a non-constant expression is silently accepted. If ALLOW_NON_CONSTANT_P is true and the expression is not constant, NON_CONSTANT_P is set to TRUE. If ALLOW_NON_CONSTANT_P is false, NON_CONSTANT_P should be NULL. / static tree cp_parser_constant_expression (cp_parser* parser, bool allow_non_constant_p, bool non_constant_p) { bool saved_integral_constant_expression_p; bool saved_allow_non_integral_constant_expression_p; bool saved_non_integral_constant_expression_p; tree expression; / It might seem that we could simply parse the conditional-expression, and then check to see if it were TREE_CONSTANT. However, an expression that is TREE_CONSTANT is one that the compiler can figure out is constant, possibly after doing some simplifications or optimizations. The standard has a precise definition of constant-expression, and we must honor that, even though it is somewhat more restrictive. For example: int i[(2, 3)]; is not a legal declaration, because `(2, 3)' is not a constant-expression. The `,' operator is forbidden in a constant-expression. However, GCC's constant-folding machinery will fold this operation to an INTEGER_CST for `3'. / / Save the old settings. / saved_integral_constant_expression_p = parser->integral_constant_expression_p; saved_allow_non_integral_constant_expression_p = parser->allow_non_integral_constant_expression_p; saved_non_integral_constant_expression_p = parser->non_integral_constant_expression_p; / We are now parsing a constant-expression. / parser->integral_constant_expression_p = true; parser->allow_non_integral_constant_expression_p = allow_non_constant_p; parser->non_integral_constant_expression_p = false; / Although the grammar says "conditional-expression", we parse an "assignment-expression", which also permits "throw-expression" and the use of assignment operators. In the case that ALLOW_NON_CONSTANT_P is false, we get better errors than we would otherwise. In the case that ALLOW_NON_CONSTANT_P is true, it is actually essential that we look for an assignment-expression. For example, cp_parser_initializer_clauses uses this function to determine whether a particular assignment-expression is in fact constant. / expression = cp_parser_assignment_expression (parser, /cast_p=/false); / Restore the old settings. / parser->integral_constant_expression_p = saved_integral_constant_expression_p; parser->allow_non_integral_constant_expression_p = saved_allow_non_integral_constant_expression_p; if (allow_non_constant_p) non_constant_p = parser->non_integral_constant_expression_p; else if (parser->non_integral_constant_expression_p) expression = error_mark_node; parser->non_integral_constant_expression_p = saved_non_integral_constant_expression_p; return expression; } /* Parse __builtin_offsetof. offsetof-expression: "__builtin_offsetof" "(" type-id "," offsetof-member-designator ")" offsetof-member-designator: id-expression \| offsetof-member-designator "." id-expression \| offsetof-member-designator "[" expression "]" / static tree cp_parser_builtin_offsetof (cp_parser parser) { int save_ice_p, save_non_ice_p; tree type, expr; cp_id_kind dummy; /* We're about to accept non-integral-constant things, but will definitely yield an integral constant expression. Save and restore these values around our local parsing. / save_ice_p = parser->integral_constant_expression_p; save_non_ice_p = parser->non_integral_constant_expression_p; / Consume the "__builtin_offsetof" token. / cp_lexer_consume_token (parser->lexer); / Consume the opening `('. / cp_parser_require (parser, CPP_OPEN_PAREN, "`('"); / Parse the type-id. / type = cp_parser_type_id (parser); / Look for the `,'. / cp_parser_require (parser, CPP_COMMA, "`,'"); / Build the (type )null that begins the traditional offsetof macro. / expr = build_static_cast (build_pointer_type (type), null_pointer_node); /* Parse the offsetof-member-designator. We begin as if we saw "expr->". / expr = cp_parser_postfix_dot_deref_expression (parser, CPP_DEREF, expr, true, &dummy); while (true) { cp_token token = cp_lexer_peek_token (parser->lexer); switch (token->type) { case CPP_OPEN_SQUARE: /* offsetof-member-designator "[" expression "]" / expr = cp_parser_postfix_open_square_expression (parser, expr, true); break; case CPP_DOT: / offsetof-member-designator "." identifier / cp_lexer_consume_token (parser->lexer); expr = cp_parser_postfix_dot_deref_expression (parser, CPP_DOT, expr, true, &dummy); break; case CPP_CLOSE_PAREN: / Consume the ")" token. / cp_lexer_consume_token (parser->lexer); goto success; default: / Error. We know the following require will fail, but that gives the proper error message. / cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'"); cp_parser_skip_to_closing_parenthesis (parser, true, false, true); expr = error_mark_node; goto failure; } } success: / If we're processing a template, we can't finish the semantics yet. Otherwise we can fold the entire expression now. / if (processing_template_decl) expr = build1 (OFFSETOF_EXPR, size_type_node, expr); else expr = finish_offsetof (expr); failure: parser->integral_constant_expression_p = save_ice_p; parser->non_integral_constant_expression_p = save_non_ice_p; return expr; } / Statements [gram.stmt.stmt] / / Parse a statement. statement: labeled-statement expression-statement compound-statement selection-statement iteration-statement jump-statement declaration-statement try-block IN_COMPOUND is true when the statement is nested inside a cp_parser_compound_statement; this matters for certain pragmas. / static void cp_parser_statement (cp_parser parser, tree in_statement_expr, bool in_compound) { tree statement; cp_token token; location_t statement_location; restart: / There is no statement yet. / statement = NULL_TREE; / Peek at the next token. / token = cp_lexer_peek_token (parser->lexer); / Remember the location of the first token in the statement. / statement_location = token->location; / If this is a keyword, then that will often determine what kind of statement we have. / if (token->type == CPP_KEYWORD) { enum rid keyword = token->keyword; switch (keyword) { case RID_CASE: case RID_DEFAULT: / Looks like a labeled-statement with a case label. Parse the label, and then use tail recursion to parse the statement. / cp_parser_label_for_labeled_statement (parser); goto restart; case RID_IF: case RID_SWITCH: statement = cp_parser_selection_statement (parser); break; case RID_WHILE: case RID_DO: case RID_FOR: statement = cp_parser_iteration_statement (parser); break; case RID_BREAK: case RID_CONTINUE: case RID_RETURN: case RID_GOTO: statement = cp_parser_jump_statement (parser); break; / Objective-C++ exception-handling constructs. / case RID_AT_TRY: case RID_AT_CATCH: case RID_AT_FINALLY: case RID_AT_SYNCHRONIZED: case RID_AT_THROW: statement = cp_parser_objc_statement (parser); break; case RID_TRY: statement = cp_parser_try_block (parser); break; default: / It might be a keyword like `int' that can start a declaration-statement. / break; } } else if (token->type == CPP_NAME) { / If the next token is a `:', then we are looking at a labeled-statement. / token = cp_lexer_peek_nth_token (parser->lexer, 2); if (token->type == CPP_COLON) { / Looks like a labeled-statement with an ordinary label. Parse the label, and then use tail recursion to parse the statement. / cp_parser_label_for_labeled_statement (parser); goto restart; } } / Anything that starts with a `{' must be a compound-statement. / else if (token->type == CPP_OPEN_BRACE) statement = cp_parser_compound_statement (parser, NULL, false); / CPP_PRAGMA is a #pragma inside a function body, which constitutes a statement all its own. / else if (token->type == CPP_PRAGMA) { / Only certain OpenMP pragmas are attached to statements, and thus are considered statements themselves. All others are not. In the context of a compound, accept the pragma as a "statement" and return so that we can check for a close brace. Otherwise we require a real statement and must go back and read one. / if (in_compound) cp_parser_pragma (parser, pragma_compound); else if (!cp_parser_pragma (parser, pragma_stmt)) goto restart; return; } else if (token->type == CPP_EOF) { cp_parser_error (parser, "expected statement"); return; } / Everything else must be a declaration-statement or an expression-statement. Try for the declaration-statement first, unless we are looking at a `;', in which case we know that we have an expression-statement. / if (!statement) { if (cp_lexer_next_token_is_not (parser->lexer, CPP_SEMICOLON)) { cp_parser_parse_tentatively (parser); / Try to parse the declaration-statement. / cp_parser_declaration_statement (parser); / If that worked, we're done. / if (cp_parser_parse_definitely (parser)) return; } / Look for an expression-statement instead. / statement = cp_parser_expression_statement (parser, in_statement_expr); } / Set the line number for the statement. / if (statement && STATEMENT_CODE_P (TREE_CODE (statement))) SET_EXPR_LOCATION (statement, statement_location); } / Parse the label for a labeled-statement, i.e. identifier : case constant-expression : default : GNU Extension: case constant-expression ... constant-expression : statement When a label is parsed without errors, the label is added to the parse tree by the finish_* functions, so this function doesn't have to return the label. / static void cp_parser_label_for_labeled_statement (cp_parser parser) { cp_token token; / The next token should be an identifier. / token = cp_lexer_peek_token (parser->lexer); if (token->type != CPP_NAME && token->type != CPP_KEYWORD) { cp_parser_error (parser, "expected labeled-statement"); return; } switch (token->keyword) { case RID_CASE: { tree expr, expr_hi; cp_token ellipsis; /* Consume the `case' token. / cp_lexer_consume_token (parser->lexer); / Parse the constant-expression. / expr = cp_parser_constant_expression (parser, /allow_non_constant_p=/false, NULL); ellipsis = cp_lexer_peek_token (parser->lexer); if (ellipsis->type == CPP_ELLIPSIS) { / Consume the `...' token. / cp_lexer_consume_token (parser->lexer); expr_hi = cp_parser_constant_expression (parser, /allow_non_constant_p=/false, NULL); / We don't need to emit warnings here, as the common code will do this for us. / } else expr_hi = NULL_TREE; if (parser->in_switch_statement_p) finish_case_label (expr, expr_hi); else error ("case label %qE not within a switch statement", expr); } break; case RID_DEFAULT: / Consume the `default' token. / cp_lexer_consume_token (parser->lexer); if (parser->in_switch_statement_p) finish_case_label (NULL_TREE, NULL_TREE); else error ("case label not within a switch statement"); break; default: / Anything else must be an ordinary label. / finish_label_stmt (cp_parser_identifier (parser)); break; } / Require the `:' token. / cp_parser_require (parser, CPP_COLON, "`:'"); } / Parse an expression-statement. expression-statement: expression [opt] ; Returns the new EXPR_STMT -- or NULL_TREE if the expression statement consists of nothing more than an `;'. IN_STATEMENT_EXPR_P indicates whether this expression-statement is part of an expression statement. / static tree cp_parser_expression_statement (cp_parser parser, tree in_statement_expr) { tree statement = NULL_TREE; /* If the next token is a ';', then there is no expression statement. / if (cp_lexer_next_token_is_not (parser->lexer, CPP_SEMICOLON)) statement = cp_parser_expression (parser, /cast_p=/false); / Consume the final `;'. / cp_parser_consume_semicolon_at_end_of_statement (parser); if (in_statement_expr && cp_lexer_next_token_is (parser->lexer, CPP_CLOSE_BRACE)) / This is the final expression statement of a statement expression. / statement = finish_stmt_expr_expr (statement, in_statement_expr); else if (statement) statement = finish_expr_stmt (statement); else finish_stmt (); return statement; } / Parse a compound-statement. compound-statement: { statement-seq [opt] } Returns a tree representing the statement. / static tree cp_parser_compound_statement (cp_parser parser, tree in_statement_expr, bool in_try) { tree compound_stmt; /* Consume the `{'. / if (!cp_parser_require (parser, CPP_OPEN_BRACE, "`{'")) return error_mark_node; / Begin the compound-statement. / compound_stmt = begin_compound_stmt (in_try ? BCS_TRY_BLOCK : 0); / Parse an (optional) statement-seq. / cp_parser_statement_seq_opt (parser, in_statement_expr); / Finish the compound-statement. / finish_compound_stmt (compound_stmt); / Consume the `}'. / cp_parser_require (parser, CPP_CLOSE_BRACE, "`}'"); return compound_stmt; } / Parse an (optional) statement-seq. statement-seq: statement statement-seq [opt] statement / static void cp_parser_statement_seq_opt (cp_parser parser, tree in_statement_expr) { /* Scan statements until there aren't any more. / while (true) { cp_token token = cp_lexer_peek_token (parser->lexer); /* If we're looking at a `}', then we've run out of statements. / if (token->type == CPP_CLOSE_BRACE \|\| token->type == CPP_EOF \|\| token->type == CPP_PRAGMA_EOL) break; / Parse the statement. / cp_parser_statement (parser, in_statement_expr, true); } } / Parse a selection-statement. selection-statement: if ( condition ) statement if ( condition ) statement else statement switch ( condition ) statement Returns the new IF_STMT or SWITCH_STMT. / static tree cp_parser_selection_statement (cp_parser parser) { cp_token token; enum rid keyword; / Peek at the next token. / token = cp_parser_require (parser, CPP_KEYWORD, "selection-statement"); / See what kind of keyword it is. / keyword = token->keyword; switch (keyword) { case RID_IF: case RID_SWITCH: { tree statement; tree condition; / Look for the `('. / if (!cp_parser_require (parser, CPP_OPEN_PAREN, "`('")) { cp_parser_skip_to_end_of_statement (parser); return error_mark_node; } / Begin the selection-statement. / if (keyword == RID_IF) statement = begin_if_stmt (); else statement = begin_switch_stmt (); / Parse the condition. / condition = cp_parser_condition (parser); / Look for the `)'. / if (!cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'")) cp_parser_skip_to_closing_parenthesis (parser, true, false, /consume_paren=/true); if (keyword == RID_IF) { / Add the condition. / finish_if_stmt_cond (condition, statement); / Parse the then-clause. / cp_parser_implicitly_scoped_statement (parser); finish_then_clause (statement); / If the next token is `else', parse the else-clause. / if (cp_lexer_next_token_is_keyword (parser->lexer, RID_ELSE)) { / Consume the `else' keyword. / cp_lexer_consume_token (parser->lexer); begin_else_clause (statement); / Parse the else-clause. / cp_parser_implicitly_scoped_statement (parser); finish_else_clause (statement); } / Now we're all done with the if-statement. / finish_if_stmt (statement); } else { bool in_switch_statement_p; unsigned char in_statement; / Add the condition. / finish_switch_cond (condition, statement); / Parse the body of the switch-statement. / in_switch_statement_p = parser->in_switch_statement_p; in_statement = parser->in_statement; parser->in_switch_statement_p = true; parser->in_statement \|= IN_SWITCH_STMT; cp_parser_implicitly_scoped_statement (parser); parser->in_switch_statement_p = in_switch_statement_p; parser->in_statement = in_statement; / Now we're all done with the switch-statement. / finish_switch_stmt (statement); } return statement; } break; default: cp_parser_error (parser, "expected selection-statement"); return error_mark_node; } } / Parse a condition. condition: expression type-specifier-seq declarator = assignment-expression GNU Extension: condition: type-specifier-seq declarator asm-specification [opt] attributes [opt] = assignment-expression Returns the expression that should be tested. / static tree cp_parser_condition (cp_parser parser) { cp_decl_specifier_seq type_specifiers; const char saved_message; / Try the declaration first. / cp_parser_parse_tentatively (parser); / New types are not allowed in the type-specifier-seq for a condition. / saved_message = parser->type_definition_forbidden_message; parser->type_definition_forbidden_message = "types may not be defined in conditions"; / Parse the type-specifier-seq. / cp_parser_type_specifier_seq (parser, /is_condition==/true, &type_specifiers); / Restore the saved message. / parser->type_definition_forbidden_message = saved_message; / If all is well, we might be looking at a declaration. / if (!cp_parser_error_occurred (parser)) { tree decl; tree asm_specification; tree attributes; cp_declarator declarator; tree initializer = NULL_TREE; /* Parse the declarator. / declarator = cp_parser_declarator (parser, CP_PARSER_DECLARATOR_NAMED, /ctor_dtor_or_conv_p=/NULL, /parenthesized_p=/NULL, /member_p=/false); / Parse the attributes. / attributes = cp_parser_attributes_opt (parser); / Parse the asm-specification. / asm_specification = cp_parser_asm_specification_opt (parser); / If the next token is not an `=', then we might still be looking at an expression. For example: if (A(a).x) looks like a decl-specifier-seq and a declarator -- but then there is no `=', so this is an expression. / cp_parser_require (parser, CPP_EQ, "`='"); / If we did see an `=', then we are looking at a declaration for sure. / if (cp_parser_parse_definitely (parser)) { tree pushed_scope; bool non_constant_p; / Create the declaration. / decl = start_decl (declarator, &type_specifiers, /initialized_p=/true, attributes, /prefix_attributes=/NULL_TREE, &pushed_scope); / Parse the assignment-expression. / initializer = cp_parser_constant_expression (parser, /allow_non_constant_p=/true, &non_constant_p); if (!non_constant_p) initializer = fold_non_dependent_expr (initializer); / Process the initializer. / cp_finish_decl (decl, initializer, !non_constant_p, asm_specification, LOOKUP_ONLYCONVERTING); if (pushed_scope) pop_scope (pushed_scope); return convert_from_reference (decl); } } / If we didn't even get past the declarator successfully, we are definitely not looking at a declaration. / else cp_parser_abort_tentative_parse (parser); / Otherwise, we are looking at an expression. / return cp_parser_expression (parser, /cast_p=/false); } / Parse an iteration-statement. iteration-statement: while ( condition ) statement do statement while ( expression ) ; for ( for-init-statement condition [opt] ; expression [opt] ) statement Returns the new WHILE_STMT, DO_STMT, or FOR_STMT. / static tree cp_parser_iteration_statement (cp_parser parser) { cp_token token; enum rid keyword; tree statement; unsigned char in_statement; / Peek at the next token. / token = cp_parser_require (parser, CPP_KEYWORD, "iteration-statement"); if (!token) return error_mark_node; / Remember whether or not we are already within an iteration statement. / in_statement = parser->in_statement; / See what kind of keyword it is. / keyword = token->keyword; switch (keyword) { case RID_WHILE: { tree condition; / Begin the while-statement. / statement = begin_while_stmt (); / Look for the `('. / cp_parser_require (parser, CPP_OPEN_PAREN, "`('"); / Parse the condition. / condition = cp_parser_condition (parser); finish_while_stmt_cond (condition, statement); / Look for the `)'. / cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'"); / Parse the dependent statement. / parser->in_statement = IN_ITERATION_STMT; cp_parser_already_scoped_statement (parser); parser->in_statement = in_statement; / We're done with the while-statement. / finish_while_stmt (statement); } break; case RID_DO: { tree expression; / Begin the do-statement. / statement = begin_do_stmt (); / Parse the body of the do-statement. / parser->in_statement = IN_ITERATION_STMT; cp_parser_implicitly_scoped_statement (parser); parser->in_statement = in_statement; finish_do_body (statement); / Look for the `while' keyword. / cp_parser_require_keyword (parser, RID_WHILE, "`while'"); / Look for the `('. / cp_parser_require (parser, CPP_OPEN_PAREN, "`('"); / Parse the expression. / expression = cp_parser_expression (parser, /cast_p=/false); / We're done with the do-statement. / finish_do_stmt (expression, statement); / Look for the `)'. / cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'"); / Look for the `;'. / cp_parser_require (parser, CPP_SEMICOLON, "`;'"); } break; case RID_FOR: { tree condition = NULL_TREE; tree expression = NULL_TREE; / Begin the for-statement. / statement = begin_for_stmt (); / Look for the `('. / cp_parser_require (parser, CPP_OPEN_PAREN, "`('"); / Parse the initialization. / cp_parser_for_init_statement (parser); finish_for_init_stmt (statement); / If there's a condition, process it. / if (cp_lexer_next_token_is_not (parser->lexer, CPP_SEMICOLON)) condition = cp_parser_condition (parser); finish_for_cond (condition, statement); / Look for the `;'. / cp_parser_require (parser, CPP_SEMICOLON, "`;'"); / If there's an expression, process it. / if (cp_lexer_next_token_is_not (parser->lexer, CPP_CLOSE_PAREN)) expression = cp_parser_expression (parser, /cast_p=/false); finish_for_expr (expression, statement); / Look for the `)'. / cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'"); / Parse the body of the for-statement. / parser->in_statement = IN_ITERATION_STMT; cp_parser_already_scoped_statement (parser); parser->in_statement = in_statement; / We're done with the for-statement. / finish_for_stmt (statement); } break; default: cp_parser_error (parser, "expected iteration-statement"); statement = error_mark_node; break; } return statement; } / Parse a for-init-statement. for-init-statement: expression-statement simple-declaration / static void cp_parser_for_init_statement (cp_parser parser) { /* If the next token is a `;', then we have an empty expression-statement. Grammatically, this is also a simple-declaration, but an invalid one, because it does not declare anything. Therefore, if we did not handle this case specially, we would issue an error message about an invalid declaration. / if (cp_lexer_next_token_is_not (parser->lexer, CPP_SEMICOLON)) { / We're going to speculatively look for a declaration, falling back to an expression, if necessary. / cp_parser_parse_tentatively (parser); / Parse the declaration. / cp_parser_simple_declaration (parser, /function_definition_allowed_p=/false); / If the tentative parse failed, then we shall need to look for an expression-statement. / if (cp_parser_parse_definitely (parser)) return; } cp_parser_expression_statement (parser, false); } / Parse a jump-statement. jump-statement: break ; continue ; return expression [opt] ; goto identifier ; GNU extension: jump-statement: goto * expression ; Returns the new BREAK_STMT, CONTINUE_STMT, RETURN_EXPR, or GOTO_EXPR. / static tree cp_parser_jump_statement (cp_parser parser) { tree statement = error_mark_node; cp_token token; enum rid keyword; / Peek at the next token. / token = cp_parser_require (parser, CPP_KEYWORD, "jump-statement"); if (!token) return error_mark_node; / See what kind of keyword it is. / keyword = token->keyword; switch (keyword) { case RID_BREAK: switch (parser->in_statement) { case 0: error ("break statement not within loop or switch"); break; default: gcc_assert ((parser->in_statement & IN_SWITCH_STMT) \|\| parser->in_statement == IN_ITERATION_STMT); statement = finish_break_stmt (); break; case IN_OMP_BLOCK: error ("invalid exit from OpenMP structured block"); break; case IN_OMP_FOR: error ("break statement used with OpenMP for loop"); break; } cp_parser_require (parser, CPP_SEMICOLON, "%<;%>"); break; case RID_CONTINUE: switch (parser->in_statement & ~IN_SWITCH_STMT) { case 0: error ("continue statement not within a loop"); break; case IN_ITERATION_STMT: case IN_OMP_FOR: statement = finish_continue_stmt (); break; case IN_OMP_BLOCK: error ("invalid exit from OpenMP structured block"); break; default: gcc_unreachable (); } cp_parser_require (parser, CPP_SEMICOLON, "%<;%>"); break; case RID_RETURN: { tree expr; / If the next token is a `;', then there is no expression. / if (cp_lexer_next_token_is_not (parser->lexer, CPP_SEMICOLON)) expr = cp_parser_expression (parser, /cast_p=/false); else expr = NULL_TREE; / Build the return-statement. / statement = finish_return_stmt (expr); / Look for the final `;'. / cp_parser_require (parser, CPP_SEMICOLON, "%<;%>"); } break; case RID_GOTO: / Create the goto-statement. / if (cp_lexer_next_token_is (parser->lexer, CPP_MULT)) { / Issue a warning about this use of a GNU extension. / if (pedantic) pedwarn ("ISO C++ forbids computed gotos"); / Consume the '' token. / cp_lexer_consume_token (parser->lexer); /* Parse the dependent expression. / finish_goto_stmt (cp_parser_expression (parser, /cast_p=/false)); } else finish_goto_stmt (cp_parser_identifier (parser)); / Look for the final `;'. / cp_parser_require (parser, CPP_SEMICOLON, "%<;%>"); break; default: cp_parser_error (parser, "expected jump-statement"); break; } return statement; } / Parse a declaration-statement. declaration-statement: block-declaration / static void cp_parser_declaration_statement (cp_parser parser) { void p; / Get the high-water mark for the DECLARATOR_OBSTACK. / p = obstack_alloc (&declarator_obstack, 0); / Parse the block-declaration. / cp_parser_block_declaration (parser, /statement_p=/true); / Free any declarators allocated. / obstack_free (&declarator_obstack, p); / Finish off the statement. / finish_stmt (); } / Some dependent statements (like `if (cond) statement'), are implicitly in their own scope. In other words, if the statement is a single statement (as opposed to a compound-statement), it is none-the-less treated as if it were enclosed in braces. Any declarations appearing in the dependent statement are out of scope after control passes that point. This function parses a statement, but ensures that is in its own scope, even if it is not a compound-statement. Returns the new statement. / static tree cp_parser_implicitly_scoped_statement (cp_parser parser) { tree statement; /* Mark if () ; with a special NOP_EXPR. / if (cp_lexer_next_token_is (parser->lexer, CPP_SEMICOLON)) { cp_lexer_consume_token (parser->lexer); statement = add_stmt (build_empty_stmt ()); } / if a compound is opened, we simply parse the statement directly. / else if (cp_lexer_next_token_is (parser->lexer, CPP_OPEN_BRACE)) statement = cp_parser_compound_statement (parser, NULL, false); / If the token is not a `{', then we must take special action. / else { / Create a compound-statement. / statement = begin_compound_stmt (0); / Parse the dependent-statement. / cp_parser_statement (parser, NULL_TREE, false); / Finish the dummy compound-statement. / finish_compound_stmt (statement); } / Return the statement. / return statement; } / For some dependent statements (like `while (cond) statement'), we have already created a scope. Therefore, even if the dependent statement is a compound-statement, we do not want to create another scope. / static void cp_parser_already_scoped_statement (cp_parser parser) { /* If the token is a `{', then we must take special action. / if (cp_lexer_next_token_is_not (parser->lexer, CPP_OPEN_BRACE)) cp_parser_statement (parser, NULL_TREE, false); else { / Avoid calling cp_parser_compound_statement, so that we don't create a new scope. Do everything else by hand. / cp_parser_require (parser, CPP_OPEN_BRACE, "`{'"); cp_parser_statement_seq_opt (parser, NULL_TREE); cp_parser_require (parser, CPP_CLOSE_BRACE, "`}'"); } } / Declarations [gram.dcl.dcl] / / Parse an optional declaration-sequence. declaration-seq: declaration declaration-seq declaration / static void cp_parser_declaration_seq_opt (cp_parser parser) { while (true) { cp_token token; token = cp_lexer_peek_token (parser->lexer); if (token->type == CPP_CLOSE_BRACE \|\| token->type == CPP_EOF \|\| token->type == CPP_PRAGMA_EOL) break; if (token->type == CPP_SEMICOLON) { / A declaration consisting of a single semicolon is invalid. Allow it unless we're being pedantic. / cp_lexer_consume_token (parser->lexer); if (pedantic && !in_system_header) pedwarn ("extra %<;%>"); continue; } / If we're entering or exiting a region that's implicitly extern "C", modify the lang context appropriately. / if (!parser->implicit_extern_c && token->implicit_extern_c) { push_lang_context (lang_name_c); parser->implicit_extern_c = true; } else if (parser->implicit_extern_c && !token->implicit_extern_c) { pop_lang_context (); parser->implicit_extern_c = false; } if (token->type == CPP_PRAGMA) { / A top-level declaration can consist solely of a #pragma. A nested declaration cannot, so this is done here and not in cp_parser_declaration. (A #pragma at block scope is handled in cp_parser_statement.) / cp_parser_pragma (parser, pragma_external); continue; } / Parse the declaration itself. / cp_parser_declaration (parser); } } / Parse a declaration. declaration: block-declaration function-definition template-declaration explicit-instantiation explicit-specialization linkage-specification namespace-definition GNU extension: declaration: __extension__ declaration / static void cp_parser_declaration (cp_parser parser) { cp_token token1; cp_token token2; int saved_pedantic; void p; / Check for the `__extension__' keyword. / if (cp_parser_extension_opt (parser, &saved_pedantic)) { / Parse the qualified declaration. / cp_parser_declaration (parser); / Restore the PEDANTIC flag. / pedantic = saved_pedantic; return; } / Try to figure out what kind of declaration is present. / token1 = cp_lexer_peek_token (parser->lexer); if (token1.type != CPP_EOF) token2 = cp_lexer_peek_nth_token (parser->lexer, 2); else { token2.type = CPP_EOF; token2.keyword = RID_MAX; } / Get the high-water mark for the DECLARATOR_OBSTACK. / p = obstack_alloc (&declarator_obstack, 0); / If the next token is `extern' and the following token is a string literal, then we have a linkage specification. / if (token1.keyword == RID_EXTERN && cp_parser_is_string_literal (&token2)) cp_parser_linkage_specification (parser); / If the next token is `template', then we have either a template declaration, an explicit instantiation, or an explicit specialization. / else if (token1.keyword == RID_TEMPLATE) { / `template <>' indicates a template specialization. / if (token2.type == CPP_LESS && cp_lexer_peek_nth_token (parser->lexer, 3)->type == CPP_GREATER) cp_parser_explicit_specialization (parser); / `template <' indicates a template declaration. / else if (token2.type == CPP_LESS) cp_parser_template_declaration (parser, /member_p=/false); / Anything else must be an explicit instantiation. / else cp_parser_explicit_instantiation (parser); } / If the next token is `export', then we have a template declaration. / else if (token1.keyword == RID_EXPORT) cp_parser_template_declaration (parser, /member_p=/false); / If the next token is `extern', 'static' or 'inline' and the one after that is `template', we have a GNU extended explicit instantiation directive. / else if (cp_parser_allow_gnu_extensions_p (parser) && (token1.keyword == RID_EXTERN \|\| token1.keyword == RID_STATIC \|\| token1.keyword == RID_INLINE) && token2.keyword == RID_TEMPLATE) cp_parser_explicit_instantiation (parser); / If the next token is `namespace', check for a named or unnamed namespace definition. / else if (token1.keyword == RID_NAMESPACE && (/ A named namespace definition. / (token2.type == CPP_NAME && (cp_lexer_peek_nth_token (parser->lexer, 3)->type != CPP_EQ)) / An unnamed namespace definition. / \|\| token2.type == CPP_OPEN_BRACE \|\| token2.keyword == RID_ATTRIBUTE)) cp_parser_namespace_definition (parser); / Objective-C++ declaration/definition. / else if (c_dialect_objc () && OBJC_IS_AT_KEYWORD (token1.keyword)) cp_parser_objc_declaration (parser); / We must have either a block declaration or a function definition. / else / Try to parse a block-declaration, or a function-definition. / cp_parser_block_declaration (parser, /statement_p=/false); / Free any declarators allocated. / obstack_free (&declarator_obstack, p); } / Parse a block-declaration. block-declaration: simple-declaration asm-definition namespace-alias-definition using-declaration using-directive GNU Extension: block-declaration: __extension__ block-declaration label-declaration If STATEMENT_P is TRUE, then this block-declaration is occurring as part of a declaration-statement. / static void cp_parser_block_declaration (cp_parser parser, bool statement_p) { cp_token token1; int saved_pedantic; / Check for the `__extension__' keyword. / if (cp_parser_extension_opt (parser, &saved_pedantic)) { / Parse the qualified declaration. / cp_parser_block_declaration (parser, statement_p); / Restore the PEDANTIC flag. / pedantic = saved_pedantic; return; } / Peek at the next token to figure out which kind of declaration is present. / token1 = cp_lexer_peek_token (parser->lexer); / If the next keyword is `asm', we have an asm-definition. / if (token1->keyword == RID_ASM) { if (statement_p) cp_parser_commit_to_tentative_parse (parser); cp_parser_asm_definition (parser); } / If the next keyword is `namespace', we have a namespace-alias-definition. / else if (token1->keyword == RID_NAMESPACE) cp_parser_namespace_alias_definition (parser); / If the next keyword is `using', we have either a using-declaration or a using-directive. / else if (token1->keyword == RID_USING) { cp_token token2; if (statement_p) cp_parser_commit_to_tentative_parse (parser); /* If the token after `using' is `namespace', then we have a using-directive. / token2 = cp_lexer_peek_nth_token (parser->lexer, 2); if (token2->keyword == RID_NAMESPACE) cp_parser_using_directive (parser); / Otherwise, it's a using-declaration. / else cp_parser_using_declaration (parser, /access_declaration_p=/false); } / If the next keyword is `__label__' we have a label declaration. / else if (token1->keyword == RID_LABEL) { if (statement_p) cp_parser_commit_to_tentative_parse (parser); cp_parser_label_declaration (parser); } / Anything else must be a simple-declaration. / else cp_parser_simple_declaration (parser, !statement_p); } / Parse a simple-declaration. simple-declaration: decl-specifier-seq [opt] init-declarator-list [opt] ; init-declarator-list: init-declarator init-declarator-list , init-declarator If FUNCTION_DEFINITION_ALLOWED_P is TRUE, then we also recognize a function-definition as a simple-declaration. / static void cp_parser_simple_declaration (cp_parser parser, bool function_definition_allowed_p) { cp_decl_specifier_seq decl_specifiers; int declares_class_or_enum; bool saw_declarator; /* Defer access checks until we know what is being declared; the checks for names appearing in the decl-specifier-seq should be done as if we were in the scope of the thing being declared. / push_deferring_access_checks (dk_deferred); / Parse the decl-specifier-seq. We have to keep track of whether or not the decl-specifier-seq declares a named class or enumeration type, since that is the only case in which the init-declarator-list is allowed to be empty. [dcl.dcl] In a simple-declaration, the optional init-declarator-list can be omitted only when declaring a class or enumeration, that is when the decl-specifier-seq contains either a class-specifier, an elaborated-type-specifier, or an enum-specifier. / cp_parser_decl_specifier_seq (parser, CP_PARSER_FLAGS_OPTIONAL, &decl_specifiers, &declares_class_or_enum); / We no longer need to defer access checks. / stop_deferring_access_checks (); / In a block scope, a valid declaration must always have a decl-specifier-seq. By not trying to parse declarators, we can resolve the declaration/expression ambiguity more quickly. / if (!function_definition_allowed_p && !decl_specifiers.any_specifiers_p) { cp_parser_error (parser, "expected declaration"); goto done; } / If the next two tokens are both identifiers, the code is erroneous. The usual cause of this situation is code like: T t; where "T" should name a type -- but does not. / if (!decl_specifiers.type && cp_parser_parse_and_diagnose_invalid_type_name (parser)) { / If parsing tentatively, we should commit; we really are looking at a declaration. / cp_parser_commit_to_tentative_parse (parser); / Give up. / goto done; } / If we have seen at least one decl-specifier, and the next token is not a parenthesis, then we must be looking at a declaration. (After "int (" we might be looking at a functional cast.) / if (decl_specifiers.any_specifiers_p && cp_lexer_next_token_is_not (parser->lexer, CPP_OPEN_PAREN)) cp_parser_commit_to_tentative_parse (parser); / Keep going until we hit the `;' at the end of the simple declaration. / saw_declarator = false; while (cp_lexer_next_token_is_not (parser->lexer, CPP_SEMICOLON)) { cp_token token; bool function_definition_p; tree decl; if (saw_declarator) { /* If we are processing next declarator, coma is expected / token = cp_lexer_peek_token (parser->lexer); gcc_assert (token->type == CPP_COMMA); cp_lexer_consume_token (parser->lexer); } else saw_declarator = true; / Parse the init-declarator. / decl = cp_parser_init_declarator (parser, &decl_specifiers, /checks=/NULL, function_definition_allowed_p, /member_p=/false, declares_class_or_enum, &function_definition_p); / If an error occurred while parsing tentatively, exit quickly. (That usually happens when in the body of a function; each statement is treated as a declaration-statement until proven otherwise.) / if (cp_parser_error_occurred (parser)) goto done; / Handle function definitions specially. / if (function_definition_p) { / If the next token is a `,', then we are probably processing something like: void f() {}, p; which is erroneous. / if (cp_lexer_next_token_is (parser->lexer, CPP_COMMA)) error ("mixing declarations and function-definitions is forbidden"); /* Otherwise, we're done with the list of declarators. / else { pop_deferring_access_checks (); return; } } / The next token should be either a `,' or a `;'. / token = cp_lexer_peek_token (parser->lexer); / If it's a `,', there are more declarators to come. / if (token->type == CPP_COMMA) / will be consumed next time around /; / If it's a `;', we are done. / else if (token->type == CPP_SEMICOLON) break; / Anything else is an error. / else { / If we have already issued an error message we don't need to issue another one. / if (decl != error_mark_node \|\| cp_parser_uncommitted_to_tentative_parse_p (parser)) cp_parser_error (parser, "expected %<,%> or %<;%>"); / Skip tokens until we reach the end of the statement. / cp_parser_skip_to_end_of_statement (parser); / If the next token is now a `;', consume it. / if (cp_lexer_next_token_is (parser->lexer, CPP_SEMICOLON)) cp_lexer_consume_token (parser->lexer); goto done; } / After the first time around, a function-definition is not allowed -- even if it was OK at first. For example: int i, f() {} is not valid. / function_definition_allowed_p = false; } / Issue an error message if no declarators are present, and the decl-specifier-seq does not itself declare a class or enumeration. / if (!saw_declarator) { if (cp_parser_declares_only_class_p (parser)) shadow_tag (&decl_specifiers); / Perform any deferred access checks. / perform_deferred_access_checks (); } / Consume the `;'. / cp_parser_require (parser, CPP_SEMICOLON, "`;'"); done: pop_deferring_access_checks (); } / Parse a decl-specifier-seq. decl-specifier-seq: decl-specifier-seq [opt] decl-specifier decl-specifier: storage-class-specifier type-specifier function-specifier friend typedef GNU Extension: decl-specifier: attributes Set DECL_SPECS to a representation of the decl-specifier-seq. The parser flags FLAGS is used to control type-specifier parsing. DECLARES_CLASS_OR_ENUM is set to the bitwise or of the following flags: 1: one of the decl-specifiers is an elaborated-type-specifier (i.e., a type declaration) 2: one of the decl-specifiers is an enum-specifier or a class-specifier (i.e., a type definition) / static void cp_parser_decl_specifier_seq (cp_parser parser, cp_parser_flags flags, cp_decl_specifier_seq decl_specs, int declares_class_or_enum) { bool constructor_possible_p = !parser->in_declarator_p; /* Clear DECL_SPECS. / clear_decl_specs (decl_specs); / Assume no class or enumeration type is declared. / declares_class_or_enum = 0; /* Keep reading specifiers until there are no more to read. / while (true) { bool constructor_p; bool found_decl_spec; cp_token token; /* Peek at the next token. / token = cp_lexer_peek_token (parser->lexer); / Handle attributes. / if (token->keyword == RID_ATTRIBUTE) { / Parse the attributes. / decl_specs->attributes = chainon (decl_specs->attributes, cp_parser_attributes_opt (parser)); continue; } / Assume we will find a decl-specifier keyword. / found_decl_spec = true; / If the next token is an appropriate keyword, we can simply add it to the list. / switch (token->keyword) { / decl-specifier: friend / case RID_FRIEND: if (!at_class_scope_p ()) { error ("%<friend%> used outside of class"); cp_lexer_purge_token (parser->lexer); } else { ++decl_specs->specs[(int) ds_friend]; / Consume the token. / cp_lexer_consume_token (parser->lexer); } break; / function-specifier: inline virtual explicit / case RID_INLINE: case RID_VIRTUAL: case RID_EXPLICIT: cp_parser_function_specifier_opt (parser, decl_specs); break; / decl-specifier: typedef / case RID_TYPEDEF: ++decl_specs->specs[(int) ds_typedef]; / Consume the token. / cp_lexer_consume_token (parser->lexer); / A constructor declarator cannot appear in a typedef. / constructor_possible_p = false; / The "typedef" keyword can only occur in a declaration; we may as well commit at this point. / cp_parser_commit_to_tentative_parse (parser); if (decl_specs->storage_class != sc_none) decl_specs->conflicting_specifiers_p = true; break; / storage-class-specifier: auto register static extern mutable GNU Extension: thread / case RID_AUTO: case RID_REGISTER: case RID_STATIC: case RID_EXTERN: case RID_MUTABLE: / Consume the token. / cp_lexer_consume_token (parser->lexer); cp_parser_set_storage_class (parser, decl_specs, token->keyword); break; case RID_THREAD: / Consume the token. / cp_lexer_consume_token (parser->lexer); ++decl_specs->specs[(int) ds_thread]; break; default: / We did not yet find a decl-specifier yet. / found_decl_spec = false; break; } / Constructors are a special case. The `S' in `S()' is not a decl-specifier; it is the beginning of the declarator. / constructor_p = (!found_decl_spec && constructor_possible_p && (cp_parser_constructor_declarator_p (parser, decl_specs->specs[(int) ds_friend] != 0))); / If we don't have a DECL_SPEC yet, then we must be looking at a type-specifier. / if (!found_decl_spec && !constructor_p) { int decl_spec_declares_class_or_enum; bool is_cv_qualifier; tree type_spec; type_spec = cp_parser_type_specifier (parser, flags, decl_specs, /is_declaration=/true, &decl_spec_declares_class_or_enum, &is_cv_qualifier); declares_class_or_enum \|= decl_spec_declares_class_or_enum; /* If this type-specifier referenced a user-defined type (a typedef, class-name, etc.), then we can't allow any more such type-specifiers henceforth. [dcl.spec] The longest sequence of decl-specifiers that could possibly be a type name is taken as the decl-specifier-seq of a declaration. The sequence shall be self-consistent as described below. [dcl.type] As a general rule, at most one type-specifier is allowed in the complete decl-specifier-seq of a declaration. The only exceptions are the following: -- const or volatile can be combined with any other type-specifier. -- signed or unsigned can be combined with char, long, short, or int. -- .. Example: typedef char* Pc; void g (const int Pc); Here, Pc is not part of the decl-specifier seq; it's the declarator. Therefore, once we see a type-specifier (other than a cv-qualifier), we forbid any additional user-defined types. We do still allow things like `int int' to be considered a decl-specifier-seq, and issue the error message later. / if (type_spec && !is_cv_qualifier) flags \|= CP_PARSER_FLAGS_NO_USER_DEFINED_TYPES; / A constructor declarator cannot follow a type-specifier. / if (type_spec) { constructor_possible_p = false; found_decl_spec = true; } } / If we still do not have a DECL_SPEC, then there are no more decl-specifiers. / if (!found_decl_spec) break; decl_specs->any_specifiers_p = true; / After we see one decl-specifier, further decl-specifiers are always optional. / flags \|= CP_PARSER_FLAGS_OPTIONAL; } cp_parser_check_decl_spec (decl_specs); / Don't allow a friend specifier with a class definition. / if (decl_specs->specs[(int) ds_friend] != 0 && (declares_class_or_enum & 2)) error ("class definition may not be declared a friend"); } /* Parse an (optional) storage-class-specifier. storage-class-specifier: auto register static extern mutable GNU Extension: storage-class-specifier: thread Returns an IDENTIFIER_NODE corresponding to the keyword used. / static tree cp_parser_storage_class_specifier_opt (cp_parser parser) { switch (cp_lexer_peek_token (parser->lexer)->keyword) { case RID_AUTO: case RID_REGISTER: case RID_STATIC: case RID_EXTERN: case RID_MUTABLE: case RID_THREAD: /* Consume the token. / return cp_lexer_consume_token (parser->lexer)->u.value; default: return NULL_TREE; } } / Parse an (optional) function-specifier. function-specifier: inline virtual explicit Returns an IDENTIFIER_NODE corresponding to the keyword used. Updates DECL_SPECS, if it is non-NULL. / static tree cp_parser_function_specifier_opt (cp_parser parser, cp_decl_specifier_seq decl_specs) { switch (cp_lexer_peek_token (parser->lexer)->keyword) { case RID_INLINE: if (decl_specs) ++decl_specs->specs[(int) ds_inline]; break; case RID_VIRTUAL: / 14.5.2.3 [temp.mem] A member function template shall not be virtual. / if (PROCESSING_REAL_TEMPLATE_DECL_P ()) error ("templates may not be %<virtual%>"); else if (decl_specs) ++decl_specs->specs[(int) ds_virtual]; break; case RID_EXPLICIT: if (decl_specs) ++decl_specs->specs[(int) ds_explicit]; break; default: return NULL_TREE; } / Consume the token. / return cp_lexer_consume_token (parser->lexer)->u.value; } / Parse a linkage-specification. linkage-specification: extern string-literal { declaration-seq [opt] } extern string-literal declaration / static void cp_parser_linkage_specification (cp_parser parser) { tree linkage; /* Look for the `extern' keyword. / cp_parser_require_keyword (parser, RID_EXTERN, "`extern'"); / Look for the string-literal. / linkage = cp_parser_string_literal (parser, false, false); / Transform the literal into an identifier. If the literal is a wide-character string, or contains embedded NULs, then we can't handle it as the user wants. / if (strlen (TREE_STRING_POINTER (linkage)) != (size_t) (TREE_STRING_LENGTH (linkage) - 1)) { cp_parser_error (parser, "invalid linkage-specification"); / Assume C++ linkage. / linkage = lang_name_cplusplus; } else linkage = get_identifier (TREE_STRING_POINTER (linkage)); / We're now using the new linkage. / push_lang_context (linkage); / If the next token is a `{', then we're using the first production. / if (cp_lexer_next_token_is (parser->lexer, CPP_OPEN_BRACE)) { / Consume the `{' token. / cp_lexer_consume_token (parser->lexer); / Parse the declarations. / cp_parser_declaration_seq_opt (parser); / Look for the closing `}'. / cp_parser_require (parser, CPP_CLOSE_BRACE, "`}'"); } / Otherwise, there's just one declaration. / else { bool saved_in_unbraced_linkage_specification_p; saved_in_unbraced_linkage_specification_p = parser->in_unbraced_linkage_specification_p; parser->in_unbraced_linkage_specification_p = true; cp_parser_declaration (parser); parser->in_unbraced_linkage_specification_p = saved_in_unbraced_linkage_specification_p; } / We're done with the linkage-specification. / pop_lang_context (); } / Special member functions [gram.special] / / Parse a conversion-function-id. conversion-function-id: operator conversion-type-id Returns an IDENTIFIER_NODE representing the operator. / static tree cp_parser_conversion_function_id (cp_parser parser) { tree type; tree saved_scope; tree saved_qualifying_scope; tree saved_object_scope; tree pushed_scope = NULL_TREE; /* Look for the `operator' token. / if (!cp_parser_require_keyword (parser, RID_OPERATOR, "`operator'")) return error_mark_node; / When we parse the conversion-type-id, the current scope will be reset. However, we need that information in able to look up the conversion function later, so we save it here. / saved_scope = parser->scope; saved_qualifying_scope = parser->qualifying_scope; saved_object_scope = parser->object_scope; / We must enter the scope of the class so that the names of entities declared within the class are available in the conversion-type-id. For example, consider: struct S { typedef int I; operator I(); }; S::operator I() { ... } In order to see that `I' is a type-name in the definition, we must be in the scope of `S'. / if (saved_scope) pushed_scope = push_scope (saved_scope); / Parse the conversion-type-id. / type = cp_parser_conversion_type_id (parser); / Leave the scope of the class, if any. / if (pushed_scope) pop_scope (pushed_scope); / Restore the saved scope. / parser->scope = saved_scope; parser->qualifying_scope = saved_qualifying_scope; parser->object_scope = saved_object_scope; / If the TYPE is invalid, indicate failure. / if (type == error_mark_node) return error_mark_node; return mangle_conv_op_name_for_type (type); } / Parse a conversion-type-id: conversion-type-id: type-specifier-seq conversion-declarator [opt] Returns the TYPE specified. / static tree cp_parser_conversion_type_id (cp_parser parser) { tree attributes; cp_decl_specifier_seq type_specifiers; cp_declarator declarator; tree type_specified; / Parse the attributes. / attributes = cp_parser_attributes_opt (parser); / Parse the type-specifiers. / cp_parser_type_specifier_seq (parser, /is_condition=/false, &type_specifiers); / If that didn't work, stop. / if (type_specifiers.type == error_mark_node) return error_mark_node; / Parse the conversion-declarator. / declarator = cp_parser_conversion_declarator_opt (parser); type_specified = grokdeclarator (declarator, &type_specifiers, TYPENAME, /initialized=/0, &attributes); if (attributes) cplus_decl_attributes (&type_specified, attributes, /flags=/0); return type_specified; } / Parse an (optional) conversion-declarator. conversion-declarator: ptr-operator conversion-declarator [opt] / static cp_declarator cp_parser_conversion_declarator_opt (cp_parser* parser) { enum tree_code code; tree class_type; cp_cv_quals cv_quals; /* We don't know if there's a ptr-operator next, or not. / cp_parser_parse_tentatively (parser); / Try the ptr-operator. / code = cp_parser_ptr_operator (parser, &class_type, &cv_quals); / If it worked, look for more conversion-declarators. / if (cp_parser_parse_definitely (parser)) { cp_declarator declarator; /* Parse another optional declarator. / declarator = cp_parser_conversion_declarator_opt (parser); / Create the representation of the declarator. / if (class_type) declarator = make_ptrmem_declarator (cv_quals, class_type, declarator); else if (code == INDIRECT_REF) declarator = make_pointer_declarator (cv_quals, declarator); else declarator = make_reference_declarator (cv_quals, declarator); return declarator; } return NULL; } / Parse an (optional) ctor-initializer. ctor-initializer: : mem-initializer-list Returns TRUE iff the ctor-initializer was actually present. / static bool cp_parser_ctor_initializer_opt (cp_parser parser) { /* If the next token is not a `:', then there is no ctor-initializer. / if (cp_lexer_next_token_is_not (parser->lexer, CPP_COLON)) { / Do default initialization of any bases and members. / if (DECL_CONSTRUCTOR_P (current_function_decl)) finish_mem_initializers (NULL_TREE); return false; } / Consume the `:' token. / cp_lexer_consume_token (parser->lexer); / And the mem-initializer-list. / cp_parser_mem_initializer_list (parser); return true; } / Parse a mem-initializer-list. mem-initializer-list: mem-initializer mem-initializer , mem-initializer-list / static void cp_parser_mem_initializer_list (cp_parser parser) { tree mem_initializer_list = NULL_TREE; /* Let the semantic analysis code know that we are starting the mem-initializer-list. / if (!DECL_CONSTRUCTOR_P (current_function_decl)) error ("only constructors take base initializers"); / Loop through the list. / while (true) { tree mem_initializer; / Parse the mem-initializer. / mem_initializer = cp_parser_mem_initializer (parser); / Add it to the list, unless it was erroneous. / if (mem_initializer != error_mark_node) { TREE_CHAIN (mem_initializer) = mem_initializer_list; mem_initializer_list = mem_initializer; } / If the next token is not a `,', we're done. / if (cp_lexer_next_token_is_not (parser->lexer, CPP_COMMA)) break; / Consume the `,' token. / cp_lexer_consume_token (parser->lexer); } / Perform semantic analysis. / if (DECL_CONSTRUCTOR_P (current_function_decl)) finish_mem_initializers (mem_initializer_list); } / Parse a mem-initializer. mem-initializer: mem-initializer-id ( expression-list [opt] ) GNU extension: mem-initializer: ( expression-list [opt] ) Returns a TREE_LIST. The TREE_PURPOSE is the TYPE (for a base class) or FIELD_DECL (for a non-static data member) to initialize; the TREE_VALUE is the expression-list. An empty initialization list is represented by void_list_node. / static tree cp_parser_mem_initializer (cp_parser parser) { tree mem_initializer_id; tree expression_list; tree member; /* Find out what is being initialized. / if (cp_lexer_next_token_is (parser->lexer, CPP_OPEN_PAREN)) { pedwarn ("anachronistic old-style base class initializer"); mem_initializer_id = NULL_TREE; } else mem_initializer_id = cp_parser_mem_initializer_id (parser); member = expand_member_init (mem_initializer_id); if (member && !DECL_P (member)) in_base_initializer = 1; expression_list = cp_parser_parenthesized_expression_list (parser, false, /cast_p=/false, /non_constant_p=/NULL); if (expression_list == error_mark_node) return error_mark_node; if (!expression_list) expression_list = void_type_node; in_base_initializer = 0; return member ? build_tree_list (member, expression_list) : error_mark_node; } / Parse a mem-initializer-id. mem-initializer-id: :: [opt] nested-name-specifier [opt] class-name identifier Returns a TYPE indicating the class to be initializer for the first production. Returns an IDENTIFIER_NODE indicating the data member to be initialized for the second production. / static tree cp_parser_mem_initializer_id (cp_parser parser) { bool global_scope_p; bool nested_name_specifier_p; bool template_p = false; tree id; /* `typename' is not allowed in this context ([temp.res]). / if (cp_lexer_next_token_is_keyword (parser->lexer, RID_TYPENAME)) { error ("keyword %<typename%> not allowed in this context (a qualified " "member initializer is implicitly a type)"); cp_lexer_consume_token (parser->lexer); } / Look for the optional `::' operator. / global_scope_p = (cp_parser_global_scope_opt (parser, /current_scope_valid_p=/false) != NULL_TREE); / Look for the optional nested-name-specifier. The simplest way to implement: [temp.res] The keyword `typename' is not permitted in a base-specifier or mem-initializer; in these contexts a qualified name that depends on a template-parameter is implicitly assumed to be a type name. is to assume that we have seen the `typename' keyword at this point. / nested_name_specifier_p = (cp_parser_nested_name_specifier_opt (parser, /typename_keyword_p=/true, /check_dependency_p=/true, /type_p=/true, /is_declaration=/true) != NULL_TREE); if (nested_name_specifier_p) template_p = cp_parser_optional_template_keyword (parser); / If there is a `::' operator or a nested-name-specifier, then we are definitely looking for a class-name. / if (global_scope_p \|\| nested_name_specifier_p) return cp_parser_class_name (parser, /typename_keyword_p=/true, /template_keyword_p=/template_p, none_type, /check_dependency_p=/true, /class_head_p=/false, /is_declaration=/true); / Otherwise, we could also be looking for an ordinary identifier. / cp_parser_parse_tentatively (parser); / Try a class-name. / id = cp_parser_class_name (parser, /typename_keyword_p=/true, /template_keyword_p=/false, none_type, /check_dependency_p=/true, /class_head_p=/false, /is_declaration=/true); / If we found one, we're done. / if (cp_parser_parse_definitely (parser)) return id; / Otherwise, look for an ordinary identifier. / return cp_parser_identifier (parser); } / Overloading [gram.over] / / Parse an operator-function-id. operator-function-id: operator operator Returns an IDENTIFIER_NODE for the operator which is a human-readable spelling of the identifier, e.g., `operator +'. / static tree cp_parser_operator_function_id (cp_parser parser) { /* Look for the `operator' keyword. / if (!cp_parser_require_keyword (parser, RID_OPERATOR, "`operator'")) return error_mark_node; / And then the name of the operator itself. / return cp_parser_operator (parser); } / Parse an operator. operator: new delete new[] delete[] + - * / % ^ & \| ~ ! = < > += -= = /= %= ^= &= \|= << >> >>= <<= == != <= >= && \|\| ++ -- , -> -> () [] GNU Extensions: operator: <? >? <?= >?= Returns an IDENTIFIER_NODE for the operator which is a human-readable spelling of the identifier, e.g., `operator +'. / static tree cp_parser_operator (cp_parser parser) { tree id = NULL_TREE; cp_token token; / Peek at the next token. / token = cp_lexer_peek_token (parser->lexer); / Figure out which operator we have. / switch (token->type) { case CPP_KEYWORD: { enum tree_code op; / The keyword should be either `new' or `delete'. / if (token->keyword == RID_NEW) op = NEW_EXPR; else if (token->keyword == RID_DELETE) op = DELETE_EXPR; else break; / Consume the `new' or `delete' token. / cp_lexer_consume_token (parser->lexer); / Peek at the next token. / token = cp_lexer_peek_token (parser->lexer); / If it's a `[' token then this is the array variant of the operator. / if (token->type == CPP_OPEN_SQUARE) { / Consume the `[' token. / cp_lexer_consume_token (parser->lexer); / Look for the `]' token. / cp_parser_require (parser, CPP_CLOSE_SQUARE, "`]'"); id = ansi_opname (op == NEW_EXPR ? VEC_NEW_EXPR : VEC_DELETE_EXPR); } / Otherwise, we have the non-array variant. / else id = ansi_opname (op); return id; } case CPP_PLUS: id = ansi_opname (PLUS_EXPR); break; case CPP_MINUS: id = ansi_opname (MINUS_EXPR); break; case CPP_MULT: id = ansi_opname (MULT_EXPR); break; case CPP_DIV: id = ansi_opname (TRUNC_DIV_EXPR); break; case CPP_MOD: id = ansi_opname (TRUNC_MOD_EXPR); break; case CPP_XOR: id = ansi_opname (BIT_XOR_EXPR); break; case CPP_AND: id = ansi_opname (BIT_AND_EXPR); break; case CPP_OR: id = ansi_opname (BIT_IOR_EXPR); break; case CPP_COMPL: id = ansi_opname (BIT_NOT_EXPR); break; case CPP_NOT: id = ansi_opname (TRUTH_NOT_EXPR); break; case CPP_EQ: id = ansi_assopname (NOP_EXPR); break; case CPP_LESS: id = ansi_opname (LT_EXPR); break; case CPP_GREATER: id = ansi_opname (GT_EXPR); break; case CPP_PLUS_EQ: id = ansi_assopname (PLUS_EXPR); break; case CPP_MINUS_EQ: id = ansi_assopname (MINUS_EXPR); break; case CPP_MULT_EQ: id = ansi_assopname (MULT_EXPR); break; case CPP_DIV_EQ: id = ansi_assopname (TRUNC_DIV_EXPR); break; case CPP_MOD_EQ: id = ansi_assopname (TRUNC_MOD_EXPR); break; case CPP_XOR_EQ: id = ansi_assopname (BIT_XOR_EXPR); break; case CPP_AND_EQ: id = ansi_assopname (BIT_AND_EXPR); break; case CPP_OR_EQ: id = ansi_assopname (BIT_IOR_EXPR); break; case CPP_LSHIFT: id = ansi_opname (LSHIFT_EXPR); break; case CPP_RSHIFT: id = ansi_opname (RSHIFT_EXPR); break; case CPP_LSHIFT_EQ: id = ansi_assopname (LSHIFT_EXPR); break; case CPP_RSHIFT_EQ: id = ansi_assopname (RSHIFT_EXPR); break; case CPP_EQ_EQ: id = ansi_opname (EQ_EXPR); break; case CPP_NOT_EQ: id = ansi_opname (NE_EXPR); break; case CPP_LESS_EQ: id = ansi_opname (LE_EXPR); break; case CPP_GREATER_EQ: id = ansi_opname (GE_EXPR); break; case CPP_AND_AND: id = ansi_opname (TRUTH_ANDIF_EXPR); break; case CPP_OR_OR: id = ansi_opname (TRUTH_ORIF_EXPR); break; case CPP_PLUS_PLUS: id = ansi_opname (POSTINCREMENT_EXPR); break; case CPP_MINUS_MINUS: id = ansi_opname (PREDECREMENT_EXPR); break; case CPP_COMMA: id = ansi_opname (COMPOUND_EXPR); break; case CPP_DEREF_STAR: id = ansi_opname (MEMBER_REF); break; case CPP_DEREF: id = ansi_opname (COMPONENT_REF); break; case CPP_OPEN_PAREN: / Consume the `('. / cp_lexer_consume_token (parser->lexer); / Look for the matching `)'. / cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'"); return ansi_opname (CALL_EXPR); case CPP_OPEN_SQUARE: / Consume the `['. / cp_lexer_consume_token (parser->lexer); / Look for the matching `]'. / cp_parser_require (parser, CPP_CLOSE_SQUARE, "`]'"); return ansi_opname (ARRAY_REF); default: / Anything else is an error. / break; } / If we have selected an identifier, we need to consume the operator token. / if (id) cp_lexer_consume_token (parser->lexer); / Otherwise, no valid operator name was present. / else { cp_parser_error (parser, "expected operator"); id = error_mark_node; } return id; } / Parse a template-declaration. template-declaration: export [opt] template < template-parameter-list > declaration If MEMBER_P is TRUE, this template-declaration occurs within a class-specifier. The grammar rule given by the standard isn't correct. What is really meant is: template-declaration: export [opt] template-parameter-list-seq decl-specifier-seq [opt] init-declarator [opt] ; export [opt] template-parameter-list-seq function-definition template-parameter-list-seq: template-parameter-list-seq [opt] template < template-parameter-list > / static void cp_parser_template_declaration (cp_parser parser, bool member_p) { /* Check for `export'. / if (cp_lexer_next_token_is_keyword (parser->lexer, RID_EXPORT)) { / Consume the `export' token. / cp_lexer_consume_token (parser->lexer); / Warn that we do not support `export'. / warning (0, "keyword %<export%> not implemented, and will be ignored"); } cp_parser_template_declaration_after_export (parser, member_p); } / Parse a template-parameter-list. template-parameter-list: template-parameter template-parameter-list , template-parameter Returns a TREE_LIST. Each node represents a template parameter. The nodes are connected via their TREE_CHAINs. / static tree cp_parser_template_parameter_list (cp_parser parser) { tree parameter_list = NULL_TREE; begin_template_parm_list (); while (true) { tree parameter; cp_token token; bool is_non_type; / Parse the template-parameter. / parameter = cp_parser_template_parameter (parser, &is_non_type); / Add it to the list. / if (parameter != error_mark_node) parameter_list = process_template_parm (parameter_list, parameter, is_non_type); else { tree err_parm = build_tree_list (parameter, parameter); TREE_VALUE (err_parm) = error_mark_node; parameter_list = chainon (parameter_list, err_parm); } / Peek at the next token. / token = cp_lexer_peek_token (parser->lexer); / If it's not a `,', we're done. / if (token->type != CPP_COMMA) break; / Otherwise, consume the `,' token. / cp_lexer_consume_token (parser->lexer); } return end_template_parm_list (parameter_list); } / Parse a template-parameter. template-parameter: type-parameter parameter-declaration If all goes well, returns a TREE_LIST. The TREE_VALUE represents the parameter. The TREE_PURPOSE is the default value, if any. Returns ERROR_MARK_NODE on failure. IS_NON_TYPE is set to true iff this parameter is a non-type parameter. / static tree cp_parser_template_parameter (cp_parser* parser, bool is_non_type) { cp_token token; cp_parameter_declarator parameter_declarator; tree parm; / Assume it is a type parameter or a template parameter. / is_non_type = false; /* Peek at the next token. / token = cp_lexer_peek_token (parser->lexer); / If it is `class' or `template', we have a type-parameter. / if (token->keyword == RID_TEMPLATE) return cp_parser_type_parameter (parser); / If it is `class' or `typename' we do not know yet whether it is a type parameter or a non-type parameter. Consider: template <typename T, typename T::X X> ... or: template <class C, class D> ... Here, the first parameter is a type parameter, and the second is a non-type parameter. We can tell by looking at the token after the identifier -- if it is a `,', `=', or `>' then we have a type parameter. / if (token->keyword == RID_TYPENAME \|\| token->keyword == RID_CLASS) { /* Peek at the token after `class' or `typename'. / token = cp_lexer_peek_nth_token (parser->lexer, 2); / If it's an identifier, skip it. / if (token->type == CPP_NAME) token = cp_lexer_peek_nth_token (parser->lexer, 3); / Now, see if the token looks like the end of a template parameter. / if (token->type == CPP_COMMA \|\| token->type == CPP_EQ \|\| token->type == CPP_GREATER) return cp_parser_type_parameter (parser); } / Otherwise, it is a non-type parameter. [temp.param] When parsing a default template-argument for a non-type template-parameter, the first non-nested `>' is taken as the end of the template parameter-list rather than a greater-than operator. / is_non_type = true; parameter_declarator = cp_parser_parameter_declaration (parser, /template_parm_p=/true, /parenthesized_p=/NULL); parm = grokdeclarator (parameter_declarator->declarator, &parameter_declarator->decl_specifiers, PARM, /initialized=/0, /attrlist=/NULL); if (parm == error_mark_node) return error_mark_node; return build_tree_list (parameter_declarator->default_argument, parm); } /* Parse a type-parameter. type-parameter: class identifier [opt] class identifier [opt] = type-id typename identifier [opt] typename identifier [opt] = type-id template < template-parameter-list > class identifier [opt] template < template-parameter-list > class identifier [opt] = id-expression Returns a TREE_LIST. The TREE_VALUE is itself a TREE_LIST. The TREE_PURPOSE is the default-argument, if any. The TREE_VALUE is the declaration of the parameter. / static tree cp_parser_type_parameter (cp_parser parser) { cp_token token; tree parameter; / Look for a keyword to tell us what kind of parameter this is. / token = cp_parser_require (parser, CPP_KEYWORD, "`class', `typename', or `template'"); if (!token) return error_mark_node; switch (token->keyword) { case RID_CLASS: case RID_TYPENAME: { tree identifier; tree default_argument; / If the next token is an identifier, then it names the parameter. / if (cp_lexer_next_token_is (parser->lexer, CPP_NAME)) identifier = cp_parser_identifier (parser); else identifier = NULL_TREE; / Create the parameter. / parameter = finish_template_type_parm (class_type_node, identifier); / If the next token is an `=', we have a default argument. / if (cp_lexer_next_token_is (parser->lexer, CPP_EQ)) { / Consume the `=' token. / cp_lexer_consume_token (parser->lexer); / Parse the default-argument. / push_deferring_access_checks (dk_no_deferred); default_argument = cp_parser_type_id (parser); pop_deferring_access_checks (); } else default_argument = NULL_TREE; / Create the combined representation of the parameter and the default argument. / parameter = build_tree_list (default_argument, parameter); } break; case RID_TEMPLATE: { tree parameter_list; tree identifier; tree default_argument; / Look for the `<'. / cp_parser_require (parser, CPP_LESS, "`<'"); / Parse the template-parameter-list. / parameter_list = cp_parser_template_parameter_list (parser); / Look for the `>'. / cp_parser_require (parser, CPP_GREATER, "`>'"); / Look for the `class' keyword. / cp_parser_require_keyword (parser, RID_CLASS, "`class'"); / If the next token is an `=', then there is a default-argument. If the next token is a `>', we are at the end of the parameter-list. If the next token is a `,', then we are at the end of this parameter. / if (cp_lexer_next_token_is_not (parser->lexer, CPP_EQ) && cp_lexer_next_token_is_not (parser->lexer, CPP_GREATER) && cp_lexer_next_token_is_not (parser->lexer, CPP_COMMA)) { identifier = cp_parser_identifier (parser); / Treat invalid names as if the parameter were nameless. / if (identifier == error_mark_node) identifier = NULL_TREE; } else identifier = NULL_TREE; / Create the template parameter. / parameter = finish_template_template_parm (class_type_node, identifier); / If the next token is an `=', then there is a default-argument. / if (cp_lexer_next_token_is (parser->lexer, CPP_EQ)) { bool is_template; / Consume the `='. / cp_lexer_consume_token (parser->lexer); / Parse the id-expression. / push_deferring_access_checks (dk_no_deferred); default_argument = cp_parser_id_expression (parser, /template_keyword_p=/false, /check_dependency_p=/true, /template_p=/&is_template, /declarator_p=/false, /optional_p=/false); if (TREE_CODE (default_argument) == TYPE_DECL) / If the id-expression was a template-id that refers to a template-class, we already have the declaration here, so no further lookup is needed. / ; else / Look up the name. / default_argument = cp_parser_lookup_name (parser, default_argument, none_type, /is_template=/is_template, /is_namespace=/false, /check_dependency=/true, /ambiguous_decls=/NULL); / See if the default argument is valid. / default_argument = check_template_template_default_arg (default_argument); pop_deferring_access_checks (); } else default_argument = NULL_TREE; / Create the combined representation of the parameter and the default argument. / parameter = build_tree_list (default_argument, parameter); } break; default: gcc_unreachable (); break; } return parameter; } / Parse a template-id. template-id: template-name < template-argument-list [opt] > If TEMPLATE_KEYWORD_P is TRUE, then we have just seen the `template' keyword. In this case, a TEMPLATE_ID_EXPR will be returned. Otherwise, if the template-name names a function, or set of functions, returns a TEMPLATE_ID_EXPR. If the template-name names a class, returns a TYPE_DECL for the specialization. If CHECK_DEPENDENCY_P is FALSE, names are looked up in uninstantiated templates. / static tree cp_parser_template_id (cp_parser parser, bool template_keyword_p, bool check_dependency_p, bool is_declaration) { int i; tree template; tree arguments; tree template_id; cp_token_position start_of_id = 0; deferred_access_check chk; VEC (deferred_access_check,gc) access_check; cp_token next_token, next_token_2; bool is_identifier; /* If the next token corresponds to a template-id, there is no need to reparse it. / next_token = cp_lexer_peek_token (parser->lexer); if (next_token->type == CPP_TEMPLATE_ID) { struct tree_check check_value; /* Get the stored value. / check_value = cp_lexer_consume_token (parser->lexer)->u.tree_check_value; / Perform any access checks that were deferred. / access_check = check_value->checks; if (access_check) { for (i = 0 ; VEC_iterate (deferred_access_check, access_check, i, chk) ; ++i) { perform_or_defer_access_check (chk->binfo, chk->decl, chk->diag_decl); } } / Return the stored value. / return check_value->value; } / Avoid performing name lookup if there is no possibility of finding a template-id. / if ((next_token->type != CPP_NAME && next_token->keyword != RID_OPERATOR) \|\| (next_token->type == CPP_NAME && !cp_parser_nth_token_starts_template_argument_list_p (parser, 2))) { cp_parser_error (parser, "expected template-id"); return error_mark_node; } / Remember where the template-id starts. / if (cp_parser_uncommitted_to_tentative_parse_p (parser)) start_of_id = cp_lexer_token_position (parser->lexer, false); push_deferring_access_checks (dk_deferred); / Parse the template-name. / is_identifier = false; template = cp_parser_template_name (parser, template_keyword_p, check_dependency_p, is_declaration, &is_identifier); if (template == error_mark_node \|\| is_identifier) { pop_deferring_access_checks (); return template; } / If we find the sequence `[:' after a template-name, it's probably a digraph-typo for `< ::'. Substitute the tokens and check if we can parse correctly the argument list. / next_token = cp_lexer_peek_token (parser->lexer); next_token_2 = cp_lexer_peek_nth_token (parser->lexer, 2); if (next_token->type == CPP_OPEN_SQUARE && next_token->flags & DIGRAPH && next_token_2->type == CPP_COLON && !(next_token_2->flags & PREV_WHITE)) { cp_parser_parse_tentatively (parser); / Change `:' into `::'. / next_token_2->type = CPP_SCOPE; / Consume the first token (CPP_OPEN_SQUARE - which we pretend it is CPP_LESS. / cp_lexer_consume_token (parser->lexer); / Parse the arguments. / arguments = cp_parser_enclosed_template_argument_list (parser); if (!cp_parser_parse_definitely (parser)) { / If we couldn't parse an argument list, then we revert our changes and return simply an error. Maybe this is not a template-id after all. / next_token_2->type = CPP_COLON; cp_parser_error (parser, "expected %<<%>"); pop_deferring_access_checks (); return error_mark_node; } / Otherwise, emit an error about the invalid digraph, but continue parsing because we got our argument list. / pedwarn ("%<<::%> cannot begin a template-argument list"); inform ("%<<:%> is an alternate spelling for %<[%>. Insert whitespace " "between %<<%> and %<::%>"); if (!flag_permissive) { static bool hint; if (!hint) { inform ("(if you use -fpermissive G++ will accept your code)"); hint = true; } } } else { / Look for the `<' that starts the template-argument-list. / if (!cp_parser_require (parser, CPP_LESS, "`<'")) { pop_deferring_access_checks (); return error_mark_node; } / Parse the arguments. / arguments = cp_parser_enclosed_template_argument_list (parser); } / Build a representation of the specialization. / if (TREE_CODE (template) == IDENTIFIER_NODE) template_id = build_min_nt (TEMPLATE_ID_EXPR, template, arguments); else if (DECL_CLASS_TEMPLATE_P (template) \|\| DECL_TEMPLATE_TEMPLATE_PARM_P (template)) { bool entering_scope; / In "template <typename T> ... A<T>::", A<T> is the abstract A template (rather than some instantiation thereof) only if is not nested within some other construct. For example, in "template <typename T> void f(T) { A<T>::", A<T> is just an instantiation of A. / entering_scope = (template_parm_scope_p () && cp_lexer_next_token_is (parser->lexer, CPP_SCOPE)); template_id = finish_template_type (template, arguments, entering_scope); } else { / If it's not a class-template or a template-template, it should be a function-template. / gcc_assert ((DECL_FUNCTION_TEMPLATE_P (template) \|\| TREE_CODE (template) == OVERLOAD \|\| BASELINK_P (template))); template_id = lookup_template_function (template, arguments); } / If parsing tentatively, replace the sequence of tokens that makes up the template-id with a CPP_TEMPLATE_ID token. That way, should we re-parse the token stream, we will not have to repeat the effort required to do the parse, nor will we issue duplicate error messages about problems during instantiation of the template. / if (start_of_id) { cp_token token = cp_lexer_token_at (parser->lexer, start_of_id); /* Reset the contents of the START_OF_ID token. / token->type = CPP_TEMPLATE_ID; / Retrieve any deferred checks. Do not pop this access checks yet so the memory will not be reclaimed during token replacing below. / token->u.tree_check_value = GGC_CNEW (struct tree_check); token->u.tree_check_value->value = template_id; token->u.tree_check_value->checks = get_deferred_access_checks (); token->keyword = RID_MAX; / Purge all subsequent tokens. / cp_lexer_purge_tokens_after (parser->lexer, start_of_id); / ??? Can we actually assume that, if template_id == error_mark_node, we will have issued a diagnostic to the user, as opposed to simply marking the tentative parse as failed? / if (cp_parser_error_occurred (parser) && template_id != error_mark_node) error ("parse error in template argument list"); } pop_deferring_access_checks (); return template_id; } / Parse a template-name. template-name: identifier The standard should actually say: template-name: identifier operator-function-id A defect report has been filed about this issue. A conversion-function-id cannot be a template name because they cannot be part of a template-id. In fact, looking at this code: a.operator K<int>() the conversion-function-id is "operator K<int>", and K<int> is a type-id. It is impossible to call a templated conversion-function-id with an explicit argument list, since the only allowed template parameter is the type to which it is converting. If TEMPLATE_KEYWORD_P is true, then we have just seen the `template' keyword, in a construction like: T::template f<3>() In that case `f' is taken to be a template-name, even though there is no way of knowing for sure. Returns the TEMPLATE_DECL for the template, or an OVERLOAD if the name refers to a set of overloaded functions, at least one of which is a template, or an IDENTIFIER_NODE with the name of the template, if TEMPLATE_KEYWORD_P is true. If CHECK_DEPENDENCY_P is FALSE, names are looked up inside uninstantiated templates. / static tree cp_parser_template_name (cp_parser parser, bool template_keyword_p, bool check_dependency_p, bool is_declaration, bool is_identifier) { tree identifier; tree decl; tree fns; / If the next token is `operator', then we have either an operator-function-id or a conversion-function-id. / if (cp_lexer_next_token_is_keyword (parser->lexer, RID_OPERATOR)) { / We don't know whether we're looking at an operator-function-id or a conversion-function-id. / cp_parser_parse_tentatively (parser); / Try an operator-function-id. / identifier = cp_parser_operator_function_id (parser); / If that didn't work, try a conversion-function-id. / if (!cp_parser_parse_definitely (parser)) { cp_parser_error (parser, "expected template-name"); return error_mark_node; } } / Look for the identifier. / else identifier = cp_parser_identifier (parser); / If we didn't find an identifier, we don't have a template-id. / if (identifier == error_mark_node) return error_mark_node; / If the name immediately followed the `template' keyword, then it is a template-name. However, if the next token is not `<', then we do not treat it as a template-name, since it is not being used as part of a template-id. This enables us to handle constructs like: template <typename T> struct S { S(); }; template <typename T> S<T>::S(); correctly. We would treat `S' as a template -- if it were `S<T>' -- but we do not if there is no `<'. / if (processing_template_decl && cp_parser_nth_token_starts_template_argument_list_p (parser, 1)) { / In a declaration, in a dependent context, we pretend that the "template" keyword was present in order to improve error recovery. For example, given: template <typename T> void f(T::X<int>); we want to treat "X<int>" as a template-id. / if (is_declaration && !template_keyword_p && parser->scope && TYPE_P (parser->scope) && check_dependency_p && dependent_type_p (parser->scope) / Do not do this for dtors (or ctors), since they never need the template keyword before their name. / && !constructor_name_p (identifier, parser->scope)) { cp_token_position start = 0; / Explain what went wrong. / error ("non-template %qD used as template", identifier); inform ("use %<%T::template %D%> to indicate that it is a template", parser->scope, identifier); / If parsing tentatively, find the location of the "<" token. / if (cp_parser_simulate_error (parser)) start = cp_lexer_token_position (parser->lexer, true); / Parse the template arguments so that we can issue error messages about them. / cp_lexer_consume_token (parser->lexer); cp_parser_enclosed_template_argument_list (parser); / Skip tokens until we find a good place from which to continue parsing. / cp_parser_skip_to_closing_parenthesis (parser, /recovering=/true, /or_comma=/true, /consume_paren=/false); / If parsing tentatively, permanently remove the template argument list. That will prevent duplicate error messages from being issued about the missing "template" keyword. / if (start) cp_lexer_purge_tokens_after (parser->lexer, start); if (is_identifier) is_identifier = true; return identifier; } /* If the "template" keyword is present, then there is generally no point in doing name-lookup, so we just return IDENTIFIER. But, if the qualifying scope is non-dependent then we can (and must) do name-lookup normally. / if (template_keyword_p && (!parser->scope \|\| (TYPE_P (parser->scope) && dependent_type_p (parser->scope)))) return identifier; } / Look up the name. / decl = cp_parser_lookup_name (parser, identifier, none_type, /is_template=/false, /is_namespace=/false, check_dependency_p, /ambiguous_decls=/NULL); decl = maybe_get_template_decl_from_type_decl (decl); / If DECL is a template, then the name was a template-name. / if (TREE_CODE (decl) == TEMPLATE_DECL) ; else { tree fn = NULL_TREE; / The standard does not explicitly indicate whether a name that names a set of overloaded declarations, some of which are templates, is a template-name. However, such a name should be a template-name; otherwise, there is no way to form a template-id for the overloaded templates. / fns = BASELINK_P (decl) ? BASELINK_FUNCTIONS (decl) : decl; if (TREE_CODE (fns) == OVERLOAD) for (fn = fns; fn; fn = OVL_NEXT (fn)) if (TREE_CODE (OVL_CURRENT (fn)) == TEMPLATE_DECL) break; if (!fn) { / The name does not name a template. / cp_parser_error (parser, "expected template-name"); return error_mark_node; } } / If DECL is dependent, and refers to a function, then just return its name; we will look it up again during template instantiation. / if (DECL_FUNCTION_TEMPLATE_P (decl) \|\| !DECL_P (decl)) { tree scope = CP_DECL_CONTEXT (get_first_fn (decl)); if (TYPE_P (scope) && dependent_type_p (scope)) return identifier; } return decl; } / Parse a template-argument-list. template-argument-list: template-argument template-argument-list , template-argument Returns a TREE_VEC containing the arguments. / static tree cp_parser_template_argument_list (cp_parser parser) { tree fixed_args[10]; unsigned n_args = 0; unsigned alloced = 10; tree arg_ary = fixed_args; tree vec; bool saved_in_template_argument_list_p; bool saved_ice_p; bool saved_non_ice_p; saved_in_template_argument_list_p = parser->in_template_argument_list_p; parser->in_template_argument_list_p = true; / Even if the template-id appears in an integral constant-expression, the contents of the argument list do not. / saved_ice_p = parser->integral_constant_expression_p; parser->integral_constant_expression_p = false; saved_non_ice_p = parser->non_integral_constant_expression_p; parser->non_integral_constant_expression_p = false; / Parse the arguments. / do { tree argument; if (n_args) / Consume the comma. / cp_lexer_consume_token (parser->lexer); / Parse the template-argument. / argument = cp_parser_template_argument (parser); if (n_args == alloced) { alloced = 2; if (arg_ary == fixed_args) { arg_ary = XNEWVEC (tree, alloced); memcpy (arg_ary, fixed_args, sizeof (tree) * n_args); } else arg_ary = XRESIZEVEC (tree, arg_ary, alloced); } arg_ary[n_args++] = argument; } while (cp_lexer_next_token_is (parser->lexer, CPP_COMMA)); vec = make_tree_vec (n_args); while (n_args--) TREE_VEC_ELT (vec, n_args) = arg_ary[n_args]; if (arg_ary != fixed_args) free (arg_ary); parser->non_integral_constant_expression_p = saved_non_ice_p; parser->integral_constant_expression_p = saved_ice_p; parser->in_template_argument_list_p = saved_in_template_argument_list_p; return vec; } /* Parse a template-argument. template-argument: assignment-expression type-id id-expression The representation is that of an assignment-expression, type-id, or id-expression -- except that the qualified id-expression is evaluated, so that the value returned is either a DECL or an OVERLOAD. Although the standard says "assignment-expression", it forbids throw-expressions or assignments in the template argument. Therefore, we use "conditional-expression" instead. / static tree cp_parser_template_argument (cp_parser parser) { tree argument; bool template_p; bool address_p; bool maybe_type_id = false; cp_token token; cp_id_kind idk; / There's really no way to know what we're looking at, so we just try each alternative in order. [temp.arg] In a template-argument, an ambiguity between a type-id and an expression is resolved to a type-id, regardless of the form of the corresponding template-parameter. Therefore, we try a type-id first. / cp_parser_parse_tentatively (parser); argument = cp_parser_type_id (parser); / If there was no error parsing the type-id but the next token is a '>>', we probably found a typo for '> >'. But there are type-id which are also valid expressions. For instance: struct X { int operator >> (int); }; template <int V> struct Foo {}; Foo<X () >> 5> r; Here 'X()' is a valid type-id of a function type, but the user just wanted to write the expression "X() >> 5". Thus, we remember that we found a valid type-id, but we still try to parse the argument as an expression to see what happens. / if (!cp_parser_error_occurred (parser) && cp_lexer_next_token_is (parser->lexer, CPP_RSHIFT)) { maybe_type_id = true; cp_parser_abort_tentative_parse (parser); } else { / If the next token isn't a `,' or a `>', then this argument wasn't really finished. This means that the argument is not a valid type-id. / if (!cp_parser_next_token_ends_template_argument_p (parser)) cp_parser_error (parser, "expected template-argument"); / If that worked, we're done. / if (cp_parser_parse_definitely (parser)) return argument; } / We're still not sure what the argument will be. / cp_parser_parse_tentatively (parser); / Try a template. / argument = cp_parser_id_expression (parser, /template_keyword_p=/false, /check_dependency_p=/true, &template_p, /declarator_p=/false, /optional_p=/false); / If the next token isn't a `,' or a `>', then this argument wasn't really finished. / if (!cp_parser_next_token_ends_template_argument_p (parser)) cp_parser_error (parser, "expected template-argument"); if (!cp_parser_error_occurred (parser)) { / Figure out what is being referred to. If the id-expression was for a class template specialization, then we will have a TYPE_DECL at this point. There is no need to do name lookup at this point in that case. / if (TREE_CODE (argument) != TYPE_DECL) argument = cp_parser_lookup_name (parser, argument, none_type, /is_template=/template_p, /is_namespace=/false, /check_dependency=/true, /ambiguous_decls=/NULL); if (TREE_CODE (argument) != TEMPLATE_DECL && TREE_CODE (argument) != UNBOUND_CLASS_TEMPLATE) cp_parser_error (parser, "expected template-name"); } if (cp_parser_parse_definitely (parser)) return argument; / It must be a non-type argument. There permitted cases are given in [temp.arg.nontype]: -- an integral constant-expression of integral or enumeration type; or -- the name of a non-type template-parameter; or -- the name of an object or function with external linkage... -- the address of an object or function with external linkage... -- a pointer to member... / / Look for a non-type template parameter. / if (cp_lexer_next_token_is (parser->lexer, CPP_NAME)) { cp_parser_parse_tentatively (parser); argument = cp_parser_primary_expression (parser, /adress_p=/false, /cast_p=/false, /template_arg_p=/true, &idk); if (TREE_CODE (argument) != TEMPLATE_PARM_INDEX \|\| !cp_parser_next_token_ends_template_argument_p (parser)) cp_parser_simulate_error (parser); if (cp_parser_parse_definitely (parser)) return argument; } / If the next token is "&", the argument must be the address of an object or function with external linkage. / address_p = cp_lexer_next_token_is (parser->lexer, CPP_AND); if (address_p) cp_lexer_consume_token (parser->lexer); / See if we might have an id-expression. / token = cp_lexer_peek_token (parser->lexer); if (token->type == CPP_NAME \|\| token->keyword == RID_OPERATOR \|\| token->type == CPP_SCOPE \|\| token->type == CPP_TEMPLATE_ID \|\| token->type == CPP_NESTED_NAME_SPECIFIER) { cp_parser_parse_tentatively (parser); argument = cp_parser_primary_expression (parser, address_p, /cast_p=/false, /template_arg_p=/true, &idk); if (cp_parser_error_occurred (parser) \|\| !cp_parser_next_token_ends_template_argument_p (parser)) cp_parser_abort_tentative_parse (parser); else { if (TREE_CODE (argument) == INDIRECT_REF) { gcc_assert (REFERENCE_REF_P (argument)); argument = TREE_OPERAND (argument, 0); } if (TREE_CODE (argument) == VAR_DECL) { / A variable without external linkage might still be a valid constant-expression, so no error is issued here if the external-linkage check fails. / if (!address_p && !DECL_EXTERNAL_LINKAGE_P (argument)) cp_parser_simulate_error (parser); } else if (is_overloaded_fn (argument)) / All overloaded functions are allowed; if the external linkage test does not pass, an error will be issued later. / ; else if (address_p && (TREE_CODE (argument) == OFFSET_REF \|\| TREE_CODE (argument) == SCOPE_REF)) / A pointer-to-member. / ; else if (TREE_CODE (argument) == TEMPLATE_PARM_INDEX) ; else cp_parser_simulate_error (parser); if (cp_parser_parse_definitely (parser)) { if (address_p) argument = build_x_unary_op (ADDR_EXPR, argument); return argument; } } } / If the argument started with "&", there are no other valid alternatives at this point. / if (address_p) { cp_parser_error (parser, "invalid non-type template argument"); return error_mark_node; } / If the argument wasn't successfully parsed as a type-id followed by '>>', the argument can only be a constant expression now. Otherwise, we try parsing the constant-expression tentatively, because the argument could really be a type-id. / if (maybe_type_id) cp_parser_parse_tentatively (parser); argument = cp_parser_constant_expression (parser, /allow_non_constant_p=/false, /non_constant_p=/NULL); argument = fold_non_dependent_expr (argument); if (!maybe_type_id) return argument; if (!cp_parser_next_token_ends_template_argument_p (parser)) cp_parser_error (parser, "expected template-argument"); if (cp_parser_parse_definitely (parser)) return argument; / We did our best to parse the argument as a non type-id, but that was the only alternative that matched (albeit with a '>' after it). We can assume it's just a typo from the user, and a diagnostic will then be issued. / return cp_parser_type_id (parser); } / Parse an explicit-instantiation. explicit-instantiation: template declaration Although the standard says `declaration', what it really means is: explicit-instantiation: template decl-specifier-seq [opt] declarator [opt] ; Things like `template int S<int>::i = 5, int S<double>::j;' are not supposed to be allowed. A defect report has been filed about this issue. GNU Extension: explicit-instantiation: storage-class-specifier template decl-specifier-seq [opt] declarator [opt] ; function-specifier template decl-specifier-seq [opt] declarator [opt] ; / static void cp_parser_explicit_instantiation (cp_parser parser) { int declares_class_or_enum; cp_decl_specifier_seq decl_specifiers; tree extension_specifier = NULL_TREE; /* Look for an (optional) storage-class-specifier or function-specifier. / if (cp_parser_allow_gnu_extensions_p (parser)) { extension_specifier = cp_parser_storage_class_specifier_opt (parser); if (!extension_specifier) extension_specifier = cp_parser_function_specifier_opt (parser, /decl_specs=/NULL); } / Look for the `template' keyword. / cp_parser_require_keyword (parser, RID_TEMPLATE, "`template'"); / Let the front end know that we are processing an explicit instantiation. / begin_explicit_instantiation (); / [temp.explicit] says that we are supposed to ignore access control while processing explicit instantiation directives. / push_deferring_access_checks (dk_no_check); / Parse a decl-specifier-seq. / cp_parser_decl_specifier_seq (parser, CP_PARSER_FLAGS_OPTIONAL, &decl_specifiers, &declares_class_or_enum); / If there was exactly one decl-specifier, and it declared a class, and there's no declarator, then we have an explicit type instantiation. / if (declares_class_or_enum && cp_parser_declares_only_class_p (parser)) { tree type; type = check_tag_decl (&decl_specifiers); / Turn access control back on for names used during template instantiation. / pop_deferring_access_checks (); if (type) do_type_instantiation (type, extension_specifier, /complain=/tf_error); } else { cp_declarator declarator; tree decl; /* Parse the declarator. / declarator = cp_parser_declarator (parser, CP_PARSER_DECLARATOR_NAMED, /ctor_dtor_or_conv_p=/NULL, /parenthesized_p=/NULL, /member_p=/false); if (declares_class_or_enum & 2) cp_parser_check_for_definition_in_return_type (declarator, decl_specifiers.type); if (declarator != cp_error_declarator) { decl = grokdeclarator (declarator, &decl_specifiers, NORMAL, 0, &decl_specifiers.attributes); / Turn access control back on for names used during template instantiation. / pop_deferring_access_checks (); / Do the explicit instantiation. / do_decl_instantiation (decl, extension_specifier); } else { pop_deferring_access_checks (); / Skip the body of the explicit instantiation. / cp_parser_skip_to_end_of_statement (parser); } } / We're done with the instantiation. / end_explicit_instantiation (); cp_parser_consume_semicolon_at_end_of_statement (parser); } / Parse an explicit-specialization. explicit-specialization: template < > declaration Although the standard says `declaration', what it really means is: explicit-specialization: template <> decl-specifier [opt] init-declarator [opt] ; template <> function-definition template <> explicit-specialization template <> template-declaration / static void cp_parser_explicit_specialization (cp_parser parser) { bool need_lang_pop; /* Look for the `template' keyword. / cp_parser_require_keyword (parser, RID_TEMPLATE, "`template'"); / Look for the `<'. / cp_parser_require (parser, CPP_LESS, "`<'"); / Look for the `>'. / cp_parser_require (parser, CPP_GREATER, "`>'"); / We have processed another parameter list. / ++parser->num_template_parameter_lists; / [temp] A template ... explicit specialization ... shall not have C linkage. / if (current_lang_name == lang_name_c) { error ("template specialization with C linkage"); / Give it C++ linkage to avoid confusing other parts of the front end. / push_lang_context (lang_name_cplusplus); need_lang_pop = true; } else need_lang_pop = false; / Let the front end know that we are beginning a specialization. / if (!begin_specialization ()) { end_specialization (); cp_parser_skip_to_end_of_block_or_statement (parser); return; } / If the next keyword is `template', we need to figure out whether or not we're looking a template-declaration. / if (cp_lexer_next_token_is_keyword (parser->lexer, RID_TEMPLATE)) { if (cp_lexer_peek_nth_token (parser->lexer, 2)->type == CPP_LESS && cp_lexer_peek_nth_token (parser->lexer, 3)->type != CPP_GREATER) cp_parser_template_declaration_after_export (parser, /member_p=/false); else cp_parser_explicit_specialization (parser); } else / Parse the dependent declaration. / cp_parser_single_declaration (parser, /checks=/NULL, /member_p=/false, /friend_p=/NULL); / We're done with the specialization. / end_specialization (); / For the erroneous case of a template with C linkage, we pushed an implicit C++ linkage scope; exit that scope now. / if (need_lang_pop) pop_lang_context (); / We're done with this parameter list. / --parser->num_template_parameter_lists; } / Parse a type-specifier. type-specifier: simple-type-specifier class-specifier enum-specifier elaborated-type-specifier cv-qualifier GNU Extension: type-specifier: __complex__ Returns a representation of the type-specifier. For a class-specifier, enum-specifier, or elaborated-type-specifier, a TREE_TYPE is returned; otherwise, a TYPE_DECL is returned. The parser flags FLAGS is used to control type-specifier parsing. If IS_DECLARATION is TRUE, then this type-specifier is appearing in a decl-specifier-seq. If DECLARES_CLASS_OR_ENUM is non-NULL, and the type-specifier is a class-specifier, enum-specifier, or elaborated-type-specifier, then DECLARES_CLASS_OR_ENUM is set to a nonzero value. The value is 1 if a type is declared; 2 if it is defined. Otherwise, it is set to zero. If IS_CV_QUALIFIER is non-NULL, and the type-specifier is a cv-qualifier, then IS_CV_QUALIFIER is set to TRUE. Otherwise, it is set to FALSE. / static tree cp_parser_type_specifier (cp_parser* parser, cp_parser_flags flags, cp_decl_specifier_seq decl_specs, bool is_declaration, int declares_class_or_enum, bool* is_cv_qualifier) { tree type_spec = NULL_TREE; cp_token token; enum rid keyword; cp_decl_spec ds = ds_last; / Assume this type-specifier does not declare a new type. / if (declares_class_or_enum) declares_class_or_enum = 0; /* And that it does not specify a cv-qualifier. / if (is_cv_qualifier) is_cv_qualifier = false; /* Peek at the next token. / token = cp_lexer_peek_token (parser->lexer); / If we're looking at a keyword, we can use that to guide the production we choose. / keyword = token->keyword; switch (keyword) { case RID_ENUM: / Look for the enum-specifier. / type_spec = cp_parser_enum_specifier (parser); / If that worked, we're done. / if (type_spec) { if (declares_class_or_enum) declares_class_or_enum = 2; if (decl_specs) cp_parser_set_decl_spec_type (decl_specs, type_spec, /user_defined_p=/true); return type_spec; } else goto elaborated_type_specifier; /* Any of these indicate either a class-specifier, or an elaborated-type-specifier. / case RID_CLASS: case RID_STRUCT: case RID_UNION: / Parse tentatively so that we can back up if we don't find a class-specifier. / cp_parser_parse_tentatively (parser); / Look for the class-specifier. / type_spec = cp_parser_class_specifier (parser); / If that worked, we're done. / if (cp_parser_parse_definitely (parser)) { if (declares_class_or_enum) declares_class_or_enum = 2; if (decl_specs) cp_parser_set_decl_spec_type (decl_specs, type_spec, /user_defined_p=/true); return type_spec; } /* Fall through. / elaborated_type_specifier: / We're declaring (not defining) a class or enum. / if (declares_class_or_enum) declares_class_or_enum = 1; /* Fall through. / case RID_TYPENAME: / Look for an elaborated-type-specifier. / type_spec = (cp_parser_elaborated_type_specifier (parser, decl_specs && decl_specs->specs[(int) ds_friend], is_declaration)); if (decl_specs) cp_parser_set_decl_spec_type (decl_specs, type_spec, /user_defined_p=/true); return type_spec; case RID_CONST: ds = ds_const; if (is_cv_qualifier) is_cv_qualifier = true; break; case RID_VOLATILE: ds = ds_volatile; if (is_cv_qualifier) is_cv_qualifier = true; break; case RID_RESTRICT: ds = ds_restrict; if (is_cv_qualifier) is_cv_qualifier = true; break; case RID_COMPLEX: /* The `__complex__' keyword is a GNU extension. / ds = ds_complex; break; default: break; } / Handle simple keywords. / if (ds != ds_last) { if (decl_specs) { ++decl_specs->specs[(int)ds]; decl_specs->any_specifiers_p = true; } return cp_lexer_consume_token (parser->lexer)->u.value; } / If we do not already have a type-specifier, assume we are looking at a simple-type-specifier. / type_spec = cp_parser_simple_type_specifier (parser, decl_specs, flags); / If we didn't find a type-specifier, and a type-specifier was not optional in this context, issue an error message. / if (!type_spec && !(flags & CP_PARSER_FLAGS_OPTIONAL)) { cp_parser_error (parser, "expected type specifier"); return error_mark_node; } return type_spec; } / Parse a simple-type-specifier. simple-type-specifier: :: [opt] nested-name-specifier [opt] type-name :: [opt] nested-name-specifier template template-id char wchar_t bool short int long signed unsigned float double void GNU Extension: simple-type-specifier: __typeof__ unary-expression __typeof__ ( type-id ) Returns the indicated TYPE_DECL. If DECL_SPECS is not NULL, it is appropriately updated. / static tree cp_parser_simple_type_specifier (cp_parser parser, cp_decl_specifier_seq decl_specs, cp_parser_flags flags) { tree type = NULL_TREE; cp_token token; /* Peek at the next token. / token = cp_lexer_peek_token (parser->lexer); / If we're looking at a keyword, things are easy. / switch (token->keyword) { case RID_CHAR: if (decl_specs) decl_specs->explicit_char_p = true; type = char_type_node; break; case RID_WCHAR: type = wchar_type_node; break; case RID_BOOL: type = boolean_type_node; break; case RID_SHORT: if (decl_specs) ++decl_specs->specs[(int) ds_short]; type = short_integer_type_node; break; case RID_INT: if (decl_specs) decl_specs->explicit_int_p = true; type = integer_type_node; break; case RID_LONG: if (decl_specs) ++decl_specs->specs[(int) ds_long]; type = long_integer_type_node; break; case RID_SIGNED: if (decl_specs) ++decl_specs->specs[(int) ds_signed]; type = integer_type_node; break; case RID_UNSIGNED: if (decl_specs) ++decl_specs->specs[(int) ds_unsigned]; type = unsigned_type_node; break; case RID_FLOAT: type = float_type_node; break; case RID_DOUBLE: type = double_type_node; break; case RID_VOID: type = void_type_node; break; case RID_TYPEOF: / Consume the `typeof' token. / cp_lexer_consume_token (parser->lexer); / Parse the operand to `typeof'. / type = cp_parser_sizeof_operand (parser, RID_TYPEOF); / If it is not already a TYPE, take its type. / if (!TYPE_P (type)) type = finish_typeof (type); if (decl_specs) cp_parser_set_decl_spec_type (decl_specs, type, /user_defined_p=/true); return type; default: break; } / If the type-specifier was for a built-in type, we're done. / if (type) { tree id; / Record the type. / if (decl_specs && (token->keyword != RID_SIGNED && token->keyword != RID_UNSIGNED && token->keyword != RID_SHORT && token->keyword != RID_LONG)) cp_parser_set_decl_spec_type (decl_specs, type, /user_defined=/false); if (decl_specs) decl_specs->any_specifiers_p = true; / Consume the token. / id = cp_lexer_consume_token (parser->lexer)->u.value; / There is no valid C++ program where a non-template type is followed by a "<". That usually indicates that the user thought that the type was a template. / cp_parser_check_for_invalid_template_id (parser, type); return TYPE_NAME (type); } / The type-specifier must be a user-defined type. / if (!(flags & CP_PARSER_FLAGS_NO_USER_DEFINED_TYPES)) { bool qualified_p; bool global_p; / Don't gobble tokens or issue error messages if this is an optional type-specifier. / if (flags & CP_PARSER_FLAGS_OPTIONAL) cp_parser_parse_tentatively (parser); / Look for the optional `::' operator. / global_p = (cp_parser_global_scope_opt (parser, /current_scope_valid_p=/false) != NULL_TREE); / Look for the nested-name specifier. / qualified_p = (cp_parser_nested_name_specifier_opt (parser, /typename_keyword_p=/false, /check_dependency_p=/true, /type_p=/false, /is_declaration=/false) != NULL_TREE); / If we have seen a nested-name-specifier, and the next token is `template', then we are using the template-id production. / if (parser->scope && cp_parser_optional_template_keyword (parser)) { / Look for the template-id. / type = cp_parser_template_id (parser, /template_keyword_p=/true, /check_dependency_p=/true, /is_declaration=/false); / If the template-id did not name a type, we are out of luck. / if (TREE_CODE (type) != TYPE_DECL) { cp_parser_error (parser, "expected template-id for type"); type = NULL_TREE; } } / Otherwise, look for a type-name. / else type = cp_parser_type_name (parser); / Keep track of all name-lookups performed in class scopes. / if (type && !global_p && !qualified_p && TREE_CODE (type) == TYPE_DECL && TREE_CODE (DECL_NAME (type)) == IDENTIFIER_NODE) maybe_note_name_used_in_class (DECL_NAME (type), type); / If it didn't work out, we don't have a TYPE. / if ((flags & CP_PARSER_FLAGS_OPTIONAL) && !cp_parser_parse_definitely (parser)) type = NULL_TREE; if (type && decl_specs) cp_parser_set_decl_spec_type (decl_specs, type, /user_defined=/true); } / If we didn't get a type-name, issue an error message. / if (!type && !(flags & CP_PARSER_FLAGS_OPTIONAL)) { cp_parser_error (parser, "expected type-name"); return error_mark_node; } / There is no valid C++ program where a non-template type is followed by a "<". That usually indicates that the user thought that the type was a template. / if (type && type != error_mark_node) { / As a last-ditch effort, see if TYPE is an Objective-C type. If it is, then the '<'...'>' enclose protocol names rather than template arguments, and so everything is fine. / if (c_dialect_objc () && (objc_is_id (type) \|\| objc_is_class_name (type))) { tree protos = cp_parser_objc_protocol_refs_opt (parser); tree qual_type = objc_get_protocol_qualified_type (type, protos); / Clobber the "unqualified" type previously entered into DECL_SPECS with the new, improved protocol-qualified version. / if (decl_specs) decl_specs->type = qual_type; return qual_type; } cp_parser_check_for_invalid_template_id (parser, TREE_TYPE (type)); } return type; } / Parse a type-name. type-name: class-name enum-name typedef-name enum-name: identifier typedef-name: identifier Returns a TYPE_DECL for the type. / static tree cp_parser_type_name (cp_parser parser) { tree type_decl; tree identifier; /* We can't know yet whether it is a class-name or not. / cp_parser_parse_tentatively (parser); / Try a class-name. / type_decl = cp_parser_class_name (parser, /typename_keyword_p=/false, /template_keyword_p=/false, none_type, /check_dependency_p=/true, /class_head_p=/false, /is_declaration=/false); / If it's not a class-name, keep looking. / if (!cp_parser_parse_definitely (parser)) { / It must be a typedef-name or an enum-name. / identifier = cp_parser_identifier (parser); if (identifier == error_mark_node) return error_mark_node; / Look up the type-name. / type_decl = cp_parser_lookup_name_simple (parser, identifier); if (TREE_CODE (type_decl) != TYPE_DECL && (objc_is_id (identifier) \|\| objc_is_class_name (identifier))) { / See if this is an Objective-C type. / tree protos = cp_parser_objc_protocol_refs_opt (parser); tree type = objc_get_protocol_qualified_type (identifier, protos); if (type) type_decl = TYPE_NAME (type); } / Issue an error if we did not find a type-name. / if (TREE_CODE (type_decl) != TYPE_DECL) { if (!cp_parser_simulate_error (parser)) cp_parser_name_lookup_error (parser, identifier, type_decl, "is not a type"); type_decl = error_mark_node; } / Remember that the name was used in the definition of the current class so that we can check later to see if the meaning would have been different after the class was entirely defined. / else if (type_decl != error_mark_node && !parser->scope) maybe_note_name_used_in_class (identifier, type_decl); } return type_decl; } / Parse an elaborated-type-specifier. Note that the grammar given here incorporates the resolution to DR68. elaborated-type-specifier: class-key :: [opt] nested-name-specifier [opt] identifier class-key :: [opt] nested-name-specifier [opt] template [opt] template-id enum :: [opt] nested-name-specifier [opt] identifier typename :: [opt] nested-name-specifier identifier typename :: [opt] nested-name-specifier template [opt] template-id GNU extension: elaborated-type-specifier: class-key attributes :: [opt] nested-name-specifier [opt] identifier class-key attributes :: [opt] nested-name-specifier [opt] template [opt] template-id enum attributes :: [opt] nested-name-specifier [opt] identifier If IS_FRIEND is TRUE, then this elaborated-type-specifier is being declared `friend'. If IS_DECLARATION is TRUE, then this elaborated-type-specifier appears in a decl-specifiers-seq, i.e., something is being declared. Returns the TYPE specified. / static tree cp_parser_elaborated_type_specifier (cp_parser parser, bool is_friend, bool is_declaration) { enum tag_types tag_type; tree identifier; tree type = NULL_TREE; tree attributes = NULL_TREE; /* See if we're looking at the `enum' keyword. / if (cp_lexer_next_token_is_keyword (parser->lexer, RID_ENUM)) { / Consume the `enum' token. / cp_lexer_consume_token (parser->lexer); / Remember that it's an enumeration type. / tag_type = enum_type; / Parse the attributes. / attributes = cp_parser_attributes_opt (parser); } / Or, it might be `typename'. / else if (cp_lexer_next_token_is_keyword (parser->lexer, RID_TYPENAME)) { / Consume the `typename' token. / cp_lexer_consume_token (parser->lexer); / Remember that it's a `typename' type. / tag_type = typename_type; / The `typename' keyword is only allowed in templates. / if (!processing_template_decl) pedwarn ("using %<typename%> outside of template"); } / Otherwise it must be a class-key. / else { tag_type = cp_parser_class_key (parser); if (tag_type == none_type) return error_mark_node; / Parse the attributes. / attributes = cp_parser_attributes_opt (parser); } / Look for the `::' operator. / cp_parser_global_scope_opt (parser, /current_scope_valid_p=/false); / Look for the nested-name-specifier. / if (tag_type == typename_type) { if (!cp_parser_nested_name_specifier (parser, /typename_keyword_p=/true, /check_dependency_p=/true, /type_p=/true, is_declaration)) return error_mark_node; } else / Even though `typename' is not present, the proposed resolution to Core Issue 180 says that in `class A<T>::B', `B' should be considered a type-name, even if `A<T>' is dependent. / cp_parser_nested_name_specifier_opt (parser, /typename_keyword_p=/true, /check_dependency_p=/true, /type_p=/true, is_declaration); / For everything but enumeration types, consider a template-id. For an enumeration type, consider only a plain identifier. / if (tag_type != enum_type) { bool template_p = false; tree decl; / Allow the `template' keyword. / template_p = cp_parser_optional_template_keyword (parser); / If we didn't see `template', we don't know if there's a template-id or not. / if (!template_p) cp_parser_parse_tentatively (parser); / Parse the template-id. / decl = cp_parser_template_id (parser, template_p, /check_dependency_p=/true, is_declaration); / If we didn't find a template-id, look for an ordinary identifier. / if (!template_p && !cp_parser_parse_definitely (parser)) ; / If DECL is a TEMPLATE_ID_EXPR, and the `typename' keyword is in effect, then we must assume that, upon instantiation, the template will correspond to a class. / else if (TREE_CODE (decl) == TEMPLATE_ID_EXPR && tag_type == typename_type) type = make_typename_type (parser->scope, decl, typename_type, /complain=/tf_error); else type = TREE_TYPE (decl); } if (!type) { identifier = cp_parser_identifier (parser); if (identifier == error_mark_node) { parser->scope = NULL_TREE; return error_mark_node; } / For a `typename', we needn't call xref_tag. / if (tag_type == typename_type && TREE_CODE (parser->scope) != NAMESPACE_DECL) return cp_parser_make_typename_type (parser, parser->scope, identifier); / Look up a qualified name in the usual way. / if (parser->scope) { tree decl; decl = cp_parser_lookup_name (parser, identifier, tag_type, /is_template=/false, /is_namespace=/false, /check_dependency=/true, /ambiguous_decls=/NULL); / If we are parsing friend declaration, DECL may be a TEMPLATE_DECL tree node here. However, we need to check whether this TEMPLATE_DECL results in valid code. Consider the following example: namespace N { template <class T> class C {}; } class X { template <class T> friend class N::C; // #1, valid code }; template <class T> class Y { friend class N::C; // #2, invalid code }; For both case #1 and #2, we arrive at a TEMPLATE_DECL after name lookup of `N::C'. We see that friend declaration must be template for the code to be valid. Note that processing_template_decl does not work here since it is always 1 for the above two cases. / decl = (cp_parser_maybe_treat_template_as_class (decl, /tag_name_p=/is_friend && parser->num_template_parameter_lists)); if (TREE_CODE (decl) != TYPE_DECL) { cp_parser_diagnose_invalid_type_name (parser, parser->scope, identifier); return error_mark_node; } if (TREE_CODE (TREE_TYPE (decl)) != TYPENAME_TYPE) { bool allow_template = (parser->num_template_parameter_lists \|\| DECL_SELF_REFERENCE_P (decl)); type = check_elaborated_type_specifier (tag_type, decl, allow_template); if (type == error_mark_node) return error_mark_node; } type = TREE_TYPE (decl); } else { / An elaborated-type-specifier sometimes introduces a new type and sometimes names an existing type. Normally, the rule is that it introduces a new type only if there is not an existing type of the same name already in scope. For example, given: struct S {}; void f() { struct S s; } the `struct S' in the body of `f' is the same `struct S' as in the global scope; the existing definition is used. However, if there were no global declaration, this would introduce a new local class named `S'. An exception to this rule applies to the following code: namespace N { struct S; } Here, the elaborated-type-specifier names a new type unconditionally; even if there is already an `S' in the containing scope this declaration names a new type. This exception only applies if the elaborated-type-specifier forms the complete declaration: [class.name] A declaration consisting solely of `class-key identifier ;' is either a redeclaration of the name in the current scope or a forward declaration of the identifier as a class name. It introduces the name into the current scope. We are in this situation precisely when the next token is a `;'. An exception to the exception is that a `friend' declaration does not name a new type; i.e., given: struct S { friend struct T; }; `T' is not a new type in the scope of `S'. Also, `new struct S' or `sizeof (struct S)' never results in the definition of a new type; a new type can only be declared in a declaration context. / tag_scope ts; bool template_p; if (is_friend) / Friends have special name lookup rules. / ts = ts_within_enclosing_non_class; else if (is_declaration && cp_lexer_next_token_is (parser->lexer, CPP_SEMICOLON)) / This is a `class-key identifier ;' / ts = ts_current; else ts = ts_global; template_p = (parser->num_template_parameter_lists && (cp_parser_next_token_starts_class_definition_p (parser) \|\| cp_lexer_next_token_is (parser->lexer, CPP_SEMICOLON))); / An unqualified name was used to reference this type, so there were no qualifying templates. / if (!cp_parser_check_template_parameters (parser, /num_templates=/0)) return error_mark_node; type = xref_tag (tag_type, identifier, ts, template_p); } } if (type == error_mark_node) return error_mark_node; / Allow attributes on forward declarations of classes. / if (attributes) { if (TREE_CODE (type) == TYPENAME_TYPE) warning (OPT_Wattributes, "attributes ignored on uninstantiated type"); else if (tag_type != enum_type && CLASSTYPE_TEMPLATE_INSTANTIATION (type) && ! processing_explicit_instantiation) warning (OPT_Wattributes, "attributes ignored on template instantiation"); else if (is_declaration && cp_parser_declares_only_class_p (parser)) cplus_decl_attributes (&type, attributes, (int) ATTR_FLAG_TYPE_IN_PLACE); else warning (OPT_Wattributes, "attributes ignored on elaborated-type-specifier that is not a forward declaration"); } if (tag_type != enum_type) cp_parser_check_class_key (tag_type, type); / A "<" cannot follow an elaborated type specifier. If that happens, the user was probably trying to form a template-id. / cp_parser_check_for_invalid_template_id (parser, type); return type; } / Parse an enum-specifier. enum-specifier: enum identifier [opt] { enumerator-list [opt] } GNU Extensions: enum attributes[opt] identifier [opt] { enumerator-list [opt] } attributes[opt] Returns an ENUM_TYPE representing the enumeration, or NULL_TREE if the token stream isn't an enum-specifier after all. / static tree cp_parser_enum_specifier (cp_parser parser) { tree identifier; tree type; tree attributes; /* Parse tentatively so that we can back up if we don't find a enum-specifier. / cp_parser_parse_tentatively (parser); / Caller guarantees that the current token is 'enum', an identifier possibly follows, and the token after that is an opening brace. If we don't have an identifier, fabricate an anonymous name for the enumeration being defined. / cp_lexer_consume_token (parser->lexer); attributes = cp_parser_attributes_opt (parser); if (cp_lexer_next_token_is (parser->lexer, CPP_NAME)) identifier = cp_parser_identifier (parser); else identifier = make_anon_name (); / Look for the `{' but don't consume it yet. / if (!cp_lexer_next_token_is (parser->lexer, CPP_OPEN_BRACE)) cp_parser_simulate_error (parser); if (!cp_parser_parse_definitely (parser)) return NULL_TREE; / Issue an error message if type-definitions are forbidden here. / if (!cp_parser_check_type_definition (parser)) type = error_mark_node; else / Create the new type. We do this before consuming the opening brace so the enum will be recorded as being on the line of its tag (or the 'enum' keyword, if there is no tag). / type = start_enum (identifier); / Consume the opening brace. / cp_lexer_consume_token (parser->lexer); if (type == error_mark_node) { cp_parser_skip_to_end_of_block_or_statement (parser); return error_mark_node; } / If the next token is not '}', then there are some enumerators. / if (cp_lexer_next_token_is_not (parser->lexer, CPP_CLOSE_BRACE)) cp_parser_enumerator_list (parser, type); / Consume the final '}'. / cp_parser_require (parser, CPP_CLOSE_BRACE, "`}'"); / Look for trailing attributes to apply to this enumeration, and apply them if appropriate. / if (cp_parser_allow_gnu_extensions_p (parser)) { tree trailing_attr = cp_parser_attributes_opt (parser); cplus_decl_attributes (&type, trailing_attr, (int) ATTR_FLAG_TYPE_IN_PLACE); } / Finish up the enumeration. / finish_enum (type); return type; } / Parse an enumerator-list. The enumerators all have the indicated TYPE. enumerator-list: enumerator-definition enumerator-list , enumerator-definition / static void cp_parser_enumerator_list (cp_parser parser, tree type) { while (true) { /* Parse an enumerator-definition. / cp_parser_enumerator_definition (parser, type); / If the next token is not a ',', we've reached the end of the list. / if (cp_lexer_next_token_is_not (parser->lexer, CPP_COMMA)) break; / Otherwise, consume the `,' and keep going. / cp_lexer_consume_token (parser->lexer); / If the next token is a `}', there is a trailing comma. / if (cp_lexer_next_token_is (parser->lexer, CPP_CLOSE_BRACE)) { if (pedantic && !in_system_header) pedwarn ("comma at end of enumerator list"); break; } } } / Parse an enumerator-definition. The enumerator has the indicated TYPE. enumerator-definition: enumerator enumerator = constant-expression enumerator: identifier / static void cp_parser_enumerator_definition (cp_parser parser, tree type) { tree identifier; tree value; /* Look for the identifier. / identifier = cp_parser_identifier (parser); if (identifier == error_mark_node) return; / If the next token is an '=', then there is an explicit value. / if (cp_lexer_next_token_is (parser->lexer, CPP_EQ)) { / Consume the `=' token. / cp_lexer_consume_token (parser->lexer); / Parse the value. / value = cp_parser_constant_expression (parser, /allow_non_constant_p=/false, NULL); } else value = NULL_TREE; / Create the enumerator. / build_enumerator (identifier, value, type); } / Parse a namespace-name. namespace-name: original-namespace-name namespace-alias Returns the NAMESPACE_DECL for the namespace. / static tree cp_parser_namespace_name (cp_parser parser) { tree identifier; tree namespace_decl; /* Get the name of the namespace. / identifier = cp_parser_identifier (parser); if (identifier == error_mark_node) return error_mark_node; / Look up the identifier in the currently active scope. Look only for namespaces, due to: [basic.lookup.udir] When looking up a namespace-name in a using-directive or alias definition, only namespace names are considered. And: [basic.lookup.qual] During the lookup of a name preceding the :: scope resolution operator, object, function, and enumerator names are ignored. (Note that cp_parser_class_or_namespace_name only calls this function if the token after the name is the scope resolution operator.) / namespace_decl = cp_parser_lookup_name (parser, identifier, none_type, /is_template=/false, /is_namespace=/true, /check_dependency=/true, /ambiguous_decls=/NULL); / If it's not a namespace, issue an error. / if (namespace_decl == error_mark_node \|\| TREE_CODE (namespace_decl) != NAMESPACE_DECL) { if (!cp_parser_uncommitted_to_tentative_parse_p (parser)) error ("%qD is not a namespace-name", identifier); cp_parser_error (parser, "expected namespace-name"); namespace_decl = error_mark_node; } return namespace_decl; } / Parse a namespace-definition. namespace-definition: named-namespace-definition unnamed-namespace-definition named-namespace-definition: original-namespace-definition extension-namespace-definition original-namespace-definition: namespace identifier { namespace-body } extension-namespace-definition: namespace original-namespace-name { namespace-body } unnamed-namespace-definition: namespace { namespace-body } / static void cp_parser_namespace_definition (cp_parser parser) { tree identifier, attribs; /* Look for the `namespace' keyword. / cp_parser_require_keyword (parser, RID_NAMESPACE, "`namespace'"); / Get the name of the namespace. We do not attempt to distinguish between an original-namespace-definition and an extension-namespace-definition at this point. The semantic analysis routines are responsible for that. / if (cp_lexer_next_token_is (parser->lexer, CPP_NAME)) identifier = cp_parser_identifier (parser); else identifier = NULL_TREE; / Parse any specified attributes. / attribs = cp_parser_attributes_opt (parser); / Look for the `{' to start the namespace. / cp_parser_require (parser, CPP_OPEN_BRACE, "`{'"); / Start the namespace. / push_namespace_with_attribs (identifier, attribs); / Parse the body of the namespace. / cp_parser_namespace_body (parser); / Finish the namespace. / pop_namespace (); / Look for the final `}'. / cp_parser_require (parser, CPP_CLOSE_BRACE, "`}'"); } / Parse a namespace-body. namespace-body: declaration-seq [opt] / static void cp_parser_namespace_body (cp_parser parser) { cp_parser_declaration_seq_opt (parser); } /* Parse a namespace-alias-definition. namespace-alias-definition: namespace identifier = qualified-namespace-specifier ; / static void cp_parser_namespace_alias_definition (cp_parser parser) { tree identifier; tree namespace_specifier; /* Look for the `namespace' keyword. / cp_parser_require_keyword (parser, RID_NAMESPACE, "`namespace'"); / Look for the identifier. / identifier = cp_parser_identifier (parser); if (identifier == error_mark_node) return; / Look for the `=' token. / cp_parser_require (parser, CPP_EQ, "`='"); / Look for the qualified-namespace-specifier. / namespace_specifier = cp_parser_qualified_namespace_specifier (parser); / Look for the `;' token. / cp_parser_require (parser, CPP_SEMICOLON, "`;'"); / Register the alias in the symbol table. / do_namespace_alias (identifier, namespace_specifier); } / Parse a qualified-namespace-specifier. qualified-namespace-specifier: :: [opt] nested-name-specifier [opt] namespace-name Returns a NAMESPACE_DECL corresponding to the specified namespace. / static tree cp_parser_qualified_namespace_specifier (cp_parser parser) { /* Look for the optional `::'. / cp_parser_global_scope_opt (parser, /current_scope_valid_p=/false); / Look for the optional nested-name-specifier. / cp_parser_nested_name_specifier_opt (parser, /typename_keyword_p=/false, /check_dependency_p=/true, /type_p=/false, /is_declaration=/true); return cp_parser_namespace_name (parser); } / Parse a using-declaration, or, if ACCESS_DECLARATION_P is true, an access declaration. using-declaration: using typename [opt] :: [opt] nested-name-specifier unqualified-id ; using :: unqualified-id ; access-declaration: qualified-id ; / static bool cp_parser_using_declaration (cp_parser parser, bool access_declaration_p) { cp_token token; bool typename_p = false; bool global_scope_p; tree decl; tree identifier; tree qscope; if (access_declaration_p) cp_parser_parse_tentatively (parser); else { / Look for the `using' keyword. / cp_parser_require_keyword (parser, RID_USING, "`using'"); / Peek at the next token. / token = cp_lexer_peek_token (parser->lexer); / See if it's `typename'. / if (token->keyword == RID_TYPENAME) { / Remember that we've seen it. / typename_p = true; / Consume the `typename' token. / cp_lexer_consume_token (parser->lexer); } } / Look for the optional global scope qualification. / global_scope_p = (cp_parser_global_scope_opt (parser, /current_scope_valid_p=/false) != NULL_TREE); / If we saw `typename', or didn't see `::', then there must be a nested-name-specifier present. / if (typename_p \|\| !global_scope_p) qscope = cp_parser_nested_name_specifier (parser, typename_p, /check_dependency_p=/true, /type_p=/false, /is_declaration=/true); / Otherwise, we could be in either of the two productions. In that case, treat the nested-name-specifier as optional. / else qscope = cp_parser_nested_name_specifier_opt (parser, /typename_keyword_p=/false, /check_dependency_p=/true, /type_p=/false, /is_declaration=/true); if (!qscope) qscope = global_namespace; if (access_declaration_p && cp_parser_error_occurred (parser)) / Something has already gone wrong; there's no need to parse further. Since an error has occurred, the return value of cp_parser_parse_definitely will be false, as required. / return cp_parser_parse_definitely (parser); / Parse the unqualified-id. / identifier = cp_parser_unqualified_id (parser, /template_keyword_p=/false, /check_dependency_p=/true, /declarator_p=/true, /optional_p=/false); if (access_declaration_p) { if (cp_lexer_next_token_is_not (parser->lexer, CPP_SEMICOLON)) cp_parser_simulate_error (parser); if (!cp_parser_parse_definitely (parser)) return false; } / The function we call to handle a using-declaration is different depending on what scope we are in. / if (qscope == error_mark_node \|\| identifier == error_mark_node) ; else if (TREE_CODE (identifier) != IDENTIFIER_NODE && TREE_CODE (identifier) != BIT_NOT_EXPR) / [namespace.udecl] A using declaration shall not name a template-id. / error ("a template-id may not appear in a using-declaration"); else { if (at_class_scope_p ()) { / Create the USING_DECL. / decl = do_class_using_decl (parser->scope, identifier); / Add it to the list of members in this class. / finish_member_declaration (decl); } else { decl = cp_parser_lookup_name_simple (parser, identifier); if (decl == error_mark_node) cp_parser_name_lookup_error (parser, identifier, decl, NULL); else if (!at_namespace_scope_p ()) do_local_using_decl (decl, qscope, identifier); else do_toplevel_using_decl (decl, qscope, identifier); } } / Look for the final `;'. / cp_parser_require (parser, CPP_SEMICOLON, "`;'"); return true; } / Parse a using-directive. using-directive: using namespace :: [opt] nested-name-specifier [opt] namespace-name ; / static void cp_parser_using_directive (cp_parser parser) { tree namespace_decl; tree attribs; /* Look for the `using' keyword. / cp_parser_require_keyword (parser, RID_USING, "`using'"); / And the `namespace' keyword. / cp_parser_require_keyword (parser, RID_NAMESPACE, "`namespace'"); / Look for the optional `::' operator. / cp_parser_global_scope_opt (parser, /current_scope_valid_p=/false); / And the optional nested-name-specifier. / cp_parser_nested_name_specifier_opt (parser, /typename_keyword_p=/false, /check_dependency_p=/true, /type_p=/false, /is_declaration=/true); / Get the namespace being used. / namespace_decl = cp_parser_namespace_name (parser); / And any specified attributes. / attribs = cp_parser_attributes_opt (parser); / Update the symbol table. / parse_using_directive (namespace_decl, attribs); / Look for the final `;'. / cp_parser_require (parser, CPP_SEMICOLON, "`;'"); } / Parse an asm-definition. asm-definition: asm ( string-literal ) ; GNU Extension: asm-definition: asm volatile [opt] ( string-literal ) ; asm volatile [opt] ( string-literal : asm-operand-list [opt] ) ; asm volatile [opt] ( string-literal : asm-operand-list [opt] : asm-operand-list [opt] ) ; asm volatile [opt] ( string-literal : asm-operand-list [opt] : asm-operand-list [opt] : asm-operand-list [opt] ) ; / static void cp_parser_asm_definition (cp_parser parser) { tree string; tree outputs = NULL_TREE; tree inputs = NULL_TREE; tree clobbers = NULL_TREE; tree asm_stmt; bool volatile_p = false; bool extended_p = false; /* Look for the `asm' keyword. / cp_parser_require_keyword (parser, RID_ASM, "`asm'"); / See if the next token is `volatile'. / if (cp_parser_allow_gnu_extensions_p (parser) && cp_lexer_next_token_is_keyword (parser->lexer, RID_VOLATILE)) { / Remember that we saw the `volatile' keyword. / volatile_p = true; / Consume the token. / cp_lexer_consume_token (parser->lexer); } / Look for the opening `('. / if (!cp_parser_require (parser, CPP_OPEN_PAREN, "`('")) return; / Look for the string. / string = cp_parser_string_literal (parser, false, false); if (string == error_mark_node) { cp_parser_skip_to_closing_parenthesis (parser, true, false, /consume_paren=/true); return; } / If we're allowing GNU extensions, check for the extended assembly syntax. Unfortunately, the `:' tokens need not be separated by a space in C, and so, for compatibility, we tolerate that here too. Doing that means that we have to treat the `::' operator as two `:' tokens. / if (cp_parser_allow_gnu_extensions_p (parser) && parser->in_function_body && (cp_lexer_next_token_is (parser->lexer, CPP_COLON) \|\| cp_lexer_next_token_is (parser->lexer, CPP_SCOPE))) { bool inputs_p = false; bool clobbers_p = false; / The extended syntax was used. / extended_p = true; / Look for outputs. / if (cp_lexer_next_token_is (parser->lexer, CPP_COLON)) { / Consume the `:'. / cp_lexer_consume_token (parser->lexer); / Parse the output-operands. / if (cp_lexer_next_token_is_not (parser->lexer, CPP_COLON) && cp_lexer_next_token_is_not (parser->lexer, CPP_SCOPE) && cp_lexer_next_token_is_not (parser->lexer, CPP_CLOSE_PAREN)) outputs = cp_parser_asm_operand_list (parser); } / If the next token is `::', there are no outputs, and the next token is the beginning of the inputs. / else if (cp_lexer_next_token_is (parser->lexer, CPP_SCOPE)) / The inputs are coming next. / inputs_p = true; / Look for inputs. / if (inputs_p \|\| cp_lexer_next_token_is (parser->lexer, CPP_COLON)) { / Consume the `:' or `::'. / cp_lexer_consume_token (parser->lexer); / Parse the output-operands. / if (cp_lexer_next_token_is_not (parser->lexer, CPP_COLON) && cp_lexer_next_token_is_not (parser->lexer, CPP_CLOSE_PAREN)) inputs = cp_parser_asm_operand_list (parser); } else if (cp_lexer_next_token_is (parser->lexer, CPP_SCOPE)) / The clobbers are coming next. / clobbers_p = true; / Look for clobbers. / if (clobbers_p \|\| cp_lexer_next_token_is (parser->lexer, CPP_COLON)) { / Consume the `:' or `::'. / cp_lexer_consume_token (parser->lexer); / Parse the clobbers. / if (cp_lexer_next_token_is_not (parser->lexer, CPP_CLOSE_PAREN)) clobbers = cp_parser_asm_clobber_list (parser); } } / Look for the closing `)'. / if (!cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'")) cp_parser_skip_to_closing_parenthesis (parser, true, false, /consume_paren=/true); cp_parser_require (parser, CPP_SEMICOLON, "`;'"); / Create the ASM_EXPR. / if (parser->in_function_body) { asm_stmt = finish_asm_stmt (volatile_p, string, outputs, inputs, clobbers); / If the extended syntax was not used, mark the ASM_EXPR. / if (!extended_p) { tree temp = asm_stmt; if (TREE_CODE (temp) == CLEANUP_POINT_EXPR) temp = TREE_OPERAND (temp, 0); ASM_INPUT_P (temp) = 1; } } else cgraph_add_asm_node (string); } / Declarators [gram.dcl.decl] / / Parse an init-declarator. init-declarator: declarator initializer [opt] GNU Extension: init-declarator: declarator asm-specification [opt] attributes [opt] initializer [opt] function-definition: decl-specifier-seq [opt] declarator ctor-initializer [opt] function-body decl-specifier-seq [opt] declarator function-try-block GNU Extension: function-definition: __extension__ function-definition The DECL_SPECIFIERS apply to this declarator. Returns a representation of the entity declared. If MEMBER_P is TRUE, then this declarator appears in a class scope. The new DECL created by this declarator is returned. The CHECKS are access checks that should be performed once we know what entity is being declared (and, therefore, what classes have befriended it). If FUNCTION_DEFINITION_ALLOWED_P then we handle the declarator and for a function-definition here as well. If the declarator is a declarator for a function-definition, FUNCTION_DEFINITION_P will be TRUE upon return. By that point, the function-definition will have been completely parsed. FUNCTION_DEFINITION_P may be NULL if FUNCTION_DEFINITION_ALLOWED_P is FALSE. / static tree cp_parser_init_declarator (cp_parser* parser, cp_decl_specifier_seq decl_specifiers, VEC (deferred_access_check,gc) checks, bool function_definition_allowed_p, bool member_p, int declares_class_or_enum, bool* function_definition_p) { cp_token token; cp_declarator declarator; tree prefix_attributes; tree attributes; tree asm_specification; tree initializer; tree decl = NULL_TREE; tree scope; bool is_initialized; /* Only valid if IS_INITIALIZED is true. In that case, CPP_EQ if initialized with "= ..", CPP_OPEN_PAREN if initialized with "(...)". / enum cpp_ttype initialization_kind; bool is_parenthesized_init = false; bool is_non_constant_init; int ctor_dtor_or_conv_p; bool friend_p; tree pushed_scope = NULL; / Gather the attributes that were provided with the decl-specifiers. / prefix_attributes = decl_specifiers->attributes; / Assume that this is not the declarator for a function definition. / if (function_definition_p) function_definition_p = false; /* Defer access checks while parsing the declarator; we cannot know what names are accessible until we know what is being declared. / resume_deferring_access_checks (); / Parse the declarator. / declarator = cp_parser_declarator (parser, CP_PARSER_DECLARATOR_NAMED, &ctor_dtor_or_conv_p, /parenthesized_p=/NULL, /member_p=/false); / Gather up the deferred checks. / stop_deferring_access_checks (); / If the DECLARATOR was erroneous, there's no need to go further. / if (declarator == cp_error_declarator) return error_mark_node; / Check that the number of template-parameter-lists is OK. / if (!cp_parser_check_declarator_template_parameters (parser, declarator)) return error_mark_node; if (declares_class_or_enum & 2) cp_parser_check_for_definition_in_return_type (declarator, decl_specifiers->type); / Figure out what scope the entity declared by the DECLARATOR is located in. `grokdeclarator' sometimes changes the scope, so we compute it now. / scope = get_scope_of_declarator (declarator); / If we're allowing GNU extensions, look for an asm-specification and attributes. / if (cp_parser_allow_gnu_extensions_p (parser)) { / Look for an asm-specification. / asm_specification = cp_parser_asm_specification_opt (parser); / And attributes. / attributes = cp_parser_attributes_opt (parser); } else { asm_specification = NULL_TREE; attributes = NULL_TREE; } / Peek at the next token. / token = cp_lexer_peek_token (parser->lexer); / Check to see if the token indicates the start of a function-definition. / if (cp_parser_token_starts_function_definition_p (token)) { if (!function_definition_allowed_p) { / If a function-definition should not appear here, issue an error message. / cp_parser_error (parser, "a function-definition is not allowed here"); return error_mark_node; } else { / Neither attributes nor an asm-specification are allowed on a function-definition. / if (asm_specification) error ("an asm-specification is not allowed on a function-definition"); if (attributes) error ("attributes are not allowed on a function-definition"); / This is a function-definition. / function_definition_p = true; /* Parse the function definition. / if (member_p) decl = cp_parser_save_member_function_body (parser, decl_specifiers, declarator, prefix_attributes); else decl = (cp_parser_function_definition_from_specifiers_and_declarator (parser, decl_specifiers, prefix_attributes, declarator)); return decl; } } / [dcl.dcl] Only in function declarations for constructors, destructors, and type conversions can the decl-specifier-seq be omitted. We explicitly postpone this check past the point where we handle function-definitions because we tolerate function-definitions that are missing their return types in some modes. / if (!decl_specifiers->any_specifiers_p && ctor_dtor_or_conv_p <= 0) { cp_parser_error (parser, "expected constructor, destructor, or type conversion"); return error_mark_node; } / An `=' or an `(' indicates an initializer. / if (token->type == CPP_EQ \|\| token->type == CPP_OPEN_PAREN) { is_initialized = true; initialization_kind = token->type; } else { / If the init-declarator isn't initialized and isn't followed by a `,' or `;', it's not a valid init-declarator. / if (token->type != CPP_COMMA && token->type != CPP_SEMICOLON) { cp_parser_error (parser, "expected initializer"); return error_mark_node; } is_initialized = false; initialization_kind = CPP_EOF; } / Because start_decl has side-effects, we should only call it if we know we're going ahead. By this point, we know that we cannot possibly be looking at any other construct. / cp_parser_commit_to_tentative_parse (parser); / If the decl specifiers were bad, issue an error now that we're sure this was intended to be a declarator. Then continue declaring the variable(s), as int, to try to cut down on further errors. / if (decl_specifiers->any_specifiers_p && decl_specifiers->type == error_mark_node) { cp_parser_error (parser, "invalid type in declaration"); decl_specifiers->type = integer_type_node; } / Check to see whether or not this declaration is a friend. / friend_p = cp_parser_friend_p (decl_specifiers); / Enter the newly declared entry in the symbol table. If we're processing a declaration in a class-specifier, we wait until after processing the initializer. / if (!member_p) { if (parser->in_unbraced_linkage_specification_p) decl_specifiers->storage_class = sc_extern; decl = start_decl (declarator, decl_specifiers, is_initialized, attributes, prefix_attributes, &pushed_scope); } else if (scope) / Enter the SCOPE. That way unqualified names appearing in the initializer will be looked up in SCOPE. / pushed_scope = push_scope (scope); / Perform deferred access control checks, now that we know in which SCOPE the declared entity resides. / if (!member_p && decl) { tree saved_current_function_decl = NULL_TREE; / If the entity being declared is a function, pretend that we are in its scope. If it is a `friend', it may have access to things that would not otherwise be accessible. / if (TREE_CODE (decl) == FUNCTION_DECL) { saved_current_function_decl = current_function_decl; current_function_decl = decl; } / Perform access checks for template parameters. / cp_parser_perform_template_parameter_access_checks (checks); / Perform the access control checks for the declarator and the the decl-specifiers. / perform_deferred_access_checks (); / Restore the saved value. / if (TREE_CODE (decl) == FUNCTION_DECL) current_function_decl = saved_current_function_decl; } / Parse the initializer. / initializer = NULL_TREE; is_parenthesized_init = false; is_non_constant_init = true; if (is_initialized) { if (function_declarator_p (declarator)) { if (initialization_kind == CPP_EQ) initializer = cp_parser_pure_specifier (parser); else { / If the declaration was erroneous, we don't really know what the user intended, so just silently consume the initializer. / if (decl != error_mark_node) error ("initializer provided for function"); cp_parser_skip_to_closing_parenthesis (parser, /recovering=/true, /or_comma=/false, /consume_paren=/true); } } else initializer = cp_parser_initializer (parser, &is_parenthesized_init, &is_non_constant_init); } / The old parser allows attributes to appear after a parenthesized initializer. Mark Mitchell proposed removing this functionality on the GCC mailing lists on 2002-08-13. This parser accepts the attributes -- but ignores them. / if (cp_parser_allow_gnu_extensions_p (parser) && is_parenthesized_init) if (cp_parser_attributes_opt (parser)) warning (OPT_Wattributes, "attributes after parenthesized initializer ignored"); / For an in-class declaration, use `grokfield' to create the declaration. / if (member_p) { if (pushed_scope) { pop_scope (pushed_scope); pushed_scope = false; } decl = grokfield (declarator, decl_specifiers, initializer, !is_non_constant_init, /asmspec=/NULL_TREE, prefix_attributes); if (decl && TREE_CODE (decl) == FUNCTION_DECL) cp_parser_save_default_args (parser, decl); } / Finish processing the declaration. But, skip friend declarations. / if (!friend_p && decl && decl != error_mark_node) { cp_finish_decl (decl, initializer, !is_non_constant_init, asm_specification, / If the initializer is in parentheses, then this is a direct-initialization, which means that an `explicit' constructor is OK. Otherwise, an `explicit' constructor cannot be used. / ((is_parenthesized_init \|\| !is_initialized) ? 0 : LOOKUP_ONLYCONVERTING)); } if (!friend_p && pushed_scope) pop_scope (pushed_scope); return decl; } / Parse a declarator. declarator: direct-declarator ptr-operator declarator abstract-declarator: ptr-operator abstract-declarator [opt] direct-abstract-declarator GNU Extensions: declarator: attributes [opt] direct-declarator attributes [opt] ptr-operator declarator abstract-declarator: attributes [opt] ptr-operator abstract-declarator [opt] attributes [opt] direct-abstract-declarator If CTOR_DTOR_OR_CONV_P is not NULL, CTOR_DTOR_OR_CONV_P is used to detect constructor, destructor or conversion operators. It is set to -1 if the declarator is a name, and +1 if it is a function. Otherwise it is set to zero. Usually you just want to test for >0, but internally the negative value is used. (The reason for CTOR_DTOR_OR_CONV_P is that a declaration must have a decl-specifier-seq unless it declares a constructor, destructor, or conversion. It might seem that we could check this condition in semantic analysis, rather than parsing, but that makes it difficult to handle something like `f()'. We want to notice that there are no decl-specifiers, and therefore realize that this is an expression, not a declaration.) If PARENTHESIZED_P is non-NULL, PARENTHESIZED_P is set to true iff the declarator is a direct-declarator of the form "(...)". MEMBER_P is true iff this declarator is a member-declarator. / static cp_declarator cp_parser_declarator (cp_parser* parser, cp_parser_declarator_kind dcl_kind, int* ctor_dtor_or_conv_p, bool* parenthesized_p, bool member_p) { cp_token token; cp_declarator declarator; enum tree_code code; cp_cv_quals cv_quals; tree class_type; tree attributes = NULL_TREE; /* Assume this is not a constructor, destructor, or type-conversion operator. / if (ctor_dtor_or_conv_p) ctor_dtor_or_conv_p = 0; if (cp_parser_allow_gnu_extensions_p (parser)) attributes = cp_parser_attributes_opt (parser); /* Peek at the next token. / token = cp_lexer_peek_token (parser->lexer); / Check for the ptr-operator production. / cp_parser_parse_tentatively (parser); / Parse the ptr-operator. / code = cp_parser_ptr_operator (parser, &class_type, &cv_quals); / If that worked, then we have a ptr-operator. / if (cp_parser_parse_definitely (parser)) { / If a ptr-operator was found, then this declarator was not parenthesized. / if (parenthesized_p) parenthesized_p = true; /* The dependent declarator is optional if we are parsing an abstract-declarator. / if (dcl_kind != CP_PARSER_DECLARATOR_NAMED) cp_parser_parse_tentatively (parser); / Parse the dependent declarator. / declarator = cp_parser_declarator (parser, dcl_kind, /ctor_dtor_or_conv_p=/NULL, /parenthesized_p=/NULL, /member_p=/false); / If we are parsing an abstract-declarator, we must handle the case where the dependent declarator is absent. / if (dcl_kind != CP_PARSER_DECLARATOR_NAMED && !cp_parser_parse_definitely (parser)) declarator = NULL; / Build the representation of the ptr-operator. / if (class_type) declarator = make_ptrmem_declarator (cv_quals, class_type, declarator); else if (code == INDIRECT_REF) declarator = make_pointer_declarator (cv_quals, declarator); else declarator = make_reference_declarator (cv_quals, declarator); } / Everything else is a direct-declarator. / else { if (parenthesized_p) parenthesized_p = cp_lexer_next_token_is (parser->lexer, CPP_OPEN_PAREN); declarator = cp_parser_direct_declarator (parser, dcl_kind, ctor_dtor_or_conv_p, member_p); } if (attributes && declarator && declarator != cp_error_declarator) declarator->attributes = attributes; return declarator; } /* Parse a direct-declarator or direct-abstract-declarator. direct-declarator: declarator-id direct-declarator ( parameter-declaration-clause ) cv-qualifier-seq [opt] exception-specification [opt] direct-declarator [ constant-expression [opt] ] ( declarator ) direct-abstract-declarator: direct-abstract-declarator [opt] ( parameter-declaration-clause ) cv-qualifier-seq [opt] exception-specification [opt] direct-abstract-declarator [opt] [ constant-expression [opt] ] ( abstract-declarator ) Returns a representation of the declarator. DCL_KIND is CP_PARSER_DECLARATOR_ABSTRACT, if we are parsing a direct-abstract-declarator. It is CP_PARSER_DECLARATOR_NAMED, if we are parsing a direct-declarator. It is CP_PARSER_DECLARATOR_EITHER, if we can accept either - in the case of ambiguity we prefer an abstract declarator, as per [dcl.ambig.res]. CTOR_DTOR_OR_CONV_P and MEMBER_P are as for cp_parser_declarator. / static cp_declarator cp_parser_direct_declarator (cp_parser* parser, cp_parser_declarator_kind dcl_kind, int* ctor_dtor_or_conv_p, bool member_p) { cp_token token; cp_declarator declarator = NULL; tree scope = NULL_TREE; bool saved_default_arg_ok_p = parser->default_arg_ok_p; bool saved_in_declarator_p = parser->in_declarator_p; bool first = true; tree pushed_scope = NULL_TREE; while (true) { /* Peek at the next token. / token = cp_lexer_peek_token (parser->lexer); if (token->type == CPP_OPEN_PAREN) { / This is either a parameter-declaration-clause, or a parenthesized declarator. When we know we are parsing a named declarator, it must be a parenthesized declarator if FIRST is true. For instance, `(int)' is a parameter-declaration-clause, with an omitted direct-abstract-declarator. But `(())', is a parenthesized abstract declarator. Finally, when T is a template parameter `(T)' is a parameter-declaration-clause, and not a parenthesized named declarator. We first try and parse a parameter-declaration-clause, and then try a nested declarator (if FIRST is true). It is not an error for it not to be a parameter-declaration-clause, even when FIRST is false. Consider, int i (int); int i (3); The first is the declaration of a function while the second is a the definition of a variable, including its initializer. Having seen only the parenthesis, we cannot know which of these two alternatives should be selected. Even more complex are examples like: int i (int (a)); int i (int (3)); The former is a function-declaration; the latter is a variable initialization. Thus again, we try a parameter-declaration-clause, and if that fails, we back out and return. / if (!first \|\| dcl_kind != CP_PARSER_DECLARATOR_NAMED) { cp_parameter_declarator params; unsigned saved_num_template_parameter_lists; / In a member-declarator, the only valid interpretation of a parenthesis is the start of a parameter-declaration-clause. (It is invalid to initialize a static data member with a parenthesized initializer; only the "=" form of initialization is permitted.) / if (!member_p) cp_parser_parse_tentatively (parser); / Consume the `('. / cp_lexer_consume_token (parser->lexer); if (first) { / If this is going to be an abstract declarator, we're in a declarator and we can't have default args. / parser->default_arg_ok_p = false; parser->in_declarator_p = true; } / Inside the function parameter list, surrounding template-parameter-lists do not apply. / saved_num_template_parameter_lists = parser->num_template_parameter_lists; parser->num_template_parameter_lists = 0; / Parse the parameter-declaration-clause. / params = cp_parser_parameter_declaration_clause (parser); parser->num_template_parameter_lists = saved_num_template_parameter_lists; / If all went well, parse the cv-qualifier-seq and the exception-specification. / if (member_p \|\| cp_parser_parse_definitely (parser)) { cp_cv_quals cv_quals; tree exception_specification; if (ctor_dtor_or_conv_p) ctor_dtor_or_conv_p = ctor_dtor_or_conv_p < 0; first = false; / Consume the `)'. / cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'"); / Parse the cv-qualifier-seq. / cv_quals = cp_parser_cv_qualifier_seq_opt (parser); / And the exception-specification. / exception_specification = cp_parser_exception_specification_opt (parser); / Create the function-declarator. / declarator = make_call_declarator (declarator, params, cv_quals, exception_specification); / Any subsequent parameter lists are to do with return type, so are not those of the declared function. / parser->default_arg_ok_p = false; / Repeat the main loop. / continue; } } / If this is the first, we can try a parenthesized declarator. / if (first) { bool saved_in_type_id_in_expr_p; parser->default_arg_ok_p = saved_default_arg_ok_p; parser->in_declarator_p = saved_in_declarator_p; / Consume the `('. / cp_lexer_consume_token (parser->lexer); / Parse the nested declarator. / saved_in_type_id_in_expr_p = parser->in_type_id_in_expr_p; parser->in_type_id_in_expr_p = true; declarator = cp_parser_declarator (parser, dcl_kind, ctor_dtor_or_conv_p, /parenthesized_p=/NULL, member_p); parser->in_type_id_in_expr_p = saved_in_type_id_in_expr_p; first = false; / Expect a `)'. / if (!cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'")) declarator = cp_error_declarator; if (declarator == cp_error_declarator) break; goto handle_declarator; } / Otherwise, we must be done. / else break; } else if ((!first \|\| dcl_kind != CP_PARSER_DECLARATOR_NAMED) && token->type == CPP_OPEN_SQUARE) { / Parse an array-declarator. / tree bounds; if (ctor_dtor_or_conv_p) ctor_dtor_or_conv_p = 0; first = false; parser->default_arg_ok_p = false; parser->in_declarator_p = true; /* Consume the `['. / cp_lexer_consume_token (parser->lexer); / Peek at the next token. / token = cp_lexer_peek_token (parser->lexer); / If the next token is `]', then there is no constant-expression. / if (token->type != CPP_CLOSE_SQUARE) { bool non_constant_p; bounds = cp_parser_constant_expression (parser, /allow_non_constant=/true, &non_constant_p); if (!non_constant_p) bounds = fold_non_dependent_expr (bounds); / Normally, the array bound must be an integral constant expression. However, as an extension, we allow VLAs in function scopes. / else if (!parser->in_function_body) { error ("array bound is not an integer constant"); bounds = error_mark_node; } } else bounds = NULL_TREE; / Look for the closing `]'. / if (!cp_parser_require (parser, CPP_CLOSE_SQUARE, "`]'")) { declarator = cp_error_declarator; break; } declarator = make_array_declarator (declarator, bounds); } else if (first && dcl_kind != CP_PARSER_DECLARATOR_ABSTRACT) { tree qualifying_scope; tree unqualified_name; special_function_kind sfk; bool abstract_ok; / Parse a declarator-id / abstract_ok = (dcl_kind == CP_PARSER_DECLARATOR_EITHER); if (abstract_ok) cp_parser_parse_tentatively (parser); unqualified_name = cp_parser_declarator_id (parser, /optional_p=/abstract_ok); qualifying_scope = parser->scope; if (abstract_ok) { if (!cp_parser_parse_definitely (parser)) unqualified_name = error_mark_node; else if (unqualified_name && (qualifying_scope \|\| (TREE_CODE (unqualified_name) != IDENTIFIER_NODE))) { cp_parser_error (parser, "expected unqualified-id"); unqualified_name = error_mark_node; } } if (!unqualified_name) return NULL; if (unqualified_name == error_mark_node) { declarator = cp_error_declarator; break; } if (qualifying_scope && at_namespace_scope_p () && TREE_CODE (qualifying_scope) == TYPENAME_TYPE) { / In the declaration of a member of a template class outside of the class itself, the SCOPE will sometimes be a TYPENAME_TYPE. For example, given: template <typename T> int S<T>::R::i = 3; the SCOPE will be a TYPENAME_TYPE for `S<T>::R'. In this context, we must resolve S<T>::R to an ordinary type, rather than a typename type. The reason we normally avoid resolving TYPENAME_TYPEs is that a specialization of `S' might render `S<T>::R' not a type. However, if `S' is specialized, then this `i' will not be used, so there is no harm in resolving the types here. / tree type; / Resolve the TYPENAME_TYPE. / type = resolve_typename_type (qualifying_scope, /only_current_p=/false); / If that failed, the declarator is invalid. / if (type == error_mark_node) error ("%<%T::%D%> is not a type", TYPE_CONTEXT (qualifying_scope), TYPE_IDENTIFIER (qualifying_scope)); qualifying_scope = type; } sfk = sfk_none; if (unqualified_name) { tree class_type; if (qualifying_scope && CLASS_TYPE_P (qualifying_scope)) class_type = qualifying_scope; else class_type = current_class_type; if (TREE_CODE (unqualified_name) == TYPE_DECL) { tree name_type = TREE_TYPE (unqualified_name); if (class_type && same_type_p (name_type, class_type)) { if (qualifying_scope && CLASSTYPE_USE_TEMPLATE (name_type)) { error ("invalid use of constructor as a template"); inform ("use %<%T::%D%> instead of %<%T::%D%> to " "name the constructor in a qualified name", class_type, DECL_NAME (TYPE_TI_TEMPLATE (class_type)), class_type, name_type); declarator = cp_error_declarator; break; } else unqualified_name = constructor_name (class_type); } else { / We do not attempt to print the declarator here because we do not have enough information about its original syntactic form. / cp_parser_error (parser, "invalid declarator"); declarator = cp_error_declarator; break; } } if (class_type) { if (TREE_CODE (unqualified_name) == BIT_NOT_EXPR) sfk = sfk_destructor; else if (IDENTIFIER_TYPENAME_P (unqualified_name)) sfk = sfk_conversion; else if (/ There's no way to declare a constructor for an anonymous type, even if the type got a name for linkage purposes. / !TYPE_WAS_ANONYMOUS (class_type) && constructor_name_p (unqualified_name, class_type)) { unqualified_name = constructor_name (class_type); sfk = sfk_constructor; } if (ctor_dtor_or_conv_p && sfk != sfk_none) ctor_dtor_or_conv_p = -1; } } declarator = make_id_declarator (qualifying_scope, unqualified_name, sfk); declarator->id_loc = token->location; handle_declarator:; scope = get_scope_of_declarator (declarator); if (scope) /* Any names that appear after the declarator-id for a member are looked up in the containing scope. / pushed_scope = push_scope (scope); parser->in_declarator_p = true; if ((ctor_dtor_or_conv_p && ctor_dtor_or_conv_p) \|\| (declarator && declarator->kind == cdk_id)) /* Default args are only allowed on function declarations. / parser->default_arg_ok_p = saved_default_arg_ok_p; else parser->default_arg_ok_p = false; first = false; } / We're done. / else break; } / For an abstract declarator, we might wind up with nothing at this point. That's an error; the declarator is not optional. / if (!declarator) cp_parser_error (parser, "expected declarator"); / If we entered a scope, we must exit it now. / if (pushed_scope) pop_scope (pushed_scope); parser->default_arg_ok_p = saved_default_arg_ok_p; parser->in_declarator_p = saved_in_declarator_p; return declarator; } / Parse a ptr-operator. ptr-operator: * cv-qualifier-seq [opt] & :: [opt] nested-name-specifier * cv-qualifier-seq [opt] GNU Extension: ptr-operator: & cv-qualifier-seq [opt] Returns INDIRECT_REF if a pointer, or pointer-to-member, was used. Returns ADDR_EXPR if a reference was used. In the case of a pointer-to-member, TYPE is filled in with the TYPE containing the member. CV_QUALS is filled in with the cv-qualifier-seq, or TYPE_UNQUALIFIED, if there are no cv-qualifiers. Returns ERROR_MARK if an error occurred. / static enum tree_code cp_parser_ptr_operator (cp_parser parser, tree* type, cp_cv_quals cv_quals) { enum tree_code code = ERROR_MARK; cp_token token; /* Assume that it's not a pointer-to-member. / type = NULL_TREE; /* And that there are no cv-qualifiers. / cv_quals = TYPE_UNQUALIFIED; /* Peek at the next token. / token = cp_lexer_peek_token (parser->lexer); / If it's a `' or `&' we have a pointer or reference. / if (token->type == CPP_MULT \|\| token->type == CPP_AND) { /* Remember which ptr-operator we were processing. / code = (token->type == CPP_AND ? ADDR_EXPR : INDIRECT_REF); / Consume the `' or `&'. / cp_lexer_consume_token (parser->lexer); /* A `' can be followed by a cv-qualifier-seq, and so can a `&', if we are allowing GNU extensions. (The only qualifier that can legally appear after `&' is `restrict', but that is enforced during semantic analysis. / if (code == INDIRECT_REF \|\| cp_parser_allow_gnu_extensions_p (parser)) cv_quals = cp_parser_cv_qualifier_seq_opt (parser); } else { / Try the pointer-to-member case. / cp_parser_parse_tentatively (parser); / Look for the optional `::' operator. / cp_parser_global_scope_opt (parser, /current_scope_valid_p=/false); / Look for the nested-name specifier. / cp_parser_nested_name_specifier (parser, /typename_keyword_p=/false, /check_dependency_p=/true, /type_p=/false, /is_declaration=/false); / If we found it, and the next token is a `', then we are indeed looking at a pointer-to-member operator. / if (!cp_parser_error_occurred (parser) && cp_parser_require (parser, CPP_MULT, "`'")) { / Indicate that the `' operator was used. / code = INDIRECT_REF; if (TREE_CODE (parser->scope) == NAMESPACE_DECL) error ("%qD is a namespace", parser->scope); else { /* The type of which the member is a member is given by the current SCOPE. / type = parser->scope; /* The next name will not be qualified. / parser->scope = NULL_TREE; parser->qualifying_scope = NULL_TREE; parser->object_scope = NULL_TREE; / Look for the optional cv-qualifier-seq. / cv_quals = cp_parser_cv_qualifier_seq_opt (parser); } } /* If that didn't work we don't have a ptr-operator. / if (!cp_parser_parse_definitely (parser)) cp_parser_error (parser, "expected ptr-operator"); } return code; } / Parse an (optional) cv-qualifier-seq. cv-qualifier-seq: cv-qualifier cv-qualifier-seq [opt] cv-qualifier: const volatile GNU Extension: cv-qualifier: __restrict__ Returns a bitmask representing the cv-qualifiers. / static cp_cv_quals cp_parser_cv_qualifier_seq_opt (cp_parser parser) { cp_cv_quals cv_quals = TYPE_UNQUALIFIED; while (true) { cp_token token; cp_cv_quals cv_qualifier; / Peek at the next token. / token = cp_lexer_peek_token (parser->lexer); / See if it's a cv-qualifier. / switch (token->keyword) { case RID_CONST: cv_qualifier = TYPE_QUAL_CONST; break; case RID_VOLATILE: cv_qualifier = TYPE_QUAL_VOLATILE; break; case RID_RESTRICT: cv_qualifier = TYPE_QUAL_RESTRICT; break; default: cv_qualifier = TYPE_UNQUALIFIED; break; } if (!cv_qualifier) break; if (cv_quals & cv_qualifier) { error ("duplicate cv-qualifier"); cp_lexer_purge_token (parser->lexer); } else { cp_lexer_consume_token (parser->lexer); cv_quals \|= cv_qualifier; } } return cv_quals; } / Parse a declarator-id. declarator-id: id-expression :: [opt] nested-name-specifier [opt] type-name In the `id-expression' case, the value returned is as for cp_parser_id_expression if the id-expression was an unqualified-id. If the id-expression was a qualified-id, then a SCOPE_REF is returned. The first operand is the scope (either a NAMESPACE_DECL or TREE_TYPE), but the second is still just a representation of an unqualified-id. / static tree cp_parser_declarator_id (cp_parser parser, bool optional_p) { tree id; /* The expression must be an id-expression. Assume that qualified names are the names of types so that: template <class T> int S<T>::R::i = 3; will work; we must treat `S<T>::R' as the name of a type. Similarly, assume that qualified names are templates, where required, so that: template <class T> int S<T>::R<T>::i = 3; will work, too. / id = cp_parser_id_expression (parser, /template_keyword_p=/false, /check_dependency_p=/false, /template_p=/NULL, /declarator_p=/true, optional_p); if (id && BASELINK_P (id)) id = BASELINK_FUNCTIONS (id); return id; } / Parse a type-id. type-id: type-specifier-seq abstract-declarator [opt] Returns the TYPE specified. / static tree cp_parser_type_id (cp_parser parser) { cp_decl_specifier_seq type_specifier_seq; cp_declarator abstract_declarator; / Parse the type-specifier-seq. / cp_parser_type_specifier_seq (parser, /is_condition=/false, &type_specifier_seq); if (type_specifier_seq.type == error_mark_node) return error_mark_node; / There might or might not be an abstract declarator. / cp_parser_parse_tentatively (parser); / Look for the declarator. / abstract_declarator = cp_parser_declarator (parser, CP_PARSER_DECLARATOR_ABSTRACT, NULL, /parenthesized_p=/NULL, /member_p=/false); / Check to see if there really was a declarator. / if (!cp_parser_parse_definitely (parser)) abstract_declarator = NULL; return groktypename (&type_specifier_seq, abstract_declarator); } / Parse a type-specifier-seq. type-specifier-seq: type-specifier type-specifier-seq [opt] GNU extension: type-specifier-seq: attributes type-specifier-seq [opt] If IS_CONDITION is true, we are at the start of a "condition", e.g., we've just seen "if (". Sets TYPE_SPECIFIER_SEQ to represent the sequence. / static void cp_parser_type_specifier_seq (cp_parser* parser, bool is_condition, cp_decl_specifier_seq type_specifier_seq) { bool seen_type_specifier = false; cp_parser_flags flags = CP_PARSER_FLAGS_OPTIONAL; / Clear the TYPE_SPECIFIER_SEQ. / clear_decl_specs (type_specifier_seq); / Parse the type-specifiers and attributes. / while (true) { tree type_specifier; bool is_cv_qualifier; / Check for attributes first. / if (cp_lexer_next_token_is_keyword (parser->lexer, RID_ATTRIBUTE)) { type_specifier_seq->attributes = chainon (type_specifier_seq->attributes, cp_parser_attributes_opt (parser)); continue; } / Look for the type-specifier. / type_specifier = cp_parser_type_specifier (parser, flags, type_specifier_seq, /is_declaration=/false, NULL, &is_cv_qualifier); if (!type_specifier) { / If the first type-specifier could not be found, this is not a type-specifier-seq at all. / if (!seen_type_specifier) { cp_parser_error (parser, "expected type-specifier"); type_specifier_seq->type = error_mark_node; return; } / If subsequent type-specifiers could not be found, the type-specifier-seq is complete. / break; } seen_type_specifier = true; / The standard says that a condition can be: type-specifier-seq declarator = assignment-expression However, given: struct S {}; if (int S = ...) we should treat the "S" as a declarator, not as a type-specifier. The standard doesn't say that explicitly for type-specifier-seq, but it does say that for decl-specifier-seq in an ordinary declaration. Perhaps it would be clearer just to allow a decl-specifier-seq here, and then add a semantic restriction that if any decl-specifiers that are not type-specifiers appear, the program is invalid. / if (is_condition && !is_cv_qualifier) flags \|= CP_PARSER_FLAGS_NO_USER_DEFINED_TYPES; } cp_parser_check_decl_spec (type_specifier_seq); } / Parse a parameter-declaration-clause. parameter-declaration-clause: parameter-declaration-list [opt] ... [opt] parameter-declaration-list , ... Returns a representation for the parameter declarations. A return value of NULL indicates a parameter-declaration-clause consisting only of an ellipsis. / static cp_parameter_declarator cp_parser_parameter_declaration_clause (cp_parser* parser) { cp_parameter_declarator parameters; cp_token token; bool ellipsis_p; bool is_error; /* Peek at the next token. / token = cp_lexer_peek_token (parser->lexer); / Check for trivial parameter-declaration-clauses. / if (token->type == CPP_ELLIPSIS) { / Consume the `...' token. / cp_lexer_consume_token (parser->lexer); return NULL; } else if (token->type == CPP_CLOSE_PAREN) / There are no parameters. / { #ifndef NO_IMPLICIT_EXTERN_C if (in_system_header && current_class_type == NULL && current_lang_name == lang_name_c) return NULL; else #endif return no_parameters; } / Check for `(void)', too, which is a special case. / else if (token->keyword == RID_VOID && (cp_lexer_peek_nth_token (parser->lexer, 2)->type == CPP_CLOSE_PAREN)) { / Consume the `void' token. / cp_lexer_consume_token (parser->lexer); / There are no parameters. / return no_parameters; } / Parse the parameter-declaration-list. / parameters = cp_parser_parameter_declaration_list (parser, &is_error); / If a parse error occurred while parsing the parameter-declaration-list, then the entire parameter-declaration-clause is erroneous. / if (is_error) return NULL; / Peek at the next token. / token = cp_lexer_peek_token (parser->lexer); / If it's a `,', the clause should terminate with an ellipsis. / if (token->type == CPP_COMMA) { / Consume the `,'. / cp_lexer_consume_token (parser->lexer); / Expect an ellipsis. / ellipsis_p = (cp_parser_require (parser, CPP_ELLIPSIS, "`...'") != NULL); } / It might also be `...' if the optional trailing `,' was omitted. / else if (token->type == CPP_ELLIPSIS) { / Consume the `...' token. / cp_lexer_consume_token (parser->lexer); / And remember that we saw it. / ellipsis_p = true; } else ellipsis_p = false; / Finish the parameter list. / if (parameters && ellipsis_p) parameters->ellipsis_p = true; return parameters; } / Parse a parameter-declaration-list. parameter-declaration-list: parameter-declaration parameter-declaration-list , parameter-declaration Returns a representation of the parameter-declaration-list, as for cp_parser_parameter_declaration_clause. However, the `void_list_node' is never appended to the list. Upon return, IS_ERROR will be true iff an error occurred. / static cp_parameter_declarator * cp_parser_parameter_declaration_list (cp_parser* parser, bool is_error) { cp_parameter_declarator parameters = NULL; cp_parameter_declarator *tail = &parameters; bool saved_in_unbraced_linkage_specification_p; / Assume all will go well. / is_error = false; /* The special considerations that apply to a function within an unbraced linkage specifications do not apply to the parameters to the function. / saved_in_unbraced_linkage_specification_p = parser->in_unbraced_linkage_specification_p; parser->in_unbraced_linkage_specification_p = false; / Look for more parameters. / while (true) { cp_parameter_declarator parameter; bool parenthesized_p; /* Parse the parameter. / parameter = cp_parser_parameter_declaration (parser, /template_parm_p=/false, &parenthesized_p); / If a parse error occurred parsing the parameter declaration, then the entire parameter-declaration-list is erroneous. / if (!parameter) { is_error = true; parameters = NULL; break; } /* Add the new parameter to the list. / tail = parameter; tail = &parameter->next; /* Peek at the next token. / if (cp_lexer_next_token_is (parser->lexer, CPP_CLOSE_PAREN) \|\| cp_lexer_next_token_is (parser->lexer, CPP_ELLIPSIS) / These are for Objective-C++ / \|\| cp_lexer_next_token_is (parser->lexer, CPP_SEMICOLON) \|\| cp_lexer_next_token_is (parser->lexer, CPP_OPEN_BRACE)) / The parameter-declaration-list is complete. / break; else if (cp_lexer_next_token_is (parser->lexer, CPP_COMMA)) { cp_token token; /* Peek at the next token. / token = cp_lexer_peek_nth_token (parser->lexer, 2); / If it's an ellipsis, then the list is complete. / if (token->type == CPP_ELLIPSIS) break; / Otherwise, there must be more parameters. Consume the `,'. / cp_lexer_consume_token (parser->lexer); / When parsing something like: int i(float f, double d) we can tell after seeing the declaration for "f" that we are not looking at an initialization of a variable "i", but rather at the declaration of a function "i". Due to the fact that the parsing of template arguments (as specified to a template-id) requires backtracking we cannot use this technique when inside a template argument list. / if (!parser->in_template_argument_list_p && !parser->in_type_id_in_expr_p && cp_parser_uncommitted_to_tentative_parse_p (parser) / However, a parameter-declaration of the form "foat(f)" (which is a valid declaration of a parameter "f") can also be interpreted as an expression (the conversion of "f" to "float"). / && !parenthesized_p) cp_parser_commit_to_tentative_parse (parser); } else { cp_parser_error (parser, "expected %<,%> or %<...%>"); if (!cp_parser_uncommitted_to_tentative_parse_p (parser)) cp_parser_skip_to_closing_parenthesis (parser, /recovering=/true, /or_comma=/false, /consume_paren=/false); break; } } parser->in_unbraced_linkage_specification_p = saved_in_unbraced_linkage_specification_p; return parameters; } / Parse a parameter declaration. parameter-declaration: decl-specifier-seq declarator decl-specifier-seq declarator = assignment-expression decl-specifier-seq abstract-declarator [opt] decl-specifier-seq abstract-declarator [opt] = assignment-expression If TEMPLATE_PARM_P is TRUE, then this parameter-declaration declares a template parameter. (In that case, a non-nested `>' token encountered during the parsing of the assignment-expression is not interpreted as a greater-than operator.) Returns a representation of the parameter, or NULL if an error occurs. If PARENTHESIZED_P is non-NULL, PARENTHESIZED_P is set to true iff the declarator is of the form "(p)". / static cp_parameter_declarator * cp_parser_parameter_declaration (cp_parser parser, bool template_parm_p, bool parenthesized_p) { int declares_class_or_enum; bool greater_than_is_operator_p; cp_decl_specifier_seq decl_specifiers; cp_declarator declarator; tree default_argument; cp_token token; const char saved_message; / In a template parameter, `>' is not an operator. [temp.param] When parsing a default template-argument for a non-type template-parameter, the first non-nested `>' is taken as the end of the template parameter-list rather than a greater-than operator. / greater_than_is_operator_p = !template_parm_p; / Type definitions may not appear in parameter types. / saved_message = parser->type_definition_forbidden_message; parser->type_definition_forbidden_message = "types may not be defined in parameter types"; / Parse the declaration-specifiers. / cp_parser_decl_specifier_seq (parser, CP_PARSER_FLAGS_NONE, &decl_specifiers, &declares_class_or_enum); / If an error occurred, there's no reason to attempt to parse the rest of the declaration. / if (cp_parser_error_occurred (parser)) { parser->type_definition_forbidden_message = saved_message; return NULL; } / Peek at the next token. / token = cp_lexer_peek_token (parser->lexer); / If the next token is a `)', `,', `=', `>', or `...', then there is no declarator. / if (token->type == CPP_CLOSE_PAREN \|\| token->type == CPP_COMMA \|\| token->type == CPP_EQ \|\| token->type == CPP_ELLIPSIS \|\| token->type == CPP_GREATER) { declarator = NULL; if (parenthesized_p) parenthesized_p = false; } /* Otherwise, there should be a declarator. / else { bool saved_default_arg_ok_p = parser->default_arg_ok_p; parser->default_arg_ok_p = false; / After seeing a decl-specifier-seq, if the next token is not a "(", there is no possibility that the code is a valid expression. Therefore, if parsing tentatively, we commit at this point. / if (!parser->in_template_argument_list_p / In an expression context, having seen: (int((char ... we cannot be sure whether we are looking at a function-type (taking a "char" as a parameter) or a cast of some object of type "char" to "int". / && !parser->in_type_id_in_expr_p && cp_parser_uncommitted_to_tentative_parse_p (parser) && cp_lexer_next_token_is_not (parser->lexer, CPP_OPEN_PAREN)) cp_parser_commit_to_tentative_parse (parser); / Parse the declarator. / declarator = cp_parser_declarator (parser, CP_PARSER_DECLARATOR_EITHER, /ctor_dtor_or_conv_p=/NULL, parenthesized_p, /member_p=/false); parser->default_arg_ok_p = saved_default_arg_ok_p; / After the declarator, allow more attributes. / decl_specifiers.attributes = chainon (decl_specifiers.attributes, cp_parser_attributes_opt (parser)); } / The restriction on defining new types applies only to the type of the parameter, not to the default argument. / parser->type_definition_forbidden_message = saved_message; / If the next token is `=', then process a default argument. / if (cp_lexer_next_token_is (parser->lexer, CPP_EQ)) { bool saved_greater_than_is_operator_p; / Consume the `='. / cp_lexer_consume_token (parser->lexer); / If we are defining a class, then the tokens that make up the default argument must be saved and processed later. / if (!template_parm_p && at_class_scope_p () && TYPE_BEING_DEFINED (current_class_type)) { unsigned depth = 0; cp_token first_token; cp_token token; / Add tokens until we have processed the entire default argument. We add the range [first_token, token). / first_token = cp_lexer_peek_token (parser->lexer); while (true) { bool done = false; / Peek at the next token. / token = cp_lexer_peek_token (parser->lexer); / What we do depends on what token we have. / switch (token->type) { / In valid code, a default argument must be immediately followed by a `,' `)', or `...'. / case CPP_COMMA: case CPP_CLOSE_PAREN: case CPP_ELLIPSIS: / If we run into a non-nested `;', `}', or `]', then the code is invalid -- but the default argument is certainly over. / case CPP_SEMICOLON: case CPP_CLOSE_BRACE: case CPP_CLOSE_SQUARE: if (depth == 0) done = true; / Update DEPTH, if necessary. / else if (token->type == CPP_CLOSE_PAREN \|\| token->type == CPP_CLOSE_BRACE \|\| token->type == CPP_CLOSE_SQUARE) --depth; break; case CPP_OPEN_PAREN: case CPP_OPEN_SQUARE: case CPP_OPEN_BRACE: ++depth; break; case CPP_GREATER: / If we see a non-nested `>', and `>' is not an operator, then it marks the end of the default argument. / if (!depth && !greater_than_is_operator_p) done = true; break; / If we run out of tokens, issue an error message. / case CPP_EOF: case CPP_PRAGMA_EOL: error ("file ends in default argument"); done = true; break; case CPP_NAME: case CPP_SCOPE: / In these cases, we should look for template-ids. For example, if the default argument is `X<int, double>()', we need to do name lookup to figure out whether or not `X' is a template; if so, the `,' does not end the default argument. That is not yet done. / break; default: break; } / If we've reached the end, stop. / if (done) break; / Add the token to the token block. / token = cp_lexer_consume_token (parser->lexer); } / Create a DEFAULT_ARG to represented the unparsed default argument. / default_argument = make_node (DEFAULT_ARG); DEFARG_TOKENS (default_argument) = cp_token_cache_new (first_token, token); DEFARG_INSTANTIATIONS (default_argument) = NULL; } / Outside of a class definition, we can just parse the assignment-expression. / else { bool saved_local_variables_forbidden_p; / Make sure that PARSER->GREATER_THAN_IS_OPERATOR_P is set correctly. / saved_greater_than_is_operator_p = parser->greater_than_is_operator_p; parser->greater_than_is_operator_p = greater_than_is_operator_p; / Local variable names (and the `this' keyword) may not appear in a default argument. / saved_local_variables_forbidden_p = parser->local_variables_forbidden_p; parser->local_variables_forbidden_p = true; / The default argument expression may cause implicitly defined member functions to be synthesized, which will result in garbage collection. We must treat this situation as if we were within the body of function so as to avoid collecting live data on the stack. / ++function_depth; / Parse the assignment-expression. / if (template_parm_p) push_deferring_access_checks (dk_no_deferred); default_argument = cp_parser_assignment_expression (parser, /cast_p=/false); if (template_parm_p) pop_deferring_access_checks (); / Restore saved state. / --function_depth; parser->greater_than_is_operator_p = saved_greater_than_is_operator_p; parser->local_variables_forbidden_p = saved_local_variables_forbidden_p; } if (!parser->default_arg_ok_p) { if (!flag_pedantic_errors) warning (0, "deprecated use of default argument for parameter of non-function"); else { error ("default arguments are only permitted for function parameters"); default_argument = NULL_TREE; } } } else default_argument = NULL_TREE; return make_parameter_declarator (&decl_specifiers, declarator, default_argument); } / Parse a function-body. function-body: compound_statement / static void cp_parser_function_body (cp_parser parser) { cp_parser_compound_statement (parser, NULL, false); } /* Parse a ctor-initializer-opt followed by a function-body. Return true if a ctor-initializer was present. / static bool cp_parser_ctor_initializer_opt_and_function_body (cp_parser parser) { tree body; bool ctor_initializer_p; /* Begin the function body. / body = begin_function_body (); / Parse the optional ctor-initializer. / ctor_initializer_p = cp_parser_ctor_initializer_opt (parser); / Parse the function-body. / cp_parser_function_body (parser); / Finish the function body. / finish_function_body (body); return ctor_initializer_p; } / Parse an initializer. initializer: = initializer-clause ( expression-list ) Returns an expression representing the initializer. If no initializer is present, NULL_TREE is returned. IS_PARENTHESIZED_INIT is set to TRUE if the `( expression-list )' production is used, and zero otherwise. IS_PARENTHESIZED_INIT is set to FALSE if there is no initializer present. If there is an initializer, and it is not a constant-expression, NON_CONSTANT_P is set to true; otherwise it is set to false. / static tree cp_parser_initializer (cp_parser* parser, bool* is_parenthesized_init, bool* non_constant_p) { cp_token token; tree init; / Peek at the next token. / token = cp_lexer_peek_token (parser->lexer); / Let our caller know whether or not this initializer was parenthesized. / is_parenthesized_init = (token->type == CPP_OPEN_PAREN); /* Assume that the initializer is constant. / non_constant_p = false; if (token->type == CPP_EQ) { /* Consume the `='. / cp_lexer_consume_token (parser->lexer); / Parse the initializer-clause. / init = cp_parser_initializer_clause (parser, non_constant_p); } else if (token->type == CPP_OPEN_PAREN) init = cp_parser_parenthesized_expression_list (parser, false, /cast_p=/false, non_constant_p); else { / Anything else is an error. / cp_parser_error (parser, "expected initializer"); init = error_mark_node; } return init; } / Parse an initializer-clause. initializer-clause: assignment-expression { initializer-list , [opt] } { } Returns an expression representing the initializer. If the `assignment-expression' production is used the value returned is simply a representation for the expression. Otherwise, a CONSTRUCTOR is returned. The CONSTRUCTOR_ELTS will be the elements of the initializer-list (or NULL, if the last production is used). The TREE_TYPE for the CONSTRUCTOR will be NULL_TREE. There is no way to detect whether or not the optional trailing `,' was provided. NON_CONSTANT_P is as for cp_parser_initializer. / static tree cp_parser_initializer_clause (cp_parser parser, bool* non_constant_p) { tree initializer; /* Assume the expression is constant. / non_constant_p = false; /* If it is not a `{', then we are looking at an assignment-expression. / if (cp_lexer_next_token_is_not (parser->lexer, CPP_OPEN_BRACE)) { initializer = cp_parser_constant_expression (parser, /allow_non_constant_p=/true, non_constant_p); if (!non_constant_p) initializer = fold_non_dependent_expr (initializer); } else { /* Consume the `{' token. / cp_lexer_consume_token (parser->lexer); / Create a CONSTRUCTOR to represent the braced-initializer. / initializer = make_node (CONSTRUCTOR); / If it's not a `}', then there is a non-trivial initializer. / if (cp_lexer_next_token_is_not (parser->lexer, CPP_CLOSE_BRACE)) { / Parse the initializer list. / CONSTRUCTOR_ELTS (initializer) = cp_parser_initializer_list (parser, non_constant_p); / A trailing `,' token is allowed. / if (cp_lexer_next_token_is (parser->lexer, CPP_COMMA)) cp_lexer_consume_token (parser->lexer); } / Now, there should be a trailing `}'. / cp_parser_require (parser, CPP_CLOSE_BRACE, "`}'"); } return initializer; } / Parse an initializer-list. initializer-list: initializer-clause initializer-list , initializer-clause GNU Extension: initializer-list: identifier : initializer-clause initializer-list, identifier : initializer-clause Returns a VEC of constructor_elt. The VALUE of each elt is an expression for the initializer. If the INDEX of the elt is non-NULL, it is the IDENTIFIER_NODE naming the field to initialize. NON_CONSTANT_P is as for cp_parser_initializer. / static VEC(constructor_elt,gc) cp_parser_initializer_list (cp_parser* parser, bool* non_constant_p) { VEC(constructor_elt,gc) v = NULL; / Assume all of the expressions are constant. / non_constant_p = false; /* Parse the rest of the list. / while (true) { cp_token token; tree identifier; tree initializer; bool clause_non_constant_p; /* If the next token is an identifier and the following one is a colon, we are looking at the GNU designated-initializer syntax. / if (cp_parser_allow_gnu_extensions_p (parser) && cp_lexer_next_token_is (parser->lexer, CPP_NAME) && cp_lexer_peek_nth_token (parser->lexer, 2)->type == CPP_COLON) { / Warn the user that they are using an extension. / if (pedantic) pedwarn ("ISO C++ does not allow designated initializers"); / Consume the identifier. / identifier = cp_lexer_consume_token (parser->lexer)->u.value; / Consume the `:'. / cp_lexer_consume_token (parser->lexer); } else identifier = NULL_TREE; / Parse the initializer. / initializer = cp_parser_initializer_clause (parser, &clause_non_constant_p); / If any clause is non-constant, so is the entire initializer. / if (clause_non_constant_p) non_constant_p = true; /* Add it to the vector. / CONSTRUCTOR_APPEND_ELT(v, identifier, initializer); / If the next token is not a comma, we have reached the end of the list. / if (cp_lexer_next_token_is_not (parser->lexer, CPP_COMMA)) break; / Peek at the next token. / token = cp_lexer_peek_nth_token (parser->lexer, 2); / If the next token is a `}', then we're still done. An initializer-clause can have a trailing `,' after the initializer-list and before the closing `}'. / if (token->type == CPP_CLOSE_BRACE) break; / Consume the `,' token. / cp_lexer_consume_token (parser->lexer); } return v; } / Classes [gram.class] / / Parse a class-name. class-name: identifier template-id TYPENAME_KEYWORD_P is true iff the `typename' keyword has been used to indicate that names looked up in dependent types should be assumed to be types. TEMPLATE_KEYWORD_P is true iff the `template' keyword has been used to indicate that the name that appears next is a template. TAG_TYPE indicates the explicit tag given before the type name, if any. If CHECK_DEPENDENCY_P is FALSE, names are looked up in dependent scopes. If CLASS_HEAD_P is TRUE, this class is the class being defined in a class-head. Returns the TYPE_DECL representing the class. / static tree cp_parser_class_name (cp_parser parser, bool typename_keyword_p, bool template_keyword_p, enum tag_types tag_type, bool check_dependency_p, bool class_head_p, bool is_declaration) { tree decl; tree scope; bool typename_p; cp_token token; / All class-names start with an identifier. / token = cp_lexer_peek_token (parser->lexer); if (token->type != CPP_NAME && token->type != CPP_TEMPLATE_ID) { cp_parser_error (parser, "expected class-name"); return error_mark_node; } / PARSER->SCOPE can be cleared when parsing the template-arguments to a template-id, so we save it here. / scope = parser->scope; if (scope == error_mark_node) return error_mark_node; / Any name names a type if we're following the `typename' keyword in a qualified name where the enclosing scope is type-dependent. / typename_p = (typename_keyword_p && scope && TYPE_P (scope) && dependent_type_p (scope)); / Handle the common case (an identifier, but not a template-id) efficiently. / if (token->type == CPP_NAME && !cp_parser_nth_token_starts_template_argument_list_p (parser, 2)) { cp_token identifier_token; tree identifier; bool ambiguous_p; /* Look for the identifier. / identifier_token = cp_lexer_peek_token (parser->lexer); ambiguous_p = identifier_token->ambiguous_p; identifier = cp_parser_identifier (parser); / If the next token isn't an identifier, we are certainly not looking at a class-name. / if (identifier == error_mark_node) decl = error_mark_node; / If we know this is a type-name, there's no need to look it up. / else if (typename_p) decl = identifier; else { tree ambiguous_decls; / If we already know that this lookup is ambiguous, then we've already issued an error message; there's no reason to check again. / if (ambiguous_p) { cp_parser_simulate_error (parser); return error_mark_node; } / If the next token is a `::', then the name must be a type name. [basic.lookup.qual] During the lookup for a name preceding the :: scope resolution operator, object, function, and enumerator names are ignored. / if (cp_lexer_next_token_is (parser->lexer, CPP_SCOPE)) tag_type = typename_type; / Look up the name. / decl = cp_parser_lookup_name (parser, identifier, tag_type, /is_template=/false, /is_namespace=/false, check_dependency_p, &ambiguous_decls); if (ambiguous_decls) { error ("reference to %qD is ambiguous", identifier); print_candidates (ambiguous_decls); if (cp_parser_parsing_tentatively (parser)) { identifier_token->ambiguous_p = true; cp_parser_simulate_error (parser); } return error_mark_node; } } } else { / Try a template-id. / decl = cp_parser_template_id (parser, template_keyword_p, check_dependency_p, is_declaration); if (decl == error_mark_node) return error_mark_node; } decl = cp_parser_maybe_treat_template_as_class (decl, class_head_p); / If this is a typename, create a TYPENAME_TYPE. / if (typename_p && decl != error_mark_node) { decl = make_typename_type (scope, decl, typename_type, /complain=/tf_error); if (decl != error_mark_node) decl = TYPE_NAME (decl); } / Check to see that it is really the name of a class. / if (TREE_CODE (decl) == TEMPLATE_ID_EXPR && TREE_CODE (TREE_OPERAND (decl, 0)) == IDENTIFIER_NODE && cp_lexer_next_token_is (parser->lexer, CPP_SCOPE)) / Situations like this: template <typename T> struct A { typename T::template X<int>::I i; }; are problematic. Is `T::template X<int>' a class-name? The standard does not seem to be definitive, but there is no other valid interpretation of the following `::'. Therefore, those names are considered class-names. / { decl = make_typename_type (scope, decl, tag_type, tf_error); if (decl != error_mark_node) decl = TYPE_NAME (decl); } else if (TREE_CODE (decl) != TYPE_DECL \|\| TREE_TYPE (decl) == error_mark_node \|\| !IS_AGGR_TYPE (TREE_TYPE (decl))) decl = error_mark_node; if (decl == error_mark_node) cp_parser_error (parser, "expected class-name"); return decl; } / Parse a class-specifier. class-specifier: class-head { member-specification [opt] } Returns the TREE_TYPE representing the class. / static tree cp_parser_class_specifier (cp_parser parser) { cp_token token; tree type; tree attributes = NULL_TREE; int has_trailing_semicolon; bool nested_name_specifier_p; unsigned saved_num_template_parameter_lists; bool saved_in_function_body; tree old_scope = NULL_TREE; tree scope = NULL_TREE; tree bases; push_deferring_access_checks (dk_no_deferred); / Parse the class-head. / type = cp_parser_class_head (parser, &nested_name_specifier_p, &attributes, &bases); / If the class-head was a semantic disaster, skip the entire body of the class. / if (!type) { cp_parser_skip_to_end_of_block_or_statement (parser); pop_deferring_access_checks (); return error_mark_node; } / Look for the `{'. / if (!cp_parser_require (parser, CPP_OPEN_BRACE, "`{'")) { pop_deferring_access_checks (); return error_mark_node; } / Process the base classes. If they're invalid, skip the entire class body. / if (!xref_basetypes (type, bases)) { cp_parser_skip_to_closing_brace (parser); / Consuming the closing brace yields better error messages later on. / cp_lexer_consume_token (parser->lexer); pop_deferring_access_checks (); return error_mark_node; } / Issue an error message if type-definitions are forbidden here. / cp_parser_check_type_definition (parser); / Remember that we are defining one more class. / ++parser->num_classes_being_defined; / Inside the class, surrounding template-parameter-lists do not apply. / saved_num_template_parameter_lists = parser->num_template_parameter_lists; parser->num_template_parameter_lists = 0; / We are not in a function body. / saved_in_function_body = parser->in_function_body; parser->in_function_body = false; / Start the class. / if (nested_name_specifier_p) { scope = CP_DECL_CONTEXT (TYPE_MAIN_DECL (type)); old_scope = push_inner_scope (scope); } type = begin_class_definition (type, attributes); if (type == error_mark_node) / If the type is erroneous, skip the entire body of the class. / cp_parser_skip_to_closing_brace (parser); else / Parse the member-specification. / cp_parser_member_specification_opt (parser); / Look for the trailing `}'. / cp_parser_require (parser, CPP_CLOSE_BRACE, "`}'"); / We get better error messages by noticing a common problem: a missing trailing `;'. / token = cp_lexer_peek_token (parser->lexer); has_trailing_semicolon = (token->type == CPP_SEMICOLON); / Look for trailing attributes to apply to this class. / if (cp_parser_allow_gnu_extensions_p (parser)) attributes = cp_parser_attributes_opt (parser); if (type != error_mark_node) type = finish_struct (type, attributes); if (nested_name_specifier_p) pop_inner_scope (old_scope, scope); / If this class is not itself within the scope of another class, then we need to parse the bodies of all of the queued function definitions. Note that the queued functions defined in a class are not always processed immediately following the class-specifier for that class. Consider: struct A { struct B { void f() { sizeof (A); } }; }; If `f' were processed before the processing of `A' were completed, there would be no way to compute the size of `A'. Note that the nesting we are interested in here is lexical -- not the semantic nesting given by TYPE_CONTEXT. In particular, for: struct A { struct B; }; struct A::B { void f() { } }; there is no need to delay the parsing of `A::B::f'. / if (--parser->num_classes_being_defined == 0) { tree queue_entry; tree fn; tree class_type = NULL_TREE; tree pushed_scope = NULL_TREE; / In a first pass, parse default arguments to the functions. Then, in a second pass, parse the bodies of the functions. This two-phased approach handles cases like: struct S { void f() { g(); } void g(int i = 3); }; / for (TREE_PURPOSE (parser->unparsed_functions_queues) = nreverse (TREE_PURPOSE (parser->unparsed_functions_queues)); (queue_entry = TREE_PURPOSE (parser->unparsed_functions_queues)); TREE_PURPOSE (parser->unparsed_functions_queues) = TREE_CHAIN (TREE_PURPOSE (parser->unparsed_functions_queues))) { fn = TREE_VALUE (queue_entry); / If there are default arguments that have not yet been processed, take care of them now. / if (class_type != TREE_PURPOSE (queue_entry)) { if (pushed_scope) pop_scope (pushed_scope); class_type = TREE_PURPOSE (queue_entry); pushed_scope = push_scope (class_type); } / Make sure that any template parameters are in scope. / maybe_begin_member_template_processing (fn); / Parse the default argument expressions. / cp_parser_late_parsing_default_args (parser, fn); / Remove any template parameters from the symbol table. / maybe_end_member_template_processing (); } if (pushed_scope) pop_scope (pushed_scope); / Now parse the body of the functions. / for (TREE_VALUE (parser->unparsed_functions_queues) = nreverse (TREE_VALUE (parser->unparsed_functions_queues)); (queue_entry = TREE_VALUE (parser->unparsed_functions_queues)); TREE_VALUE (parser->unparsed_functions_queues) = TREE_CHAIN (TREE_VALUE (parser->unparsed_functions_queues))) { / Figure out which function we need to process. / fn = TREE_VALUE (queue_entry); / Parse the function. / cp_parser_late_parsing_for_member (parser, fn); } } / Put back any saved access checks. / pop_deferring_access_checks (); / Restore saved state. / parser->in_function_body = saved_in_function_body; parser->num_template_parameter_lists = saved_num_template_parameter_lists; return type; } / Parse a class-head. class-head: class-key identifier [opt] base-clause [opt] class-key nested-name-specifier identifier base-clause [opt] class-key nested-name-specifier [opt] template-id base-clause [opt] GNU Extensions: class-key attributes identifier [opt] base-clause [opt] class-key attributes nested-name-specifier identifier base-clause [opt] class-key attributes nested-name-specifier [opt] template-id base-clause [opt] Returns the TYPE of the indicated class. Sets NESTED_NAME_SPECIFIER_P to TRUE iff one of the productions involving a nested-name-specifier was used, and FALSE otherwise. Returns error_mark_node if this is not a class-head. Returns NULL_TREE if the class-head is syntactically valid, but semantically invalid in a way that means we should skip the entire body of the class. / static tree cp_parser_class_head (cp_parser* parser, bool* nested_name_specifier_p, tree attributes_p, tree bases) { tree nested_name_specifier; enum tag_types class_key; tree id = NULL_TREE; tree type = NULL_TREE; tree attributes; bool template_id_p = false; bool qualified_p = false; bool invalid_nested_name_p = false; bool invalid_explicit_specialization_p = false; tree pushed_scope = NULL_TREE; unsigned num_templates; /* Assume no nested-name-specifier will be present. / nested_name_specifier_p = false; /* Assume no template parameter lists will be used in defining the type. / num_templates = 0; / Look for the class-key. / class_key = cp_parser_class_key (parser); if (class_key == none_type) return error_mark_node; / Parse the attributes. / attributes = cp_parser_attributes_opt (parser); / If the next token is `::', that is invalid -- but sometimes people do try to write: struct ::S {}; Handle this gracefully by accepting the extra qualifier, and then issuing an error about it later if this really is a class-head. If it turns out just to be an elaborated type specifier, remain silent. / if (cp_parser_global_scope_opt (parser, /current_scope_valid_p=/false)) qualified_p = true; push_deferring_access_checks (dk_no_check); / Determine the name of the class. Begin by looking for an optional nested-name-specifier. / nested_name_specifier = cp_parser_nested_name_specifier_opt (parser, /typename_keyword_p=/false, /check_dependency_p=/false, /type_p=/false, /is_declaration=/false); / If there was a nested-name-specifier, then there must be an identifier. / if (nested_name_specifier) { / Although the grammar says `identifier', it really means `class-name' or `template-name'. You are only allowed to define a class that has already been declared with this syntax. The proposed resolution for Core Issue 180 says that wherever you see `class T::X' you should treat `X' as a type-name. It is OK to define an inaccessible class; for example: class A { class B; }; class A::B {}; We do not know if we will see a class-name, or a template-name. We look for a class-name first, in case the class-name is a template-id; if we looked for the template-name first we would stop after the template-name. / cp_parser_parse_tentatively (parser); type = cp_parser_class_name (parser, /typename_keyword_p=/false, /template_keyword_p=/false, class_type, /check_dependency_p=/false, /class_head_p=/true, /is_declaration=/false); / If that didn't work, ignore the nested-name-specifier. / if (!cp_parser_parse_definitely (parser)) { invalid_nested_name_p = true; id = cp_parser_identifier (parser); if (id == error_mark_node) id = NULL_TREE; } / If we could not find a corresponding TYPE, treat this declaration like an unqualified declaration. / if (type == error_mark_node) nested_name_specifier = NULL_TREE; / Otherwise, count the number of templates used in TYPE and its containing scopes. / else { tree scope; for (scope = TREE_TYPE (type); scope && TREE_CODE (scope) != NAMESPACE_DECL; scope = (TYPE_P (scope) ? TYPE_CONTEXT (scope) : DECL_CONTEXT (scope))) if (TYPE_P (scope) && CLASS_TYPE_P (scope) && CLASSTYPE_TEMPLATE_INFO (scope) && PRIMARY_TEMPLATE_P (CLASSTYPE_TI_TEMPLATE (scope)) && !CLASSTYPE_TEMPLATE_SPECIALIZATION (scope)) ++num_templates; } } / Otherwise, the identifier is optional. / else { / We don't know whether what comes next is a template-id, an identifier, or nothing at all. / cp_parser_parse_tentatively (parser); / Check for a template-id. / id = cp_parser_template_id (parser, /template_keyword_p=/false, /check_dependency_p=/true, /is_declaration=/true); / If that didn't work, it could still be an identifier. / if (!cp_parser_parse_definitely (parser)) { if (cp_lexer_next_token_is (parser->lexer, CPP_NAME)) id = cp_parser_identifier (parser); else id = NULL_TREE; } else { template_id_p = true; ++num_templates; } } pop_deferring_access_checks (); if (id) cp_parser_check_for_invalid_template_id (parser, id); / If it's not a `:' or a `{' then we can't really be looking at a class-head, since a class-head only appears as part of a class-specifier. We have to detect this situation before calling xref_tag, since that has irreversible side-effects. / if (!cp_parser_next_token_starts_class_definition_p (parser)) { cp_parser_error (parser, "expected %<{%> or %<:%>"); return error_mark_node; } / At this point, we're going ahead with the class-specifier, even if some other problem occurs. / cp_parser_commit_to_tentative_parse (parser); / Issue the error about the overly-qualified name now. / if (qualified_p) cp_parser_error (parser, "global qualification of class name is invalid"); else if (invalid_nested_name_p) cp_parser_error (parser, "qualified name does not name a class"); else if (nested_name_specifier) { tree scope; / Reject typedef-names in class heads. / if (!DECL_IMPLICIT_TYPEDEF_P (type)) { error ("invalid class name in declaration of %qD", type); type = NULL_TREE; goto done; } / Figure out in what scope the declaration is being placed. / scope = current_scope (); / If that scope does not contain the scope in which the class was originally declared, the program is invalid. / if (scope && !is_ancestor (scope, nested_name_specifier)) { error ("declaration of %qD in %qD which does not enclose %qD", type, scope, nested_name_specifier); type = NULL_TREE; goto done; } / [dcl.meaning] A declarator-id shall not be qualified exception of the definition of a ... nested class outside of its class ... [or] a the definition or explicit instantiation of a class member of a namespace outside of its namespace. / if (scope == nested_name_specifier) { pedwarn ("extra qualification ignored"); nested_name_specifier = NULL_TREE; num_templates = 0; } } / An explicit-specialization must be preceded by "template <>". If it is not, try to recover gracefully. / if (at_namespace_scope_p () && parser->num_template_parameter_lists == 0 && template_id_p) { error ("an explicit specialization must be preceded by %<template <>%>"); invalid_explicit_specialization_p = true; / Take the same action that would have been taken by cp_parser_explicit_specialization. / ++parser->num_template_parameter_lists; begin_specialization (); } / There must be no "return" statements between this point and the end of this function; set "type "to the correct return value and use "goto done;" to return. / / Make sure that the right number of template parameters were present. / if (!cp_parser_check_template_parameters (parser, num_templates)) { / If something went wrong, there is no point in even trying to process the class-definition. / type = NULL_TREE; goto done; } / Look up the type. / if (template_id_p) { type = TREE_TYPE (id); type = maybe_process_partial_specialization (type); if (nested_name_specifier) pushed_scope = push_scope (nested_name_specifier); } else if (nested_name_specifier) { tree class_type; / Given: template <typename T> struct S { struct T }; template <typename T> struct S<T>::T { }; we will get a TYPENAME_TYPE when processing the definition of `S::T'. We need to resolve it to the actual type before we try to define it. / if (TREE_CODE (TREE_TYPE (type)) == TYPENAME_TYPE) { class_type = resolve_typename_type (TREE_TYPE (type), /only_current_p=/false); if (class_type != error_mark_node) type = TYPE_NAME (class_type); else { cp_parser_error (parser, "could not resolve typename type"); type = error_mark_node; } } maybe_process_partial_specialization (TREE_TYPE (type)); class_type = current_class_type; / Enter the scope indicated by the nested-name-specifier. / pushed_scope = push_scope (nested_name_specifier); / Get the canonical version of this type. / type = TYPE_MAIN_DECL (TREE_TYPE (type)); if (PROCESSING_REAL_TEMPLATE_DECL_P () && !CLASSTYPE_TEMPLATE_SPECIALIZATION (TREE_TYPE (type))) { type = push_template_decl (type); if (type == error_mark_node) { type = NULL_TREE; goto done; } } type = TREE_TYPE (type); nested_name_specifier_p = true; } else /* The name is not a nested name. / { / If the class was unnamed, create a dummy name. / if (!id) id = make_anon_name (); type = xref_tag (class_key, id, /tag_scope=/ts_current, parser->num_template_parameter_lists); } / Indicate whether this class was declared as a `class' or as a `struct'. / if (TREE_CODE (type) == RECORD_TYPE) CLASSTYPE_DECLARED_CLASS (type) = (class_key == class_type); cp_parser_check_class_key (class_key, type); / If this type was already complete, and we see another definition, that's an error. / if (type != error_mark_node && COMPLETE_TYPE_P (type)) { error ("redefinition of %q#T", type); error ("previous definition of %q+#T", type); type = NULL_TREE; goto done; } else if (type == error_mark_node) type = NULL_TREE; / We will have entered the scope containing the class; the names of base classes should be looked up in that context. For example: struct A { struct B {}; struct C; }; struct A::C : B {}; is valid. / bases = NULL_TREE; /* Get the list of base-classes, if there is one. / if (cp_lexer_next_token_is (parser->lexer, CPP_COLON)) bases = cp_parser_base_clause (parser); done: /* Leave the scope given by the nested-name-specifier. We will enter the class scope itself while processing the members. / if (pushed_scope) pop_scope (pushed_scope); if (invalid_explicit_specialization_p) { end_specialization (); --parser->num_template_parameter_lists; } attributes_p = attributes; return type; } /* Parse a class-key. class-key: class struct union Returns the kind of class-key specified, or none_type to indicate error. / static enum tag_types cp_parser_class_key (cp_parser parser) { cp_token token; enum tag_types tag_type; / Look for the class-key. / token = cp_parser_require (parser, CPP_KEYWORD, "class-key"); if (!token) return none_type; / Check to see if the TOKEN is a class-key. / tag_type = cp_parser_token_is_class_key (token); if (!tag_type) cp_parser_error (parser, "expected class-key"); return tag_type; } / Parse an (optional) member-specification. member-specification: member-declaration member-specification [opt] access-specifier : member-specification [opt] / static void cp_parser_member_specification_opt (cp_parser parser) { while (true) { cp_token token; enum rid keyword; / Peek at the next token. / token = cp_lexer_peek_token (parser->lexer); / If it's a `}', or EOF then we've seen all the members. / if (token->type == CPP_CLOSE_BRACE \|\| token->type == CPP_EOF \|\| token->type == CPP_PRAGMA_EOL) break; / See if this token is a keyword. / keyword = token->keyword; switch (keyword) { case RID_PUBLIC: case RID_PROTECTED: case RID_PRIVATE: / Consume the access-specifier. / cp_lexer_consume_token (parser->lexer); / Remember which access-specifier is active. / current_access_specifier = token->u.value; / Look for the `:'. / cp_parser_require (parser, CPP_COLON, "`:'"); break; default: / Accept #pragmas at class scope. / if (token->type == CPP_PRAGMA) { cp_parser_pragma (parser, pragma_external); break; } / Otherwise, the next construction must be a member-declaration. / cp_parser_member_declaration (parser); } } } / Parse a member-declaration. member-declaration: decl-specifier-seq [opt] member-declarator-list [opt] ; function-definition ; [opt] :: [opt] nested-name-specifier template [opt] unqualified-id ; using-declaration template-declaration member-declarator-list: member-declarator member-declarator-list , member-declarator member-declarator: declarator pure-specifier [opt] declarator constant-initializer [opt] identifier [opt] : constant-expression GNU Extensions: member-declaration: __extension__ member-declaration member-declarator: declarator attributes [opt] pure-specifier [opt] declarator attributes [opt] constant-initializer [opt] identifier [opt] attributes [opt] : constant-expression / static void cp_parser_member_declaration (cp_parser parser) { cp_decl_specifier_seq decl_specifiers; tree prefix_attributes; tree decl; int declares_class_or_enum; bool friend_p; cp_token token; int saved_pedantic; / Check for the `__extension__' keyword. / if (cp_parser_extension_opt (parser, &saved_pedantic)) { / Recurse. / cp_parser_member_declaration (parser); / Restore the old value of the PEDANTIC flag. / pedantic = saved_pedantic; return; } / Check for a template-declaration. / if (cp_lexer_next_token_is_keyword (parser->lexer, RID_TEMPLATE)) { / An explicit specialization here is an error condition, and we expect the specialization handler to detect and report this. / if (cp_lexer_peek_nth_token (parser->lexer, 2)->type == CPP_LESS && cp_lexer_peek_nth_token (parser->lexer, 3)->type == CPP_GREATER) cp_parser_explicit_specialization (parser); else cp_parser_template_declaration (parser, /member_p=/true); return; } / Check for a using-declaration. / if (cp_lexer_next_token_is_keyword (parser->lexer, RID_USING)) { / Parse the using-declaration. / cp_parser_using_declaration (parser, /access_declaration_p=/false); return; } / Check for @defs. / if (cp_lexer_next_token_is_keyword (parser->lexer, RID_AT_DEFS)) { tree ivar, member; tree ivar_chains = cp_parser_objc_defs_expression (parser); ivar = ivar_chains; while (ivar) { member = ivar; ivar = TREE_CHAIN (member); TREE_CHAIN (member) = NULL_TREE; finish_member_declaration (member); } return; } if (cp_parser_using_declaration (parser, /access_declaration=/true)) return; / Parse the decl-specifier-seq. / cp_parser_decl_specifier_seq (parser, CP_PARSER_FLAGS_OPTIONAL, &decl_specifiers, &declares_class_or_enum); prefix_attributes = decl_specifiers.attributes; decl_specifiers.attributes = NULL_TREE; / Check for an invalid type-name. / if (!decl_specifiers.type && cp_parser_parse_and_diagnose_invalid_type_name (parser)) return; / If there is no declarator, then the decl-specifier-seq should specify a type. / if (cp_lexer_next_token_is (parser->lexer, CPP_SEMICOLON)) { / If there was no decl-specifier-seq, and the next token is a `;', then we have something like: struct S { ; }; [class.mem] Each member-declaration shall declare at least one member name of the class. / if (!decl_specifiers.any_specifiers_p) { cp_token token = cp_lexer_peek_token (parser->lexer); if (pedantic && !token->in_system_header) pedwarn ("%Hextra %<;%>", &token->location); } else { tree type; /* See if this declaration is a friend. / friend_p = cp_parser_friend_p (&decl_specifiers); / If there were decl-specifiers, check to see if there was a class-declaration. / type = check_tag_decl (&decl_specifiers); / Nested classes have already been added to the class, but a `friend' needs to be explicitly registered. / if (friend_p) { / If the `friend' keyword was present, the friend must be introduced with a class-key. / if (!declares_class_or_enum) error ("a class-key must be used when declaring a friend"); / In this case: template <typename T> struct A { friend struct A<T>::B; }; A<T>::B will be represented by a TYPENAME_TYPE, and therefore not recognized by check_tag_decl. / if (!type && decl_specifiers.type && TYPE_P (decl_specifiers.type)) type = decl_specifiers.type; if (!type \|\| !TYPE_P (type)) error ("friend declaration does not name a class or " "function"); else make_friend_class (current_class_type, type, /complain=/true); } / If there is no TYPE, an error message will already have been issued. / else if (!type \|\| type == error_mark_node) ; / An anonymous aggregate has to be handled specially; such a declaration really declares a data member (with a particular type), as opposed to a nested class. / else if (ANON_AGGR_TYPE_P (type)) { / Remove constructors and such from TYPE, now that we know it is an anonymous aggregate. / fixup_anonymous_aggr (type); / And make the corresponding data member. / decl = build_decl (FIELD_DECL, NULL_TREE, type); / Add it to the class. / finish_member_declaration (decl); } else cp_parser_check_access_in_redeclaration (TYPE_NAME (type)); } } else { / See if these declarations will be friends. / friend_p = cp_parser_friend_p (&decl_specifiers); / Keep going until we hit the `;' at the end of the declaration. / while (cp_lexer_next_token_is_not (parser->lexer, CPP_SEMICOLON)) { tree attributes = NULL_TREE; tree first_attribute; / Peek at the next token. / token = cp_lexer_peek_token (parser->lexer); / Check for a bitfield declaration. / if (token->type == CPP_COLON \|\| (token->type == CPP_NAME && cp_lexer_peek_nth_token (parser->lexer, 2)->type == CPP_COLON)) { tree identifier; tree width; / Get the name of the bitfield. Note that we cannot just check TOKEN here because it may have been invalidated by the call to cp_lexer_peek_nth_token above. / if (cp_lexer_peek_token (parser->lexer)->type != CPP_COLON) identifier = cp_parser_identifier (parser); else identifier = NULL_TREE; / Consume the `:' token. / cp_lexer_consume_token (parser->lexer); / Get the width of the bitfield. / width = cp_parser_constant_expression (parser, /allow_non_constant=/false, NULL); / Look for attributes that apply to the bitfield. / attributes = cp_parser_attributes_opt (parser); / Remember which attributes are prefix attributes and which are not. / first_attribute = attributes; / Combine the attributes. / attributes = chainon (prefix_attributes, attributes); / Create the bitfield declaration. / decl = grokbitfield (identifier ? make_id_declarator (NULL_TREE, identifier, sfk_none) : NULL, &decl_specifiers, width); / Apply the attributes. / cplus_decl_attributes (&decl, attributes, /flags=/0); } else { cp_declarator declarator; tree initializer; tree asm_specification; int ctor_dtor_or_conv_p; /* Parse the declarator. / declarator = cp_parser_declarator (parser, CP_PARSER_DECLARATOR_NAMED, &ctor_dtor_or_conv_p, /parenthesized_p=/NULL, /member_p=/true); / If something went wrong parsing the declarator, make sure that we at least consume some tokens. / if (declarator == cp_error_declarator) { / Skip to the end of the statement. / cp_parser_skip_to_end_of_statement (parser); / If the next token is not a semicolon, that is probably because we just skipped over the body of a function. So, we consume a semicolon if present, but do not issue an error message if it is not present. / if (cp_lexer_next_token_is (parser->lexer, CPP_SEMICOLON)) cp_lexer_consume_token (parser->lexer); return; } if (declares_class_or_enum & 2) cp_parser_check_for_definition_in_return_type (declarator, decl_specifiers.type); / Look for an asm-specification. / asm_specification = cp_parser_asm_specification_opt (parser); / Look for attributes that apply to the declaration. / attributes = cp_parser_attributes_opt (parser); / Remember which attributes are prefix attributes and which are not. / first_attribute = attributes; / Combine the attributes. / attributes = chainon (prefix_attributes, attributes); / If it's an `=', then we have a constant-initializer or a pure-specifier. It is not correct to parse the initializer before registering the member declaration since the member declaration should be in scope while its initializer is processed. However, the rest of the front end does not yet provide an interface that allows us to handle this correctly. / if (cp_lexer_next_token_is (parser->lexer, CPP_EQ)) { / In [class.mem]: A pure-specifier shall be used only in the declaration of a virtual function. A member-declarator can contain a constant-initializer only if it declares a static member of integral or enumeration type. Therefore, if the DECLARATOR is for a function, we look for a pure-specifier; otherwise, we look for a constant-initializer. When we call `grokfield', it will perform more stringent semantics checks. / if (function_declarator_p (declarator)) initializer = cp_parser_pure_specifier (parser); else / Parse the initializer. / initializer = cp_parser_constant_initializer (parser); } / Otherwise, there is no initializer. / else initializer = NULL_TREE; / See if we are probably looking at a function definition. We are certainly not looking at a member-declarator. Calling `grokfield' has side-effects, so we must not do it unless we are sure that we are looking at a member-declarator. / if (cp_parser_token_starts_function_definition_p (cp_lexer_peek_token (parser->lexer))) { / The grammar does not allow a pure-specifier to be used when a member function is defined. (It is possible that this fact is an oversight in the standard, since a pure function may be defined outside of the class-specifier. / if (initializer) error ("pure-specifier on function-definition"); decl = cp_parser_save_member_function_body (parser, &decl_specifiers, declarator, attributes); / If the member was not a friend, declare it here. / if (!friend_p) finish_member_declaration (decl); / Peek at the next token. / token = cp_lexer_peek_token (parser->lexer); / If the next token is a semicolon, consume it. / if (token->type == CPP_SEMICOLON) cp_lexer_consume_token (parser->lexer); return; } else / Create the declaration. / decl = grokfield (declarator, &decl_specifiers, initializer, /init_const_expr_p=/true, asm_specification, attributes); } / Reset PREFIX_ATTRIBUTES. / while (attributes && TREE_CHAIN (attributes) != first_attribute) attributes = TREE_CHAIN (attributes); if (attributes) TREE_CHAIN (attributes) = NULL_TREE; / If there is any qualification still in effect, clear it now; we will be starting fresh with the next declarator. / parser->scope = NULL_TREE; parser->qualifying_scope = NULL_TREE; parser->object_scope = NULL_TREE; / If it's a `,', then there are more declarators. / if (cp_lexer_next_token_is (parser->lexer, CPP_COMMA)) cp_lexer_consume_token (parser->lexer); / If the next token isn't a `;', then we have a parse error. / else if (cp_lexer_next_token_is_not (parser->lexer, CPP_SEMICOLON)) { cp_parser_error (parser, "expected %<;%>"); / Skip tokens until we find a `;'. / cp_parser_skip_to_end_of_statement (parser); break; } if (decl) { / Add DECL to the list of members. / if (!friend_p) finish_member_declaration (decl); if (TREE_CODE (decl) == FUNCTION_DECL) cp_parser_save_default_args (parser, decl); } } } cp_parser_require (parser, CPP_SEMICOLON, "`;'"); } / Parse a pure-specifier. pure-specifier: = 0 Returns INTEGER_ZERO_NODE if a pure specifier is found. Otherwise, ERROR_MARK_NODE is returned. / static tree cp_parser_pure_specifier (cp_parser parser) { cp_token token; / Look for the `=' token. / if (!cp_parser_require (parser, CPP_EQ, "`='")) return error_mark_node; / Look for the `0' token. / token = cp_lexer_consume_token (parser->lexer); / c_lex_with_flags marks a single digit '0' with PURE_ZERO. / if (token->type != CPP_NUMBER \|\| !(token->flags & PURE_ZERO)) { cp_parser_error (parser, "invalid pure specifier (only `= 0' is allowed)"); cp_parser_skip_to_end_of_statement (parser); return error_mark_node; } if (PROCESSING_REAL_TEMPLATE_DECL_P ()) { error ("templates may not be %<virtual%>"); return error_mark_node; } return integer_zero_node; } / Parse a constant-initializer. constant-initializer: = constant-expression Returns a representation of the constant-expression. / static tree cp_parser_constant_initializer (cp_parser parser) { /* Look for the `=' token. / if (!cp_parser_require (parser, CPP_EQ, "`='")) return error_mark_node; / It is invalid to write: struct S { static const int i = { 7 }; }; / if (cp_lexer_next_token_is (parser->lexer, CPP_OPEN_BRACE)) { cp_parser_error (parser, "a brace-enclosed initializer is not allowed here"); / Consume the opening brace. / cp_lexer_consume_token (parser->lexer); / Skip the initializer. / cp_parser_skip_to_closing_brace (parser); / Look for the trailing `}'. / cp_parser_require (parser, CPP_CLOSE_BRACE, "`}'"); return error_mark_node; } return cp_parser_constant_expression (parser, /allow_non_constant=/false, NULL); } / Derived classes [gram.class.derived] / / Parse a base-clause. base-clause: : base-specifier-list base-specifier-list: base-specifier base-specifier-list , base-specifier Returns a TREE_LIST representing the base-classes, in the order in which they were declared. The representation of each node is as described by cp_parser_base_specifier. In the case that no bases are specified, this function will return NULL_TREE, not ERROR_MARK_NODE. / static tree cp_parser_base_clause (cp_parser parser) { tree bases = NULL_TREE; /* Look for the `:' that begins the list. / cp_parser_require (parser, CPP_COLON, "`:'"); / Scan the base-specifier-list. / while (true) { cp_token token; tree base; /* Look for the base-specifier. / base = cp_parser_base_specifier (parser); / Add BASE to the front of the list. / if (base != error_mark_node) { TREE_CHAIN (base) = bases; bases = base; } / Peek at the next token. / token = cp_lexer_peek_token (parser->lexer); / If it's not a comma, then the list is complete. / if (token->type != CPP_COMMA) break; / Consume the `,'. / cp_lexer_consume_token (parser->lexer); } / PARSER->SCOPE may still be non-NULL at this point, if the last base class had a qualified name. However, the next name that appears is certainly not qualified. / parser->scope = NULL_TREE; parser->qualifying_scope = NULL_TREE; parser->object_scope = NULL_TREE; return nreverse (bases); } / Parse a base-specifier. base-specifier: :: [opt] nested-name-specifier [opt] class-name virtual access-specifier [opt] :: [opt] nested-name-specifier [opt] class-name access-specifier virtual [opt] :: [opt] nested-name-specifier [opt] class-name Returns a TREE_LIST. The TREE_PURPOSE will be one of ACCESS_{DEFAULT,PUBLIC,PROTECTED,PRIVATE}_[VIRTUAL]_NODE to indicate the specifiers provided. The TREE_VALUE will be a TYPE (or the ERROR_MARK_NODE) indicating the type that was specified. / static tree cp_parser_base_specifier (cp_parser parser) { cp_token token; bool done = false; bool virtual_p = false; bool duplicate_virtual_error_issued_p = false; bool duplicate_access_error_issued_p = false; bool class_scope_p, template_p; tree access = access_default_node; tree type; / Process the optional `virtual' and `access-specifier'. / while (!done) { / Peek at the next token. / token = cp_lexer_peek_token (parser->lexer); / Process `virtual'. / switch (token->keyword) { case RID_VIRTUAL: / If `virtual' appears more than once, issue an error. / if (virtual_p && !duplicate_virtual_error_issued_p) { cp_parser_error (parser, "%<virtual%> specified more than once in base-specified"); duplicate_virtual_error_issued_p = true; } virtual_p = true; / Consume the `virtual' token. / cp_lexer_consume_token (parser->lexer); break; case RID_PUBLIC: case RID_PROTECTED: case RID_PRIVATE: / If more than one access specifier appears, issue an error. / if (access != access_default_node && !duplicate_access_error_issued_p) { cp_parser_error (parser, "more than one access specifier in base-specified"); duplicate_access_error_issued_p = true; } access = ridpointers[(int) token->keyword]; / Consume the access-specifier. / cp_lexer_consume_token (parser->lexer); break; default: done = true; break; } } / It is not uncommon to see programs mechanically, erroneously, use the 'typename' keyword to denote (dependent) qualified types as base classes. / if (cp_lexer_next_token_is_keyword (parser->lexer, RID_TYPENAME)) { if (!processing_template_decl) error ("keyword %<typename%> not allowed outside of templates"); else error ("keyword %<typename%> not allowed in this context " "(the base class is implicitly a type)"); cp_lexer_consume_token (parser->lexer); } / Look for the optional `::' operator. / cp_parser_global_scope_opt (parser, /current_scope_valid_p=/false); / Look for the nested-name-specifier. The simplest way to implement: [temp.res] The keyword `typename' is not permitted in a base-specifier or mem-initializer; in these contexts a qualified name that depends on a template-parameter is implicitly assumed to be a type name. is to pretend that we have seen the `typename' keyword at this point. / cp_parser_nested_name_specifier_opt (parser, /typename_keyword_p=/true, /check_dependency_p=/true, typename_type, /is_declaration=/true); / If the base class is given by a qualified name, assume that names we see are type names or templates, as appropriate. / class_scope_p = (parser->scope && TYPE_P (parser->scope)); template_p = class_scope_p && cp_parser_optional_template_keyword (parser); / Finally, look for the class-name. / type = cp_parser_class_name (parser, class_scope_p, template_p, typename_type, /check_dependency_p=/true, /class_head_p=/false, /is_declaration=/true); if (type == error_mark_node) return error_mark_node; return finish_base_specifier (TREE_TYPE (type), access, virtual_p); } / Exception handling [gram.exception] / / Parse an (optional) exception-specification. exception-specification: throw ( type-id-list [opt] ) Returns a TREE_LIST representing the exception-specification. The TREE_VALUE of each node is a type. / static tree cp_parser_exception_specification_opt (cp_parser parser) { cp_token token; tree type_id_list; / Peek at the next token. / token = cp_lexer_peek_token (parser->lexer); / If it's not `throw', then there's no exception-specification. / if (!cp_parser_is_keyword (token, RID_THROW)) return NULL_TREE; / Consume the `throw'. / cp_lexer_consume_token (parser->lexer); / Look for the `('. / cp_parser_require (parser, CPP_OPEN_PAREN, "`('"); / Peek at the next token. / token = cp_lexer_peek_token (parser->lexer); / If it's not a `)', then there is a type-id-list. / if (token->type != CPP_CLOSE_PAREN) { const char saved_message; /* Types may not be defined in an exception-specification. / saved_message = parser->type_definition_forbidden_message; parser->type_definition_forbidden_message = "types may not be defined in an exception-specification"; / Parse the type-id-list. / type_id_list = cp_parser_type_id_list (parser); / Restore the saved message. / parser->type_definition_forbidden_message = saved_message; } else type_id_list = empty_except_spec; / Look for the `)'. / cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'"); return type_id_list; } / Parse an (optional) type-id-list. type-id-list: type-id type-id-list , type-id Returns a TREE_LIST. The TREE_VALUE of each node is a TYPE, in the order that the types were presented. / static tree cp_parser_type_id_list (cp_parser parser) { tree types = NULL_TREE; while (true) { cp_token token; tree type; / Get the next type-id. / type = cp_parser_type_id (parser); / Add it to the list. / types = add_exception_specifier (types, type, /complain=/1); / Peek at the next token. / token = cp_lexer_peek_token (parser->lexer); / If it is not a `,', we are done. / if (token->type != CPP_COMMA) break; / Consume the `,'. / cp_lexer_consume_token (parser->lexer); } return nreverse (types); } / Parse a try-block. try-block: try compound-statement handler-seq / static tree cp_parser_try_block (cp_parser parser) { tree try_block; cp_parser_require_keyword (parser, RID_TRY, "`try'"); try_block = begin_try_block (); cp_parser_compound_statement (parser, NULL, true); finish_try_block (try_block); cp_parser_handler_seq (parser); finish_handler_sequence (try_block); return try_block; } /* Parse a function-try-block. function-try-block: try ctor-initializer [opt] function-body handler-seq / static bool cp_parser_function_try_block (cp_parser parser) { tree compound_stmt; tree try_block; bool ctor_initializer_p; /* Look for the `try' keyword. / if (!cp_parser_require_keyword (parser, RID_TRY, "`try'")) return false; / Let the rest of the front-end know where we are. / try_block = begin_function_try_block (&compound_stmt); / Parse the function-body. / ctor_initializer_p = cp_parser_ctor_initializer_opt_and_function_body (parser); / We're done with the `try' part. / finish_function_try_block (try_block); / Parse the handlers. / cp_parser_handler_seq (parser); / We're done with the handlers. / finish_function_handler_sequence (try_block, compound_stmt); return ctor_initializer_p; } / Parse a handler-seq. handler-seq: handler handler-seq [opt] / static void cp_parser_handler_seq (cp_parser parser) { while (true) { cp_token token; / Parse the handler. / cp_parser_handler (parser); / Peek at the next token. / token = cp_lexer_peek_token (parser->lexer); / If it's not `catch' then there are no more handlers. / if (!cp_parser_is_keyword (token, RID_CATCH)) break; } } / Parse a handler. handler: catch ( exception-declaration ) compound-statement / static void cp_parser_handler (cp_parser parser) { tree handler; tree declaration; cp_parser_require_keyword (parser, RID_CATCH, "`catch'"); handler = begin_handler (); cp_parser_require (parser, CPP_OPEN_PAREN, "`('"); declaration = cp_parser_exception_declaration (parser); finish_handler_parms (declaration, handler); cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'"); cp_parser_compound_statement (parser, NULL, false); finish_handler (handler); } /* Parse an exception-declaration. exception-declaration: type-specifier-seq declarator type-specifier-seq abstract-declarator type-specifier-seq ... Returns a VAR_DECL for the declaration, or NULL_TREE if the ellipsis variant is used. / static tree cp_parser_exception_declaration (cp_parser parser) { cp_decl_specifier_seq type_specifiers; cp_declarator declarator; const char saved_message; /* If it's an ellipsis, it's easy to handle. / if (cp_lexer_next_token_is (parser->lexer, CPP_ELLIPSIS)) { / Consume the `...' token. / cp_lexer_consume_token (parser->lexer); return NULL_TREE; } / Types may not be defined in exception-declarations. / saved_message = parser->type_definition_forbidden_message; parser->type_definition_forbidden_message = "types may not be defined in exception-declarations"; / Parse the type-specifier-seq. / cp_parser_type_specifier_seq (parser, /is_condition=/false, &type_specifiers); / If it's a `)', then there is no declarator. / if (cp_lexer_next_token_is (parser->lexer, CPP_CLOSE_PAREN)) declarator = NULL; else declarator = cp_parser_declarator (parser, CP_PARSER_DECLARATOR_EITHER, /ctor_dtor_or_conv_p=/NULL, /parenthesized_p=/NULL, /member_p=/false); / Restore the saved message. / parser->type_definition_forbidden_message = saved_message; if (!type_specifiers.any_specifiers_p) return error_mark_node; return grokdeclarator (declarator, &type_specifiers, CATCHPARM, 1, NULL); } / Parse a throw-expression. throw-expression: throw assignment-expression [opt] Returns a THROW_EXPR representing the throw-expression. / static tree cp_parser_throw_expression (cp_parser parser) { tree expression; cp_token* token; cp_parser_require_keyword (parser, RID_THROW, "`throw'"); token = cp_lexer_peek_token (parser->lexer); /* Figure out whether or not there is an assignment-expression following the "throw" keyword. / if (token->type == CPP_COMMA \|\| token->type == CPP_SEMICOLON \|\| token->type == CPP_CLOSE_PAREN \|\| token->type == CPP_CLOSE_SQUARE \|\| token->type == CPP_CLOSE_BRACE \|\| token->type == CPP_COLON) expression = NULL_TREE; else expression = cp_parser_assignment_expression (parser, /cast_p=/false); return build_throw (expression); } / GNU Extensions / / Parse an (optional) asm-specification. asm-specification: asm ( string-literal ) If the asm-specification is present, returns a STRING_CST corresponding to the string-literal. Otherwise, returns NULL_TREE. / static tree cp_parser_asm_specification_opt (cp_parser parser) { cp_token token; tree asm_specification; / Peek at the next token. / token = cp_lexer_peek_token (parser->lexer); / If the next token isn't the `asm' keyword, then there's no asm-specification. / if (!cp_parser_is_keyword (token, RID_ASM)) return NULL_TREE; / Consume the `asm' token. / cp_lexer_consume_token (parser->lexer); / Look for the `('. / cp_parser_require (parser, CPP_OPEN_PAREN, "`('"); / Look for the string-literal. / asm_specification = cp_parser_string_literal (parser, false, false); / Look for the `)'. / cp_parser_require (parser, CPP_CLOSE_PAREN, "`('"); return asm_specification; } / Parse an asm-operand-list. asm-operand-list: asm-operand asm-operand-list , asm-operand asm-operand: string-literal ( expression ) [ string-literal ] string-literal ( expression ) Returns a TREE_LIST representing the operands. The TREE_VALUE of each node is the expression. The TREE_PURPOSE is itself a TREE_LIST whose TREE_PURPOSE is a STRING_CST for the bracketed string-literal (or NULL_TREE if not present) and whose TREE_VALUE is a STRING_CST for the string literal before the parenthesis. / static tree cp_parser_asm_operand_list (cp_parser parser) { tree asm_operands = NULL_TREE; while (true) { tree string_literal; tree expression; tree name; if (cp_lexer_next_token_is (parser->lexer, CPP_OPEN_SQUARE)) { /* Consume the `[' token. / cp_lexer_consume_token (parser->lexer); / Read the operand name. / name = cp_parser_identifier (parser); if (name != error_mark_node) name = build_string (IDENTIFIER_LENGTH (name), IDENTIFIER_POINTER (name)); / Look for the closing `]'. / cp_parser_require (parser, CPP_CLOSE_SQUARE, "`]'"); } else name = NULL_TREE; / Look for the string-literal. / string_literal = cp_parser_string_literal (parser, false, false); / Look for the `('. / cp_parser_require (parser, CPP_OPEN_PAREN, "`('"); / Parse the expression. / expression = cp_parser_expression (parser, /cast_p=/false); / Look for the `)'. / cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'"); / Add this operand to the list. / asm_operands = tree_cons (build_tree_list (name, string_literal), expression, asm_operands); / If the next token is not a `,', there are no more operands. / if (cp_lexer_next_token_is_not (parser->lexer, CPP_COMMA)) break; / Consume the `,'. / cp_lexer_consume_token (parser->lexer); } return nreverse (asm_operands); } / Parse an asm-clobber-list. asm-clobber-list: string-literal asm-clobber-list , string-literal Returns a TREE_LIST, indicating the clobbers in the order that they appeared. The TREE_VALUE of each node is a STRING_CST. / static tree cp_parser_asm_clobber_list (cp_parser parser) { tree clobbers = NULL_TREE; while (true) { tree string_literal; /* Look for the string literal. / string_literal = cp_parser_string_literal (parser, false, false); / Add it to the list. / clobbers = tree_cons (NULL_TREE, string_literal, clobbers); / If the next token is not a `,', then the list is complete. / if (cp_lexer_next_token_is_not (parser->lexer, CPP_COMMA)) break; / Consume the `,' token. / cp_lexer_consume_token (parser->lexer); } return clobbers; } / Parse an (optional) series of attributes. attributes: attributes attribute attribute: __attribute__ (( attribute-list [opt] )) The return value is as for cp_parser_attribute_list. / static tree cp_parser_attributes_opt (cp_parser parser) { tree attributes = NULL_TREE; while (true) { cp_token token; tree attribute_list; / Peek at the next token. / token = cp_lexer_peek_token (parser->lexer); / If it's not `__attribute__', then we're done. / if (token->keyword != RID_ATTRIBUTE) break; / Consume the `__attribute__' keyword. / cp_lexer_consume_token (parser->lexer); / Look for the two `(' tokens. / cp_parser_require (parser, CPP_OPEN_PAREN, "`('"); cp_parser_require (parser, CPP_OPEN_PAREN, "`('"); / Peek at the next token. / token = cp_lexer_peek_token (parser->lexer); if (token->type != CPP_CLOSE_PAREN) / Parse the attribute-list. / attribute_list = cp_parser_attribute_list (parser); else / If the next token is a `)', then there is no attribute list. / attribute_list = NULL; / Look for the two `)' tokens. / cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'"); cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'"); / Add these new attributes to the list. / attributes = chainon (attributes, attribute_list); } return attributes; } / Parse an attribute-list. attribute-list: attribute attribute-list , attribute attribute: identifier identifier ( identifier ) identifier ( identifier , expression-list ) identifier ( expression-list ) Returns a TREE_LIST, or NULL_TREE on error. Each node corresponds to an attribute. The TREE_PURPOSE of each node is the identifier indicating which attribute is in use. The TREE_VALUE represents the arguments, if any. / static tree cp_parser_attribute_list (cp_parser parser) { tree attribute_list = NULL_TREE; bool save_translate_strings_p = parser->translate_strings_p; parser->translate_strings_p = false; while (true) { cp_token token; tree identifier; tree attribute; / Look for the identifier. We also allow keywords here; for example `__attribute__ ((const))' is legal. / token = cp_lexer_peek_token (parser->lexer); if (token->type == CPP_NAME \|\| token->type == CPP_KEYWORD) { tree arguments = NULL_TREE; / Consume the token. / token = cp_lexer_consume_token (parser->lexer); / Save away the identifier that indicates which attribute this is. / identifier = token->u.value; attribute = build_tree_list (identifier, NULL_TREE); / Peek at the next token. / token = cp_lexer_peek_token (parser->lexer); / If it's an `(', then parse the attribute arguments. / if (token->type == CPP_OPEN_PAREN) { arguments = cp_parser_parenthesized_expression_list (parser, true, /cast_p=/false, /non_constant_p=/NULL); / Save the arguments away. / TREE_VALUE (attribute) = arguments; } if (arguments != error_mark_node) { / Add this attribute to the list. / TREE_CHAIN (attribute) = attribute_list; attribute_list = attribute; } token = cp_lexer_peek_token (parser->lexer); } / Now, look for more attributes. If the next token isn't a `,', we're done. / if (token->type != CPP_COMMA) break; / Consume the comma and keep going. / cp_lexer_consume_token (parser->lexer); } parser->translate_strings_p = save_translate_strings_p; / We built up the list in reverse order. / return nreverse (attribute_list); } / Parse an optional `__extension__' keyword. Returns TRUE if it is present, and FALSE otherwise. SAVED_PEDANTIC is set to the current value of the PEDANTIC flag, regardless of whether or not the `__extension__' keyword is present. The caller is responsible for restoring the value of the PEDANTIC flag. / static bool cp_parser_extension_opt (cp_parser* parser, int* saved_pedantic) { /* Save the old value of the PEDANTIC flag. / saved_pedantic = pedantic; if (cp_lexer_next_token_is_keyword (parser->lexer, RID_EXTENSION)) { /* Consume the `__extension__' token. / cp_lexer_consume_token (parser->lexer); / We're not being pedantic while the `__extension__' keyword is in effect. / pedantic = 0; return true; } return false; } / Parse a label declaration. label-declaration: __label__ label-declarator-seq ; label-declarator-seq: identifier , label-declarator-seq identifier / static void cp_parser_label_declaration (cp_parser parser) { /* Look for the `__label__' keyword. / cp_parser_require_keyword (parser, RID_LABEL, "`__label__'"); while (true) { tree identifier; / Look for an identifier. / identifier = cp_parser_identifier (parser); / If we failed, stop. / if (identifier == error_mark_node) break; / Declare it as a label. / finish_label_decl (identifier); / If the next token is a `;', stop. / if (cp_lexer_next_token_is (parser->lexer, CPP_SEMICOLON)) break; / Look for the `,' separating the label declarations. / cp_parser_require (parser, CPP_COMMA, "`,'"); } / Look for the final `;'. / cp_parser_require (parser, CPP_SEMICOLON, "`;'"); } / Support Functions / / Looks up NAME in the current scope, as given by PARSER->SCOPE. NAME should have one of the representations used for an id-expression. If NAME is the ERROR_MARK_NODE, the ERROR_MARK_NODE is returned. If PARSER->SCOPE is a dependent type, then a SCOPE_REF is returned. If NAME is a TEMPLATE_ID_EXPR, then it will be immediately returned; the name was already resolved when the TEMPLATE_ID_EXPR was formed. Abstractly, such entities should not be passed to this function, because they do not need to be looked up, but it is simpler to check for this special case here, rather than at the call-sites. In cases not explicitly covered above, this function returns a DECL, OVERLOAD, or baselink representing the result of the lookup. If there was no entity with the indicated NAME, the ERROR_MARK_NODE is returned. If TAG_TYPE is not NONE_TYPE, it indicates an explicit type keyword (e.g., "struct") that was used. In that case bindings that do not refer to types are ignored. If IS_TEMPLATE is TRUE, bindings that do not refer to templates are ignored. If IS_NAMESPACE is TRUE, bindings that do not refer to namespaces are ignored. If CHECK_DEPENDENCY is TRUE, names are not looked up in dependent types. If AMBIGUOUS_DECLS is non-NULL, AMBIGUOUS_DECLS is set to a TREE_LIST of candidates if name-lookup results in an ambiguity, and NULL_TREE otherwise. / static tree cp_parser_lookup_name (cp_parser parser, tree name, enum tag_types tag_type, bool is_template, bool is_namespace, bool check_dependency, tree ambiguous_decls) { int flags = 0; tree decl; tree object_type = parser->context->object_type; if (!cp_parser_uncommitted_to_tentative_parse_p (parser)) flags \|= LOOKUP_COMPLAIN; /* Assume that the lookup will be unambiguous. / if (ambiguous_decls) ambiguous_decls = NULL_TREE; /* Now that we have looked up the name, the OBJECT_TYPE (if any) is no longer valid. Note that if we are parsing tentatively, and the parse fails, OBJECT_TYPE will be automatically restored. / parser->context->object_type = NULL_TREE; if (name == error_mark_node) return error_mark_node; / A template-id has already been resolved; there is no lookup to do. / if (TREE_CODE (name) == TEMPLATE_ID_EXPR) return name; if (BASELINK_P (name)) { gcc_assert (TREE_CODE (BASELINK_FUNCTIONS (name)) == TEMPLATE_ID_EXPR); return name; } / A BIT_NOT_EXPR is used to represent a destructor. By this point, it should already have been checked to make sure that the name used matches the type being destroyed. / if (TREE_CODE (name) == BIT_NOT_EXPR) { tree type; / Figure out to which type this destructor applies. / if (parser->scope) type = parser->scope; else if (object_type) type = object_type; else type = current_class_type; / If that's not a class type, there is no destructor. / if (!type \|\| !CLASS_TYPE_P (type)) return error_mark_node; if (CLASSTYPE_LAZY_DESTRUCTOR (type)) lazily_declare_fn (sfk_destructor, type); if (!CLASSTYPE_DESTRUCTORS (type)) return error_mark_node; / If it was a class type, return the destructor. / return CLASSTYPE_DESTRUCTORS (type); } / By this point, the NAME should be an ordinary identifier. If the id-expression was a qualified name, the qualifying scope is stored in PARSER->SCOPE at this point. / gcc_assert (TREE_CODE (name) == IDENTIFIER_NODE); / Perform the lookup. / if (parser->scope) { bool dependent_p; if (parser->scope == error_mark_node) return error_mark_node; / If the SCOPE is dependent, the lookup must be deferred until the template is instantiated -- unless we are explicitly looking up names in uninstantiated templates. Even then, we cannot look up the name if the scope is not a class type; it might, for example, be a template type parameter. / dependent_p = (TYPE_P (parser->scope) && !(parser->in_declarator_p && currently_open_class (parser->scope)) && dependent_type_p (parser->scope)); if ((check_dependency \|\| !CLASS_TYPE_P (parser->scope)) && dependent_p) { if (tag_type) { tree type; / The resolution to Core Issue 180 says that `struct A::B' should be considered a type-name, even if `A' is dependent. / type = make_typename_type (parser->scope, name, tag_type, /complain=/tf_error); decl = TYPE_NAME (type); } else if (is_template && (cp_parser_next_token_ends_template_argument_p (parser) \|\| cp_lexer_next_token_is (parser->lexer, CPP_CLOSE_PAREN))) decl = make_unbound_class_template (parser->scope, name, NULL_TREE, /complain=/tf_error); else decl = build_qualified_name (/type=/NULL_TREE, parser->scope, name, is_template); } else { tree pushed_scope = NULL_TREE; / If PARSER->SCOPE is a dependent type, then it must be a class type, and we must not be checking dependencies; otherwise, we would have processed this lookup above. So that PARSER->SCOPE is not considered a dependent base by lookup_member, we must enter the scope here. / if (dependent_p) pushed_scope = push_scope (parser->scope); / If the PARSER->SCOPE is a template specialization, it may be instantiated during name lookup. In that case, errors may be issued. Even if we rollback the current tentative parse, those errors are valid. / decl = lookup_qualified_name (parser->scope, name, tag_type != none_type, /complain=/true); if (pushed_scope) pop_scope (pushed_scope); } parser->qualifying_scope = parser->scope; parser->object_scope = NULL_TREE; } else if (object_type) { tree object_decl = NULL_TREE; / Look up the name in the scope of the OBJECT_TYPE, unless the OBJECT_TYPE is not a class. / if (CLASS_TYPE_P (object_type)) / If the OBJECT_TYPE is a template specialization, it may be instantiated during name lookup. In that case, errors may be issued. Even if we rollback the current tentative parse, those errors are valid. / object_decl = lookup_member (object_type, name, /protect=/0, tag_type != none_type); / Look it up in the enclosing context, too. / decl = lookup_name_real (name, tag_type != none_type, /nonclass=/0, /block_p=/true, is_namespace, flags); parser->object_scope = object_type; parser->qualifying_scope = NULL_TREE; if (object_decl) decl = object_decl; } else { decl = lookup_name_real (name, tag_type != none_type, /nonclass=/0, /block_p=/true, is_namespace, flags); parser->qualifying_scope = NULL_TREE; parser->object_scope = NULL_TREE; } / If the lookup failed, let our caller know. / if (!decl \|\| decl == error_mark_node) return error_mark_node; / If it's a TREE_LIST, the result of the lookup was ambiguous. / if (TREE_CODE (decl) == TREE_LIST) { if (ambiguous_decls) ambiguous_decls = decl; /* The error message we have to print is too complicated for cp_parser_error, so we incorporate its actions directly. / if (!cp_parser_simulate_error (parser)) { error ("reference to %qD is ambiguous", name); print_candidates (decl); } return error_mark_node; } gcc_assert (DECL_P (decl) \|\| TREE_CODE (decl) == OVERLOAD \|\| TREE_CODE (decl) == SCOPE_REF \|\| TREE_CODE (decl) == UNBOUND_CLASS_TEMPLATE \|\| BASELINK_P (decl)); / If we have resolved the name of a member declaration, check to see if the declaration is accessible. When the name resolves to set of overloaded functions, accessibility is checked when overload resolution is done. During an explicit instantiation, access is not checked at all, as per [temp.explicit]. / if (DECL_P (decl)) check_accessibility_of_qualified_id (decl, object_type, parser->scope); return decl; } / Like cp_parser_lookup_name, but for use in the typical case where CHECK_ACCESS is TRUE, IS_TYPE is FALSE, IS_TEMPLATE is FALSE, IS_NAMESPACE is FALSE, and CHECK_DEPENDENCY is TRUE. / static tree cp_parser_lookup_name_simple (cp_parser parser, tree name) { return cp_parser_lookup_name (parser, name, none_type, /is_template=/false, /is_namespace=/false, /check_dependency=/true, /ambiguous_decls=/NULL); } /* If DECL is a TEMPLATE_DECL that can be treated like a TYPE_DECL in the current context, return the TYPE_DECL. If TAG_NAME_P is true, the DECL indicates the class being defined in a class-head, or declared in an elaborated-type-specifier. Otherwise, return DECL. / static tree cp_parser_maybe_treat_template_as_class (tree decl, bool tag_name_p) { / If the TEMPLATE_DECL is being declared as part of a class-head, the translation from TEMPLATE_DECL to TYPE_DECL occurs: struct A { template <typename T> struct B; }; template <typename T> struct A::B {}; Similarly, in an elaborated-type-specifier: namespace N { struct X{}; } struct A { template <typename T> friend struct N::X; }; However, if the DECL refers to a class type, and we are in the scope of the class, then the name lookup automatically finds the TYPE_DECL created by build_self_reference rather than a TEMPLATE_DECL. For example, in: template <class T> struct S { S s; }; there is no need to handle such case. / if (DECL_CLASS_TEMPLATE_P (decl) && tag_name_p) return DECL_TEMPLATE_RESULT (decl); return decl; } / If too many, or too few, template-parameter lists apply to the declarator, issue an error message. Returns TRUE if all went well, and FALSE otherwise. / static bool cp_parser_check_declarator_template_parameters (cp_parser parser, cp_declarator declarator) { unsigned num_templates; / We haven't seen any classes that involve template parameters yet. / num_templates = 0; switch (declarator->kind) { case cdk_id: if (declarator->u.id.qualifying_scope) { tree scope; tree member; scope = declarator->u.id.qualifying_scope; member = declarator->u.id.unqualified_name; while (scope && CLASS_TYPE_P (scope)) { / You're supposed to have one `template <...>' for every template class, but you don't need one for a full specialization. For example: template <class T> struct S{}; template <> struct S<int> { void f(); }; void S<int>::f () {} is correct; there shouldn't be a `template <>' for the definition of `S<int>::f'. / if (!CLASSTYPE_TEMPLATE_INFO (scope)) / If SCOPE does not have template information of any kind, then it is not a template, nor is it nested within a template. / break; if (explicit_class_specialization_p (scope)) break; if (PRIMARY_TEMPLATE_P (CLASSTYPE_TI_TEMPLATE (scope))) ++num_templates; scope = TYPE_CONTEXT (scope); } } else if (TREE_CODE (declarator->u.id.unqualified_name) == TEMPLATE_ID_EXPR) / If the DECLARATOR has the form `X<y>' then it uses one additional level of template parameters. / ++num_templates; return cp_parser_check_template_parameters (parser, num_templates); case cdk_function: case cdk_array: case cdk_pointer: case cdk_reference: case cdk_ptrmem: return (cp_parser_check_declarator_template_parameters (parser, declarator->declarator)); case cdk_error: return true; default: gcc_unreachable (); } return false; } / NUM_TEMPLATES were used in the current declaration. If that is invalid, return FALSE and issue an error messages. Otherwise, return TRUE. / static bool cp_parser_check_template_parameters (cp_parser parser, unsigned num_templates) { /* If there are more template classes than parameter lists, we have something like: template <class T> void S<T>::R<T>::f (); / if (parser->num_template_parameter_lists < num_templates) { error ("too few template-parameter-lists"); return false; } / If there are the same number of template classes and parameter lists, that's OK. / if (parser->num_template_parameter_lists == num_templates) return true; / If there are more, but only one more, then we are referring to a member template. That's OK too. / if (parser->num_template_parameter_lists == num_templates + 1) return true; / Otherwise, there are too many template parameter lists. We have something like: template <class T> template <class U> void S::f(); / error ("too many template-parameter-lists"); return false; } / Parse an optional `::' token indicating that the following name is from the global namespace. If so, PARSER->SCOPE is set to the GLOBAL_NAMESPACE. Otherwise, PARSER->SCOPE is set to NULL_TREE, unless CURRENT_SCOPE_VALID_P is TRUE, in which case it is left alone. Returns the new value of PARSER->SCOPE, if the `::' token is present, and NULL_TREE otherwise. / static tree cp_parser_global_scope_opt (cp_parser parser, bool current_scope_valid_p) { cp_token token; / Peek at the next token. / token = cp_lexer_peek_token (parser->lexer); / If we're looking at a `::' token then we're starting from the global namespace, not our current location. / if (token->type == CPP_SCOPE) { / Consume the `::' token. / cp_lexer_consume_token (parser->lexer); / Set the SCOPE so that we know where to start the lookup. / parser->scope = global_namespace; parser->qualifying_scope = global_namespace; parser->object_scope = NULL_TREE; return parser->scope; } else if (!current_scope_valid_p) { parser->scope = NULL_TREE; parser->qualifying_scope = NULL_TREE; parser->object_scope = NULL_TREE; } return NULL_TREE; } / Returns TRUE if the upcoming token sequence is the start of a constructor declarator. If FRIEND_P is true, the declarator is preceded by the `friend' specifier. / static bool cp_parser_constructor_declarator_p (cp_parser parser, bool friend_p) { bool constructor_p; tree type_decl = NULL_TREE; bool nested_name_p; cp_token next_token; / The common case is that this is not a constructor declarator, so try to avoid doing lots of work if at all possible. It's not valid declare a constructor at function scope. / if (parser->in_function_body) return false; / And only certain tokens can begin a constructor declarator. / next_token = cp_lexer_peek_token (parser->lexer); if (next_token->type != CPP_NAME && next_token->type != CPP_SCOPE && next_token->type != CPP_NESTED_NAME_SPECIFIER && next_token->type != CPP_TEMPLATE_ID) return false; / Parse tentatively; we are going to roll back all of the tokens consumed here. / cp_parser_parse_tentatively (parser); / Assume that we are looking at a constructor declarator. / constructor_p = true; / Look for the optional `::' operator. / cp_parser_global_scope_opt (parser, /current_scope_valid_p=/false); / Look for the nested-name-specifier. / nested_name_p = (cp_parser_nested_name_specifier_opt (parser, /typename_keyword_p=/false, /check_dependency_p=/false, /type_p=/false, /is_declaration=/false) != NULL_TREE); / Outside of a class-specifier, there must be a nested-name-specifier. / if (!nested_name_p && (!at_class_scope_p () \|\| !TYPE_BEING_DEFINED (current_class_type) \|\| friend_p)) constructor_p = false; / If we still think that this might be a constructor-declarator, look for a class-name. / if (constructor_p) { / If we have: template <typename T> struct S { S(); }; template <typename T> S<T>::S (); we must recognize that the nested `S' names a class. Similarly, for: template <typename T> S<T>::S<T> (); we must recognize that the nested `S' names a template. / type_decl = cp_parser_class_name (parser, /typename_keyword_p=/false, /template_keyword_p=/false, none_type, /check_dependency_p=/false, /class_head_p=/false, /is_declaration=/false); / If there was no class-name, then this is not a constructor. / constructor_p = !cp_parser_error_occurred (parser); } / If we're still considering a constructor, we have to see a `(', to begin the parameter-declaration-clause, followed by either a `)', an `...', or a decl-specifier. We need to check for a type-specifier to avoid being fooled into thinking that: S::S (f) (int); is a constructor. (It is actually a function named `f' that takes one parameter (of type `int') and returns a value of type `S::S'. / if (constructor_p && cp_parser_require (parser, CPP_OPEN_PAREN, "`('")) { if (cp_lexer_next_token_is_not (parser->lexer, CPP_CLOSE_PAREN) && cp_lexer_next_token_is_not (parser->lexer, CPP_ELLIPSIS) / A parameter declaration begins with a decl-specifier, which is either the "attribute" keyword, a storage class specifier, or (usually) a type-specifier. / && !cp_lexer_next_token_is_decl_specifier_keyword (parser->lexer)) { tree type; tree pushed_scope = NULL_TREE; unsigned saved_num_template_parameter_lists; / Names appearing in the type-specifier should be looked up in the scope of the class. / if (current_class_type) type = NULL_TREE; else { type = TREE_TYPE (type_decl); if (TREE_CODE (type) == TYPENAME_TYPE) { type = resolve_typename_type (type, /only_current_p=/false); if (type == error_mark_node) { cp_parser_abort_tentative_parse (parser); return false; } } pushed_scope = push_scope (type); } / Inside the constructor parameter list, surrounding template-parameter-lists do not apply. / saved_num_template_parameter_lists = parser->num_template_parameter_lists; parser->num_template_parameter_lists = 0; / Look for the type-specifier. / cp_parser_type_specifier (parser, CP_PARSER_FLAGS_NONE, /decl_specs=/NULL, /is_declarator=/true, /declares_class_or_enum=/NULL, /is_cv_qualifier=/NULL); parser->num_template_parameter_lists = saved_num_template_parameter_lists; / Leave the scope of the class. / if (pushed_scope) pop_scope (pushed_scope); constructor_p = !cp_parser_error_occurred (parser); } } else constructor_p = false; / We did not really want to consume any tokens. / cp_parser_abort_tentative_parse (parser); return constructor_p; } / Parse the definition of the function given by the DECL_SPECIFIERS, ATTRIBUTES, and DECLARATOR. The access checks have been deferred; they must be performed once we are in the scope of the function. Returns the function defined. / static tree cp_parser_function_definition_from_specifiers_and_declarator (cp_parser parser, cp_decl_specifier_seq decl_specifiers, tree attributes, const cp_declarator declarator) { tree fn; bool success_p; /* Begin the function-definition. / success_p = start_function (decl_specifiers, declarator, attributes); / The things we're about to see are not directly qualified by any template headers we've seen thus far. / reset_specialization (); / If there were names looked up in the decl-specifier-seq that we did not check, check them now. We must wait until we are in the scope of the function to perform the checks, since the function might be a friend. / perform_deferred_access_checks (); if (!success_p) { / Skip the entire function. / cp_parser_skip_to_end_of_block_or_statement (parser); fn = error_mark_node; } else fn = cp_parser_function_definition_after_declarator (parser, /inline_p=/false); return fn; } / Parse the part of a function-definition that follows the declarator. INLINE_P is TRUE iff this function is an inline function defined with a class-specifier. Returns the function defined. / static tree cp_parser_function_definition_after_declarator (cp_parser parser, bool inline_p) { tree fn; bool ctor_initializer_p = false; bool saved_in_unbraced_linkage_specification_p; bool saved_in_function_body; unsigned saved_num_template_parameter_lists; saved_in_function_body = parser->in_function_body; parser->in_function_body = true; /* If the next token is `return', then the code may be trying to make use of the "named return value" extension that G++ used to support. / if (cp_lexer_next_token_is_keyword (parser->lexer, RID_RETURN)) { / Consume the `return' keyword. / cp_lexer_consume_token (parser->lexer); / Look for the identifier that indicates what value is to be returned. / cp_parser_identifier (parser); / Issue an error message. / error ("named return values are no longer supported"); / Skip tokens until we reach the start of the function body. / while (true) { cp_token token = cp_lexer_peek_token (parser->lexer); if (token->type == CPP_OPEN_BRACE \|\| token->type == CPP_EOF \|\| token->type == CPP_PRAGMA_EOL) break; cp_lexer_consume_token (parser->lexer); } } /* The `extern' in `extern "C" void f () { ... }' does not apply to anything declared inside `f'. / saved_in_unbraced_linkage_specification_p = parser->in_unbraced_linkage_specification_p; parser->in_unbraced_linkage_specification_p = false; / Inside the function, surrounding template-parameter-lists do not apply. / saved_num_template_parameter_lists = parser->num_template_parameter_lists; parser->num_template_parameter_lists = 0; / If the next token is `try', then we are looking at a function-try-block. / if (cp_lexer_next_token_is_keyword (parser->lexer, RID_TRY)) ctor_initializer_p = cp_parser_function_try_block (parser); / A function-try-block includes the function-body, so we only do this next part if we're not processing a function-try-block. / else ctor_initializer_p = cp_parser_ctor_initializer_opt_and_function_body (parser); / Finish the function. / fn = finish_function ((ctor_initializer_p ? 1 : 0) \| (inline_p ? 2 : 0)); / Generate code for it, if necessary. / expand_or_defer_fn (fn); / Restore the saved values. / parser->in_unbraced_linkage_specification_p = saved_in_unbraced_linkage_specification_p; parser->num_template_parameter_lists = saved_num_template_parameter_lists; parser->in_function_body = saved_in_function_body; return fn; } / Parse a template-declaration, assuming that the `export' (and `extern') keywords, if present, has already been scanned. MEMBER_P is as for cp_parser_template_declaration. / static void cp_parser_template_declaration_after_export (cp_parser parser, bool member_p) { tree decl = NULL_TREE; VEC (deferred_access_check,gc) checks; tree parameter_list; bool friend_p = false; bool need_lang_pop; / Look for the `template' keyword. / if (!cp_parser_require_keyword (parser, RID_TEMPLATE, "`template'")) return; / And the `<'. / if (!cp_parser_require (parser, CPP_LESS, "`<'")) return; if (at_class_scope_p () && current_function_decl) { / 14.5.2.2 [temp.mem] A local class shall not have member templates. / error ("invalid declaration of member template in local class"); cp_parser_skip_to_end_of_block_or_statement (parser); return; } / [temp] A template ... shall not have C linkage. / if (current_lang_name == lang_name_c) { error ("template with C linkage"); / Give it C++ linkage to avoid confusing other parts of the front end. / push_lang_context (lang_name_cplusplus); need_lang_pop = true; } else need_lang_pop = false; / We cannot perform access checks on the template parameter declarations until we know what is being declared, just as we cannot check the decl-specifier list. / push_deferring_access_checks (dk_deferred); / If the next token is `>', then we have an invalid specialization. Rather than complain about an invalid template parameter, issue an error message here. / if (cp_lexer_next_token_is (parser->lexer, CPP_GREATER)) { cp_parser_error (parser, "invalid explicit specialization"); begin_specialization (); parameter_list = NULL_TREE; } else / Parse the template parameters. / parameter_list = cp_parser_template_parameter_list (parser); / Get the deferred access checks from the parameter list. These will be checked once we know what is being declared, as for a member template the checks must be performed in the scope of the class containing the member. / checks = get_deferred_access_checks (); / Look for the `>'. / cp_parser_skip_to_end_of_template_parameter_list (parser); / We just processed one more parameter list. / ++parser->num_template_parameter_lists; / If the next token is `template', there are more template parameters. / if (cp_lexer_next_token_is_keyword (parser->lexer, RID_TEMPLATE)) cp_parser_template_declaration_after_export (parser, member_p); else { / There are no access checks when parsing a template, as we do not know if a specialization will be a friend. / push_deferring_access_checks (dk_no_check); decl = cp_parser_single_declaration (parser, checks, member_p, &friend_p); pop_deferring_access_checks (); / If this is a member template declaration, let the front end know. / if (member_p && !friend_p && decl) { if (TREE_CODE (decl) == TYPE_DECL) cp_parser_check_access_in_redeclaration (decl); decl = finish_member_template_decl (decl); } else if (friend_p && decl && TREE_CODE (decl) == TYPE_DECL) make_friend_class (current_class_type, TREE_TYPE (decl), /complain=/true); } / We are done with the current parameter list. / --parser->num_template_parameter_lists; pop_deferring_access_checks (); / Finish up. / finish_template_decl (parameter_list); / Register member declarations. / if (member_p && !friend_p && decl && !DECL_CLASS_TEMPLATE_P (decl)) finish_member_declaration (decl); / For the erroneous case of a template with C linkage, we pushed an implicit C++ linkage scope; exit that scope now. / if (need_lang_pop) pop_lang_context (); / If DECL is a function template, we must return to parse it later. (Even though there is no definition, there might be default arguments that need handling.) / if (member_p && decl && (TREE_CODE (decl) == FUNCTION_DECL \|\| DECL_FUNCTION_TEMPLATE_P (decl))) TREE_VALUE (parser->unparsed_functions_queues) = tree_cons (NULL_TREE, decl, TREE_VALUE (parser->unparsed_functions_queues)); } / Perform the deferred access checks from a template-parameter-list. CHECKS is a TREE_LIST of access checks, as returned by get_deferred_access_checks. / static void cp_parser_perform_template_parameter_access_checks (VEC (deferred_access_check,gc) checks) { ++processing_template_parmlist; perform_access_checks (checks); --processing_template_parmlist; } /* Parse a `decl-specifier-seq [opt] init-declarator [opt] ;' or `function-definition' sequence. MEMBER_P is true, this declaration appears in a class scope. Returns the DECL for the declared entity. If FRIEND_P is non-NULL, FRIEND_P is set to TRUE iff the declaration is a friend. / static tree cp_parser_single_declaration (cp_parser* parser, VEC (deferred_access_check,gc)* checks, bool member_p, bool* friend_p) { int declares_class_or_enum; tree decl = NULL_TREE; cp_decl_specifier_seq decl_specifiers; bool function_definition_p = false; /* This function is only used when processing a template declaration. / gcc_assert (innermost_scope_kind () == sk_template_parms \|\| innermost_scope_kind () == sk_template_spec); / Defer access checks until we know what is being declared. / push_deferring_access_checks (dk_deferred); / Try the `decl-specifier-seq [opt] init-declarator [opt]' alternative. / cp_parser_decl_specifier_seq (parser, CP_PARSER_FLAGS_OPTIONAL, &decl_specifiers, &declares_class_or_enum); if (friend_p) friend_p = cp_parser_friend_p (&decl_specifiers); /* There are no template typedefs. / if (decl_specifiers.specs[(int) ds_typedef]) { error ("template declaration of %qs", "typedef"); decl = error_mark_node; } / Gather up the access checks that occurred the decl-specifier-seq. / stop_deferring_access_checks (); / Check for the declaration of a template class. / if (declares_class_or_enum) { if (cp_parser_declares_only_class_p (parser)) { decl = shadow_tag (&decl_specifiers); / In this case: struct C { friend template <typename T> struct A<T>::B; }; A<T>::B will be represented by a TYPENAME_TYPE, and therefore not recognized by shadow_tag. / if (friend_p && friend_p && !decl && decl_specifiers.type && TYPE_P (decl_specifiers.type)) decl = decl_specifiers.type; if (decl && decl != error_mark_node) decl = TYPE_NAME (decl); else decl = error_mark_node; /* Perform access checks for template parameters. / cp_parser_perform_template_parameter_access_checks (checks); } } / If it's not a template class, try for a template function. If the next token is a `;', then this declaration does not declare anything. But, if there were errors in the decl-specifiers, then the error might well have come from an attempted class-specifier. In that case, there's no need to warn about a missing declarator. / if (!decl && (cp_lexer_next_token_is_not (parser->lexer, CPP_SEMICOLON) \|\| decl_specifiers.type != error_mark_node)) decl = cp_parser_init_declarator (parser, &decl_specifiers, checks, /function_definition_allowed_p=/true, member_p, declares_class_or_enum, &function_definition_p); pop_deferring_access_checks (); / Clear any current qualification; whatever comes next is the start of something new. / parser->scope = NULL_TREE; parser->qualifying_scope = NULL_TREE; parser->object_scope = NULL_TREE; / Look for a trailing `;' after the declaration. / if (!function_definition_p && (decl == error_mark_node \|\| !cp_parser_require (parser, CPP_SEMICOLON, "`;'"))) cp_parser_skip_to_end_of_block_or_statement (parser); return decl; } / Parse a cast-expression that is not the operand of a unary "&". / static tree cp_parser_simple_cast_expression (cp_parser parser) { return cp_parser_cast_expression (parser, /address_p=/false, /cast_p=/false); } /* Parse a functional cast to TYPE. Returns an expression representing the cast. / static tree cp_parser_functional_cast (cp_parser parser, tree type) { tree expression_list; tree cast; expression_list = cp_parser_parenthesized_expression_list (parser, false, /cast_p=/true, /non_constant_p=/NULL); cast = build_functional_cast (type, expression_list); /* [expr.const]/1: In an integral constant expression "only type conversions to integral or enumeration type can be used". / if (TREE_CODE (type) == TYPE_DECL) type = TREE_TYPE (type); if (cast != error_mark_node && !cast_valid_in_integral_constant_expression_p (type) && (cp_parser_non_integral_constant_expression (parser, "a call to a constructor"))) return error_mark_node; return cast; } / Save the tokens that make up the body of a member function defined in a class-specifier. The DECL_SPECIFIERS and DECLARATOR have already been parsed. The ATTRIBUTES are any GNU "__attribute__" specifiers applied to the declaration. Returns the FUNCTION_DECL for the member function. / static tree cp_parser_save_member_function_body (cp_parser parser, cp_decl_specifier_seq decl_specifiers, cp_declarator declarator, tree attributes) { cp_token first; cp_token last; tree fn; /* Create the function-declaration. / fn = start_method (decl_specifiers, declarator, attributes); / If something went badly wrong, bail out now. / if (fn == error_mark_node) { / If there's a function-body, skip it. / if (cp_parser_token_starts_function_definition_p (cp_lexer_peek_token (parser->lexer))) cp_parser_skip_to_end_of_block_or_statement (parser); return error_mark_node; } / Remember it, if there default args to post process. / cp_parser_save_default_args (parser, fn); / Save away the tokens that make up the body of the function. / first = parser->lexer->next_token; cp_parser_cache_group (parser, CPP_CLOSE_BRACE, /depth=/0); / Handle function try blocks. / while (cp_lexer_next_token_is_keyword (parser->lexer, RID_CATCH)) cp_parser_cache_group (parser, CPP_CLOSE_BRACE, /depth=/0); last = parser->lexer->next_token; / Save away the inline definition; we will process it when the class is complete. / DECL_PENDING_INLINE_INFO (fn) = cp_token_cache_new (first, last); DECL_PENDING_INLINE_P (fn) = 1; / We need to know that this was defined in the class, so that friend templates are handled correctly. / DECL_INITIALIZED_IN_CLASS_P (fn) = 1; / We're done with the inline definition. / finish_method (fn); / Add FN to the queue of functions to be parsed later. / TREE_VALUE (parser->unparsed_functions_queues) = tree_cons (NULL_TREE, fn, TREE_VALUE (parser->unparsed_functions_queues)); return fn; } / Parse a template-argument-list, as well as the trailing ">" (but not the opening ">"). See cp_parser_template_argument_list for the return value. / static tree cp_parser_enclosed_template_argument_list (cp_parser parser) { tree arguments; tree saved_scope; tree saved_qualifying_scope; tree saved_object_scope; bool saved_greater_than_is_operator_p; bool saved_skip_evaluation; /* [temp.names] When parsing a template-id, the first non-nested `>' is taken as the end of the template-argument-list rather than a greater-than operator. / saved_greater_than_is_operator_p = parser->greater_than_is_operator_p; parser->greater_than_is_operator_p = false; / Parsing the argument list may modify SCOPE, so we save it here. / saved_scope = parser->scope; saved_qualifying_scope = parser->qualifying_scope; saved_object_scope = parser->object_scope; / We need to evaluate the template arguments, even though this template-id may be nested within a "sizeof". / saved_skip_evaluation = skip_evaluation; skip_evaluation = false; / Parse the template-argument-list itself. / if (cp_lexer_next_token_is (parser->lexer, CPP_GREATER)) arguments = NULL_TREE; else arguments = cp_parser_template_argument_list (parser); / Look for the `>' that ends the template-argument-list. If we find a '>>' instead, it's probably just a typo. / if (cp_lexer_next_token_is (parser->lexer, CPP_RSHIFT)) { if (!saved_greater_than_is_operator_p) { / If we're in a nested template argument list, the '>>' has to be a typo for '> >'. We emit the error message, but we continue parsing and we push a '>' as next token, so that the argument list will be parsed correctly. Note that the global source location is still on the token before the '>>', so we need to say explicitly where we want it. / cp_token token = cp_lexer_peek_token (parser->lexer); error ("%H%<>>%> should be %<> >%> " "within a nested template argument list", &token->location); /* ??? Proper recovery should terminate two levels of template argument list here. / token->type = CPP_GREATER; } else { / If this is not a nested template argument list, the '>>' is a typo for '>'. Emit an error message and continue. Same deal about the token location, but here we can get it right by consuming the '>>' before issuing the diagnostic. / cp_lexer_consume_token (parser->lexer); error ("spurious %<>>%>, use %<>%> to terminate " "a template argument list"); } } else cp_parser_skip_to_end_of_template_parameter_list (parser); / The `>' token might be a greater-than operator again now. / parser->greater_than_is_operator_p = saved_greater_than_is_operator_p; / Restore the SAVED_SCOPE. / parser->scope = saved_scope; parser->qualifying_scope = saved_qualifying_scope; parser->object_scope = saved_object_scope; skip_evaluation = saved_skip_evaluation; return arguments; } / MEMBER_FUNCTION is a member function, or a friend. If default arguments, or the body of the function have not yet been parsed, parse them now. / static void cp_parser_late_parsing_for_member (cp_parser parser, tree member_function) { /* If this member is a template, get the underlying FUNCTION_DECL. / if (DECL_FUNCTION_TEMPLATE_P (member_function)) member_function = DECL_TEMPLATE_RESULT (member_function); / There should not be any class definitions in progress at this point; the bodies of members are only parsed outside of all class definitions. / gcc_assert (parser->num_classes_being_defined == 0); / While we're parsing the member functions we might encounter more classes. We want to handle them right away, but we don't want them getting mixed up with functions that are currently in the queue. / parser->unparsed_functions_queues = tree_cons (NULL_TREE, NULL_TREE, parser->unparsed_functions_queues); / Make sure that any template parameters are in scope. / maybe_begin_member_template_processing (member_function); / If the body of the function has not yet been parsed, parse it now. / if (DECL_PENDING_INLINE_P (member_function)) { tree function_scope; cp_token_cache tokens; /* The function is no longer pending; we are processing it. / tokens = DECL_PENDING_INLINE_INFO (member_function); DECL_PENDING_INLINE_INFO (member_function) = NULL; DECL_PENDING_INLINE_P (member_function) = 0; / If this is a local class, enter the scope of the containing function. / function_scope = current_function_decl; if (function_scope) push_function_context_to (function_scope); / Push the body of the function onto the lexer stack. / cp_parser_push_lexer_for_tokens (parser, tokens); / Let the front end know that we going to be defining this function. / start_preparsed_function (member_function, NULL_TREE, SF_PRE_PARSED \| SF_INCLASS_INLINE); / Don't do access checking if it is a templated function. / if (processing_template_decl) push_deferring_access_checks (dk_no_check); / Now, parse the body of the function. / cp_parser_function_definition_after_declarator (parser, /inline_p=/true); if (processing_template_decl) pop_deferring_access_checks (); / Leave the scope of the containing function. / if (function_scope) pop_function_context_from (function_scope); cp_parser_pop_lexer (parser); } / Remove any template parameters from the symbol table. / maybe_end_member_template_processing (); / Restore the queue. / parser->unparsed_functions_queues = TREE_CHAIN (parser->unparsed_functions_queues); } / If DECL contains any default args, remember it on the unparsed functions queue. / static void cp_parser_save_default_args (cp_parser parser, tree decl) { tree probe; for (probe = TYPE_ARG_TYPES (TREE_TYPE (decl)); probe; probe = TREE_CHAIN (probe)) if (TREE_PURPOSE (probe)) { TREE_PURPOSE (parser->unparsed_functions_queues) = tree_cons (current_class_type, decl, TREE_PURPOSE (parser->unparsed_functions_queues)); break; } } /* FN is a FUNCTION_DECL which may contains a parameter with an unparsed DEFAULT_ARG. Parse the default args now. This function assumes that the current scope is the scope in which the default argument should be processed. / static void cp_parser_late_parsing_default_args (cp_parser parser, tree fn) { bool saved_local_variables_forbidden_p; tree parm; /* While we're parsing the default args, we might (due to the statement expression extension) encounter more classes. We want to handle them right away, but we don't want them getting mixed up with default args that are currently in the queue. / parser->unparsed_functions_queues = tree_cons (NULL_TREE, NULL_TREE, parser->unparsed_functions_queues); / Local variable names (and the `this' keyword) may not appear in a default argument. / saved_local_variables_forbidden_p = parser->local_variables_forbidden_p; parser->local_variables_forbidden_p = true; for (parm = TYPE_ARG_TYPES (TREE_TYPE (fn)); parm; parm = TREE_CHAIN (parm)) { cp_token_cache tokens; tree default_arg = TREE_PURPOSE (parm); tree parsed_arg; VEC(tree,gc) insts; tree copy; unsigned ix; if (!default_arg) continue; if (TREE_CODE (default_arg) != DEFAULT_ARG) / This can happen for a friend declaration for a function already declared with default arguments. / continue; / Push the saved tokens for the default argument onto the parser's lexer stack. / tokens = DEFARG_TOKENS (default_arg); cp_parser_push_lexer_for_tokens (parser, tokens); / Parse the assignment-expression. / parsed_arg = cp_parser_assignment_expression (parser, /cast_p=/false); if (!processing_template_decl) parsed_arg = check_default_argument (TREE_VALUE (parm), parsed_arg); TREE_PURPOSE (parm) = parsed_arg; / Update any instantiations we've already created. / for (insts = DEFARG_INSTANTIATIONS (default_arg), ix = 0; VEC_iterate (tree, insts, ix, copy); ix++) TREE_PURPOSE (copy) = parsed_arg; / If the token stream has not been completely used up, then there was extra junk after the end of the default argument. / if (!cp_lexer_next_token_is (parser->lexer, CPP_EOF)) cp_parser_error (parser, "expected %<,%>"); / Revert to the main lexer. / cp_parser_pop_lexer (parser); } / Make sure no default arg is missing. / check_default_args (fn); / Restore the state of local_variables_forbidden_p. / parser->local_variables_forbidden_p = saved_local_variables_forbidden_p; / Restore the queue. / parser->unparsed_functions_queues = TREE_CHAIN (parser->unparsed_functions_queues); } / Parse the operand of `sizeof' (or a similar operator). Returns either a TYPE or an expression, depending on the form of the input. The KEYWORD indicates which kind of expression we have encountered. / static tree cp_parser_sizeof_operand (cp_parser parser, enum rid keyword) { static const char format; tree expr = NULL_TREE; const char saved_message; bool saved_integral_constant_expression_p; bool saved_non_integral_constant_expression_p; /* Initialize FORMAT the first time we get here. / if (!format) format = "types may not be defined in '%s' expressions"; / Types cannot be defined in a `sizeof' expression. Save away the old message. / saved_message = parser->type_definition_forbidden_message; / And create the new one. / parser->type_definition_forbidden_message = XNEWVEC (const char, strlen (format) + strlen (IDENTIFIER_POINTER (ridpointers[keyword])) + 1 / `\0' /); sprintf ((char ) parser->type_definition_forbidden_message, format, IDENTIFIER_POINTER (ridpointers[keyword])); /* The restrictions on constant-expressions do not apply inside sizeof expressions. / saved_integral_constant_expression_p = parser->integral_constant_expression_p; saved_non_integral_constant_expression_p = parser->non_integral_constant_expression_p; parser->integral_constant_expression_p = false; / Do not actually evaluate the expression. / ++skip_evaluation; / If it's a `(', then we might be looking at the type-id construction. / if (cp_lexer_next_token_is (parser->lexer, CPP_OPEN_PAREN)) { tree type; bool saved_in_type_id_in_expr_p; / We can't be sure yet whether we're looking at a type-id or an expression. / cp_parser_parse_tentatively (parser); / Consume the `('. / cp_lexer_consume_token (parser->lexer); / Parse the type-id. / saved_in_type_id_in_expr_p = parser->in_type_id_in_expr_p; parser->in_type_id_in_expr_p = true; type = cp_parser_type_id (parser); parser->in_type_id_in_expr_p = saved_in_type_id_in_expr_p; / Now, look for the trailing `)'. / cp_parser_require (parser, CPP_CLOSE_PAREN, "%<)%>"); / If all went well, then we're done. / if (cp_parser_parse_definitely (parser)) { cp_decl_specifier_seq decl_specs; / Build a trivial decl-specifier-seq. / clear_decl_specs (&decl_specs); decl_specs.type = type; / Call grokdeclarator to figure out what type this is. / expr = grokdeclarator (NULL, &decl_specs, TYPENAME, /initialized=/0, /attrlist=/NULL); } } / If the type-id production did not work out, then we must be looking at the unary-expression production. / if (!expr) expr = cp_parser_unary_expression (parser, /address_p=/false, /cast_p=/false); / Go back to evaluating expressions. / --skip_evaluation; / Free the message we created. / free ((char ) parser->type_definition_forbidden_message); /* And restore the old one. / parser->type_definition_forbidden_message = saved_message; parser->integral_constant_expression_p = saved_integral_constant_expression_p; parser->non_integral_constant_expression_p = saved_non_integral_constant_expression_p; return expr; } / If the current declaration has no declarator, return true. / static bool cp_parser_declares_only_class_p (cp_parser parser) { /* If the next token is a `;' or a `,' then there is no declarator. / return (cp_lexer_next_token_is (parser->lexer, CPP_SEMICOLON) \|\| cp_lexer_next_token_is (parser->lexer, CPP_COMMA)); } / Update the DECL_SPECS to reflect the storage class indicated by KEYWORD. / static void cp_parser_set_storage_class (cp_parser parser, cp_decl_specifier_seq decl_specs, enum rid keyword) { cp_storage_class storage_class; if (parser->in_unbraced_linkage_specification_p) { error ("invalid use of %qD in linkage specification", ridpointers[keyword]); return; } else if (decl_specs->storage_class != sc_none) { decl_specs->conflicting_specifiers_p = true; return; } if ((keyword == RID_EXTERN \|\| keyword == RID_STATIC) && decl_specs->specs[(int) ds_thread]) { error ("%<__thread%> before %qD", ridpointers[keyword]); decl_specs->specs[(int) ds_thread] = 0; } switch (keyword) { case RID_AUTO: storage_class = sc_auto; break; case RID_REGISTER: storage_class = sc_register; break; case RID_STATIC: storage_class = sc_static; break; case RID_EXTERN: storage_class = sc_extern; break; case RID_MUTABLE: storage_class = sc_mutable; break; default: gcc_unreachable (); } decl_specs->storage_class = storage_class; / A storage class specifier cannot be applied alongside a typedef specifier. If there is a typedef specifier present then set conflicting_specifiers_p which will trigger an error later on in grokdeclarator. / if (decl_specs->specs[(int)ds_typedef]) decl_specs->conflicting_specifiers_p = true; } / Update the DECL_SPECS to reflect the TYPE_SPEC. If USER_DEFINED_P is true, the type is a user-defined type; otherwise it is a built-in type specified by a keyword. / static void cp_parser_set_decl_spec_type (cp_decl_specifier_seq decl_specs, tree type_spec, bool user_defined_p) { decl_specs->any_specifiers_p = true; /* If the user tries to redeclare bool or wchar_t (with, for example, in "typedef int wchar_t;") we remember that this is what happened. In system headers, we ignore these declarations so that G++ can work with system headers that are not C++-safe. / if (decl_specs->specs[(int) ds_typedef] && !user_defined_p && (type_spec == boolean_type_node \|\| type_spec == wchar_type_node) && (decl_specs->type \|\| decl_specs->specs[(int) ds_long] \|\| decl_specs->specs[(int) ds_short] \|\| decl_specs->specs[(int) ds_unsigned] \|\| decl_specs->specs[(int) ds_signed])) { decl_specs->redefined_builtin_type = type_spec; if (!decl_specs->type) { decl_specs->type = type_spec; decl_specs->user_defined_type_p = false; } } else if (decl_specs->type) decl_specs->multiple_types_p = true; else { decl_specs->type = type_spec; decl_specs->user_defined_type_p = user_defined_p; decl_specs->redefined_builtin_type = NULL_TREE; } } / DECL_SPECIFIERS is the representation of a decl-specifier-seq. Returns TRUE iff `friend' appears among the DECL_SPECIFIERS. / static bool cp_parser_friend_p (const cp_decl_specifier_seq decl_specifiers) { return decl_specifiers->specs[(int) ds_friend] != 0; } /* If the next token is of the indicated TYPE, consume it. Otherwise, issue an error message indicating that TOKEN_DESC was expected. Returns the token consumed, if the token had the appropriate type. Otherwise, returns NULL. / static cp_token cp_parser_require (cp_parser* parser, enum cpp_ttype type, const char* token_desc) { if (cp_lexer_next_token_is (parser->lexer, type)) return cp_lexer_consume_token (parser->lexer); else { /* Output the MESSAGE -- unless we're parsing tentatively. / if (!cp_parser_simulate_error (parser)) { char message = concat ("expected ", token_desc, NULL); cp_parser_error (parser, message); free (message); } return NULL; } } /* An error message is produced if the next token is not '>'. All further tokens are skipped until the desired token is found or '{', '}', ';' or an unbalanced ')' or ']'. / static void cp_parser_skip_to_end_of_template_parameter_list (cp_parser parser) { /* Current level of '< ... >'. / unsigned level = 0; / Ignore '<' and '>' nested inside '( ... )' or '[ ... ]'. / unsigned nesting_depth = 0; / Are we ready, yet? If not, issue error message. / if (cp_parser_require (parser, CPP_GREATER, "%<>%>")) return; / Skip tokens until the desired token is found. / while (true) { / Peek at the next token. / switch (cp_lexer_peek_token (parser->lexer)->type) { case CPP_LESS: if (!nesting_depth) ++level; break; case CPP_GREATER: if (!nesting_depth && level-- == 0) { / We've reached the token we want, consume it and stop. / cp_lexer_consume_token (parser->lexer); return; } break; case CPP_OPEN_PAREN: case CPP_OPEN_SQUARE: ++nesting_depth; break; case CPP_CLOSE_PAREN: case CPP_CLOSE_SQUARE: if (nesting_depth-- == 0) return; break; case CPP_EOF: case CPP_PRAGMA_EOL: case CPP_SEMICOLON: case CPP_OPEN_BRACE: case CPP_CLOSE_BRACE: / The '>' was probably forgotten, don't look further. / return; default: break; } / Consume this token. / cp_lexer_consume_token (parser->lexer); } } / If the next token is the indicated keyword, consume it. Otherwise, issue an error message indicating that TOKEN_DESC was expected. Returns the token consumed, if the token had the appropriate type. Otherwise, returns NULL. / static cp_token cp_parser_require_keyword (cp_parser* parser, enum rid keyword, const char* token_desc) { cp_token token = cp_parser_require (parser, CPP_KEYWORD, token_desc); if (token && token->keyword != keyword) { dyn_string_t error_msg; / Format the error message. / error_msg = dyn_string_new (0); dyn_string_append_cstr (error_msg, "expected "); dyn_string_append_cstr (error_msg, token_desc); cp_parser_error (parser, error_msg->s); dyn_string_delete (error_msg); return NULL; } return token; } / Returns TRUE iff TOKEN is a token that can begin the body of a function-definition. / static bool cp_parser_token_starts_function_definition_p (cp_token token) { return (/* An ordinary function-body begins with an `{'. / token->type == CPP_OPEN_BRACE / A ctor-initializer begins with a `:'. / \|\| token->type == CPP_COLON / A function-try-block begins with `try'. / \|\| token->keyword == RID_TRY / The named return value extension begins with `return'. / \|\| token->keyword == RID_RETURN); } / Returns TRUE iff the next token is the ":" or "{" beginning a class definition. / static bool cp_parser_next_token_starts_class_definition_p (cp_parser parser) { cp_token token; token = cp_lexer_peek_token (parser->lexer); return (token->type == CPP_OPEN_BRACE \|\| token->type == CPP_COLON); } / Returns TRUE iff the next token is the "," or ">" ending a template-argument. / static bool cp_parser_next_token_ends_template_argument_p (cp_parser parser) { cp_token token; token = cp_lexer_peek_token (parser->lexer); return (token->type == CPP_COMMA \|\| token->type == CPP_GREATER); } / Returns TRUE iff the n-th token is a "<", or the n-th is a "[" and the (n+1)-th is a ":" (which is a possible digraph typo for "< ::"). / static bool cp_parser_nth_token_starts_template_argument_list_p (cp_parser parser, size_t n) { cp_token token; token = cp_lexer_peek_nth_token (parser->lexer, n); if (token->type == CPP_LESS) return true; / Check for the sequence `<::' in the original code. It would be lexed as `[:', where `[' is a digraph, and there is no whitespace before `:'. / if (token->type == CPP_OPEN_SQUARE && token->flags & DIGRAPH) { cp_token token2; token2 = cp_lexer_peek_nth_token (parser->lexer, n+1); if (token2->type == CPP_COLON && !(token2->flags & PREV_WHITE)) return true; } return false; } /* Returns the kind of tag indicated by TOKEN, if it is a class-key, or none_type otherwise. / static enum tag_types cp_parser_token_is_class_key (cp_token token) { switch (token->keyword) { case RID_CLASS: return class_type; case RID_STRUCT: return record_type; case RID_UNION: return union_type; default: return none_type; } } /* Issue an error message if the CLASS_KEY does not match the TYPE. / static void cp_parser_check_class_key (enum tag_types class_key, tree type) { if ((TREE_CODE (type) == UNION_TYPE) != (class_key == union_type)) pedwarn ("%qs tag used in naming %q#T", class_key == union_type ? "union" : class_key == record_type ? "struct" : "class", type); } / Issue an error message if DECL is redeclared with different access than its original declaration [class.access.spec/3]. This applies to nested classes and nested class templates. [class.mem/1]. / static void cp_parser_check_access_in_redeclaration (tree decl) { if (!CLASS_TYPE_P (TREE_TYPE (decl))) return; if ((TREE_PRIVATE (decl) != (current_access_specifier == access_private_node)) \|\| (TREE_PROTECTED (decl) != (current_access_specifier == access_protected_node))) error ("%qD redeclared with different access", decl); } / Look for the `template' keyword, as a syntactic disambiguator. Return TRUE iff it is present, in which case it will be consumed. / static bool cp_parser_optional_template_keyword (cp_parser parser) { if (cp_lexer_next_token_is_keyword (parser->lexer, RID_TEMPLATE)) { /* The `template' keyword can only be used within templates; outside templates the parser can always figure out what is a template and what is not. / if (!processing_template_decl) { error ("%<template%> (as a disambiguator) is only allowed " "within templates"); / If this part of the token stream is rescanned, the same error message would be generated. So, we purge the token from the stream. / cp_lexer_purge_token (parser->lexer); return false; } else { / Consume the `template' keyword. / cp_lexer_consume_token (parser->lexer); return true; } } return false; } / The next token is a CPP_NESTED_NAME_SPECIFIER. Consume the token, set PARSER->SCOPE, and perform other related actions. / static void cp_parser_pre_parsed_nested_name_specifier (cp_parser parser) { int i; struct tree_check check_value; deferred_access_check chk; VEC (deferred_access_check,gc) checks; / Get the stored value. / check_value = cp_lexer_consume_token (parser->lexer)->u.tree_check_value; / Perform any access checks that were deferred. / checks = check_value->checks; if (checks) { for (i = 0 ; VEC_iterate (deferred_access_check, checks, i, chk) ; ++i) { perform_or_defer_access_check (chk->binfo, chk->decl, chk->diag_decl); } } / Set the scope from the stored value. / parser->scope = check_value->value; parser->qualifying_scope = check_value->qualifying_scope; parser->object_scope = NULL_TREE; } / Consume tokens up through a non-nested END token. / static void cp_parser_cache_group (cp_parser parser, enum cpp_ttype end, unsigned depth) { while (true) { cp_token token; / Abort a parenthesized expression if we encounter a brace. / if ((end == CPP_CLOSE_PAREN \|\| depth == 0) && cp_lexer_next_token_is (parser->lexer, CPP_SEMICOLON)) return; / If we've reached the end of the file, stop. / if (cp_lexer_next_token_is (parser->lexer, CPP_EOF) \|\| (end != CPP_PRAGMA_EOL && cp_lexer_next_token_is (parser->lexer, CPP_PRAGMA_EOL))) return; / Consume the next token. / token = cp_lexer_consume_token (parser->lexer); / See if it starts a new group. / if (token->type == CPP_OPEN_BRACE) { cp_parser_cache_group (parser, CPP_CLOSE_BRACE, depth + 1); if (depth == 0) return; } else if (token->type == CPP_OPEN_PAREN) cp_parser_cache_group (parser, CPP_CLOSE_PAREN, depth + 1); else if (token->type == CPP_PRAGMA) cp_parser_cache_group (parser, CPP_PRAGMA_EOL, depth + 1); else if (token->type == end) return; } } / Begin parsing tentatively. We always save tokens while parsing tentatively so that if the tentative parsing fails we can restore the tokens. / static void cp_parser_parse_tentatively (cp_parser parser) { /* Enter a new parsing context. / parser->context = cp_parser_context_new (parser->context); / Begin saving tokens. / cp_lexer_save_tokens (parser->lexer); / In order to avoid repetitive access control error messages, access checks are queued up until we are no longer parsing tentatively. / push_deferring_access_checks (dk_deferred); } / Commit to the currently active tentative parse. / static void cp_parser_commit_to_tentative_parse (cp_parser parser) { cp_parser_context context; cp_lexer lexer; /* Mark all of the levels as committed. / lexer = parser->lexer; for (context = parser->context; context->next; context = context->next) { if (context->status == CP_PARSER_STATUS_KIND_COMMITTED) break; context->status = CP_PARSER_STATUS_KIND_COMMITTED; while (!cp_lexer_saving_tokens (lexer)) lexer = lexer->next; cp_lexer_commit_tokens (lexer); } } / Abort the currently active tentative parse. All consumed tokens will be rolled back, and no diagnostics will be issued. / static void cp_parser_abort_tentative_parse (cp_parser parser) { cp_parser_simulate_error (parser); /* Now, pretend that we want to see if the construct was successfully parsed. / cp_parser_parse_definitely (parser); } / Stop parsing tentatively. If a parse error has occurred, restore the token stream. Otherwise, commit to the tokens we have consumed. Returns true if no error occurred; false otherwise. / static bool cp_parser_parse_definitely (cp_parser parser) { bool error_occurred; cp_parser_context context; / Remember whether or not an error occurred, since we are about to destroy that information. / error_occurred = cp_parser_error_occurred (parser); / Remove the topmost context from the stack. / context = parser->context; parser->context = context->next; / If no parse errors occurred, commit to the tentative parse. / if (!error_occurred) { / Commit to the tokens read tentatively, unless that was already done. / if (context->status != CP_PARSER_STATUS_KIND_COMMITTED) cp_lexer_commit_tokens (parser->lexer); pop_to_parent_deferring_access_checks (); } / Otherwise, if errors occurred, roll back our state so that things are just as they were before we began the tentative parse. / else { cp_lexer_rollback_tokens (parser->lexer); pop_deferring_access_checks (); } / Add the context to the front of the free list. / context->next = cp_parser_context_free_list; cp_parser_context_free_list = context; return !error_occurred; } / Returns true if we are parsing tentatively and are not committed to this tentative parse. / static bool cp_parser_uncommitted_to_tentative_parse_p (cp_parser parser) { return (cp_parser_parsing_tentatively (parser) && parser->context->status != CP_PARSER_STATUS_KIND_COMMITTED); } /* Returns nonzero iff an error has occurred during the most recent tentative parse. / static bool cp_parser_error_occurred (cp_parser parser) { return (cp_parser_parsing_tentatively (parser) && parser->context->status == CP_PARSER_STATUS_KIND_ERROR); } /* Returns nonzero if GNU extensions are allowed. / static bool cp_parser_allow_gnu_extensions_p (cp_parser parser) { return parser->allow_gnu_extensions_p; } /* Objective-C++ Productions / / Parse an Objective-C expression, which feeds into a primary-expression above. objc-expression: objc-message-expression objc-string-literal objc-encode-expression objc-protocol-expression objc-selector-expression Returns a tree representation of the expression. / static tree cp_parser_objc_expression (cp_parser parser) { /* Try to figure out what kind of declaration is present. / cp_token kwd = cp_lexer_peek_token (parser->lexer); switch (kwd->type) { case CPP_OPEN_SQUARE: return cp_parser_objc_message_expression (parser); case CPP_OBJC_STRING: kwd = cp_lexer_consume_token (parser->lexer); return objc_build_string_object (kwd->u.value); case CPP_KEYWORD: switch (kwd->keyword) { case RID_AT_ENCODE: return cp_parser_objc_encode_expression (parser); case RID_AT_PROTOCOL: return cp_parser_objc_protocol_expression (parser); case RID_AT_SELECTOR: return cp_parser_objc_selector_expression (parser); default: break; } default: error ("misplaced %<@%D%> Objective-C++ construct", kwd->u.value); cp_parser_skip_to_end_of_block_or_statement (parser); } return error_mark_node; } /* Parse an Objective-C message expression. objc-message-expression: [ objc-message-receiver objc-message-args ] Returns a representation of an Objective-C message. / static tree cp_parser_objc_message_expression (cp_parser parser) { tree receiver, messageargs; cp_lexer_consume_token (parser->lexer); /* Eat '['. / receiver = cp_parser_objc_message_receiver (parser); messageargs = cp_parser_objc_message_args (parser); cp_parser_require (parser, CPP_CLOSE_SQUARE, "`]'"); return objc_build_message_expr (build_tree_list (receiver, messageargs)); } / Parse an objc-message-receiver. objc-message-receiver: expression simple-type-specifier Returns a representation of the type or expression. / static tree cp_parser_objc_message_receiver (cp_parser parser) { tree rcv; /* An Objective-C message receiver may be either (1) a type or (2) an expression. / cp_parser_parse_tentatively (parser); rcv = cp_parser_expression (parser, false); if (cp_parser_parse_definitely (parser)) return rcv; rcv = cp_parser_simple_type_specifier (parser, /decl_specs=/NULL, CP_PARSER_FLAGS_NONE); return objc_get_class_reference (rcv); } / Parse the arguments and selectors comprising an Objective-C message. objc-message-args: objc-selector objc-selector-args objc-selector-args , objc-comma-args objc-selector-args: objc-selector [opt] : assignment-expression objc-selector-args objc-selector [opt] : assignment-expression objc-comma-args: assignment-expression objc-comma-args , assignment-expression Returns a TREE_LIST, with TREE_PURPOSE containing a list of selector arguments and TREE_VALUE containing a list of comma arguments. / static tree cp_parser_objc_message_args (cp_parser parser) { tree sel_args = NULL_TREE, addl_args = NULL_TREE; bool maybe_unary_selector_p = true; cp_token token = cp_lexer_peek_token (parser->lexer); while (cp_parser_objc_selector_p (token->type) \|\| token->type == CPP_COLON) { tree selector = NULL_TREE, arg; if (token->type != CPP_COLON) selector = cp_parser_objc_selector (parser); / Detect if we have a unary selector. / if (maybe_unary_selector_p && cp_lexer_next_token_is_not (parser->lexer, CPP_COLON)) return build_tree_list (selector, NULL_TREE); maybe_unary_selector_p = false; cp_parser_require (parser, CPP_COLON, "`:'"); arg = cp_parser_assignment_expression (parser, false); sel_args = chainon (sel_args, build_tree_list (selector, arg)); token = cp_lexer_peek_token (parser->lexer); } / Handle non-selector arguments, if any. / while (token->type == CPP_COMMA) { tree arg; cp_lexer_consume_token (parser->lexer); arg = cp_parser_assignment_expression (parser, false); addl_args = chainon (addl_args, build_tree_list (NULL_TREE, arg)); token = cp_lexer_peek_token (parser->lexer); } return build_tree_list (sel_args, addl_args); } / Parse an Objective-C encode expression. objc-encode-expression: @encode objc-typename Returns an encoded representation of the type argument. / static tree cp_parser_objc_encode_expression (cp_parser parser) { tree type; cp_lexer_consume_token (parser->lexer); /* Eat '@encode'. / cp_parser_require (parser, CPP_OPEN_PAREN, "`('"); type = complete_type (cp_parser_type_id (parser)); cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'"); if (!type) { error ("%<@encode%> must specify a type as an argument"); return error_mark_node; } return objc_build_encode_expr (type); } / Parse an Objective-C @defs expression. / static tree cp_parser_objc_defs_expression (cp_parser parser) { tree name; cp_lexer_consume_token (parser->lexer); /* Eat '@defs'. / cp_parser_require (parser, CPP_OPEN_PAREN, "`('"); name = cp_parser_identifier (parser); cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'"); return objc_get_class_ivars (name); } / Parse an Objective-C protocol expression. objc-protocol-expression: @protocol ( identifier ) Returns a representation of the protocol expression. / static tree cp_parser_objc_protocol_expression (cp_parser parser) { tree proto; cp_lexer_consume_token (parser->lexer); /* Eat '@protocol'. / cp_parser_require (parser, CPP_OPEN_PAREN, "`('"); proto = cp_parser_identifier (parser); cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'"); return objc_build_protocol_expr (proto); } / Parse an Objective-C selector expression. objc-selector-expression: @selector ( objc-method-signature ) objc-method-signature: objc-selector objc-selector-seq objc-selector-seq: objc-selector : objc-selector-seq objc-selector : Returns a representation of the method selector. / static tree cp_parser_objc_selector_expression (cp_parser parser) { tree sel_seq = NULL_TREE; bool maybe_unary_selector_p = true; cp_token token; cp_lexer_consume_token (parser->lexer); / Eat '@selector'. / cp_parser_require (parser, CPP_OPEN_PAREN, "`('"); token = cp_lexer_peek_token (parser->lexer); while (cp_parser_objc_selector_p (token->type) \|\| token->type == CPP_COLON \|\| token->type == CPP_SCOPE) { tree selector = NULL_TREE; if (token->type != CPP_COLON \|\| token->type == CPP_SCOPE) selector = cp_parser_objc_selector (parser); if (cp_lexer_next_token_is_not (parser->lexer, CPP_COLON) && cp_lexer_next_token_is_not (parser->lexer, CPP_SCOPE)) { / Detect if we have a unary selector. / if (maybe_unary_selector_p) { sel_seq = selector; goto finish_selector; } else { cp_parser_error (parser, "expected %<:%>"); } } maybe_unary_selector_p = false; token = cp_lexer_consume_token (parser->lexer); if (token->type == CPP_SCOPE) { sel_seq = chainon (sel_seq, build_tree_list (selector, NULL_TREE)); sel_seq = chainon (sel_seq, build_tree_list (NULL_TREE, NULL_TREE)); } else sel_seq = chainon (sel_seq, build_tree_list (selector, NULL_TREE)); token = cp_lexer_peek_token (parser->lexer); } finish_selector: cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'"); return objc_build_selector_expr (sel_seq); } / Parse a list of identifiers. objc-identifier-list: identifier objc-identifier-list , identifier Returns a TREE_LIST of identifier nodes. / static tree cp_parser_objc_identifier_list (cp_parser parser) { tree list = build_tree_list (NULL_TREE, cp_parser_identifier (parser)); cp_token sep = cp_lexer_peek_token (parser->lexer); while (sep->type == CPP_COMMA) { cp_lexer_consume_token (parser->lexer); / Eat ','. / list = chainon (list, build_tree_list (NULL_TREE, cp_parser_identifier (parser))); sep = cp_lexer_peek_token (parser->lexer); } return list; } / Parse an Objective-C alias declaration. objc-alias-declaration: @compatibility_alias identifier identifier ; This function registers the alias mapping with the Objective-C front-end. It returns nothing. / static void cp_parser_objc_alias_declaration (cp_parser parser) { tree alias, orig; cp_lexer_consume_token (parser->lexer); /* Eat '@compatibility_alias'. / alias = cp_parser_identifier (parser); orig = cp_parser_identifier (parser); objc_declare_alias (alias, orig); cp_parser_consume_semicolon_at_end_of_statement (parser); } / Parse an Objective-C class forward-declaration. objc-class-declaration: @class objc-identifier-list ; The function registers the forward declarations with the Objective-C front-end. It returns nothing. / static void cp_parser_objc_class_declaration (cp_parser parser) { cp_lexer_consume_token (parser->lexer); /* Eat '@class'. / objc_declare_class (cp_parser_objc_identifier_list (parser)); cp_parser_consume_semicolon_at_end_of_statement (parser); } / Parse a list of Objective-C protocol references. objc-protocol-refs-opt: objc-protocol-refs [opt] objc-protocol-refs: < objc-identifier-list > Returns a TREE_LIST of identifiers, if any. / static tree cp_parser_objc_protocol_refs_opt (cp_parser parser) { tree protorefs = NULL_TREE; if(cp_lexer_next_token_is (parser->lexer, CPP_LESS)) { cp_lexer_consume_token (parser->lexer); /* Eat '<'. / protorefs = cp_parser_objc_identifier_list (parser); cp_parser_require (parser, CPP_GREATER, "`>'"); } return protorefs; } / Parse a Objective-C visibility specification. / static void cp_parser_objc_visibility_spec (cp_parser parser) { cp_token vis = cp_lexer_peek_token (parser->lexer); switch (vis->keyword) { case RID_AT_PRIVATE: objc_set_visibility (2); break; case RID_AT_PROTECTED: objc_set_visibility (0); break; case RID_AT_PUBLIC: objc_set_visibility (1); break; default: return; } / Eat '@private'/'@protected'/'@public'. / cp_lexer_consume_token (parser->lexer); } / Parse an Objective-C method type. / static void cp_parser_objc_method_type (cp_parser parser) { objc_set_method_type (cp_lexer_consume_token (parser->lexer)->type == CPP_PLUS ? PLUS_EXPR : MINUS_EXPR); } /* Parse an Objective-C protocol qualifier. / static tree cp_parser_objc_protocol_qualifiers (cp_parser parser) { tree quals = NULL_TREE, node; cp_token token = cp_lexer_peek_token (parser->lexer); node = token->u.value; while (node && TREE_CODE (node) == IDENTIFIER_NODE && (node == ridpointers [(int) RID_IN] \|\| node == ridpointers [(int) RID_OUT] \|\| node == ridpointers [(int) RID_INOUT] \|\| node == ridpointers [(int) RID_BYCOPY] \|\| node == ridpointers [(int) RID_BYREF] \|\| node == ridpointers [(int) RID_ONEWAY])) { quals = tree_cons (NULL_TREE, node, quals); cp_lexer_consume_token (parser->lexer); token = cp_lexer_peek_token (parser->lexer); node = token->u.value; } return quals; } / Parse an Objective-C typename. / static tree cp_parser_objc_typename (cp_parser parser) { tree typename = NULL_TREE; if (cp_lexer_next_token_is (parser->lexer, CPP_OPEN_PAREN)) { tree proto_quals, cp_type = NULL_TREE; cp_lexer_consume_token (parser->lexer); /* Eat '('. / proto_quals = cp_parser_objc_protocol_qualifiers (parser); / An ObjC type name may consist of just protocol qualifiers, in which case the type shall default to 'id'. / if (cp_lexer_next_token_is_not (parser->lexer, CPP_CLOSE_PAREN)) cp_type = cp_parser_type_id (parser); cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'"); typename = build_tree_list (proto_quals, cp_type); } return typename; } / Check to see if TYPE refers to an Objective-C selector name. / static bool cp_parser_objc_selector_p (enum cpp_ttype type) { return (type == CPP_NAME \|\| type == CPP_KEYWORD \|\| type == CPP_AND_AND \|\| type == CPP_AND_EQ \|\| type == CPP_AND \|\| type == CPP_OR \|\| type == CPP_COMPL \|\| type == CPP_NOT \|\| type == CPP_NOT_EQ \|\| type == CPP_OR_OR \|\| type == CPP_OR_EQ \|\| type == CPP_XOR \|\| type == CPP_XOR_EQ); } / Parse an Objective-C selector. / static tree cp_parser_objc_selector (cp_parser parser) { cp_token token = cp_lexer_consume_token (parser->lexer); if (!cp_parser_objc_selector_p (token->type)) { error ("invalid Objective-C++ selector name"); return error_mark_node; } / C++ operator names are allowed to appear in ObjC selectors. / switch (token->type) { case CPP_AND_AND: return get_identifier ("and"); case CPP_AND_EQ: return get_identifier ("and_eq"); case CPP_AND: return get_identifier ("bitand"); case CPP_OR: return get_identifier ("bitor"); case CPP_COMPL: return get_identifier ("compl"); case CPP_NOT: return get_identifier ("not"); case CPP_NOT_EQ: return get_identifier ("not_eq"); case CPP_OR_OR: return get_identifier ("or"); case CPP_OR_EQ: return get_identifier ("or_eq"); case CPP_XOR: return get_identifier ("xor"); case CPP_XOR_EQ: return get_identifier ("xor_eq"); default: return token->u.value; } } / Parse an Objective-C params list. / static tree cp_parser_objc_method_keyword_params (cp_parser parser) { tree params = NULL_TREE; bool maybe_unary_selector_p = true; cp_token token = cp_lexer_peek_token (parser->lexer); while (cp_parser_objc_selector_p (token->type) \|\| token->type == CPP_COLON) { tree selector = NULL_TREE, typename, identifier; if (token->type != CPP_COLON) selector = cp_parser_objc_selector (parser); / Detect if we have a unary selector. / if (maybe_unary_selector_p && cp_lexer_next_token_is_not (parser->lexer, CPP_COLON)) return selector; maybe_unary_selector_p = false; cp_parser_require (parser, CPP_COLON, "`:'"); typename = cp_parser_objc_typename (parser); identifier = cp_parser_identifier (parser); params = chainon (params, objc_build_keyword_decl (selector, typename, identifier)); token = cp_lexer_peek_token (parser->lexer); } return params; } / Parse the non-keyword Objective-C params. / static tree cp_parser_objc_method_tail_params_opt (cp_parser parser, bool ellipsisp) { tree params = make_node (TREE_LIST); cp_token token = cp_lexer_peek_token (parser->lexer); ellipsisp = false; / Initially, assume no ellipsis. / while (token->type == CPP_COMMA) { cp_parameter_declarator parmdecl; tree parm; cp_lexer_consume_token (parser->lexer); /* Eat ','. / token = cp_lexer_peek_token (parser->lexer); if (token->type == CPP_ELLIPSIS) { cp_lexer_consume_token (parser->lexer); / Eat '...'. / ellipsisp = true; break; } parmdecl = cp_parser_parameter_declaration (parser, false, NULL); parm = grokdeclarator (parmdecl->declarator, &parmdecl->decl_specifiers, PARM, /initialized=/0, /attrlist=/NULL); chainon (params, build_tree_list (NULL_TREE, parm)); token = cp_lexer_peek_token (parser->lexer); } return params; } /* Parse a linkage specification, a pragma, an extra semicolon or a block. / static void cp_parser_objc_interstitial_code (cp_parser parser) { cp_token token = cp_lexer_peek_token (parser->lexer); / If the next token is `extern' and the following token is a string literal, then we have a linkage specification. / if (token->keyword == RID_EXTERN && cp_parser_is_string_literal (cp_lexer_peek_nth_token (parser->lexer, 2))) cp_parser_linkage_specification (parser); / Handle #pragma, if any. / else if (token->type == CPP_PRAGMA) cp_parser_pragma (parser, pragma_external); / Allow stray semicolons. / else if (token->type == CPP_SEMICOLON) cp_lexer_consume_token (parser->lexer); / Finally, try to parse a block-declaration, or a function-definition. / else cp_parser_block_declaration (parser, /statement_p=/false); } / Parse a method signature. / static tree cp_parser_objc_method_signature (cp_parser parser) { tree rettype, kwdparms, optparms; bool ellipsis = false; cp_parser_objc_method_type (parser); rettype = cp_parser_objc_typename (parser); kwdparms = cp_parser_objc_method_keyword_params (parser); optparms = cp_parser_objc_method_tail_params_opt (parser, &ellipsis); return objc_build_method_signature (rettype, kwdparms, optparms, ellipsis); } /* Pars an Objective-C method prototype list. / static void cp_parser_objc_method_prototype_list (cp_parser parser) { cp_token token = cp_lexer_peek_token (parser->lexer); while (token->keyword != RID_AT_END) { if (token->type == CPP_PLUS \|\| token->type == CPP_MINUS) { objc_add_method_declaration (cp_parser_objc_method_signature (parser)); cp_parser_consume_semicolon_at_end_of_statement (parser); } else / Allow for interspersed non-ObjC++ code. / cp_parser_objc_interstitial_code (parser); token = cp_lexer_peek_token (parser->lexer); } cp_lexer_consume_token (parser->lexer); / Eat '@end'. / objc_finish_interface (); } / Parse an Objective-C method definition list. / static void cp_parser_objc_method_definition_list (cp_parser parser) { cp_token token = cp_lexer_peek_token (parser->lexer); while (token->keyword != RID_AT_END) { tree meth; if (token->type == CPP_PLUS \|\| token->type == CPP_MINUS) { push_deferring_access_checks (dk_deferred); objc_start_method_definition (cp_parser_objc_method_signature (parser)); / For historical reasons, we accept an optional semicolon. / if (cp_lexer_next_token_is (parser->lexer, CPP_SEMICOLON)) cp_lexer_consume_token (parser->lexer); perform_deferred_access_checks (); stop_deferring_access_checks (); meth = cp_parser_function_definition_after_declarator (parser, false); pop_deferring_access_checks (); objc_finish_method_definition (meth); } else / Allow for interspersed non-ObjC++ code. / cp_parser_objc_interstitial_code (parser); token = cp_lexer_peek_token (parser->lexer); } cp_lexer_consume_token (parser->lexer); / Eat '@end'. / objc_finish_implementation (); } / Parse Objective-C ivars. / static void cp_parser_objc_class_ivars (cp_parser parser) { cp_token token = cp_lexer_peek_token (parser->lexer); if (token->type != CPP_OPEN_BRACE) return; / No ivars specified. / cp_lexer_consume_token (parser->lexer); / Eat '{'. / token = cp_lexer_peek_token (parser->lexer); while (token->type != CPP_CLOSE_BRACE) { cp_decl_specifier_seq declspecs; int decl_class_or_enum_p; tree prefix_attributes; cp_parser_objc_visibility_spec (parser); if (cp_lexer_next_token_is (parser->lexer, CPP_CLOSE_BRACE)) break; cp_parser_decl_specifier_seq (parser, CP_PARSER_FLAGS_OPTIONAL, &declspecs, &decl_class_or_enum_p); prefix_attributes = declspecs.attributes; declspecs.attributes = NULL_TREE; / Keep going until we hit the `;' at the end of the declaration. / while (cp_lexer_next_token_is_not (parser->lexer, CPP_SEMICOLON)) { tree width = NULL_TREE, attributes, first_attribute, decl; cp_declarator declarator = NULL; int ctor_dtor_or_conv_p; /* Check for a (possibly unnamed) bitfield declaration. / token = cp_lexer_peek_token (parser->lexer); if (token->type == CPP_COLON) goto eat_colon; if (token->type == CPP_NAME && (cp_lexer_peek_nth_token (parser->lexer, 2)->type == CPP_COLON)) { / Get the name of the bitfield. / declarator = make_id_declarator (NULL_TREE, cp_parser_identifier (parser), sfk_none); eat_colon: cp_lexer_consume_token (parser->lexer); / Eat ':'. / / Get the width of the bitfield. / width = cp_parser_constant_expression (parser, /allow_non_constant=/false, NULL); } else { / Parse the declarator. / declarator = cp_parser_declarator (parser, CP_PARSER_DECLARATOR_NAMED, &ctor_dtor_or_conv_p, /parenthesized_p=/NULL, /member_p=/false); } / Look for attributes that apply to the ivar. / attributes = cp_parser_attributes_opt (parser); / Remember which attributes are prefix attributes and which are not. / first_attribute = attributes; / Combine the attributes. / attributes = chainon (prefix_attributes, attributes); if (width) { / Create the bitfield declaration. / decl = grokbitfield (declarator, &declspecs, width); cplus_decl_attributes (&decl, attributes, /flags=/0); } else decl = grokfield (declarator, &declspecs, NULL_TREE, /init_const_expr_p=/false, NULL_TREE, attributes); / Add the instance variable. / objc_add_instance_variable (decl); / Reset PREFIX_ATTRIBUTES. / while (attributes && TREE_CHAIN (attributes) != first_attribute) attributes = TREE_CHAIN (attributes); if (attributes) TREE_CHAIN (attributes) = NULL_TREE; token = cp_lexer_peek_token (parser->lexer); if (token->type == CPP_COMMA) { cp_lexer_consume_token (parser->lexer); / Eat ','. / continue; } break; } cp_parser_consume_semicolon_at_end_of_statement (parser); token = cp_lexer_peek_token (parser->lexer); } cp_lexer_consume_token (parser->lexer); / Eat '}'. / / For historical reasons, we accept an optional semicolon. / if (cp_lexer_next_token_is (parser->lexer, CPP_SEMICOLON)) cp_lexer_consume_token (parser->lexer); } / Parse an Objective-C protocol declaration. / static void cp_parser_objc_protocol_declaration (cp_parser parser) { tree proto, protorefs; cp_token tok; cp_lexer_consume_token (parser->lexer); / Eat '@protocol'. / if (cp_lexer_next_token_is_not (parser->lexer, CPP_NAME)) { error ("identifier expected after %<@protocol%>"); goto finish; } / See if we have a forward declaration or a definition. / tok = cp_lexer_peek_nth_token (parser->lexer, 2); / Try a forward declaration first. / if (tok->type == CPP_COMMA \|\| tok->type == CPP_SEMICOLON) { objc_declare_protocols (cp_parser_objc_identifier_list (parser)); finish: cp_parser_consume_semicolon_at_end_of_statement (parser); } / Ok, we got a full-fledged definition (or at least should). / else { proto = cp_parser_identifier (parser); protorefs = cp_parser_objc_protocol_refs_opt (parser); objc_start_protocol (proto, protorefs); cp_parser_objc_method_prototype_list (parser); } } / Parse an Objective-C superclass or category. / static void cp_parser_objc_superclass_or_category (cp_parser parser, tree super, tree categ) { cp_token next = cp_lexer_peek_token (parser->lexer); super = categ = NULL_TREE; if (next->type == CPP_COLON) { cp_lexer_consume_token (parser->lexer); / Eat ':'. / super = cp_parser_identifier (parser); } else if (next->type == CPP_OPEN_PAREN) { cp_lexer_consume_token (parser->lexer); /* Eat '('. / categ = cp_parser_identifier (parser); cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'"); } } /* Parse an Objective-C class interface. / static void cp_parser_objc_class_interface (cp_parser parser) { tree name, super, categ, protos; cp_lexer_consume_token (parser->lexer); /* Eat '@interface'. / name = cp_parser_identifier (parser); cp_parser_objc_superclass_or_category (parser, &super, &categ); protos = cp_parser_objc_protocol_refs_opt (parser); / We have either a class or a category on our hands. / if (categ) objc_start_category_interface (name, categ, protos); else { objc_start_class_interface (name, super, protos); / Handle instance variable declarations, if any. / cp_parser_objc_class_ivars (parser); objc_continue_interface (); } cp_parser_objc_method_prototype_list (parser); } / Parse an Objective-C class implementation. / static void cp_parser_objc_class_implementation (cp_parser parser) { tree name, super, categ; cp_lexer_consume_token (parser->lexer); /* Eat '@implementation'. / name = cp_parser_identifier (parser); cp_parser_objc_superclass_or_category (parser, &super, &categ); / We have either a class or a category on our hands. / if (categ) objc_start_category_implementation (name, categ); else { objc_start_class_implementation (name, super); / Handle instance variable declarations, if any. / cp_parser_objc_class_ivars (parser); objc_continue_implementation (); } cp_parser_objc_method_definition_list (parser); } / Consume the @end token and finish off the implementation. / static void cp_parser_objc_end_implementation (cp_parser parser) { cp_lexer_consume_token (parser->lexer); /* Eat '@end'. / objc_finish_implementation (); } / Parse an Objective-C declaration. / static void cp_parser_objc_declaration (cp_parser parser) { /* Try to figure out what kind of declaration is present. / cp_token kwd = cp_lexer_peek_token (parser->lexer); switch (kwd->keyword) { case RID_AT_ALIAS: cp_parser_objc_alias_declaration (parser); break; case RID_AT_CLASS: cp_parser_objc_class_declaration (parser); break; case RID_AT_PROTOCOL: cp_parser_objc_protocol_declaration (parser); break; case RID_AT_INTERFACE: cp_parser_objc_class_interface (parser); break; case RID_AT_IMPLEMENTATION: cp_parser_objc_class_implementation (parser); break; case RID_AT_END: cp_parser_objc_end_implementation (parser); break; default: error ("misplaced %<@%D%> Objective-C++ construct", kwd->u.value); cp_parser_skip_to_end_of_block_or_statement (parser); } } /* Parse an Objective-C try-catch-finally statement. objc-try-catch-finally-stmt: @try compound-statement objc-catch-clause-seq [opt] objc-finally-clause [opt] objc-catch-clause-seq: objc-catch-clause objc-catch-clause-seq [opt] objc-catch-clause: @catch ( exception-declaration ) compound-statement objc-finally-clause @finally compound-statement Returns NULL_TREE. / static tree cp_parser_objc_try_catch_finally_statement (cp_parser parser) { location_t location; tree stmt; cp_parser_require_keyword (parser, RID_AT_TRY, "`@try'"); location = cp_lexer_peek_token (parser->lexer)->location; /* NB: The @try block needs to be wrapped in its own STATEMENT_LIST node, lest it get absorbed into the surrounding block. / stmt = push_stmt_list (); cp_parser_compound_statement (parser, NULL, false); objc_begin_try_stmt (location, pop_stmt_list (stmt)); while (cp_lexer_next_token_is_keyword (parser->lexer, RID_AT_CATCH)) { cp_parameter_declarator parmdecl; tree parm; cp_lexer_consume_token (parser->lexer); cp_parser_require (parser, CPP_OPEN_PAREN, "`('"); parmdecl = cp_parser_parameter_declaration (parser, false, NULL); parm = grokdeclarator (parmdecl->declarator, &parmdecl->decl_specifiers, PARM, /initialized=/0, /attrlist=/NULL); cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'"); objc_begin_catch_clause (parm); cp_parser_compound_statement (parser, NULL, false); objc_finish_catch_clause (); } if (cp_lexer_next_token_is_keyword (parser->lexer, RID_AT_FINALLY)) { cp_lexer_consume_token (parser->lexer); location = cp_lexer_peek_token (parser->lexer)->location; /* NB: The @finally block needs to be wrapped in its own STATEMENT_LIST node, lest it get absorbed into the surrounding block. / stmt = push_stmt_list (); cp_parser_compound_statement (parser, NULL, false); objc_build_finally_clause (location, pop_stmt_list (stmt)); } return objc_finish_try_stmt (); } / Parse an Objective-C synchronized statement. objc-synchronized-stmt: @synchronized ( expression ) compound-statement Returns NULL_TREE. / static tree cp_parser_objc_synchronized_statement (cp_parser parser) { location_t location; tree lock, stmt; cp_parser_require_keyword (parser, RID_AT_SYNCHRONIZED, "`@synchronized'"); location = cp_lexer_peek_token (parser->lexer)->location; cp_parser_require (parser, CPP_OPEN_PAREN, "`('"); lock = cp_parser_expression (parser, false); cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'"); /* NB: The @synchronized block needs to be wrapped in its own STATEMENT_LIST node, lest it get absorbed into the surrounding block. / stmt = push_stmt_list (); cp_parser_compound_statement (parser, NULL, false); return objc_build_synchronized (location, lock, pop_stmt_list (stmt)); } / Parse an Objective-C throw statement. objc-throw-stmt: @throw assignment-expression [opt] ; Returns a constructed '@throw' statement. / static tree cp_parser_objc_throw_statement (cp_parser parser) { tree expr = NULL_TREE; cp_parser_require_keyword (parser, RID_AT_THROW, "`@throw'"); if (cp_lexer_next_token_is_not (parser->lexer, CPP_SEMICOLON)) expr = cp_parser_assignment_expression (parser, false); cp_parser_consume_semicolon_at_end_of_statement (parser); return objc_build_throw_stmt (expr); } /* Parse an Objective-C statement. / static tree cp_parser_objc_statement (cp_parser parser) { /* Try to figure out what kind of declaration is present. / cp_token kwd = cp_lexer_peek_token (parser->lexer); switch (kwd->keyword) { case RID_AT_TRY: return cp_parser_objc_try_catch_finally_statement (parser); case RID_AT_SYNCHRONIZED: return cp_parser_objc_synchronized_statement (parser); case RID_AT_THROW: return cp_parser_objc_throw_statement (parser); default: error ("misplaced %<@%D%> Objective-C++ construct", kwd->u.value); cp_parser_skip_to_end_of_block_or_statement (parser); } return error_mark_node; } /* OpenMP 2.5 parsing routines. / / All OpenMP clauses. OpenMP 2.5. / typedef enum pragma_omp_clause { PRAGMA_OMP_CLAUSE_NONE = 0, PRAGMA_OMP_CLAUSE_COPYIN, PRAGMA_OMP_CLAUSE_COPYPRIVATE, PRAGMA_OMP_CLAUSE_DEFAULT, PRAGMA_OMP_CLAUSE_FIRSTPRIVATE, PRAGMA_OMP_CLAUSE_IF, PRAGMA_OMP_CLAUSE_LASTPRIVATE, PRAGMA_OMP_CLAUSE_NOWAIT, PRAGMA_OMP_CLAUSE_NUM_THREADS, PRAGMA_OMP_CLAUSE_ORDERED, PRAGMA_OMP_CLAUSE_PRIVATE, PRAGMA_OMP_CLAUSE_REDUCTION, PRAGMA_OMP_CLAUSE_SCHEDULE, PRAGMA_OMP_CLAUSE_SHARED } pragma_omp_clause; / Returns name of the next clause. If the clause is not recognized PRAGMA_OMP_CLAUSE_NONE is returned and the token is not consumed. Otherwise appropriate pragma_omp_clause is returned and the token is consumed. / static pragma_omp_clause cp_parser_omp_clause_name (cp_parser parser) { pragma_omp_clause result = PRAGMA_OMP_CLAUSE_NONE; if (cp_lexer_next_token_is_keyword (parser->lexer, RID_IF)) result = PRAGMA_OMP_CLAUSE_IF; else if (cp_lexer_next_token_is_keyword (parser->lexer, RID_DEFAULT)) result = PRAGMA_OMP_CLAUSE_DEFAULT; else if (cp_lexer_next_token_is_keyword (parser->lexer, RID_PRIVATE)) result = PRAGMA_OMP_CLAUSE_PRIVATE; else if (cp_lexer_next_token_is (parser->lexer, CPP_NAME)) { tree id = cp_lexer_peek_token (parser->lexer)->u.value; const char p = IDENTIFIER_POINTER (id); switch (p[0]) { case 'c': if (!strcmp ("copyin", p)) result = PRAGMA_OMP_CLAUSE_COPYIN; else if (!strcmp ("copyprivate", p)) result = PRAGMA_OMP_CLAUSE_COPYPRIVATE; break; case 'f': if (!strcmp ("firstprivate", p)) result = PRAGMA_OMP_CLAUSE_FIRSTPRIVATE; break; case 'l': if (!strcmp ("lastprivate", p)) result = PRAGMA_OMP_CLAUSE_LASTPRIVATE; break; case 'n': if (!strcmp ("nowait", p)) result = PRAGMA_OMP_CLAUSE_NOWAIT; else if (!strcmp ("num_threads", p)) result = PRAGMA_OMP_CLAUSE_NUM_THREADS; break; case 'o': if (!strcmp ("ordered", p)) result = PRAGMA_OMP_CLAUSE_ORDERED; break; case 'r': if (!strcmp ("reduction", p)) result = PRAGMA_OMP_CLAUSE_REDUCTION; break; case 's': if (!strcmp ("schedule", p)) result = PRAGMA_OMP_CLAUSE_SCHEDULE; else if (!strcmp ("shared", p)) result = PRAGMA_OMP_CLAUSE_SHARED; break; } } if (result != PRAGMA_OMP_CLAUSE_NONE) cp_lexer_consume_token (parser->lexer); return result; } / Validate that a clause of the given type does not already exist. / static void check_no_duplicate_clause (tree clauses, enum tree_code code, const char name) { tree c; for (c = clauses; c ; c = OMP_CLAUSE_CHAIN (c)) if (OMP_CLAUSE_CODE (c) == code) { error ("too many %qs clauses", name); break; } } /* OpenMP 2.5: variable-list: identifier variable-list , identifier In addition, we match a closing parenthesis. An opening parenthesis will have been consumed by the caller. If KIND is nonzero, create the appropriate node and install the decl in OMP_CLAUSE_DECL and add the node to the head of the list. If KIND is zero, create a TREE_LIST with the decl in TREE_PURPOSE; return the list created. / static tree cp_parser_omp_var_list_no_open (cp_parser parser, enum omp_clause_code kind, tree list) { while (1) { tree name, decl; name = cp_parser_id_expression (parser, /template_p=/false, /check_dependency_p=/true, /template_p=/NULL, /declarator_p=/false, /optional_p=/false); if (name == error_mark_node) goto skip_comma; decl = cp_parser_lookup_name_simple (parser, name); if (decl == error_mark_node) cp_parser_name_lookup_error (parser, name, decl, NULL); else if (kind != 0) { tree u = build_omp_clause (kind); OMP_CLAUSE_DECL (u) = decl; OMP_CLAUSE_CHAIN (u) = list; list = u; } else list = tree_cons (decl, NULL_TREE, list); get_comma: if (cp_lexer_next_token_is_not (parser->lexer, CPP_COMMA)) break; cp_lexer_consume_token (parser->lexer); } if (!cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'")) { int ending; /* Try to resync to an unnested comma. Copied from cp_parser_parenthesized_expression_list. / skip_comma: ending = cp_parser_skip_to_closing_parenthesis (parser, /recovering=/true, /or_comma=/true, /consume_paren=/true); if (ending < 0) goto get_comma; } return list; } / Similarly, but expect leading and trailing parenthesis. This is a very common case for omp clauses. / static tree cp_parser_omp_var_list (cp_parser parser, enum omp_clause_code kind, tree list) { if (cp_parser_require (parser, CPP_OPEN_PAREN, "`('")) return cp_parser_omp_var_list_no_open (parser, kind, list); return list; } /* OpenMP 2.5: default ( shared \| none ) / static tree cp_parser_omp_clause_default (cp_parser parser, tree list) { enum omp_clause_default_kind kind = OMP_CLAUSE_DEFAULT_UNSPECIFIED; tree c; if (!cp_parser_require (parser, CPP_OPEN_PAREN, "`('")) return list; if (cp_lexer_next_token_is (parser->lexer, CPP_NAME)) { tree id = cp_lexer_peek_token (parser->lexer)->u.value; const char p = IDENTIFIER_POINTER (id); switch (p[0]) { case 'n': if (strcmp ("none", p) != 0) goto invalid_kind; kind = OMP_CLAUSE_DEFAULT_NONE; break; case 's': if (strcmp ("shared", p) != 0) goto invalid_kind; kind = OMP_CLAUSE_DEFAULT_SHARED; break; default: goto invalid_kind; } cp_lexer_consume_token (parser->lexer); } else { invalid_kind: cp_parser_error (parser, "expected %<none%> or %<shared%>"); } if (!cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'")) cp_parser_skip_to_closing_parenthesis (parser, /recovering=/true, /or_comma=/false, /consume_paren=/true); if (kind == OMP_CLAUSE_DEFAULT_UNSPECIFIED) return list; check_no_duplicate_clause (list, OMP_CLAUSE_DEFAULT, "default"); c = build_omp_clause (OMP_CLAUSE_DEFAULT); OMP_CLAUSE_CHAIN (c) = list; OMP_CLAUSE_DEFAULT_KIND (c) = kind; return c; } / OpenMP 2.5: if ( expression ) / static tree cp_parser_omp_clause_if (cp_parser parser, tree list) { tree t, c; if (!cp_parser_require (parser, CPP_OPEN_PAREN, "`('")) return list; t = cp_parser_condition (parser); if (t == error_mark_node \|\| !cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'")) cp_parser_skip_to_closing_parenthesis (parser, /recovering=/true, /or_comma=/false, /consume_paren=/true); check_no_duplicate_clause (list, OMP_CLAUSE_IF, "if"); c = build_omp_clause (OMP_CLAUSE_IF); OMP_CLAUSE_IF_EXPR (c) = t; OMP_CLAUSE_CHAIN (c) = list; return c; } /* OpenMP 2.5: nowait / static tree cp_parser_omp_clause_nowait (cp_parser parser ATTRIBUTE_UNUSED, tree list) { tree c; check_no_duplicate_clause (list, OMP_CLAUSE_NOWAIT, "nowait"); c = build_omp_clause (OMP_CLAUSE_NOWAIT); OMP_CLAUSE_CHAIN (c) = list; return c; } /* OpenMP 2.5: num_threads ( expression ) / static tree cp_parser_omp_clause_num_threads (cp_parser parser, tree list) { tree t, c; if (!cp_parser_require (parser, CPP_OPEN_PAREN, "`('")) return list; t = cp_parser_expression (parser, false); if (t == error_mark_node \|\| !cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'")) cp_parser_skip_to_closing_parenthesis (parser, /recovering=/true, /or_comma=/false, /consume_paren=/true); check_no_duplicate_clause (list, OMP_CLAUSE_NUM_THREADS, "num_threads"); c = build_omp_clause (OMP_CLAUSE_NUM_THREADS); OMP_CLAUSE_NUM_THREADS_EXPR (c) = t; OMP_CLAUSE_CHAIN (c) = list; return c; } /* OpenMP 2.5: ordered / static tree cp_parser_omp_clause_ordered (cp_parser parser ATTRIBUTE_UNUSED, tree list) { tree c; check_no_duplicate_clause (list, OMP_CLAUSE_ORDERED, "ordered"); c = build_omp_clause (OMP_CLAUSE_ORDERED); OMP_CLAUSE_CHAIN (c) = list; return c; } /* OpenMP 2.5: reduction ( reduction-operator : variable-list ) reduction-operator: One of: + * - & ^ \| && \|\| / static tree cp_parser_omp_clause_reduction (cp_parser parser, tree list) { enum tree_code code; tree nlist, c; if (!cp_parser_require (parser, CPP_OPEN_PAREN, "`('")) return list; switch (cp_lexer_peek_token (parser->lexer)->type) { case CPP_PLUS: code = PLUS_EXPR; break; case CPP_MULT: code = MULT_EXPR; break; case CPP_MINUS: code = MINUS_EXPR; break; case CPP_AND: code = BIT_AND_EXPR; break; case CPP_XOR: code = BIT_XOR_EXPR; break; case CPP_OR: code = BIT_IOR_EXPR; break; case CPP_AND_AND: code = TRUTH_ANDIF_EXPR; break; case CPP_OR_OR: code = TRUTH_ORIF_EXPR; break; default: cp_parser_error (parser, "`+', `', `-', `&', `^', `\|', `&&', or `\|\|'"); resync_fail: cp_parser_skip_to_closing_parenthesis (parser, /recovering=/true, /or_comma=/false, /consume_paren=/true); return list; } cp_lexer_consume_token (parser->lexer); if (!cp_parser_require (parser, CPP_COLON, "`:'")) goto resync_fail; nlist = cp_parser_omp_var_list_no_open (parser, OMP_CLAUSE_REDUCTION, list); for (c = nlist; c != list; c = OMP_CLAUSE_CHAIN (c)) OMP_CLAUSE_REDUCTION_CODE (c) = code; return nlist; } / OpenMP 2.5: schedule ( schedule-kind ) schedule ( schedule-kind , expression ) schedule-kind: static \| dynamic \| guided \| runtime / static tree cp_parser_omp_clause_schedule (cp_parser parser, tree list) { tree c, t; if (!cp_parser_require (parser, CPP_OPEN_PAREN, "expected %<(%>")) return list; c = build_omp_clause (OMP_CLAUSE_SCHEDULE); if (cp_lexer_next_token_is (parser->lexer, CPP_NAME)) { tree id = cp_lexer_peek_token (parser->lexer)->u.value; const char p = IDENTIFIER_POINTER (id); switch (p[0]) { case 'd': if (strcmp ("dynamic", p) != 0) goto invalid_kind; OMP_CLAUSE_SCHEDULE_KIND (c) = OMP_CLAUSE_SCHEDULE_DYNAMIC; break; case 'g': if (strcmp ("guided", p) != 0) goto invalid_kind; OMP_CLAUSE_SCHEDULE_KIND (c) = OMP_CLAUSE_SCHEDULE_GUIDED; break; case 'r': if (strcmp ("runtime", p) != 0) goto invalid_kind; OMP_CLAUSE_SCHEDULE_KIND (c) = OMP_CLAUSE_SCHEDULE_RUNTIME; break; default: goto invalid_kind; } } else if (cp_lexer_next_token_is_keyword (parser->lexer, RID_STATIC)) OMP_CLAUSE_SCHEDULE_KIND (c) = OMP_CLAUSE_SCHEDULE_STATIC; else goto invalid_kind; cp_lexer_consume_token (parser->lexer); if (cp_lexer_next_token_is (parser->lexer, CPP_COMMA)) { cp_lexer_consume_token (parser->lexer); t = cp_parser_assignment_expression (parser, false); if (t == error_mark_node) goto resync_fail; else if (OMP_CLAUSE_SCHEDULE_KIND (c) == OMP_CLAUSE_SCHEDULE_RUNTIME) error ("schedule %<runtime%> does not take " "a %<chunk_size%> parameter"); else OMP_CLAUSE_SCHEDULE_CHUNK_EXPR (c) = t; if (!cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'")) goto resync_fail; } else if (!cp_parser_require (parser, CPP_CLOSE_PAREN, "`,' or `)'")) goto resync_fail; check_no_duplicate_clause (list, OMP_CLAUSE_SCHEDULE, "schedule"); OMP_CLAUSE_CHAIN (c) = list; return c; invalid_kind: cp_parser_error (parser, "invalid schedule kind"); resync_fail: cp_parser_skip_to_closing_parenthesis (parser, /recovering=/true, /or_comma=/false, /consume_paren=/true); return list; } / Parse all OpenMP clauses. The set clauses allowed by the directive is a bitmask in MASK. Return the list of clauses found; the result of clause default goes in pdefault. / static tree cp_parser_omp_all_clauses (cp_parser parser, unsigned int mask, const char where, cp_token pragma_tok) { tree clauses = NULL; while (cp_lexer_next_token_is_not (parser->lexer, CPP_PRAGMA_EOL)) { pragma_omp_clause c_kind = cp_parser_omp_clause_name (parser); const char c_name; tree prev = clauses; switch (c_kind) { case PRAGMA_OMP_CLAUSE_COPYIN: clauses = cp_parser_omp_var_list (parser, OMP_CLAUSE_COPYIN, clauses); c_name = "copyin"; break; case PRAGMA_OMP_CLAUSE_COPYPRIVATE: clauses = cp_parser_omp_var_list (parser, OMP_CLAUSE_COPYPRIVATE, clauses); c_name = "copyprivate"; break; case PRAGMA_OMP_CLAUSE_DEFAULT: clauses = cp_parser_omp_clause_default (parser, clauses); c_name = "default"; break; case PRAGMA_OMP_CLAUSE_FIRSTPRIVATE: clauses = cp_parser_omp_var_list (parser, OMP_CLAUSE_FIRSTPRIVATE, clauses); c_name = "firstprivate"; break; case PRAGMA_OMP_CLAUSE_IF: clauses = cp_parser_omp_clause_if (parser, clauses); c_name = "if"; break; case PRAGMA_OMP_CLAUSE_LASTPRIVATE: clauses = cp_parser_omp_var_list (parser, OMP_CLAUSE_LASTPRIVATE, clauses); c_name = "lastprivate"; break; case PRAGMA_OMP_CLAUSE_NOWAIT: clauses = cp_parser_omp_clause_nowait (parser, clauses); c_name = "nowait"; break; case PRAGMA_OMP_CLAUSE_NUM_THREADS: clauses = cp_parser_omp_clause_num_threads (parser, clauses); c_name = "num_threads"; break; case PRAGMA_OMP_CLAUSE_ORDERED: clauses = cp_parser_omp_clause_ordered (parser, clauses); c_name = "ordered"; break; case PRAGMA_OMP_CLAUSE_PRIVATE: clauses = cp_parser_omp_var_list (parser, OMP_CLAUSE_PRIVATE, clauses); c_name = "private"; break; case PRAGMA_OMP_CLAUSE_REDUCTION: clauses = cp_parser_omp_clause_reduction (parser, clauses); c_name = "reduction"; break; case PRAGMA_OMP_CLAUSE_SCHEDULE: clauses = cp_parser_omp_clause_schedule (parser, clauses); c_name = "schedule"; break; case PRAGMA_OMP_CLAUSE_SHARED: clauses = cp_parser_omp_var_list (parser, OMP_CLAUSE_SHARED, clauses); c_name = "shared"; break; default: cp_parser_error (parser, "expected %<#pragma omp%> clause"); goto saw_error; } if (((mask >> c_kind) & 1) == 0) { /* Remove the invalid clause(s) from the list to avoid confusing the rest of the compiler. / clauses = prev; error ("%qs is not valid for %qs", c_name, where); } } saw_error: cp_parser_skip_to_pragma_eol (parser, pragma_tok); return finish_omp_clauses (clauses); } / OpenMP 2.5: structured-block: statement In practice, we're also interested in adding the statement to an outer node. So it is convenient if we work around the fact that cp_parser_statement calls add_stmt. / static unsigned cp_parser_begin_omp_structured_block (cp_parser parser) { unsigned save = parser->in_statement; /* Only move the values to IN_OMP_BLOCK if they weren't false. This preserves the "not within loop or switch" style error messages for nonsense cases like void foo() { #pragma omp single break; } / if (parser->in_statement) parser->in_statement = IN_OMP_BLOCK; return save; } static void cp_parser_end_omp_structured_block (cp_parser parser, unsigned save) { parser->in_statement = save; } static tree cp_parser_omp_structured_block (cp_parser parser) { tree stmt = begin_omp_structured_block (); unsigned int save = cp_parser_begin_omp_structured_block (parser); cp_parser_statement (parser, NULL_TREE, false); cp_parser_end_omp_structured_block (parser, save); return finish_omp_structured_block (stmt); } / OpenMP 2.5: # pragma omp atomic new-line expression-stmt expression-stmt: x binop= expr \| x++ \| ++x \| x-- \| --x binop: +, , -, /, &, ^, \|, <<, >> where x is an lvalue expression with scalar type. / static void cp_parser_omp_atomic (cp_parser parser, cp_token pragma_tok) { tree lhs, rhs; enum tree_code code; cp_parser_require_pragma_eol (parser, pragma_tok); lhs = cp_parser_unary_expression (parser, /address_p=/false, /cast_p=/false); switch (TREE_CODE (lhs)) { case ERROR_MARK: goto saw_error; case PREINCREMENT_EXPR: case POSTINCREMENT_EXPR: lhs = TREE_OPERAND (lhs, 0); code = PLUS_EXPR; rhs = integer_one_node; break; case PREDECREMENT_EXPR: case POSTDECREMENT_EXPR: lhs = TREE_OPERAND (lhs, 0); code = MINUS_EXPR; rhs = integer_one_node; break; default: switch (cp_lexer_peek_token (parser->lexer)->type) { case CPP_MULT_EQ: code = MULT_EXPR; break; case CPP_DIV_EQ: code = TRUNC_DIV_EXPR; break; case CPP_PLUS_EQ: code = PLUS_EXPR; break; case CPP_MINUS_EQ: code = MINUS_EXPR; break; case CPP_LSHIFT_EQ: code = LSHIFT_EXPR; break; case CPP_RSHIFT_EQ: code = RSHIFT_EXPR; break; case CPP_AND_EQ: code = BIT_AND_EXPR; break; case CPP_OR_EQ: code = BIT_IOR_EXPR; break; case CPP_XOR_EQ: code = BIT_XOR_EXPR; break; default: cp_parser_error (parser, "invalid operator for %<#pragma omp atomic%>"); goto saw_error; } cp_lexer_consume_token (parser->lexer); rhs = cp_parser_expression (parser, false); if (rhs == error_mark_node) goto saw_error; break; } finish_omp_atomic (code, lhs, rhs); cp_parser_consume_semicolon_at_end_of_statement (parser); return; saw_error: cp_parser_skip_to_end_of_block_or_statement (parser); } /* OpenMP 2.5: # pragma omp barrier new-line / static void cp_parser_omp_barrier (cp_parser parser, cp_token pragma_tok) { cp_parser_require_pragma_eol (parser, pragma_tok); finish_omp_barrier (); } / OpenMP 2.5: # pragma omp critical [(name)] new-line structured-block / static tree cp_parser_omp_critical (cp_parser parser, cp_token pragma_tok) { tree stmt, name = NULL; if (cp_lexer_next_token_is (parser->lexer, CPP_OPEN_PAREN)) { cp_lexer_consume_token (parser->lexer); name = cp_parser_identifier (parser); if (name == error_mark_node \|\| !cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'")) cp_parser_skip_to_closing_parenthesis (parser, /recovering=/true, /or_comma=/false, /consume_paren=/true); if (name == error_mark_node) name = NULL; } cp_parser_require_pragma_eol (parser, pragma_tok); stmt = cp_parser_omp_structured_block (parser); return c_finish_omp_critical (stmt, name); } / OpenMP 2.5: # pragma omp flush flush-vars[opt] new-line flush-vars: ( variable-list ) / static void cp_parser_omp_flush (cp_parser parser, cp_token pragma_tok) { if (cp_lexer_next_token_is (parser->lexer, CPP_OPEN_PAREN)) (void) cp_parser_omp_var_list (parser, 0, NULL); cp_parser_require_pragma_eol (parser, pragma_tok); finish_omp_flush (); } / Parse the restricted form of the for statment allowed by OpenMP. / static tree cp_parser_omp_for_loop (cp_parser parser) { tree init, cond, incr, body, decl, pre_body; location_t loc; if (!cp_lexer_next_token_is_keyword (parser->lexer, RID_FOR)) { cp_parser_error (parser, "for statement expected"); return NULL; } loc = cp_lexer_consume_token (parser->lexer)->location; if (!cp_parser_require (parser, CPP_OPEN_PAREN, "`('")) return NULL; init = decl = NULL; pre_body = push_stmt_list (); if (cp_lexer_next_token_is_not (parser->lexer, CPP_SEMICOLON)) { cp_decl_specifier_seq type_specifiers; /* First, try to parse as an initialized declaration. See cp_parser_condition, from whence the bulk of this is copied. / cp_parser_parse_tentatively (parser); cp_parser_type_specifier_seq (parser, /is_condition=/false, &type_specifiers); if (!cp_parser_error_occurred (parser)) { tree asm_specification, attributes; cp_declarator declarator; declarator = cp_parser_declarator (parser, CP_PARSER_DECLARATOR_NAMED, /ctor_dtor_or_conv_p=/NULL, /parenthesized_p=/NULL, /member_p=/false); attributes = cp_parser_attributes_opt (parser); asm_specification = cp_parser_asm_specification_opt (parser); cp_parser_require (parser, CPP_EQ, "`='"); if (cp_parser_parse_definitely (parser)) { tree pushed_scope; decl = start_decl (declarator, &type_specifiers, /initialized_p=/false, attributes, /prefix_attributes=/NULL_TREE, &pushed_scope); init = cp_parser_assignment_expression (parser, false); cp_finish_decl (decl, NULL_TREE, /init_const_expr_p=/false, asm_specification, LOOKUP_ONLYCONVERTING); if (pushed_scope) pop_scope (pushed_scope); } } else cp_parser_abort_tentative_parse (parser); /* If parsing as an initialized declaration failed, try again as a simple expression. / if (decl == NULL) init = cp_parser_expression (parser, false); } cp_parser_require (parser, CPP_SEMICOLON, "`;'"); pre_body = pop_stmt_list (pre_body); cond = NULL; if (cp_lexer_next_token_is_not (parser->lexer, CPP_SEMICOLON)) cond = cp_parser_condition (parser); cp_parser_require (parser, CPP_SEMICOLON, "`;'"); incr = NULL; if (cp_lexer_next_token_is_not (parser->lexer, CPP_CLOSE_PAREN)) incr = cp_parser_expression (parser, false); if (!cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'")) cp_parser_skip_to_closing_parenthesis (parser, /recovering=/true, /or_comma=/false, /consume_paren=/true); / Note that we saved the original contents of this flag when we entered the structured block, and so we don't need to re-save it here. / parser->in_statement = IN_OMP_FOR; / Note that the grammar doesn't call for a structured block here, though the loop as a whole is a structured block. / body = push_stmt_list (); cp_parser_statement (parser, NULL_TREE, false); body = pop_stmt_list (body); return finish_omp_for (loc, decl, init, cond, incr, body, pre_body); } / OpenMP 2.5: #pragma omp for for-clause[optseq] new-line for-loop / #define OMP_FOR_CLAUSE_MASK \ ( (1u << PRAGMA_OMP_CLAUSE_PRIVATE) \ \| (1u << PRAGMA_OMP_CLAUSE_FIRSTPRIVATE) \ \| (1u << PRAGMA_OMP_CLAUSE_LASTPRIVATE) \ \| (1u << PRAGMA_OMP_CLAUSE_REDUCTION) \ \| (1u << PRAGMA_OMP_CLAUSE_ORDERED) \ \| (1u << PRAGMA_OMP_CLAUSE_SCHEDULE) \ \| (1u << PRAGMA_OMP_CLAUSE_NOWAIT)) static tree cp_parser_omp_for (cp_parser parser, cp_token pragma_tok) { tree clauses, sb, ret; unsigned int save; clauses = cp_parser_omp_all_clauses (parser, OMP_FOR_CLAUSE_MASK, "#pragma omp for", pragma_tok); sb = begin_omp_structured_block (); save = cp_parser_begin_omp_structured_block (parser); ret = cp_parser_omp_for_loop (parser); if (ret) OMP_FOR_CLAUSES (ret) = clauses; cp_parser_end_omp_structured_block (parser, save); add_stmt (finish_omp_structured_block (sb)); return ret; } / OpenMP 2.5: # pragma omp master new-line structured-block / static tree cp_parser_omp_master (cp_parser parser, cp_token pragma_tok) { cp_parser_require_pragma_eol (parser, pragma_tok); return c_finish_omp_master (cp_parser_omp_structured_block (parser)); } / OpenMP 2.5: # pragma omp ordered new-line structured-block / static tree cp_parser_omp_ordered (cp_parser parser, cp_token pragma_tok) { cp_parser_require_pragma_eol (parser, pragma_tok); return c_finish_omp_ordered (cp_parser_omp_structured_block (parser)); } / OpenMP 2.5: section-scope: { section-sequence } section-sequence: section-directive[opt] structured-block section-sequence section-directive structured-block / static tree cp_parser_omp_sections_scope (cp_parser parser) { tree stmt, substmt; bool error_suppress = false; cp_token tok; if (!cp_parser_require (parser, CPP_OPEN_BRACE, "`{'")) return NULL_TREE; stmt = push_stmt_list (); if (cp_lexer_peek_token (parser->lexer)->pragma_kind != PRAGMA_OMP_SECTION) { unsigned save; substmt = begin_omp_structured_block (); save = cp_parser_begin_omp_structured_block (parser); while (1) { cp_parser_statement (parser, NULL_TREE, false); tok = cp_lexer_peek_token (parser->lexer); if (tok->pragma_kind == PRAGMA_OMP_SECTION) break; if (tok->type == CPP_CLOSE_BRACE) break; if (tok->type == CPP_EOF) break; } cp_parser_end_omp_structured_block (parser, save); substmt = finish_omp_structured_block (substmt); substmt = build1 (OMP_SECTION, void_type_node, substmt); add_stmt (substmt); } while (1) { tok = cp_lexer_peek_token (parser->lexer); if (tok->type == CPP_CLOSE_BRACE) break; if (tok->type == CPP_EOF) break; if (tok->pragma_kind == PRAGMA_OMP_SECTION) { cp_lexer_consume_token (parser->lexer); cp_parser_require_pragma_eol (parser, tok); error_suppress = false; } else if (!error_suppress) { cp_parser_error (parser, "expected %<#pragma omp section%> or %<}%>"); error_suppress = true; } substmt = cp_parser_omp_structured_block (parser); substmt = build1 (OMP_SECTION, void_type_node, substmt); add_stmt (substmt); } cp_parser_require (parser, CPP_CLOSE_BRACE, "`}'"); substmt = pop_stmt_list (stmt); stmt = make_node (OMP_SECTIONS); TREE_TYPE (stmt) = void_type_node; OMP_SECTIONS_BODY (stmt) = substmt; add_stmt (stmt); return stmt; } / OpenMP 2.5: # pragma omp sections sections-clause[optseq] newline sections-scope / #define OMP_SECTIONS_CLAUSE_MASK \ ( (1u << PRAGMA_OMP_CLAUSE_PRIVATE) \ \| (1u << PRAGMA_OMP_CLAUSE_FIRSTPRIVATE) \ \| (1u << PRAGMA_OMP_CLAUSE_LASTPRIVATE) \ \| (1u << PRAGMA_OMP_CLAUSE_REDUCTION) \ \| (1u << PRAGMA_OMP_CLAUSE_NOWAIT)) static tree cp_parser_omp_sections (cp_parser parser, cp_token pragma_tok) { tree clauses, ret; clauses = cp_parser_omp_all_clauses (parser, OMP_SECTIONS_CLAUSE_MASK, "#pragma omp sections", pragma_tok); ret = cp_parser_omp_sections_scope (parser); if (ret) OMP_SECTIONS_CLAUSES (ret) = clauses; return ret; } / OpenMP 2.5: # pragma parallel parallel-clause new-line # pragma parallel for parallel-for-clause new-line # pragma parallel sections parallel-sections-clause new-line / #define OMP_PARALLEL_CLAUSE_MASK \ ( (1u << PRAGMA_OMP_CLAUSE_IF) \ \| (1u << PRAGMA_OMP_CLAUSE_PRIVATE) \ \| (1u << PRAGMA_OMP_CLAUSE_FIRSTPRIVATE) \ \| (1u << PRAGMA_OMP_CLAUSE_DEFAULT) \ \| (1u << PRAGMA_OMP_CLAUSE_SHARED) \ \| (1u << PRAGMA_OMP_CLAUSE_COPYIN) \ \| (1u << PRAGMA_OMP_CLAUSE_REDUCTION) \ \| (1u << PRAGMA_OMP_CLAUSE_NUM_THREADS)) static tree cp_parser_omp_parallel (cp_parser parser, cp_token pragma_tok) { enum pragma_kind p_kind = PRAGMA_OMP_PARALLEL; const char p_name = "#pragma omp parallel"; tree stmt, clauses, par_clause, ws_clause, block; unsigned int mask = OMP_PARALLEL_CLAUSE_MASK; unsigned int save; if (cp_lexer_next_token_is_keyword (parser->lexer, RID_FOR)) { cp_lexer_consume_token (parser->lexer); p_kind = PRAGMA_OMP_PARALLEL_FOR; p_name = "#pragma omp parallel for"; mask \|= OMP_FOR_CLAUSE_MASK; mask &= ~(1u << PRAGMA_OMP_CLAUSE_NOWAIT); } else if (cp_lexer_next_token_is (parser->lexer, CPP_NAME)) { tree id = cp_lexer_peek_token (parser->lexer)->u.value; const char p = IDENTIFIER_POINTER (id); if (strcmp (p, "sections") == 0) { cp_lexer_consume_token (parser->lexer); p_kind = PRAGMA_OMP_PARALLEL_SECTIONS; p_name = "#pragma omp parallel sections"; mask \|= OMP_SECTIONS_CLAUSE_MASK; mask &= ~(1u << PRAGMA_OMP_CLAUSE_NOWAIT); } } clauses = cp_parser_omp_all_clauses (parser, mask, p_name, pragma_tok); block = begin_omp_parallel (); save = cp_parser_begin_omp_structured_block (parser); switch (p_kind) { case PRAGMA_OMP_PARALLEL: cp_parser_already_scoped_statement (parser); par_clause = clauses; break; case PRAGMA_OMP_PARALLEL_FOR: c_split_parallel_clauses (clauses, &par_clause, &ws_clause); stmt = cp_parser_omp_for_loop (parser); if (stmt) OMP_FOR_CLAUSES (stmt) = ws_clause; break; case PRAGMA_OMP_PARALLEL_SECTIONS: c_split_parallel_clauses (clauses, &par_clause, &ws_clause); stmt = cp_parser_omp_sections_scope (parser); if (stmt) OMP_SECTIONS_CLAUSES (stmt) = ws_clause; break; default: gcc_unreachable (); } cp_parser_end_omp_structured_block (parser, save); stmt = finish_omp_parallel (par_clause, block); if (p_kind != PRAGMA_OMP_PARALLEL) OMP_PARALLEL_COMBINED (stmt) = 1; return stmt; } / OpenMP 2.5: # pragma omp single single-clause[optseq] new-line structured-block / #define OMP_SINGLE_CLAUSE_MASK \ ( (1u << PRAGMA_OMP_CLAUSE_PRIVATE) \ \| (1u << PRAGMA_OMP_CLAUSE_FIRSTPRIVATE) \ \| (1u << PRAGMA_OMP_CLAUSE_COPYPRIVATE) \ \| (1u << PRAGMA_OMP_CLAUSE_NOWAIT)) static tree cp_parser_omp_single (cp_parser parser, cp_token pragma_tok) { tree stmt = make_node (OMP_SINGLE); TREE_TYPE (stmt) = void_type_node; OMP_SINGLE_CLAUSES (stmt) = cp_parser_omp_all_clauses (parser, OMP_SINGLE_CLAUSE_MASK, "#pragma omp single", pragma_tok); OMP_SINGLE_BODY (stmt) = cp_parser_omp_structured_block (parser); return add_stmt (stmt); } / OpenMP 2.5: # pragma omp threadprivate (variable-list) / static void cp_parser_omp_threadprivate (cp_parser parser, cp_token pragma_tok) { tree vars; vars = cp_parser_omp_var_list (parser, 0, NULL); cp_parser_require_pragma_eol (parser, pragma_tok); if (!targetm.have_tls) sorry ("threadprivate variables not supported in this target"); finish_omp_threadprivate (vars); } / Main entry point to OpenMP statement pragmas. / static void cp_parser_omp_construct (cp_parser parser, cp_token pragma_tok) { tree stmt; switch (pragma_tok->pragma_kind) { case PRAGMA_OMP_ATOMIC: cp_parser_omp_atomic (parser, pragma_tok); return; case PRAGMA_OMP_CRITICAL: stmt = cp_parser_omp_critical (parser, pragma_tok); break; case PRAGMA_OMP_FOR: stmt = cp_parser_omp_for (parser, pragma_tok); break; case PRAGMA_OMP_MASTER: stmt = cp_parser_omp_master (parser, pragma_tok); break; case PRAGMA_OMP_ORDERED: stmt = cp_parser_omp_ordered (parser, pragma_tok); break; case PRAGMA_OMP_PARALLEL: stmt = cp_parser_omp_parallel (parser, pragma_tok); break; case PRAGMA_OMP_SECTIONS: stmt = cp_parser_omp_sections (parser, pragma_tok); break; case PRAGMA_OMP_SINGLE: stmt = cp_parser_omp_single (parser, pragma_tok); break; default: gcc_unreachable (); } if (stmt) SET_EXPR_LOCATION (stmt, pragma_tok->location); } / The parser. / static GTY (()) cp_parser the_parser; /* Special handling for the first token or line in the file. The first thing in the file might be #pragma GCC pch_preprocess, which loads a PCH file, which is a GC collection point. So we need to handle this first pragma without benefit of an existing lexer structure. Always returns one token to the caller in FIRST_TOKEN. This is either the true first token of the file, or the first token after the initial pragma. / static void cp_parser_initial_pragma (cp_token first_token) { tree name = NULL; cp_lexer_get_preprocessor_token (NULL, first_token); if (first_token->pragma_kind != PRAGMA_GCC_PCH_PREPROCESS) return; cp_lexer_get_preprocessor_token (NULL, first_token); if (first_token->type == CPP_STRING) { name = first_token->u.value; cp_lexer_get_preprocessor_token (NULL, first_token); if (first_token->type != CPP_PRAGMA_EOL) error ("junk at end of %<#pragma GCC pch_preprocess%>"); } else error ("expected string literal"); / Skip to the end of the pragma. / while (first_token->type != CPP_PRAGMA_EOL && first_token->type != CPP_EOF) cp_lexer_get_preprocessor_token (NULL, first_token); / Now actually load the PCH file. / if (name) c_common_pch_pragma (parse_in, TREE_STRING_POINTER (name)); / Read one more token to return to our caller. We have to do this after reading the PCH file in, since its pointers have to be live. / cp_lexer_get_preprocessor_token (NULL, first_token); } / Normal parsing of a pragma token. Here we can (and must) use the regular lexer. / static bool cp_parser_pragma (cp_parser parser, enum pragma_context context) { cp_token pragma_tok; unsigned int id; pragma_tok = cp_lexer_consume_token (parser->lexer); gcc_assert (pragma_tok->type == CPP_PRAGMA); parser->lexer->in_pragma = true; id = pragma_tok->pragma_kind; switch (id) { case PRAGMA_GCC_PCH_PREPROCESS: error ("%<#pragma GCC pch_preprocess%> must be first"); break; case PRAGMA_OMP_BARRIER: switch (context) { case pragma_compound: cp_parser_omp_barrier (parser, pragma_tok); return false; case pragma_stmt: error ("%<#pragma omp barrier%> may only be " "used in compound statements"); break; default: goto bad_stmt; } break; case PRAGMA_OMP_FLUSH: switch (context) { case pragma_compound: cp_parser_omp_flush (parser, pragma_tok); return false; case pragma_stmt: error ("%<#pragma omp flush%> may only be " "used in compound statements"); break; default: goto bad_stmt; } break; case PRAGMA_OMP_THREADPRIVATE: cp_parser_omp_threadprivate (parser, pragma_tok); return false; case PRAGMA_OMP_ATOMIC: case PRAGMA_OMP_CRITICAL: case PRAGMA_OMP_FOR: case PRAGMA_OMP_MASTER: case PRAGMA_OMP_ORDERED: case PRAGMA_OMP_PARALLEL: case PRAGMA_OMP_SECTIONS: case PRAGMA_OMP_SINGLE: if (context == pragma_external) goto bad_stmt; cp_parser_omp_construct (parser, pragma_tok); return true; case PRAGMA_OMP_SECTION: error ("%<#pragma omp section%> may only be used in " "%<#pragma omp sections%> construct"); break; default: gcc_assert (id >= PRAGMA_FIRST_EXTERNAL); c_invoke_pragma_handler (id); break; bad_stmt: cp_parser_error (parser, "expected declaration specifiers"); break; } cp_parser_skip_to_pragma_eol (parser, pragma_tok); return false; } / The interface the pragma parsers have to the lexer. / enum cpp_ttype pragma_lex (tree value) { cp_token tok; enum cpp_ttype ret; tok = cp_lexer_peek_token (the_parser->lexer); ret = tok->type; value = tok->u.value; if (ret == CPP_PRAGMA_EOL \|\| ret == CPP_EOF) ret = CPP_EOF; else if (ret == CPP_STRING) value = cp_parser_string_literal (the_parser, false, false); else { cp_lexer_consume_token (the_parser->lexer); if (ret == CPP_KEYWORD) ret = CPP_NAME; } return ret; } / External interface. / / Parse one entire translation unit. / void c_parse_file (void) { bool error_occurred; static bool already_called = false; if (already_called) { sorry ("inter-module optimizations not implemented for C++"); return; } already_called = true; the_parser = cp_parser_new (); push_deferring_access_checks (flag_access_control ? dk_no_deferred : dk_no_check); error_occurred = cp_parser_translation_unit (the_parser); the_parser = NULL; } / This variable must be provided by every front end. */ int yydebug; #include "gt-cp-parser.h"
test_nest_lock_parallel.c	// RUN: %libomp-compile-and-run \| %sort-threads \| FileCheck %s // REQUIRES: ompt // UNSUPPORTED: gcc-4, gcc-5, gcc-6, gcc-7 #include "callback.h" #include <omp.h> int main() { omp_nest_lock_t nest_lock; omp_init_nest_lock(&nest_lock); #pragma omp parallel num_threads(2) { #pragma omp master { omp_set_nest_lock(&nest_lock); print_fuzzy_address(1); } #pragma omp barrier omp_test_nest_lock(&nest_lock); //should fail for non-master print_fuzzy_address(2); #pragma omp barrier #pragma omp master { omp_unset_nest_lock(&nest_lock); print_fuzzy_address(3); omp_unset_nest_lock(&nest_lock); print_fuzzy_address(4); } } omp_destroy_nest_lock(&nest_lock); // Check if libomp supports the callbacks for this test. // 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-NOT: {{^}}0: Could not register callback 'ompt_callback_nest_lock' // CHECK: 0: NULL_POINTER=[[NULL:.$]] // CHECK: {{^}}[[MASTER_ID:[0-9]+]]: ompt_event_wait_nest_lock: wait_id=[[WAIT_ID:[0-9]+]], hint=0, impl={{[0-9]+}}, codeptr_ra=[[RETURN_ADDRESS:0x[0-f]+]]{{[0-f][0-f]}} // CHECK: {{^}}[[MASTER_ID]]: ompt_event_acquired_nest_lock_first: wait_id=[[WAIT_ID]], codeptr_ra=[[RETURN_ADDRESS]]{{[0-f][0-f]}} // CHECK-NEXT: {{^}}[[MASTER_ID]]: fuzzy_address={{.}}[[RETURN_ADDRESS]] // CHECK: {{^}}[[MASTER_ID]]: ompt_event_wait_nest_lock: wait_id=[[WAIT_ID]], hint=0, impl={{[0-9]+}}, codeptr_ra=[[RETURN_ADDRESS:0x[0-f]+]]{{[0-f][0-f]}} // CHECK: {{^}}[[MASTER_ID]]: ompt_event_acquired_nest_lock_next: wait_id=[[WAIT_ID]], codeptr_ra=[[RETURN_ADDRESS]]{{[0-f][0-f]}} // CHECK-NEXT: {{^}}[[MASTER_ID]]: fuzzy_address={{.}}[[RETURN_ADDRESS]] // CHECK: {{^}}[[MASTER_ID]]: ompt_event_release_nest_lock_prev: wait_id=[[WAIT_ID]], codeptr_ra=[[RETURN_ADDRESS:0x[0-f]+]]{{[0-f][0-f]}} // CHECK-NEXT: {{^}}[[MASTER_ID]]: fuzzy_address={{.}}[[RETURN_ADDRESS]] // CHECK: {{^}}[[MASTER_ID]]: ompt_event_release_nest_lock_last: wait_id=[[WAIT_ID]], codeptr_ra=[[RETURN_ADDRESS:0x[0-f]+]]{{[0-f][0-f]}} // CHECK-NEXT: {{^}}[[MASTER_ID]]: fuzzy_address={{.}}[[RETURN_ADDRESS]] // CHECK: {{^}}[[MASTER_ID]]: ompt_event_destroy_nest_lock: wait_id=[[WAIT_ID]] // CHECK: {{^}}[[THREAD_ID:[0-9]+]]: ompt_event_wait_nest_lock: wait_id=[[WAIT_ID]], hint=0, impl={{[0-9]+}}, codeptr_ra=[[RETURN_ADDRESS:0x[0-f]+]]{{[0-f][0-f]}} // CHECK-NOT: {{^}}[[THREAD_ID]]: ompt_event_acquired_nest_lock_next: wait_id=[[WAIT_ID]] // CHECK-NEXT: {{^}}[[THREAD_ID]]: fuzzy_address={{.}}[[RETURN_ADDRESS]] return 0; }
GB_unaryop__abs_int32_uint8.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__abs_int32_uint8 // op(A') function: GB_tran__abs_int32_uint8 // C type: int32_t // A type: uint8_t // cast: int32_t cij = (int32_t) aij // unaryop: cij = GB_IABS (aij) #define GB_ATYPE \ uint8_t #define GB_CTYPE \ int32_t // aij = Ax [pA] #define GB_GETA(aij,Ax,pA) \ uint8_t aij = Ax [pA] #define GB_CX(p) Cx [p] // unary operator #define GB_OP(z, x) \ z = GB_IABS (x) ; // casting #define GB_CASTING(z, aij) \ int32_t z = (int32_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_ABS \|\| GxB_NO_INT32 \|\| GxB_NO_UINT8) //------------------------------------------------------------------------------ // Cx = op (cast (Ax)): apply a unary operator //------------------------------------------------------------------------------ GrB_Info GB_unop__abs_int32_uint8 ( int32_t Cx, // Cx and Ax may be aliased uint8_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__abs_int32_uint8 ( 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
fox_floats_timer_caching_omp_fileIO_benchmark.c	/* fox_floats_timer_caching_omp_fileIO_benchmark.c -- uses Fox's algorithm to multiply two square matrices * * Implementation of parallel matrix multiplication: * LaTeX: $C_{i,j} = \sum_{k} A_{i,k}B_{k,j}$ * * Input: * Input Matrix file name: A.dat, B.dat * * Output: * Output Matrix file name: C.dat * Output Sub-matrices file name: SubMatrices.dat * * Notes: * 1. Assumes the number of processes is a perfect square * 2. The array member of the matrices is statically allocated * * See Chap 7, pp. 113 & ff and pp. 125 & ff in PPMPI / / Compiler command: * mpiicc -O3 -qopenmp -qopt-report-phase=vec -qopt-report=3 fox_floats_timer_caching_omp_fileIO_benchmark.c * -o fox_floats_timer_caching_omp_fileIO_benchmark * * Run command: * mpirun -n -4 ./fox_floats_timer_caching_omp / / Head files / #include <stdio.h> #include <math.h> #include <stdlib.h> #include <mpi.h> #include <omp.h> // define problem scale, matrix row/col size #define PROBLEM_SCALE 4096 // define whether or not Print Matices in the Command Line #define PRINT_A 0 #define PRINT_B 0 #define PRINT_C 0 #define PRINT_LOCAL_A 0 #define PRINT_LOCAL_B 0 #define PRINT_LOCAL_C 0 // define float precision, 4 byte single-precision float or 8 byte double-precision float #define FLOAT double #define FLOAT_MPI MPI_DOUBLE // Define threads speed-up affnity in the computing #define NUM_THREADS 8 // Define threads affinity "scatter" or "compact" #define AFFINITY "KMP_AFFINITY = compact" / Type define structure of process grid / typedef struct { int p; / Total number of processes / MPI_Comm comm; / Communicator for entire grid / MPI_Comm row_comm; / Communicator for my row / MPI_Comm col_comm; / Communicator for my col / int q; / Order of grid / int my_row; / My row number / int my_col; / My column number / int my_rank; / My rank in the grid comm / } GRID_INFO_T; / Type define structure of local matrix / #define MAX 2097152 // Maximum number of elements in the array that store the local matrix (2^21) typedef struct { int n_bar; #define Order(A) ((A)->n_bar) // defination with parameters FLOAT entries[MAX]; #define Entry(A,i,j) ((((A)->entries) + ((A)->n_bar)(i) + (j))) // defination with parameters, Array dereference } LOCAL_MATRIX_T; / Function Declarations / LOCAL_MATRIX_T Local_matrix_allocate(int n_bar); void Free_local_matrix(LOCAL_MATRIX_T** local_A); void Read_matrix_A(char* prompt, LOCAL_MATRIX_T* local_A, GRID_INFO_T* grid, int n); // Read matrix A from a file void Read_matrix_B(char* prompt, LOCAL_MATRIX_T* local_B, // for continuous memory access, local A(i,k)B(k,j) = A(i,k)B^{T}(j,k) GRID_INFO_T* grid, int n); // Read matrix B from a file void Print_matrix_A(char* title, LOCAL_MATRIX_T* local_A, GRID_INFO_T* grid, int n); // Print matrix A in the command line void Print_matrix_B(char* title, LOCAL_MATRIX_T* local_B, // Speical print function for local matrix B^{T}(j,k) GRID_INFO_T* grid, int n); // Print matrix B in the command line void Print_matrix_C(char* title, LOCAL_MATRIX_T* local_C, GRID_INFO_T* grid, int n); // Print matrix C in the command line void Set_to_zero(LOCAL_MATRIX_T* local_A); void Local_matrix_multiply(LOCAL_MATRIX_T* local_A, LOCAL_MATRIX_T* local_B, LOCAL_MATRIX_T* local_C); void Build_matrix_type(LOCAL_MATRIX_T* local_A); MPI_Datatype local_matrix_mpi_t; LOCAL_MATRIX_T* temp_mat; // global LOCAL_MATRIX_T* type pointer void Print_local_matrices_A(char* title, LOCAL_MATRIX_T* local_A, GRID_INFO_T* grid); void Print_local_matrices_B(char* title, LOCAL_MATRIX_T* local_B, // Speical print function for local matrix B^{T}(j,k) GRID_INFO_T* grid); void Print_local_matrices_C(char* title, LOCAL_MATRIX_T* local_B, GRID_INFO_T* grid); void Write_matrix_C(char* title, LOCAL_MATRIX_T* local_C, GRID_INFO_T* grid, int n); // Write matrix multiplication to a file void Write_local_matrices_A(char* title, LOCAL_MATRIX_T* local_A, GRID_INFO_T* grid); // Write local matrix A to a file void Write_local_matrices_B(char* title, LOCAL_MATRIX_T* local_B, // Speical print function for local matrix B^{T}(j,k) GRID_INFO_T* grid); // Write local matrix B to a file void Write_local_matrices_C(char* title, LOCAL_MATRIX_T* local_A, GRID_INFO_T* grid); // Write local matrix C to a file /********************************************************/ main(int argc, char argv[]) { FILE fp; int p; int my_rank; GRID_INFO_T grid; LOCAL_MATRIX_T local_A; LOCAL_MATRIX_T* local_B; LOCAL_MATRIX_T* local_C; int n; int n_bar; double timer_start; double timer_end; int content; int i; int j; void Setup_grid(GRID_INFO_T* grid); void Fox(int n, GRID_INFO_T* grid, LOCAL_MATRIX_T* local_A, LOCAL_MATRIX_T* local_B, LOCAL_MATRIX_T* local_C); // Matrix Generator fp = fopen("A.dat", "w"); // Generate and print matrix A into a file for (i = 0; i < PROBLEM_SCALE; i++) { for (j = 0; j < PROBLEM_SCALE; j++) if(i == j){ fprintf(fp,"%d ", 1); } else { fprintf(fp,"%d ", 0); } fprintf(fp,"\n"); } fclose(fp); fp = fopen("B.dat", "w"); // Generate and print matrix B into a file for (i = 0; i < PROBLEM_SCALE; i++){ for (j = 0; j < PROBLEM_SCALE; j++) fprintf(fp,"%d ", (iPROBLEM_SCALE)+j); fprintf(fp, "\n"); } fclose(fp); // SPMD Mode start from here (Processess fork from here) MPI_Init(&argc, &argv); // MPI initializing MPI_Comm_rank(MPI_COMM_WORLD, &my_rank); // Get my process id in the MPI communicator // Initial OpenMP Environment omp_set_num_threads(NUM_THREADS); kmp_set_defaults(AFFINITY); Setup_grid(&grid); // Set up Processess grid if (my_rank == 0) { fp = fopen("A.dat","r"); n = 0; while((content = fgetc(fp)) != EOF) { //printf("fgetc = %d\n", content); if(content != 0x20 && content != 0x0A) n++; } fclose(fp); n = (int) sqrt((double) n); printf("We read the order of the matrices from A.dat is\n %d\n", n); // while(fgetc(fp) != EOF) n++; // printf("What's the order of the matrices?\n"); // scanf("%d", &n); // Overall Matrix's Order } MPI_Bcast(&n, 1, MPI_INT, 0, MPI_COMM_WORLD); // MPI broadcast the overall matrix's order n_bar = n/grid.q; // \bar n is the local matrix's order local_A = Local_matrix_allocate(n_bar); // Allocate local matrix A Order(local_A) = n_bar; // Local matrix A's order Read_matrix_A("Read A from A.dat", local_A, &grid, n); // Read local matrices A from process 0 by using stdin, and send them to each process (Procedure) if (PRINT_A == 1) Print_matrix_A("We read A =", local_A, &grid, n);// Print local matrices A from process 0 by using stdout, and send them to each process (Procedure) local_B = Local_matrix_allocate(n_bar); // Allocate local matrix Order(local_B) = n_bar; // Local matrix B's order Read_matrix_B("Read B from B.dat", local_B, &grid, n); // Read local matrix B as it's local transpose from process 0 by using stdin, and send them to each process (Procedure) if (PRINT_B == 1) Print_matrix_B("We read B =", local_B, &grid, n);// Print local matrix B as it's local transpose from process 0 by using stdout, and send them to each process (Procedure) Build_matrix_type(local_A); // Buid local_A's MPI matrix data type temp_mat = Local_matrix_allocate(n_bar); // Allocate temporary matrix of order n $\time$ n local_C = Local_matrix_allocate(n_bar); // Allocate matrix local_C Order(local_C) = n_bar; // Set matrix local_C's order MPI_Barrier(MPI_COMM_WORLD); // Set the MPI process barrier timer_start = MPI_Wtime(); // Get the MPI wall time Fox(n, &grid, local_A, local_B, local_C); // FOX parallel matrix multiplication Algorithm implement function timer_end = MPI_Wtime(); // Get the MPI wall time MPI_Barrier(MPI_COMM_WORLD); // Set the MPI process barrier Write_matrix_C("Write C into the C.dat", local_C, &grid, n); // Print matrix local_C (parallel matrix multiplication result) if (PRINT_C == 1) Print_matrix_C("The product is", local_C, &grid, n); // Print matrix local_C (parallel matrix multiplication result) Write_local_matrices_A("Write split of local matrix A into local_A.dat", local_A, &grid); // Write local matrix A into file if (PRINT_LOCAL_A == 1) Print_local_matrices_A("Split of local matrix A", local_A, &grid); // Print matrix A split in processess Write_local_matrices_B("Write split of local matrix B into local_B.dat", local_B, &grid); // Write local matrix B into file, special for row-major storage if (PRINT_LOCAL_B == 1) Print_local_matrices_B("Split of local matrix B", local_B, &grid); // Print matrix B split in processess, special for row-major storage Write_local_matrices_C("Write split of local matrix C into local_C.dat", local_C, &grid); // Print matrix C split in processess if (PRINT_LOCAL_C == 1) Print_local_matrices_C("Split of local matrix C", local_C, &grid); // Print matrix C split in processess Free_local_matrix(&local_A); // Free local matrix local_A Free_local_matrix(&local_B); // Free local matrix local_B Free_local_matrix(&local_C); // Free local matrix local_C if(my_rank == 0) printf("Parallel Fox Matrix Multiplication Elapsed time:\n %30.20E seconds\n", timer_end-timer_start); MPI_Finalize(); // MPI finalize, processes join and resource recycle } / main / /*******************************************************/ void Setup_grid( GRID_INFO_T grid /* out /) { int old_rank; int dimensions[2]; int wrap_around[2]; int coordinates[2]; int free_coords[2]; / Set up Global Grid Information / MPI_Comm_size(MPI_COMM_WORLD, &(grid->p)); MPI_Comm_rank(MPI_COMM_WORLD, &old_rank); / We assume p is a perfect square / // but what if it's not a perfect square grid->q = (int) sqrt((double) grid->p); dimensions[0] = dimensions[1] = grid->q; / We want a circular shift in second dimension. / / Don't care about first / wrap_around[0] = wrap_around[1] = 1; MPI_Cart_create(MPI_COMM_WORLD, 2, dimensions, wrap_around, 1, &(grid->comm)); MPI_Comm_rank(grid->comm, &(grid->my_rank)); MPI_Cart_coords(grid->comm, grid->my_rank, 2, coordinates); grid->my_row = coordinates[0]; grid->my_col = coordinates[1]; / Set up row communicators / free_coords[0] = 0; free_coords[1] = 1; MPI_Cart_sub(grid->comm, free_coords, &(grid->row_comm)); / Set up column communicators / free_coords[0] = 1; free_coords[1] = 0; MPI_Cart_sub(grid->comm, free_coords, &(grid->col_comm)); } / Setup_grid / /*******************************************************/ void Fox( int n / in /, GRID_INFO_T grid /* in /, LOCAL_MATRIX_T local_A /* in /, LOCAL_MATRIX_T local_B /* in /, LOCAL_MATRIX_T local_C /* out /) { LOCAL_MATRIX_T temp_A; /* Storage for the sub- / / matrix of A used during / / the current stage / int stage; int bcast_root; int n_bar; / n/sqrt(p) / int source; int dest; MPI_Status status; n_bar = n/grid->q; Set_to_zero(local_C); / Calculate addresses for row circular shift of B / source = (grid->my_row + 1) % grid->q; dest = (grid->my_row + grid->q - 1) % grid->q; / Set aside storage for the broadcast block of A / temp_A = Local_matrix_allocate(n_bar); for (stage = 0; stage < grid->q; stage++) { bcast_root = (grid->my_row + stage) % grid->q; if (bcast_root == grid->my_col) { // Process P_{ii} broadcast A_{ii} in process gird's row commnunicator MPI_Bcast(local_A, 1, local_matrix_mpi_t, bcast_root, grid->row_comm); Local_matrix_multiply(local_A, local_B, local_C); } else { // temp_A is a buffer for process P_{ij} to store A_{ij} MPI_Bcast(temp_A, 1, local_matrix_mpi_t, bcast_root, grid->row_comm); Local_matrix_multiply(temp_A, local_B, local_C); } MPI_Sendrecv_replace(local_B, 1, local_matrix_mpi_t, // MPI send and receive with single buffer dest, 0, source, 0, grid->col_comm, &status); // Circular shift of process grid B's row, after local multiplication operation } / for / } / Fox / /*******************************************************/ LOCAL_MATRIX_T Local_matrix_allocate(int local_order) { LOCAL_MATRIX_T* temp; temp = (LOCAL_MATRIX_T) malloc(sizeof(LOCAL_MATRIX_T)); return temp; } / Local_matrix_allocate / /******************************************************/ void Free_local_matrix( LOCAL_MATRIX_T local_A_ptr /* in/out /) { free(local_A_ptr); } /* Free_local_matrix / /*******************************************************/ / Read and distribute matrix for matrix A: * foreach global row of the matrix, * foreach grid column * read a block of n_bar floats on process 0 * and send them to the appropriate process. / void Read_matrix_A( char prompt /* in /, LOCAL_MATRIX_T local_A /* out /, GRID_INFO_T grid /* in /, int n / in /) { FILE fp; int mat_row, mat_col; int grid_row, grid_col; int dest; int coords[2]; FLOAT* temp; MPI_Status status; if (grid->my_rank == 0) { // Process 0 read matrix input from stdin and send them to other processess fp = fopen("A.dat","r"); temp = (FLOAT) malloc(Order(local_A)sizeof(FLOAT)); printf("%s\n", prompt); fflush(stdout); for (mat_row = 0; mat_row < n; mat_row++) { grid_row = mat_row/Order(local_A); coords[0] = grid_row; for (grid_col = 0; grid_col < grid->q; grid_col++) { coords[1] = grid_col; MPI_Cart_rank(grid->comm, coords, &dest); if (dest == 0) { for (mat_col = 0; mat_col < Order(local_A); mat_col++) fscanf(fp, "%lf", (local_A->entries)+mat_rowOrder(local_A)+mat_col); / scanf("%lf", (local_A->entries)+mat_rowOrder(local_A)+mat_col); / } else { for(mat_col = 0; mat_col < Order(local_A); mat_col++) fscanf(fp,"%lf", temp + mat_col); // scanf("%lf", temp + mat_col); MPI_Send(temp, Order(local_A), FLOAT_MPI, dest, 0, grid->comm); } } } free(temp); fclose(fp); } else { // Other processess receive matrix from process 0 for (mat_row = 0; mat_row < Order(local_A); mat_row++) MPI_Recv(&Entry(local_A, mat_row, 0), Order(local_A), FLOAT_MPI, 0, 0, grid->comm, &status); } } /* Read_matrix / /*******************************************************/ / Read and distribute matrix for local matrix B's transpose: * foreach global row of the matrix, * foreach grid column * read a block of n_bar floats on process 0 * and send them to the appropriate process. / void Read_matrix_B( char prompt /* in /, LOCAL_MATRIX_T local_B /* out /, GRID_INFO_T grid /* in /, int n / in /) { FILE fp; int mat_row, mat_col; int grid_row, grid_col; int dest; int coords[2]; FLOAT temp; MPI_Status status; if (grid->my_rank == 0) { // Process 0 read matrix input from stdin and send them to other processess fp = fopen("B.dat","r"); temp = (FLOAT) malloc(Order(local_B)sizeof(FLOAT)); printf("%s\n", prompt); fflush(stdout); for (mat_row = 0; mat_row < n; mat_row++) { grid_row = mat_row/Order(local_B); coords[0] = grid_row; for (grid_col = 0; grid_col < grid->q; grid_col++) { coords[1] = grid_col; MPI_Cart_rank(grid->comm, coords, &dest); if (dest == 0) { // process 0 (local) for (mat_col = 0; mat_col < Order(local_B); mat_col++) fscanf(fp, "%lf", (local_B->entries)+mat_colOrder(local_B)+mat_row); // switch rows and colums in local_B, for column major storage /* scanf("%lf", (local_B->entries)+mat_colOrder(local_B)+mat_row); // switch rows and colums in local_B, for column major storage / /* scanf("%lf", (local_A->entries)+mat_rowOrder(local_A)+mat_col); / } else { for(mat_col = 0; mat_col < Order(local_B); mat_col++) fscanf(fp, "%lf", temp + mat_col); // scanf("%lf", temp + mat_col); MPI_Send(temp, Order(local_B), FLOAT_MPI, dest, 0, grid->comm); } } } free(temp); fclose(fp); } else { // Other processess receive matrix from process 0 temp = (FLOAT) malloc(Order(local_B)sizeof(FLOAT)); // switch rows and colums in local_B, for column major storage for (mat_col = 0; mat_col < Order(local_B); mat_col++) { MPI_Recv(temp, Order(local_B), FLOAT_MPI, 0, 0, grid->comm, &status); // switch rows and colums in local_B, for column major storage for(mat_row = 0; mat_row < Order(local_B); mat_row++) Entry(local_B, mat_row, mat_col) = (temp + mat_row); // switch rows and colums in local_B, for column major storage / MPI_Recv(&Entry(local_A, mat_row, 0), Order(local_A), FLOAT_MPI, 0, 0, grid->comm, &status); / } free(temp); } } / Read_matrix_B / /*******************************************************/ / Recive and Print Matrix A: * foreach global row of the matrix, * foreach grid column * send n_bar floats to process 0 from each other process * receive a block of n_bar floats on process 0 from other processes and print them / void Print_matrix_A( char title /* in /, LOCAL_MATRIX_T local_A /* out /, GRID_INFO_T grid /* in /, int n / in /) { int mat_row, mat_col; int grid_row, grid_col; int source; int coords[2]; FLOAT temp; MPI_Status status; if (grid->my_rank == 0) { temp = (FLOAT) malloc(Order(local_A)sizeof(FLOAT)); printf("%s\n", title); for (mat_row = 0; mat_row < n; mat_row++) { grid_row = mat_row/Order(local_A); coords[0] = grid_row; for (grid_col = 0; grid_col < grid->q; grid_col++) { coords[1] = grid_col; MPI_Cart_rank(grid->comm, coords, &source); if (source == 0) { for(mat_col = 0; mat_col < Order(local_A); mat_col++) printf("%20.15E ", Entry(local_A, mat_row, mat_col)); } else { MPI_Recv(temp, Order(local_A), FLOAT_MPI, source, 0, grid->comm, &status); for(mat_col = 0; mat_col < Order(local_A); mat_col++) printf("%20.15E ", temp[mat_col]); } } printf("\n"); } free(temp); } else { for (mat_row = 0; mat_row < Order(local_A); mat_row++) MPI_Send(&Entry(local_A, mat_row, 0), Order(local_A), FLOAT_MPI, 0, 0, grid->comm); } } /* Print_matrix_A / /*******************************************************/ / Recive and Print Matrix for local matrix B's transpose: * foreach global row of the matrix, * foreach grid column * send n_bar floats to process 0 from each other process * receive a block of n_bar floats on process 0 from other processes and print them / void Print_matrix_B( char title /* in /, LOCAL_MATRIX_T local_B /* out /, GRID_INFO_T grid /* in /, int n / in /) { int mat_row, mat_col; int grid_row, grid_col; int source; int coords[2]; FLOAT temp; MPI_Status status; if (grid->my_rank == 0) { temp = (FLOAT) malloc(Order(local_B)sizeof(FLOAT)); printf("%s\n", title); for (mat_row = 0; mat_row < n; mat_row++) { grid_row = mat_row/Order(local_B); coords[0] = grid_row; for (grid_col = 0; grid_col < grid->q; grid_col++) { coords[1] = grid_col; MPI_Cart_rank(grid->comm, coords, &source); if (source == 0) { for(mat_col = 0; mat_col < Order(local_B); mat_col++) printf("%20.15E ", Entry(local_B, mat_col, mat_row)); // switch rows and colums in local_B, for column major storage // printf("%20.15E ", Entry(local_A, mat_row, mat_col)); } else { MPI_Recv(temp, Order(local_B), FLOAT_MPI, source, 0, grid->comm, &status); for(mat_col = 0; mat_col < Order(local_B); mat_col++) printf("%20.15E ", temp[mat_col]); } } printf("\n"); } free(temp); } else { temp = (FLOAT) malloc(Order(local_B)sizeof(FLOAT)); for (mat_col = 0; mat_col < Order(local_B); mat_col++) { for(mat_row = 0; mat_row < Order(local_B); mat_row++) (temp+mat_row) = Entry(local_B, mat_row, mat_col); // switch rows and colums in local_B, for column major storage MPI_Send(temp, Order(local_B), FLOAT_MPI, 0, 0, grid->comm); } free(temp); } } / Print_matrix_B / /*******************************************************/ / Recive and Print Matrix A: * foreach global row of the matrix, * foreach grid column * send n_bar floats to process 0 from each other process * receive a block of n_bar floats on process 0 from other processes and print them / void Print_matrix_C( char title /* in /, LOCAL_MATRIX_T local_C /* out /, GRID_INFO_T grid /* in /, int n / in /) { int mat_row, mat_col; int grid_row, grid_col; int source; int coords[2]; FLOAT temp; MPI_Status status; if (grid->my_rank == 0) { temp = (FLOAT) malloc(Order(local_C)sizeof(FLOAT)); printf("%s\n", title); for (mat_row = 0; mat_row < n; mat_row++) { grid_row = mat_row/Order(local_C); coords[0] = grid_row; for (grid_col = 0; grid_col < grid->q; grid_col++) { coords[1] = grid_col; MPI_Cart_rank(grid->comm, coords, &source); if (source == 0) { for(mat_col = 0; mat_col < Order(local_C); mat_col++) printf("%20.15E ", Entry(local_C, mat_row, mat_col)); } else { MPI_Recv(temp, Order(local_C), FLOAT_MPI, source, 0, grid->comm, &status); for(mat_col = 0; mat_col < Order(local_C); mat_col++) printf("%20.15E ", temp[mat_col]); } } printf("\n"); } free(temp); } else { for (mat_row = 0; mat_row < Order(local_C); mat_row++) MPI_Send(&Entry(local_C, mat_row, 0), Order(local_C), FLOAT_MPI, 0, 0, grid->comm); } } /* Print_matrix_C / /*******************************************************/ / Recive and Write Matrix C into a file: * foreach global row of the matrix, * foreach grid column * send n_bar floats to process 0 from each other process * receive a block of n_bar floats on process 0 from other processes and print them / void Write_matrix_C( char title /* in /, LOCAL_MATRIX_T local_C /* out /, GRID_INFO_T grid /* in /, int n / in /) { FILE fp; int mat_row, mat_col; int grid_row, grid_col; int source; int coords[2]; FLOAT* temp; MPI_Status status; if (grid->my_rank == 0) { fp = fopen("C.dat", "w+"); temp = (FLOAT) malloc(Order(local_C)sizeof(FLOAT)); printf("%s\n", title); for (mat_row = 0; mat_row < n; mat_row++) { grid_row = mat_row/Order(local_C); coords[0] = grid_row; for (grid_col = 0; grid_col < grid->q; grid_col++) { coords[1] = grid_col; MPI_Cart_rank(grid->comm, coords, &source); if (source == 0) { for(mat_col = 0; mat_col < Order(local_C); mat_col++) fprintf(fp, "%20.15E ", Entry(local_C, mat_row, mat_col)); // printf("%20.15E ", Entry(local_A, mat_row, mat_col)); } else { MPI_Recv(temp, Order(local_C), FLOAT_MPI, source, 0, grid->comm, &status); for(mat_col = 0; mat_col < Order(local_C); mat_col++) fprintf(fp, "%20.15E ", temp[mat_col]); // printf("%20.15E ", temp[mat_col]); } } fprintf(fp,"\n"); } free(temp); fclose(fp); } else { for (mat_row = 0; mat_row < Order(local_C); mat_row++) MPI_Send(&Entry(local_C, mat_row, 0), Order(local_C), FLOAT_MPI, 0, 0, grid->comm); } } /* Write_matrix_C / /*******************************************************/ / * Set local matrix's element to zero / void Set_to_zero( LOCAL_MATRIX_T local_A /* out /) { int i, j; for (i = 0; i < Order(local_A); i++) for (j = 0; j < Order(local_A); j++) Entry(local_A,i,j) = 0.0E0; } / Set_to_zero / /*******************************************************/ void Build_matrix_type( LOCAL_MATRIX_T local_A /* in /) { MPI_Datatype temp_mpi_t; int block_lengths[2]; MPI_Aint displacements[2]; MPI_Datatype typelist[2]; MPI_Aint start_address; MPI_Aint address; MPI_Type_contiguous(Order(local_A)Order(local_A), FLOAT_MPI, &temp_mpi_t); // Creates a contiguous datatype /* Synopsis int MPI_Type_contiguous(int count, MPI_Datatype oldtype, MPI_Datatype newtype) Input Parameters count replication count (nonnegative integer) oldtype old datatype (handle) / block_lengths[0] = block_lengths[1] = 1; typelist[0] = MPI_INT; typelist[1] = temp_mpi_t; MPI_Address(local_A, &start_address); // Gets the address of a location in caller's memory MPI_Address(&(local_A->n_bar), &address); /* Synopsis int MPI_Address(const void location, MPI_Aint address) Input Parameters location location in caller memory (choice) Output Parameters address address of location (address integer) / displacements[0] = address - start_address; MPI_Address(local_A->entries, &address); displacements[1] = address - start_address; MPI_Type_struct(2, block_lengths, displacements, typelist, &local_matrix_mpi_t); // Creates a struct datatype / Synopsis int MPI_Type_struct(int count, const int array_of_blocklengths, const MPI_Aint array_of_displacements, const MPI_Datatype array_of_types, MPI_Datatype newtype) Input Parameters count number of blocks (integer) -- also number of entries in arrays array_of_types , array_of_displacements and array_of_blocklengths array_of_blocklengths number of elements in each block (array) array_of_displacements byte displacement of each block (array) array_of_types type of elements in each block (array of handles to datatype objects) Output Parameters newtype new datatype (handle) / MPI_Type_commit(&local_matrix_mpi_t); // Commits the datatype / Synopsis int MPI_Type_commit(MPI_Datatype datatype) Input Parameters datatype datatype (handle) / } /* Build_matrix_type / /*******************************************************/ / local matrix multiplication function * withing OpenMP Thread Acceleration / void Local_matrix_multiply( LOCAL_MATRIX_T local_A /* in /, LOCAL_MATRIX_T local_B /* in /, LOCAL_MATRIX_T local_C /* out /) { int i, j, k; // int my_rank; // MPI_Comm_rank(MPI_COMM_WORLD, &my_rank); // Get my process id in the MPI communicator #pragma omp parallel for private(i, j, k) shared(local_A, local_B, local_C) num_threads(NUM_THREADS) // Threads acceleration upgrade, parallel task split for (i = 0; i < Order(local_A); i++) { // printf("Current in the Fox Kernel:\n my process id is %d, my thread id is %d\n",my_rank,omp_get_thread_num()); for (j = 0; j < Order(local_A); j++) for (k = 0; k < Order(local_B); k++) Entry(local_C,i,j) = Entry(local_C,i,j) // switch rows and colums in local_B, for column major storage + Entry(local_A,i,k)Entry(local_B,j,k); // continuous memory access, local matrix multiplication A(i,k)B^T(j,k) / Entry(local_C,i,j) = Entry(local_C,i,j) + Entry(local_A,i,k)Entry(local_B,k,j); // non-continuous memory access, A(i,k)B^T(j,k) is more proper / } } / Local_matrix_multiply / /*******************************************************/ / Recive and Print Local Matrix A: * Process 0 print local matrix local_A * Other Processess send local matrix local_A to process 0 * And process 0 receive local matrix local_A from other processess / void Print_local_matrices_A( char title /* in /, LOCAL_MATRIX_T local_A /* in /, GRID_INFO_T grid /* in /) { int coords[2]; int i, j; int source; MPI_Status status; // print by process No.0 in process mesh if (grid->my_rank == 0) { printf("%s\n", title); printf("Process %d > grid_row = %d, grid_col = %d\n", grid->my_rank, grid->my_row, grid->my_col); for (i = 0; i < Order(local_A); i++) { for (j = 0; j < Order(local_A); j++) printf("%20.15E ", Entry(local_A,i,j)); printf("\n"); } for (source = 1; source < grid->p; source++) { MPI_Recv(temp_mat, 1, local_matrix_mpi_t, source, 0, grid->comm, &status); MPI_Cart_coords(grid->comm, source, 2, coords); printf("Process %d > grid_row = %d, grid_col = %d\n", source, coords[0], coords[1]); for (i = 0; i < Order(temp_mat); i++) { for (j = 0; j < Order(temp_mat); j++) printf("%20.15E ", Entry(temp_mat,i,j)); printf("\n"); } } fflush(stdout); } else { MPI_Send(local_A, 1, local_matrix_mpi_t, 0, 0, grid->comm); } } / Print_local_matrices_A / /*******************************************************/ / Recive and Print Local Matrix for local matrix B's transpose: * Process 0 print local matrix local_A * Other Processess send local matrix local_A to process 0 * And process 0 receive local matrix local_A from other processess / void Print_local_matrices_B( char title /* in /, LOCAL_MATRIX_T local_B /* in /, GRID_INFO_T grid /* in /) { int coords[2]; int i, j; int source; MPI_Status status; // print by process No.0 in process mesh if (grid->my_rank == 0) { printf("%s\n", title); printf("Process %d > grid_row = %d, grid_col = %d\n", grid->my_rank, grid->my_row, grid->my_col); for (i = 0; i < Order(local_B); i++) { for (j = 0; j < Order(local_B); j++) printf("%20.15E ", Entry(local_B,j,i)); // switch rows and colums in local_B, for column major storage printf("\n"); } for (source = 1; source < grid->p; source++) { MPI_Recv(temp_mat, 1, local_matrix_mpi_t, source, 0, grid->comm, &status); MPI_Cart_coords(grid->comm, source, 2, coords); printf("Process %d > grid_row = %d, grid_col = %d\n", source, coords[0], coords[1]); for (i = 0; i < Order(temp_mat); i++) { for (j = 0; j < Order(temp_mat); j++) printf("%20.15E ", Entry(temp_mat,j,i)); // switch rows and colums in local_B, for column major storage printf("\n"); } } fflush(stdout); } else { MPI_Send(local_B, 1, local_matrix_mpi_t, 0, 0, grid->comm); } } / Print_local_matrices_B / /*******************************************************/ / Recive and Print Local Matrix A: * Process 0 print local matrix local_A * Other Processess send local matrix local_A to process 0 * And process 0 receive local matrix local_A from other processess / void Print_local_matrices_C( char title /* in /, LOCAL_MATRIX_T local_C /* in /, GRID_INFO_T grid /* in /) { int coords[2]; int i, j; int source; MPI_Status status; // print by process No.0 in process mesh if (grid->my_rank == 0) { printf("%s\n", title); printf("Process %d > grid_row = %d, grid_col = %d\n", grid->my_rank, grid->my_row, grid->my_col); for (i = 0; i < Order(local_C); i++) { for (j = 0; j < Order(local_C); j++) printf("%20.15E ", Entry(local_C,i,j)); printf("\n"); } for (source = 1; source < grid->p; source++) { MPI_Recv(temp_mat, 1, local_matrix_mpi_t, source, 0, grid->comm, &status); MPI_Cart_coords(grid->comm, source, 2, coords); printf("Process %d > grid_row = %d, grid_col = %d\n", source, coords[0], coords[1]); for (i = 0; i < Order(temp_mat); i++) { for (j = 0; j < Order(temp_mat); j++) printf("%20.15E ", Entry(temp_mat,i,j)); printf("\n"); } } fflush(stdout); } else { MPI_Send(local_C, 1, local_matrix_mpi_t, 0, 0, grid->comm); } } / Print_local_matrices_C / /*******************************************************/ / Recive and Write Local Matrix A: * Process 0 print local matrix local_A * Other Processess send local matrix local_A to process 0 * And process 0 receive local matrix local_A from other processess / void Write_local_matrices_A( char title /* in /, LOCAL_MATRIX_T local_A /* in /, GRID_INFO_T grid /* in /) { FILE fp; int coords[2]; int i, j; int source; MPI_Status status; // print by process No.0 in process mesh if (grid->my_rank == 0) { fp = fopen("local_A.dat","w+"); printf("%s\n", title); fprintf(fp,"Process %d > grid_row = %d, grid_col = %d\n", grid->my_rank, grid->my_row, grid->my_col); for (i = 0; i < Order(local_A); i++) { for (j = 0; j < Order(local_A); j++) fprintf(fp,"%20.15E ", Entry(local_A,i,j)); fprintf(fp, "\n"); } for (source = 1; source < grid->p; source++) { MPI_Recv(temp_mat, 1, local_matrix_mpi_t, source, 0, grid->comm, &status); MPI_Cart_coords(grid->comm, source, 2, coords); fprintf(fp, "Process %d > grid_row = %d, grid_col = %d\n", source, coords[0], coords[1]); for (i = 0; i < Order(temp_mat); i++) { for (j = 0; j < Order(temp_mat); j++) fprintf(fp, "%20.15E ", Entry(temp_mat,i,j)); fprintf(fp, "\n"); } } fflush(stdout); fclose(fp); } else { MPI_Send(local_A, 1, local_matrix_mpi_t, 0, 0, grid->comm); } } /* Write_local_matrices_A / /*******************************************************/ / Recive and Write Local Matrix for local matrix B's transpose: * Process 0 print local matrix local_A * Other Processess send local matrix local_A to process 0 * And process 0 receive local matrix local_A from other processess / void Write_local_matrices_B( char title /* in /, LOCAL_MATRIX_T local_B /* in /, GRID_INFO_T grid /* in /) { FILE fp; int coords[2]; int i, j; int source; MPI_Status status; // print by process No.0 in process mesh if (grid->my_rank == 0) { fp = fopen("local_B.dat","w+"); printf("%s\n", title); fprintf(fp, "Process %d > grid_row = %d, grid_col = %d\n", grid->my_rank, grid->my_row, grid->my_col); for (i = 0; i < Order(local_B); i++) { for (j = 0; j < Order(local_B); j++) fprintf(fp, "%20.15E ", Entry(local_B,j,i)); // switch rows and colums in local_B, for column major storage fprintf(fp, "\n"); } for (source = 1; source < grid->p; source++) { MPI_Recv(temp_mat, 1, local_matrix_mpi_t, source, 0, grid->comm, &status); MPI_Cart_coords(grid->comm, source, 2, coords); fprintf(fp, "Process %d > grid_row = %d, grid_col = %d\n", source, coords[0], coords[1]); for (i = 0; i < Order(temp_mat); i++) { for (j = 0; j < Order(temp_mat); j++) fprintf(fp, "%20.15E ", Entry(temp_mat,j,i)); // switch rows and colums in local_B, for column major storage fprintf(fp, "\n"); } } fflush(stdout); fclose(fp); } else { MPI_Send(local_B, 1, local_matrix_mpi_t, 0, 0, grid->comm); } } /* Write_local_matrices_B / /*******************************************************/ / Recive and Write Local Matrix C: * Process 0 print local matrix local_C * Other Processess send local matrix local_C to process 0 * And process 0 receive local matrix local_C from other processess / void Write_local_matrices_C( char title /* in /, LOCAL_MATRIX_T local_C /* in /, GRID_INFO_T grid /* in /) { FILE fp; int coords[2]; int i, j; int source; MPI_Status status; // print by process No.0 in process mesh if (grid->my_rank == 0) { fp = fopen("local_C.dat","w+"); printf("%s\n", title); fprintf(fp, "Process %d > grid_row = %d, grid_col = %d\n", grid->my_rank, grid->my_row, grid->my_col); for (i = 0; i < Order(local_C); i++) { for (j = 0; j < Order(local_C); j++) fprintf(fp, "%20.15E ", Entry(local_C,i,j)); fprintf(fp, "\n"); } for (source = 1; source < grid->p; source++) { MPI_Recv(temp_mat, 1, local_matrix_mpi_t, source, 0, grid->comm, &status); MPI_Cart_coords(grid->comm, source, 2, coords); fprintf(fp, "Process %d > grid_row = %d, grid_col = %d\n", source, coords[0], coords[1]); for (i = 0; i < Order(temp_mat); i++) { for (j = 0; j < Order(temp_mat); j++) fprintf(fp, "%20.15E ", Entry(temp_mat,i,j)); fprintf(fp, "\n"); } } fflush(stdout); fclose(fp); } else { MPI_Send(local_C, 1, local_matrix_mpi_t, 0, 0, grid->comm); } } /* Write_local_matrices_C */
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 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 "magick/studio.h" #include "magick/artifact.h" #include "magick/attribute.h" #include "magick/blob.h" #include "magick/cache.h" #include "magick/image.h" #include "magick/image-private.h" #include "magick/list.h" #include "magick/fourier.h" #include "magick/log.h" #include "magick/memory_.h" #include "magick/monitor.h" #include "magick/monitor-private.h" #include "magick/pixel-accessor.h" #include "magick/pixel-private.h" #include "magick/property.h" #include "magick/quantum-private.h" #include "magick/resource_.h" #include "magick/string-private.h" #include "magick/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 { ChannelType 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, 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) == 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); } if (SetImageStorageClass(image,DirectClass) == MagickFalse) { image=DestroyImageList(image); return(image); } image->depth=32UL; AppendImageToList(&complex_images,image); /* Apply complex mathematics to image pixels. / artifact=GetImageArtifact(image,"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; 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++) { register const PixelPacket magick_restrict Ai, magick_restrict Ar, magick_restrict Bi, magick_restrict Br; register PixelPacket magick_restrict Ci, magick_restrict Cr; register 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 PixelPacket ) NULL) \|\| (Ai == (const PixelPacket ) NULL) \|\| (Br == (const PixelPacket ) NULL) \|\| (Bi == (const PixelPacket ) NULL) \|\| (Cr == (PixelPacket ) NULL) \|\| (Ci == (PixelPacket ) NULL)) { status=MagickFalse; continue; } for (x=0; x < (ssize_t) columns; x++) { switch (op) { case AddComplexOperator: { Cr->red=Ar->red+Br->red; Ci->red=Ai->red+Bi->red; Cr->green=Ar->green+Br->green; Ci->green=Ai->green+Bi->green; Cr->blue=Ar->blue+Br->blue; Ci->blue=Ai->blue+Bi->blue; if (images->matte != MagickFalse) { Cr->opacity=Ar->opacity+Br->opacity; Ci->opacity=Ai->opacity+Bi->opacity; } break; } case ConjugateComplexOperator: default: { Cr->red=Ar->red; Ci->red=(-Bi->red); Cr->green=Ar->green; Ci->green=(-Bi->green); Cr->blue=Ar->blue; Ci->blue=(-Bi->blue); if (images->matte != MagickFalse) { Cr->opacity=Ar->opacity; Ci->opacity=(-Bi->opacity); } break; } case DivideComplexOperator: { double gamma; gamma=QuantumRangePerceptibleReciprocal(QuantumScaleBr->redBr->red+ QuantumScaleBi->redBi->red+snr); Cr->red=gamma(QuantumScaleAr->redBr->red+QuantumScaleAi->red* Bi->red); Ci->red=gamma(QuantumScaleAi->redBr->red-QuantumScaleAr->red* Bi->red); gamma=QuantumRangePerceptibleReciprocal(QuantumScaleBr->green* Br->green+QuantumScaleBi->greenBi->green+snr); Cr->green=gamma(QuantumScaleAr->greenBr->green+QuantumScale Ai->greenBi->green); Ci->green=gamma(QuantumScaleAi->greenBr->green-QuantumScale* Ar->greenBi->green); gamma=QuantumRangePerceptibleReciprocal(QuantumScaleBr->blue Br->blue+QuantumScaleBi->blueBi->blue+snr); Cr->blue=gamma(QuantumScaleAr->blueBr->blue+QuantumScale Ai->blueBi->blue); Ci->blue=gamma(QuantumScaleAi->blueBr->blue-QuantumScale* Ar->blueBi->blue); if (images->matte != MagickFalse) { gamma=QuantumRangePerceptibleReciprocal(QuantumScaleBr->opacity Br->opacity+QuantumScaleBi->opacityBi->opacity+snr); Cr->opacity=gamma(QuantumScaleAr->opacityBr->opacity+ QuantumScaleAi->opacityBi->opacity); Ci->opacity=gamma(QuantumScaleAi->opacityBr->opacity- QuantumScaleAr->opacityBi->opacity); } break; } case MagnitudePhaseComplexOperator: { Cr->red=sqrt(QuantumScaleAr->redAr->red+QuantumScale* Ai->redAi->red); Ci->red=atan2((double) Ai->red,(double) Ar->red)/(2.0MagickPI)+0.5; Cr->green=sqrt(QuantumScaleAr->greenAr->green+QuantumScale* Ai->greenAi->green); Ci->green=atan2((double) Ai->green,(double) Ar->green)/ (2.0MagickPI)+0.5; Cr->blue=sqrt(QuantumScaleAr->blueAr->blue+QuantumScale* Ai->blueAi->blue); Ci->blue=atan2(Ai->blue,Ar->blue)/(2.0MagickPI)+0.5; if (images->matte != MagickFalse) { Cr->opacity=sqrt(QuantumScaleAr->opacityAr->opacity+ QuantumScaleAi->opacityAi->opacity); Ci->opacity=atan2((double) Ai->opacity,(double) Ar->opacity)/ (2.0MagickPI)+0.5; } break; } case MultiplyComplexOperator: { Cr->red=(QuantumScaleAr->redBr->red-(double) Ai->redBi->red); Ci->red=(QuantumScaleAi->redBr->red+(double) Ar->redBi->red); Cr->green=(QuantumScaleAr->greenBr->green-(double) Ai->greenBi->green); Ci->green=(QuantumScaleAi->greenBr->green+(double) Ar->greenBi->green); Cr->blue=(QuantumScaleAr->blueBr->blue-(double) Ai->blueBi->blue); Ci->blue=(QuantumScaleAi->blueBr->blue+(double) Ar->blueBi->blue); if (images->matte != MagickFalse) { Cr->opacity=(QuantumScaleAr->opacityBr->opacity- QuantumScaleAi->opacityBi->opacity); Ci->opacity=(QuantumScaleAi->opacityBr->opacity+ QuantumScaleAr->opacityBi->opacity); } break; } case RealImaginaryComplexOperator: { Cr->red=Ar->redcos(2.0MagickPI(Ai->red-0.5)); Ci->red=Ar->redsin(2.0MagickPI(Ai->red-0.5)); Cr->green=Ar->greencos(2.0MagickPI(Ai->green-0.5)); Ci->green=Ar->greensin(2.0MagickPI(Ai->green-0.5)); Cr->blue=Ar->bluecos(2.0MagickPI(Ai->blue-0.5)); Ci->blue=Ar->bluesin(2.0MagickPI(Ai->blue-0.5)); if (images->matte != MagickFalse) { Cr->opacity=Ar->opacitycos(2.0MagickPI(Ai->opacity-0.5)); Ci->opacity=Ar->opacitysin(2.0MagickPI(Ai->opacity-0.5)); } break; } case SubtractComplexOperator: { Cr->red=Ar->red-Br->red; Ci->red=Ai->red-Bi->red; Cr->green=Ar->green-Br->green; Ci->green=Ai->green-Bi->green; Cr->blue=Ar->blue-Br->blue; Ci->blue=Ai->blue-Bi->blue; if (Cr_image->matte != MagickFalse) { Cr->opacity=Ar->opacity-Br->opacity; Ci->opacity=Ai->opacity-Bi->opacity; } break; } } Ar++; Ai++; Br++; Bi++; Cr++; Ci++; } 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; register 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,heightwidth 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; register 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) { register 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; register IndexPacket indexes; register PixelPacket q; register 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 == (PixelPacket ) NULL) break; indexes=GetCacheViewAuthenticIndexQueue(magnitude_view); for (x=0L; x < (ssize_t) fourier_info->width; x++) { switch (fourier_info->channel) { case RedChannel: default: { SetPixelRed(q,ClampToQuantum(QuantumRangemagnitude_pixels[i])); break; } case GreenChannel: { SetPixelGreen(q,ClampToQuantum(QuantumRangemagnitude_pixels[i])); break; } case BlueChannel: { SetPixelBlue(q,ClampToQuantum(QuantumRangemagnitude_pixels[i])); break; } case OpacityChannel: { SetPixelOpacity(q,ClampToQuantum(QuantumRangemagnitude_pixels[i])); break; } case IndexChannel: { SetPixelIndex(indexes+x,ClampToQuantum(QuantumRange* magnitude_pixels[i])); break; } case GrayChannels: { SetPixelGray(q,ClampToQuantum(QuantumRangemagnitude_pixels[i])); break; } } i++; q++; } 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 == (PixelPacket ) NULL) break; indexes=GetCacheViewAuthenticIndexQueue(phase_view); for (x=0L; x < (ssize_t) fourier_info->width; x++) { switch (fourier_info->channel) { case RedChannel: default: { SetPixelRed(q,ClampToQuantum(QuantumRangephase_pixels[i])); break; } case GreenChannel: { SetPixelGreen(q,ClampToQuantum(QuantumRangephase_pixels[i])); break; } case BlueChannel: { SetPixelBlue(q,ClampToQuantum(QuantumRangephase_pixels[i])); break; } case OpacityChannel: { SetPixelOpacity(q,ClampToQuantum(QuantumRangephase_pixels[i])); break; } case IndexChannel: { SetPixelIndex(indexes+x,ClampToQuantum(QuantumRangephase_pixels[i])); break; } case GrayChannels: { SetPixelGray(q,ClampToQuantum(QuantumRangephase_pixels[i])); break; } } i++; q++; } 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; register const IndexPacket indexes; register const PixelPacket p; register 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 PixelPacket ) NULL) break; indexes=GetCacheViewVirtualIndexQueue(image_view); for (x=0L; x < (ssize_t) fourier_info->width; x++) { switch (fourier_info->channel) { case RedChannel: default: { source_pixels[i]=QuantumScaleGetPixelRed(p); break; } case GreenChannel: { source_pixels[i]=QuantumScaleGetPixelGreen(p); break; } case BlueChannel: { source_pixels[i]=QuantumScaleGetPixelBlue(p); break; } case OpacityChannel: { source_pixels[i]=QuantumScaleGetPixelOpacity(p); break; } case IndexChannel: { source_pixels[i]=QuantumScaleGetPixelIndex(indexes+x); break; } case GrayChannels: { source_pixels[i]=QuantumScaleGetPixelGray(p); break; } } i++; p++; } } 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 Fourier 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 ChannelType 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=IsGrayImage(image,exception); #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, GrayChannels,modulus,fourier_image,exception); else thread_status=ForwardFourierTransformChannel(image,RedChannel, 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, GreenChannel,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, BlueChannel,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->matte != MagickFalse) thread_status=ForwardFourierTransformChannel(image, OpacityChannel,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, IndexChannel,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) { register 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; register const IndexPacket indexes; register const PixelPacket p; register 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 PixelPacket ) NULL) break; indexes=GetCacheViewAuthenticIndexQueue(magnitude_view); for (x=0L; x < (ssize_t) fourier_info->width; x++) { switch (fourier_info->channel) { case RedChannel: default: { magnitude_pixels[i]=QuantumScaleGetPixelRed(p); break; } case GreenChannel: { magnitude_pixels[i]=QuantumScaleGetPixelGreen(p); break; } case BlueChannel: { magnitude_pixels[i]=QuantumScaleGetPixelBlue(p); break; } case OpacityChannel: { magnitude_pixels[i]=QuantumScaleGetPixelOpacity(p); break; } case IndexChannel: { magnitude_pixels[i]=QuantumScaleGetPixelIndex(indexes+x); break; } case GrayChannels: { magnitude_pixels[i]=QuantumScaleGetPixelGray(p); break; } } i++; p++; } } 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 PixelPacket ) NULL) break; indexes=GetCacheViewAuthenticIndexQueue(phase_view); for (x=0L; x < (ssize_t) fourier_info->width; x++) { switch (fourier_info->channel) { case RedChannel: default: { phase_pixels[i]=QuantumScaleGetPixelRed(p); break; } case GreenChannel: { phase_pixels[i]=QuantumScaleGetPixelGreen(p); break; } case BlueChannel: { phase_pixels[i]=QuantumScaleGetPixelBlue(p); break; } case OpacityChannel: { phase_pixels[i]=QuantumScaleGetPixelOpacity(p); break; } case IndexChannel: { phase_pixels[i]=QuantumScaleGetPixelIndex(indexes+x); break; } case GrayChannels: { phase_pixels[i]=QuantumScaleGetPixelGray(p); break; } } i++; p++; } } 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; double source_pixels; const char value; fftw_plan fftw_c2r_plan; MemoryInfo source_info; register IndexPacket indexes; register PixelPacket q; register 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 == (PixelPacket ) NULL) break; indexes=GetCacheViewAuthenticIndexQueue(image_view); for (x=0L; x < (ssize_t) fourier_info->width; x++) { if (x < (ssize_t) image->columns) switch (fourier_info->channel) { case RedChannel: default: { SetPixelRed(q,ClampToQuantum(QuantumRangesource_pixels[i])); break; } case GreenChannel: { SetPixelGreen(q,ClampToQuantum(QuantumRangesource_pixels[i])); break; } case BlueChannel: { SetPixelBlue(q,ClampToQuantum(QuantumRangesource_pixels[i])); break; } case OpacityChannel: { SetPixelOpacity(q,ClampToQuantum(QuantumRangesource_pixels[i])); break; } case IndexChannel: { SetPixelIndex(indexes+x,ClampToQuantum(QuantumRange* source_pixels[i])); break; } case GrayChannels: { SetPixelGray(q,ClampToQuantum(QuantumRangesource_pixels[i])); break; } } i++; q++; } 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 ChannelType 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=IsGrayImage(magnitude_image,exception); if (is_gray != MagickFalse) is_gray=IsGrayImage(phase_image,exception); #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,GrayChannels,modulus,fourier_image,exception); else thread_status=InverseFourierTransformChannel(magnitude_image, phase_image,RedChannel,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,GreenChannel,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,BlueChannel,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->matte != MagickFalse) thread_status=InverseFourierTransformChannel(magnitude_image, phase_image,OpacityChannel,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,IndexChannel,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); }
for_misc_messages.c	// RUN: %clang_cc1 -fsyntax-only -fopenmp -triple x86_64-unknown-unknown -verify %s // expected-error@+1 {{unexpected OpenMP directive '#pragma omp for'}} #pragma omp for // expected-error@+1 {{unexpected OpenMP directive '#pragma omp for'}} #pragma omp for foo void test_no_clause() { int i; #pragma omp for for (i = 0; i < 16; ++i) ; // expected-error@+2 {{statement after '#pragma omp for' must be a for loop}} #pragma omp for ++i; } void test_branch_protected_scope() { int i = 0; L1: ++i; int x[24]; #pragma omp parallel #pragma omp for for (i = 0; i < 16; ++i) { if (i == 5) goto L1; // expected-error {{use of undeclared label 'L1'}} else if (i == 6) return; // expected-error {{cannot return from OpenMP region}} else if (i == 7) goto L2; else if (i == 8) { L2: x[i]++; } } if (x[0] == 0) goto L2; // expected-error {{use of undeclared label 'L2'}} else if (x[1] == 1) goto L1; } void test_invalid_clause() { int i; #pragma omp parallel // expected-warning@+1 {{extra tokens at the end of '#pragma omp for' are ignored}} #pragma omp for foo bar for (i = 0; i < 16; ++i) ; } void test_non_identifiers() { int i, x; #pragma omp parallel // expected-warning@+1 {{extra tokens at the end of '#pragma omp for' are ignored}} #pragma omp for; for (i = 0; i < 16; ++i) ; // expected-warning@+2 {{extra tokens at the end of '#pragma omp for' are ignored}} #pragma omp parallel #pragma omp for linear(x); for (i = 0; i < 16; ++i) ; #pragma omp parallel // expected-warning@+1 {{extra tokens at the end of '#pragma omp for' are ignored}} #pragma omp for private(x); for (i = 0; i < 16; ++i) ; #pragma omp parallel // expected-warning@+1 {{extra tokens at the end of '#pragma omp for' are ignored}} #pragma omp for, private(x); for (i = 0; i < 16; ++i) ; } extern int foo(); void test_collapse() { int i; #pragma omp parallel // expected-error@+1 {{expected '('}} #pragma omp for collapse for (i = 0; i < 16; ++i) ; #pragma omp parallel // expected-error@+1 {{expected expression}} expected-error@+1 {{expected ')'}} expected-note@+1 {{to match this '('}} #pragma omp for collapse( for (i = 0; i < 16; ++i) ; #pragma omp parallel // expected-error@+1 {{expected expression}} #pragma omp for collapse() for (i = 0; i < 16; ++i) ; #pragma omp parallel // expected-error@+1 {{expected expression}} expected-error@+1 {{expected ')'}} expected-note@+1 {{to match this '('}} #pragma omp for collapse(, for (i = 0; i < 16; ++i) ; #pragma omp parallel // expected-error@+1 {{expected expression}} expected-error@+1 {{expected ')'}} expected-note@+1 {{to match this '('}} #pragma omp for collapse(, ) for (i = 0; i < 16; ++i) ; #pragma omp parallel // expected-warning@+2 {{extra tokens at the end of '#pragma omp for' are ignored}} // expected-error@+1 {{expected '('}} #pragma omp for collapse 4) for (i = 0; i < 16; ++i) ; #pragma omp parallel // expected-error@+2 {{expected ')'}} // expected-note@+1 {{to match this '('}} expected-note@+1 {{as specified in 'collapse' clause}} #pragma omp for collapse(4 for (i = 0; i < 16; ++i) ; // expected-error {{expected 4 for loops after '#pragma omp for', but found only 1}} #pragma omp parallel // expected-error@+2 {{expected ')'}} // expected-note@+1 {{to match this '('}} expected-note@+1 {{as specified in 'collapse' clause}} #pragma omp for collapse(4, for (i = 0; i < 16; ++i) ; // expected-error {{expected 4 for loops after '#pragma omp for', but found only 1}} #pragma omp parallel // expected-error@+2 {{expected ')'}} // expected-note@+1 {{to match this '('}} expected-note@+1 {{as specified in 'collapse' clause}} #pragma omp for collapse(4, ) for (i = 0; i < 16; ++i) ; // expected-error {{expected 4 for loops after '#pragma omp for', but found only 1}} #pragma omp parallel // expected-note@+1 {{as specified in 'collapse' clause}} #pragma omp for collapse(4) for (i = 0; i < 16; ++i) ; // expected-error {{expected 4 for loops after '#pragma omp for', but found only 1}} #pragma omp parallel // expected-error@+2 {{expected ')'}} // expected-note@+1 {{to match this '('}} expected-note@+1 {{as specified in 'collapse' clause}} #pragma omp for collapse(4 4) for (i = 0; i < 16; ++i) ; // expected-error {{expected 4 for loops after '#pragma omp for', but found only 1}} #pragma omp parallel // expected-error@+2 {{expected ')'}} // expected-note@+1 {{to match this '('}} expected-note@+1 {{as specified in 'collapse' clause}} #pragma omp for collapse(4, , 4) for (i = 0; i < 16; ++i) ; // expected-error {{expected 4 for loops after '#pragma omp for', but found only 1}} #pragma omp parallel #pragma omp for collapse(4) for (int i1 = 0; i1 < 16; ++i1) for (int i2 = 0; i2 < 16; ++i2) for (int i3 = 0; i3 < 16; ++i3) for (int i4 = 0; i4 < 16; ++i4) foo(); #pragma omp parallel // expected-error@+2 {{expected ')'}} // expected-note@+1 {{to match this '('}} expected-note@+1 {{as specified in 'collapse' clause}} #pragma omp for collapse(4, 8) for (i = 0; i < 16; ++i) ; // expected-error {{expected 4 for loops after '#pragma omp for', but found only 1}} #pragma omp parallel // expected-error@+1 {{expression is not an integer constant expression}} #pragma omp for collapse(2.5) for (i = 0; i < 16; ++i) ; #pragma omp parallel // expected-error@+1 {{expression is not an integer constant expression}} #pragma omp for collapse(foo()) for (i = 0; i < 16; ++i) ; #pragma omp parallel // expected-error@+1 {{argument to 'collapse' clause must be a strictly positive integer value}} #pragma omp for collapse(-5) for (i = 0; i < 16; ++i) ; #pragma omp parallel // expected-error@+1 {{argument to 'collapse' clause must be a strictly positive integer value}} #pragma omp for collapse(0) for (i = 0; i < 16; ++i) ; #pragma omp parallel // expected-error@+1 {{argument to 'collapse' clause must be a strictly positive integer value}} #pragma omp for collapse(5 - 5) for (i = 0; i < 16; ++i) ; #pragma omp parallel #pragma omp for collapse(2) for (i = 0; i < 16; ++i) // expected-note@+1 {{variable with automatic storage duration is predetermined as private; perhaps you forget to enclose 'omp for' directive into a parallel or another task region?}} for (int j = 0; j < 16; ++j) // expected-error@+2 {{reduction variable must be shared}} // expected-error@+1 {{region cannot be closely nested inside 'for' region; perhaps you forget to enclose 'omp for' directive into a parallel region?}} #pragma omp for reduction(+ : i, j) for (int k = 0; k < 16; ++k) i += j; } void test_private() { int i; #pragma omp parallel // expected-error@+2 {{expected expression}} // expected-error@+1 {{expected ')'}} expected-note@+1 {{to match this '('}} #pragma omp for private( for (i = 0; i < 16; ++i) ; #pragma omp parallel // expected-error@+2 {{expected ')'}} expected-note@+2 {{to match this '('}} // expected-error@+1 2 {{expected expression}} #pragma omp for private(, for (i = 0; i < 16; ++i) ; #pragma omp parallel // expected-error@+1 2 {{expected expression}} #pragma omp for private(, ) for (i = 0; i < 16; ++i) ; #pragma omp parallel // expected-error@+1 {{expected expression}} #pragma omp for private() for (i = 0; i < 16; ++i) ; #pragma omp parallel // expected-error@+1 {{expected expression}} #pragma omp for private(int) for (i = 0; i < 16; ++i) ; #pragma omp parallel // expected-error@+1 {{expected variable name}} #pragma omp for private(0) for (i = 0; i < 16; ++i) ; int x, y, z; #pragma omp parallel #pragma omp for private(x) for (i = 0; i < 16; ++i) ; #pragma omp parallel #pragma omp for private(x, y) for (i = 0; i < 16; ++i) ; #pragma omp parallel #pragma omp for private(x, y, z) for (i = 0; i < 16; ++i) { x = y * i + z; } } void test_lastprivate() { int i; #pragma omp parallel // expected-error@+2 {{expected ')'}} expected-note@+2 {{to match this '('}} // expected-error@+1 {{expected expression}} #pragma omp for lastprivate( for (i = 0; i < 16; ++i) ; #pragma omp parallel // expected-error@+2 {{expected ')'}} expected-note@+2 {{to match this '('}} // expected-error@+1 2 {{expected expression}} #pragma omp for lastprivate(, for (i = 0; i < 16; ++i) ; #pragma omp parallel // expected-error@+1 2 {{expected expression}} #pragma omp for lastprivate(, ) for (i = 0; i < 16; ++i) ; #pragma omp parallel // expected-error@+1 {{expected expression}} #pragma omp for lastprivate() for (i = 0; i < 16; ++i) ; #pragma omp parallel // expected-error@+1 {{expected expression}} #pragma omp for lastprivate(int) for (i = 0; i < 16; ++i) ; #pragma omp parallel // expected-error@+1 {{expected variable name}} #pragma omp for lastprivate(0) for (i = 0; i < 16; ++i) ; int x, y, z; #pragma omp parallel #pragma omp for lastprivate(x) for (i = 0; i < 16; ++i) ; #pragma omp parallel #pragma omp for lastprivate(x, y) for (i = 0; i < 16; ++i) ; #pragma omp parallel #pragma omp for lastprivate(x, y, z) for (i = 0; i < 16; ++i) ; } void test_firstprivate() { int i; #pragma omp parallel // expected-error@+2 {{expected ')'}} expected-note@+2 {{to match this '('}} // expected-error@+1 {{expected expression}} #pragma omp for firstprivate( for (i = 0; i < 16; ++i) ; #pragma omp parallel // expected-error@+2 {{expected ')'}} expected-note@+2 {{to match this '('}} // expected-error@+1 2 {{expected expression}} #pragma omp for firstprivate(, for (i = 0; i < 16; ++i) ; #pragma omp parallel // expected-error@+1 2 {{expected expression}} #pragma omp for firstprivate(, ) for (i = 0; i < 16; ++i) ; #pragma omp parallel // expected-error@+1 {{expected expression}} #pragma omp for firstprivate() for (i = 0; i < 16; ++i) ; #pragma omp parallel // expected-error@+1 {{expected expression}} #pragma omp for firstprivate(int) for (i = 0; i < 16; ++i) ; #pragma omp parallel // expected-error@+1 {{expected variable name}} #pragma omp for firstprivate(0) for (i = 0; i < 16; ++i) ; int x, y, z; #pragma omp parallel #pragma omp for lastprivate(x) firstprivate(x) for (i = 0; i < 16; ++i) ; #pragma omp parallel #pragma omp for lastprivate(x, y) firstprivate(x, y) for (i = 0; i < 16; ++i) ; #pragma omp parallel #pragma omp for lastprivate(x, y, z) firstprivate(x, y, z) for (i = 0; i < 16; ++i) ; } void test_loop_messages() { float a[100], b[100], c[100]; #pragma omp parallel // expected-error@+2 {{variable must be of integer or pointer type}} #pragma omp for for (float fi = 0; fi < 10.0; fi++) { c[(int)fi] = a[(int)fi] + b[(int)fi]; } #pragma omp parallel // expected-error@+2 {{variable must be of integer or pointer type}} #pragma omp for for (double fi = 0; fi < 10.0; fi++) { c[(int)fi] = a[(int)fi] + b[(int)fi]; } // expected-warning@+2 {{OpenMP loop iteration variable cannot have more than 64 bits size and will be narrowed}} #pragma omp for for (__int128 ii = 0; ii < 10; ii++) { c[ii] = a[ii] + b[ii]; } }
pr39591-1.c	/* PR other/39591 / / { dg-do run } */ extern void abort (void); int err; int main (void) { #pragma omp parallel { int array[40]; int i; for (i = 0; i < sizeof array / sizeof array[0]; i++) array[i] = 0x55555555; #pragma omp for schedule(dynamic) for (i = 0; i < 50; i++) #pragma omp task shared(array) { int j; for (j = 0; j < sizeof array / sizeof array[0]; j++) if (array[j] != 0x55555555) #pragma omp atomic err++; } } if (err) abort (); return 0; }
rawSHA224_fmt_plug.c	/* * This file is part of John the Ripper password cracker, * Copyright (c) 2010 by Solar Designer * based on rawMD4_fmt.c code, with trivial changes by groszek. * * Rewritten Spring 2013, JimF. SSE code added and released with the following terms: * No copyright is claimed, and the software is hereby placed in the public domain. * In case this attempt to disclaim copyright and place the software in the public * domain is deemed null and void, then the software is Copyright (c) 2011 JimF * and it is hereby released to the general public under the following * terms: * * This software may be modified, redistributed, and used for any * purpose, in source and binary forms, with or without modification. / #if FMT_EXTERNS_H extern struct fmt_main fmt_rawSHA224; #elif FMT_REGISTERS_H john_register_one(&fmt_rawSHA224); #else #include "arch.h" #include "sha2.h" #include "stdint.h" #include "params.h" #include "common.h" #include "johnswap.h" #include "formats.h" #include "simd-intrinsics.h" //#undef SIMD_COEF_32 //#undef SIMD_PARA_SHA256 / * Only effective for SIMD. * Undef to disable reversing steps for benchmarking. / #define REVERSE_STEPS #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 "memdbg.h" #define FORMAT_LABEL "Raw-SHA224" #define FORMAT_NAME "" #define FORMAT_TAG "$SHA224$" #define TAG_LENGTH 8 #ifdef SIMD_COEF_32 #define ALGORITHM_NAME SHA256_ALGORITHM_NAME #else #define ALGORITHM_NAME "32/" ARCH_BITS_STR " " SHA2_LIB #endif #define BENCHMARK_COMMENT "" #define BENCHMARK_LENGTH -1 #ifdef SIMD_COEF_32 #define PLAINTEXT_LENGTH 55 #else #define PLAINTEXT_LENGTH 125 #endif #define CIPHERTEXT_LENGTH 56 #define BINARY_SIZE DIGEST_SIZE #define DIGEST_SIZE 28 #define DIGEST_SIZE_256 32 #define BINARY_ALIGN MEM_ALIGN_WORD #define SALT_SIZE 0 #define SALT_ALIGN 1 #ifdef SIMD_COEF_32 #define MIN_KEYS_PER_CRYPT (SIMD_COEF_32SIMD_PARA_SHA256) #define MAX_KEYS_PER_CRYPT (SIMD_COEF_32SIMD_PARA_SHA256) #else #define MIN_KEYS_PER_CRYPT 1 #define MAX_KEYS_PER_CRYPT 1 #endif static struct fmt_tests tests[] = { {"d63dc919e201d7bc4c825630d2cf25fdc93d4b2f0d46706d29038d01", "password"}, {"$SHA224$d63dc919e201d7bc4c825630d2cf25fdc93d4b2f0d46706d29038d01", "password"}, {"$SHA224$7e6a4309ddf6e8866679f61ace4f621b0e3455ebac2e831a60f13cd1", "12345678"}, {"$SHA224$d14a028c2a3a2bc9476102bb288234c415a2b01f828ea62ac5b3e42f", ""}, {"b93ff16271aa688dbf671120817d75b895b874ab2b9bb9f71481d88d", "UPPERCASE"}, {NULL} }; #ifdef SIMD_COEF_32 #define GETPOS(i, index) ( (index&(SIMD_COEF_32-1))4 + ((i)&(0xffffffff-3))SIMD_COEF_32 + (3-((i)&3)) + (unsigned int)index/SIMD_COEF_32SHA_BUF_SIZSIMD_COEF_324 ) static uint32_t (saved_key); static uint32_t (crypt_out); #else static int (saved_len); static char (saved_key)[PLAINTEXT_LENGTH + 1]; static ARCH_WORD_32 (crypt_out) [(DIGEST_SIZE + sizeof(ARCH_WORD_32) - 1) / sizeof(ARCH_WORD_32)]; #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 #ifndef SIMD_COEF_32 saved_len = mem_calloc(self->params.max_keys_per_crypt, sizeof(saved_len)); saved_key = mem_calloc(self->params.max_keys_per_crypt, sizeof(saved_key)); crypt_out = mem_calloc(self->params.max_keys_per_crypt, sizeof(crypt_out)); #else saved_key = mem_calloc_align(self->params.max_keys_per_crypt * SHA_BUF_SIZ, sizeof(saved_key), MEM_ALIGN_SIMD); crypt_out = mem_calloc_align(self->params.max_keys_per_crypt DIGEST_SIZE_256 / sizeof(uint32_t), sizeof(crypt_out), MEM_ALIGN_SIMD); #endif } static void done(void) { MEM_FREE(crypt_out); MEM_FREE(saved_key); #ifndef SIMD_COEF_32 MEM_FREE(saved_len); #endif } static int valid(char ciphertext, struct fmt_main self) { char p, q; p = ciphertext; if (!strncmp(p, FORMAT_TAG, TAG_LENGTH)) p += 8; q = p; while (atoi16[ARCH_INDEX(q)] != 0x7F) 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)) ciphertext += TAG_LENGTH; memcpy(out, FORMAT_TAG, TAG_LENGTH); memcpy(out + TAG_LENGTH, ciphertext, CIPHERTEXT_LENGTH + 1); strlwr(out + TAG_LENGTH); return out; } static void get_binary(char ciphertext) { static unsigned int outw; unsigned char out; char p; int i; if (!outw) outw = mem_calloc_tiny(DIGEST_SIZE, MEM_ALIGN_WORD); out = (unsigned char)outw; 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; } #ifdef SIMD_COEF_32 alter_endianity (out, DIGEST_SIZE); #ifdef REVERSE_STEPS sha224_reverse(outw); #endif #endif return out; } #ifdef SIMD_COEF_32 #define HASH_IDX (((unsigned int)index&(SIMD_COEF_32-1))+(unsigned int)index/SIMD_COEF_328SIMD_COEF_32 + 3SIMD_COEF_32) static int get_hash_0 (int index) { return crypt_out[HASH_IDX] & PH_MASK_0; } static int get_hash_1 (int index) { return crypt_out[HASH_IDX] & PH_MASK_1; } static int get_hash_2 (int index) { return crypt_out[HASH_IDX] & PH_MASK_2; } static int get_hash_3 (int index) { return crypt_out[HASH_IDX] & PH_MASK_3; } static int get_hash_4 (int index) { return crypt_out[HASH_IDX] & PH_MASK_4; } static int get_hash_5 (int index) { return crypt_out[HASH_IDX] & PH_MASK_5; } static int get_hash_6 (int index) { return crypt_out[HASH_IDX] & PH_MASK_6; } #else static int get_hash_0(int index) { return crypt_out[index][3] & PH_MASK_0; } static int get_hash_1(int index) { return crypt_out[index][3] & PH_MASK_1; } static int get_hash_2(int index) { return crypt_out[index][3] & PH_MASK_2; } static int get_hash_3(int index) { return crypt_out[index][3] & PH_MASK_3; } static int get_hash_4(int index) { return crypt_out[index][3] & PH_MASK_4; } static int get_hash_5(int index) { return crypt_out[index][3] & PH_MASK_5; } static int get_hash_6(int index) { return crypt_out[index][3] & PH_MASK_6; } #endif static int binary_hash_0(void binary) { return ((ARCH_WORD_32)binary)[3] & PH_MASK_0; } static int binary_hash_1(void binary) { return ((ARCH_WORD_32)binary)[3] & PH_MASK_1; } static int binary_hash_2(void binary) { return ((ARCH_WORD_32)binary)[3] & PH_MASK_2; } static int binary_hash_3(void binary) { return ((ARCH_WORD_32)binary)[3] & PH_MASK_3; } static int binary_hash_4(void binary) { return ((ARCH_WORD_32)binary)[3] & PH_MASK_4; } static int binary_hash_5(void binary) { return ((ARCH_WORD_32)binary)[3] & PH_MASK_5; } static int binary_hash_6(void binary) { return ((ARCH_WORD_32)binary)[3] & PH_MASK_6; } #ifdef SIMD_COEF_32 static void set_key(char key, int index) { #if ARCH_ALLOWS_UNALIGNED const ARCH_WORD_32 wkey = (ARCH_WORD_32)key; #else char buf_aligned[PLAINTEXT_LENGTH + 1] JTR_ALIGN(sizeof(uint32_t)); const ARCH_WORD_32 wkey = (uint32_t)(is_aligned(key, sizeof(uint32_t)) ? key : strcpy(buf_aligned, key)); #endif ARCH_WORD_32 keybuffer = &((ARCH_WORD_32 )saved_key)[(index&(SIMD_COEF_32-1)) + (unsigned int)index/SIMD_COEF_32SHA_BUF_SIZSIMD_COEF_32]; ARCH_WORD_32 keybuf_word = keybuffer; unsigned int len; ARCH_WORD_32 temp; len = 0; while((unsigned char)(temp = wkey++)) { if (!(temp & 0xff00)) { keybuf_word = JOHNSWAP((temp & 0xff) \| (0x80 << 8)); len++; goto key_cleaning; } if (!(temp & 0xff0000)) { keybuf_word = JOHNSWAP((temp & 0xffff) \| (0x80 << 16)); len+=2; goto key_cleaning; } if (!(temp & 0xff000000)) { keybuf_word = JOHNSWAP(temp \| (0x80U << 24)); len+=3; goto key_cleaning; } keybuf_word = JOHNSWAP(temp); len += 4; keybuf_word += SIMD_COEF_32; } keybuf_word = 0x80000000; key_cleaning: keybuf_word += SIMD_COEF_32; while(keybuf_word) { keybuf_word = 0; keybuf_word += SIMD_COEF_32; } keybuffer[15SIMD_COEF_32] = len << 3; } #else static void set_key(char key, int index) { int len = strlen(key); saved_len[index] = len; if (len > PLAINTEXT_LENGTH) len = saved_len[index] = PLAINTEXT_LENGTH; memcpy(saved_key[index], key, len); } #endif #ifdef SIMD_COEF_32 static char get_key(int index) { unsigned int i,s; static char out[PLAINTEXT_LENGTH+1]; unsigned char wucp = (unsigned char)saved_key; s = ((ARCH_WORD_32 )saved_key)[15SIMD_COEF_32 + (index&(SIMD_COEF_32-1)) + (unsigned int)index/SIMD_COEF_32SHA_BUF_SIZSIMD_COEF_32] >> 3; for(i=0;i<s;i++) out[i] = wucp[ GETPOS(i, index) ]; out[i] = 0; return (char) out; } #else static char get_key(int index) { saved_key[index][saved_len[index]] = 0; return saved_key[index]; } #endif #ifndef REVERSE_STEPS #undef SSEi_REVERSE_STEPS #define SSEi_REVERSE_STEPS 0 #endif static int crypt_all(int pcount, struct db_salt salt) { const int count = pcount; int index = 0; #ifdef _OPENMP #pragma omp parallel for for (index = 0; index < count; index += MAX_KEYS_PER_CRYPT) #endif { #ifdef SIMD_COEF_32 SIMDSHA256body(&saved_key[(unsigned int)index/SIMD_COEF_32SHA_BUF_SIZSIMD_COEF_32], &crypt_out[(unsigned int)index/SIMD_COEF_328SIMD_COEF_32], NULL, SSEi_REVERSE_STEPS\|SSEi_MIXED_IN\|SSEi_CRYPT_SHA224); #else SHA256_CTX ctx; SHA224_Init(&ctx); SHA224_Update(&ctx, saved_key[index], saved_len[index]); SHA224_Final((unsigned char )crypt_out[index], &ctx); #endif } return count; } static int cmp_all(void binary, int count) { unsigned int index; for (index = 0; index < count; index++) #ifdef SIMD_COEF_32 if (((ARCH_WORD_32) binary)[3] == crypt_out[HASH_IDX]) #else if ( ((ARCH_WORD_32)binary)[0] == crypt_out[index][0] ) #endif return 1; return 0; } static int cmp_one(void binary, int index) { #ifdef SIMD_COEF_32 return ((ARCH_WORD_32)binary)[3] == crypt_out[HASH_IDX]; #else return (ARCH_WORD_32)binary == crypt_out[index][0]; #endif } static int cmp_exact(char source, int index) { ARCH_WORD_32 binary = get_binary(source); char key = get_key(index); SHA256_CTX ctx; ARCH_WORD_32 crypt_out[DIGEST_SIZE / sizeof(ARCH_WORD_32)]; SHA224_Init(&ctx); SHA224_Update(&ctx, key, strlen(key)); SHA224_Final((unsigned char)crypt_out, &ctx); #ifdef SIMD_COEF_32 alter_endianity(crypt_out, DIGEST_SIZE); #ifdef REVERSE_STEPS sha224_reverse(crypt_out); #endif #endif return !memcmp(binary, crypt_out, DIGEST_SIZE); } struct fmt_main fmt_rawSHA224 = { { FORMAT_LABEL, FORMAT_NAME, "SHA224 " 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_OMP \| FMT_OMP_BAD \| FMT_SPLIT_UNIFIES_CASE, { NULL }, tests }, { init, done, fmt_default_reset, fmt_default_prepare, valid, split, get_binary, fmt_default_salt, { NULL }, 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, 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 */
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] = 32; tile_size[3] = 2048; 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(t1-6,8),ceild(8t2-Nz-19,32));t3<=min(floord(4Nt+Ny-9,32),floord(4t1+Ny-1,32));t3++) { for (t4=max(max(ceild(t1-510,512),ceild(8t2-Nz-2035,2048)),ceild(32t3-Ny-2035,2048));t4<=min(min(floord(4Nt+Nx-9,2048),floord(4t1+Nx-1,2048)),floord(32t3+Nx+19,2048));t4++) { for (t5=max(max(max(max(0,ceild(8t2-Nz+5,4)),ceild(32t3-Ny+5,4)),ceild(2048t4-Nx+5,4)),t1);t5<=min(min(min(Nt-1,t1+1),8t3+6),512t4+510);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(32t3,4t5+4);t7<=min(32t3+31,4t5+Ny-5);t7++) { lbv=max(2048t4,4t5+4); ubv=min(2048t4+2047,4t5+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; }
chunks.c	/************************************************************************* * chunks.c - * * $Id$ * * Copyright (c) INRIA 2012 * * AUTHOR: * Gregoire Malandain (gregoire.malandain@inria.fr) * * CREATION DATE: * Fri Nov 16 22:45:44 CET 2012 * * * ADDITIONS, CHANGES * * * * / #include <stdlib.h> #include <stdio.h> #include <math.h> #ifdef MAC #include <sys/types.h> #include <sys/sysctl.h> #else #include <unistd.h> #endif #ifdef _OPENMP #include <omp.h> #endif #include <pthread.h> #include <vtmalloc.h> #include <chunks.h> / debug / verbose variables / static int _verbose_ = 1; static int _debug_ = 0; void setVerboseInChunks( int v ) { _verbose_ = v; } void incrementVerboseInChunks( ) { _verbose_ ++; } void decrementVerboseInChunks( ) { _verbose_ --; if ( _verbose_ < 0 ) _verbose_ = 0; } void setDebugInChunks( int v ) { _debug_ = v; } void incrementDebugInChunks( ) { _debug_ ++; } void decrementDebugInChunks( ) { _debug_ --; if ( _debug_ < 0 ) _debug_ = 0; } / parallelism, scheduling / static parallelismType _parallelism_ = _DEFAULT_PARALLELISM_; static ompSchedulingType _omp_scheduling_ = _DYNAMIC_OMP_SCHEDULING_; void setParallelism( parallelismType p ) { _parallelism_ = p; } parallelismType getParallelism( ) { return( _parallelism_ ); } void setOmpScheduling( ompSchedulingType s ) { _omp_scheduling_ = s; } ompSchedulingType getOmpScheduling( ) { return( _omp_scheduling_ ); } / chunk related variable / static int _max_chunks_ = -1; static int _min_elements_ = 100; void setMaxChunks( int c ) { _max_chunks_ = c; } int getMaxChunks( ) { return( _max_chunks_ ); } void setMinElementsInChunks( int e ) { _min_elements_ = e; } int getMinElementsInChunks( ) { return( _min_elements_); } /*********************************************************** * * chunks processing * ***********************************************************/ #ifdef _OPENMP static int _ompProcessChunks( _chunk_callfunction ftn, typeChunks chunks, char from ) { int n; if ( chunks->n_allocated_chunks > 1 ) { switch( chunks->ompScheduling ) { default : case _DEFAULT_OMP_SCHEDULING_ : if ( _debug_ >= 3 ) fprintf( stderr, "%s: default openmp scheduling\n", from ); #pragma omp parallel for for ( n=0; n<chunks->n_allocated_chunks; n++ ) { if ( _debug_ >=2 ) { fprintf( stderr, "%s: processing chunk #%d/%d", from, n+1, chunks->n_allocated_chunks ); fprintf( stderr, " attributed to thread #%d", omp_get_thread_num() ); fprintf( stderr, "\n" ); } (void)(ftn)( &(chunks->data[n]) ); } break; case _DYNAMIC_OMP_SCHEDULING_ : if ( _debug_ >= 3 ) fprintf( stderr, "%s: dynamic openmp scheduling\n", from ); #pragma omp parallel for schedule(dynamic) for ( n=0; n<chunks->n_allocated_chunks; n++ ) { if ( _debug_ >=2 ) { fprintf( stderr, "%s: processing chunk #%d/%d", from, n+1, chunks->n_allocated_chunks ); fprintf( stderr, " attributed to thread #%d", omp_get_thread_num() ); fprintf( stderr, "\n" ); } (void)(ftn)( &(chunks->data[n]) ); } break; case _DYNAMIC_ONE_OMP_SCHEDULING_ : if ( _debug_ >= 3 ) fprintf( stderr, "%s: (dynamic,1) openmp scheduling\n", from ); #pragma omp parallel for schedule(dynamic,1) for ( n=0; n<chunks->n_allocated_chunks; n++ ) { if ( _debug_ >=2 ) { fprintf( stderr, "%s: processing chunk #%d/%d", from, n+1, chunks->n_allocated_chunks ); fprintf( stderr, " attributed to thread #%d", omp_get_thread_num() ); fprintf( stderr, "\n" ); } (void)(ftn)( &(chunks->data[n]) ); } break; case _GUIDED_OMP_SCHEDULING_ : if ( _debug_ >= 3 ) fprintf( stderr, "%s: (guided) openmp scheduling\n", from ); #pragma omp parallel for schedule(guided) for ( n=0; n<chunks->n_allocated_chunks; n++ ) { if ( _debug_ >=2 ) { fprintf( stderr, "%s: processing chunk #%d/%d", from, n+1, chunks->n_allocated_chunks ); fprintf( stderr, " attributed to thread #%d", omp_get_thread_num() ); fprintf( stderr, "\n" ); } (void)(ftn)( &(chunks->data[n]) ); } break; case _STATIC_OMP_SCHEDULING_ : if ( _debug_ >= 3 ) fprintf( stderr, "%s: (static) openmp scheduling\n", from ); #pragma omp parallel for schedule(static) for ( n=0; n<chunks->n_allocated_chunks; n++ ) { if ( _debug_ >=2 ) { fprintf( stderr, "%s: processing chunk #%d/%d", from, n+1, chunks->n_allocated_chunks ); fprintf( stderr, " attributed to thread #%d", omp_get_thread_num() ); fprintf( stderr, "\n" ); } (void)(ftn)( &(chunks->data[n]) ); } break; } } else { if ( _debug_ >= 3 ) fprintf( stderr, "%s: sequential loop\n", from ); for ( n=0; n<chunks->n_allocated_chunks; n++ ) { if ( _debug_ >= 4 ) { fprintf( stderr, "%s: processing chunk #%d/%d", from, n+1, chunks->n_allocated_chunks ); fprintf( stderr, " in a sequential way" ); fprintf( stderr, "\n" ); } (void)(ftn)( &(chunks->data[n]) ); } } / check the returned values in case of error / for ( n=0; n<chunks->n_allocated_chunks; n++ ) { if ( chunks->data[n].ret != 1 ) { if ( _verbose_ ) { fprintf( stderr, "%s: error when computing chunk #%d\n", from, n ); } return( -1 ); } } return( 1 ); } #endif static int _pthreadProcessChunks( _chunk_callfunction ftn, typeChunks chunks, char from ) { char proc = "_pthreadProcessChunks"; int n; int rc; void status; pthread_t thread; pthread_attr_t attr; if ( _debug_ >= 3 ) fprintf( stderr, "%s: pthread scheduling\n", from ); thread = (pthread_t)vtmalloc( chunks->n_allocated_chunks sizeof( pthread_t ), "thread", proc ); if ( thread == (pthread_t)NULL ) { if ( _verbose_ ) fprintf( stderr, "%s: unable to allocate array of %d threads\n", proc, chunks->n_allocated_chunks ); return( -1 ); } pthread_attr_init( &attr ); pthread_attr_setdetachstate( &attr, PTHREAD_CREATE_JOINABLE ); for ( n=0; n<chunks->n_allocated_chunks; n++ ) { rc = pthread_create( &thread[n], &attr, ftn, &(chunks->data[n]) ); if ( rc ) { if ( _verbose_ ) fprintf( stderr, "%s: error when creating threads #%d/%d (returned code = %d)\n", proc, n, chunks->n_allocated_chunks, rc ); vtfree( thread ); return( -1 ); } } pthread_attr_destroy(&attr); for ( n=0; n<chunks->n_allocated_chunks; n++ ) { rc = pthread_join( thread[n], &status ); if ( rc ) { if ( _verbose_ ) fprintf( stderr, "%s: error when joining threads #%d/%d (returned code = %d)\n", proc, n, chunks->n_allocated_chunks, rc ); vtfree( thread ); return( -1 ); } } vtfree( thread ); return( 1 ); } int processChunks( _chunk_callfunction ftn, typeChunks chunks, char from ) { char proc = "processChunks"; int n; switch( _parallelism_ ) { case _NO_PARALLELISM_ : if ( _debug_ >= 3 ) fprintf( stderr, "%s: _NO_PARALLELISM_ case\n", proc ); for ( n=0; n<chunks->n_allocated_chunks; n++ ) { (void)(ftn)( &(chunks->data[n]) ); } break; default : case _DEFAULT_PARALLELISM_ : if ( _debug_ >= 3 ) fprintf( stderr, "%s: _DEFAULT_PARALLELISM_ case\n", proc ); #ifdef _OPENMP case _OMP_PARALLELISM_ : if ( _debug_ >= 3 ) fprintf( stderr, "%s: _OMP_PARALLELISM_ case\n", proc ); return ( _ompProcessChunks( ftn, chunks, from ) ); break; #endif case _PTHREAD_PARALLELISM_ : if ( _debug_ >= 3 ) fprintf( stderr, "%s: _PTHREAD_PARALLELISM_ case\n", proc ); return ( _pthreadProcessChunks( ftn, chunks, from ) ); break; } return( 1 ); } /*********************************************************** * * chunks construction (ad hoc function) * ***********************************************************/ #ifdef MAC static int _getNCPU() { int n=1; int mib[4]; size_t lmib = 4; int ncpu; size_t lncpu = sizeof( ncpu ); int nactivecpu; size_t lnactivecpu = sizeof( nactivecpu ); int nphysicalcpu; size_t lnphysicalcpu = sizeof( nphysicalcpu ); int nphysicalcpumax; size_t lnphysicalcpumax = sizeof( nphysicalcpumax ); int nlogicalcpu; size_t lnlogicalcpu = sizeof( nlogicalcpu ); int nlogicalcpumax; size_t lnlogicalcpumax = sizeof( nlogicalcpumax ); int navailablecpu; size_t lnavailablecpu = sizeof( ncpu ); switch( _parallelism_ ) { case _NO_PARALLELISM_ : return( 1 ); default : case _DEFAULT_PARALLELISM_ : #ifdef _OPENMP case _OMP_PARALLELISM_ : return( omp_get_max_threads() ); #endif case _PTHREAD_PARALLELISM_ : mib[0] = CTL_HW; mib[1] = HW_NCPU; sysctl( mib, 2, &ncpu, &lncpu, NULL, 0); mib[0] = CTL_HW; mib[1] = HW_AVAILCPU; sysctl( mib, 2, &navailablecpu, &lnavailablecpu, NULL, 0); sysctlnametomib( "hw.ncpu", mib, &lmib ); sysctl( mib, 2, &ncpu, &lncpu, NULL, 0); sysctlnametomib( "hw.activecpu", mib, &lmib ); sysctl( mib, 2, &nactivecpu, &lnactivecpu, NULL, 0); sysctlnametomib( "hw.physicalcpu", mib, &lmib ); sysctl( mib, 2, &nphysicalcpu, &lnphysicalcpu, NULL, 0); sysctlnametomib( "hw.physicalcpu_max", mib, &lmib ); sysctl( mib, 2, &nphysicalcpumax, &lnphysicalcpumax, NULL, 0); sysctlnametomib( "hw.logicalcpu", mib, &lmib ); sysctl( mib, 2, &nlogicalcpu, &lnlogicalcpu, NULL, 0); sysctlnametomib( "hw.logicalcpu_max", mib, &lmib ); sysctl( mib, 2, &nlogicalcpumax, &lnlogicalcpumax, NULL, 0); if ( _debug_ >= 4 ) { fprintf( stderr, "ncpu = %d\n", ncpu ); fprintf( stderr, "navailablecpu = %d\n", navailablecpu ); fprintf( stderr, "nactivecpu = %d\n", nactivecpu ); fprintf( stderr, "nphysicalcpu = %d\n", nphysicalcpu ); fprintf( stderr, "nphysicalcpumax = %d\n", nphysicalcpumax ); fprintf( stderr, "nlogicalcpu = %d\n", nlogicalcpu ); fprintf( stderr, "nlogicalcpumax = %d\n", nlogicalcpumax ); } if ( n < ncpu ) n = ncpu; if ( n < nactivecpu ) n = nactivecpu; if ( n < nphysicalcpu ) n = nphysicalcpu; if ( n < nphysicalcpumax ) n = nphysicalcpumax; if ( n < nlogicalcpu ) n = nlogicalcpu; if ( n < nlogicalcpumax ) n = nlogicalcpumax; if ( n < navailablecpu ) n = navailablecpu; return( n ); } return( 1 ); } #else static int _getNCPU() { return( sysconf( _SC_NPROCESSORS_ONLN ) ); } #endif static void _setMaxChunks( ) { switch( _parallelism_ ) { case _NO_PARALLELISM_ : _max_chunks_ = 1; break; default : case _DEFAULT_PARALLELISM_ : #ifdef _OPENMP case _OMP_PARALLELISM_ : if ( omp_get_max_threads() == 1 ) { _max_chunks_ = 1; } else { if ( _max_chunks_ <= 0 ) _max_chunks_ = 100; } break; #endif case _PTHREAD_PARALLELISM_ : if ( _max_chunks_ <= 0 ) _max_chunks_ = _getNCPU(); break; } if ( _max_chunks_ == 1 ) _parallelism_ = _NO_PARALLELISM_; } int buildChunks( typeChunks chunks, size_t first, size_t last, char from ) { char proc = "buildChunks"; size_t size = last-first+1; int n; _setMaxChunks( ); n = _max_chunks_; chunks->ompScheduling = _omp_scheduling_; /* only one chunk / if ( n == 1 ) { if ( allocBuildOneChunk( chunks, first, last ) != 1 ) { if ( _verbose_ ) fprintf( stderr, "%s: error when allocating one chunk\n", proc ); return( -1 ); } return( 1 ); } / what to do when there are too few elements ? / if ( size < (size_t)n_min_elements_ ) { n = size / _min_elements_; if ( size % _min_elements_ > 0 ) n ++; if ( n == 1 ) { if ( allocBuildOneChunk( chunks, first, last ) != 1 ) { if ( _verbose_ ) fprintf( stderr, "%s: error when allocating one chunk (too few element case)\n", proc ); return( -1 ); } return( 1 ); } } if ( allocBuildEqualChunks( chunks, first, last, n ) != 1 ) { if ( _verbose_ ) fprintf( stderr, "%s: error when building %d chunks (call from %s)\n", proc, n, from ); return( -1 ); } if ( _debug_ >= 3 ) { fprintf( stderr, "\n" ); if ( from != (char)NULL ) fprintf( stderr, "%s: has computed %d chunks from '%s'\n", proc, chunks->n_allocated_chunks, from ); else fprintf( stderr, "%s: has computed %d chunks from '%s'\n", proc, chunks->n_allocated_chunks, from ); } return( 1 ); } /*********************************************************** * * chunks construction (generic functions) * ***********************************************************/ int allocBuildOneChunk( typeChunks chunks, size_t first, size_t last ) { char proc = "oneChunk"; if ( allocChunks( chunks, 1 ) <= 0 ) { if ( _verbose_ ) fprintf( stderr, "%s: error when allocating one chunk\n", proc ); return( -1 ); } chunks->data[0].first = first; chunks->data[0].last = last; return( 1 ); } int buildEqualChunks( typeChunk chunk, size_t first, size_t last, int n ) { char proc = "buildEqualChunks"; size_t totalSize = last+1-first; size_t f = first; size_t i, chunkSize; if ( n <= 0 ) { if ( _verbose_ ) fprintf( stderr, "%s: negative number of chunks\n", proc ); return( -1 ); } chunkSize = totalSize / n; if ( chunkSize <= 0 ) { if ( _verbose_ ) fprintf( stderr, "%s: negative or null chunk size (too many chunks ?)\n", proc ); return( -1 ); } for ( i=0; i<(size_t)n; i++, f+=chunkSize ) { / chunk of size chunkSize+1 / if ( chunkSize (n-i) < totalSize ) { totalSize -= chunkSize + 1; chunk[ i ].first = f; chunk[ i ].last = f+(chunkSize+1)-1; f++; } /* chunk of size chunkSize / else { totalSize -= chunkSize; chunk[ i ].first = f; chunk[ i ].last = f+chunkSize-1; } } return( 1 ); } int allocBuildEqualChunks( typeChunks chunks, size_t first, size_t last, int nchunks ) { char proc = "allocBuildEqualChunks"; size_t size = last - first + 1; int n = nchunks; if ( n <= 0 ) { if ( _verbose_ ) fprintf( stderr, "%s: negative number of chunks\n", proc ); return( -1 ); } if ( size < (size_t)n ) { n = size; } if ( allocChunks( chunks, n ) != 1 ) { if ( _verbose_ ) fprintf( stderr, "%s: error when allocating chunks\n", proc ); return( -1 ); } if ( buildEqualChunks( &(chunks->data[0]), first, last, n ) != 1 ) { freeChunks( chunks ); if ( _verbose_ ) fprintf( stderr, "%s: error when calculating chunks\n", proc ); return( -1 ); } return( 1 ); } int allocBuildInequalChunks( typeChunks chunks, size_t first, size_t last, double fraction, /* fraction of data to be put in one bucket / int chunks_bucket, / number of chunks for one bucket / size_t minimal_chunk_size, int maximal_chunk_number ) { char proc = "allocBuildInequalChunks"; size_t totalSize = last+1-first; size_t f = first; size_t i, chunkSize; int maxchunks; int n, nchunks; if ( maximal_chunk_number <= 0 ) { if ( _verbose_ ) fprintf( stderr, "%s: negative maximal number of chunks\n", proc ); return( -1 ); } if ( chunks_bucket <= 0 ) { if ( _verbose_ ) fprintf( stderr, "%s: negative number of chunks in a bucket\n", proc ); return( -1 ); } if ( fraction < 0.0 \|\| 1.0 <= fraction ) { if ( _verbose_ ) fprintf( stderr, "%s: fraction should be in ]0,1[\n", proc ); return( -1 ); } /* calculating the number of chunks / for ( nchunks=0, maxchunks=maximal_chunk_number, totalSize=last+1-first; totalSize > 0 && maxchunks > 0; ) { / put the remaining data in the remaining chunks -> equal repartition in maxchunks chunks / if ( maxchunks <= chunks_bucket ) { nchunks += maxchunks; totalSize = 0; if ( _debug_ >= 3 ) fprintf( stderr, "(1) add %d chunks -> %d\n", maxchunks, nchunks ); continue; } / the remaining data fits in one bucket -> equal repartition in chunks_bucket chunks / if ( totalSize / chunks_bucket < minimal_chunk_size ) { nchunks += chunks_bucket; totalSize = 0; if ( _debug_ >= 3 ) fprintf( stderr, "(2) add %d chunks -> %d\n", chunks_bucket, nchunks ); continue; } / the considered fraction of data in the bucket yield too small chunks -> equal repartition in min( totalSize / minimal_chunk_size, maxchunks) / if ( (fraction totalSize) / chunks_bucket < minimal_chunk_size ) { n = totalSize / minimal_chunk_size; if ( n > maxchunks ) n = maxchunks; nchunks += n; totalSize = 0; if ( _debug_ >= 3 ) fprintf( stderr, "(3) add %d chunks -> %d\n", n, nchunks ); continue; } /* after filling the bucket, there will be too much remaining data -> equal repartition in maxchunks / if ( (maxchunks <= 2chunks_bucket) && (fraction * totalSize) / chunks_bucket < ((1-fraction) * totalSize) / (maxchunks-chunks_bucket) ) { nchunks += maxchunks; totalSize = 0; if ( _debug_ >= 3 ) fprintf( stderr, "(4) add %d chunks -> %d\n", maxchunks, nchunks ); continue; } /* generic case / chunkSize = (fraction totalSize) / chunks_bucket; nchunks += chunks_bucket; maxchunks -= chunks_bucket; totalSize -= chunks_bucket * chunkSize; if ( _debug_ >= 3 ) fprintf( stderr, "(5) add %d chunks -> %d\n", chunks_bucket, nchunks ); } /* allocating the chunks / if ( allocChunks( chunks, nchunks ) <= 0 ) { if ( _verbose_ ) fprintf( stderr, "%s: error when allocating chunks\n", proc ); return( -1 ); } / filling chunks / for ( nchunks=0, maxchunks=maximal_chunk_number, totalSize=last+1-first, f=first; totalSize > 0 && maxchunks > 0; ) { / put the remaining data in the remaining chunks -> equal repartition in maxchunks chunks / if ( maxchunks <= chunks_bucket ) { if ( buildEqualChunks( &(chunks->data[nchunks]), f, last, maxchunks ) != 1 ) { freeChunks( chunks ); if ( _verbose_ ) fprintf( stderr, "%s: error when calculating chunks\n", proc ); return( -1 ); } totalSize = 0; continue; } / the remaining data fits in one bucket -> equal repartition in chunks_bucket chunks / if ( totalSize / chunks_bucket < minimal_chunk_size ) { if ( buildEqualChunks( &(chunks->data[nchunks]), f, last, chunks_bucket ) != 1 ) { freeChunks( chunks ); if ( _verbose_ ) fprintf( stderr, "%s: error when calculating chunks\n", proc ); return( -1 ); } totalSize = 0; continue; } / the considered fraction of data in the bucket yield too small chunks -> equal repartition in min( totalSize / minimal_chunk_size, maxchunks) / if ( (fraction totalSize) / chunks_bucket < minimal_chunk_size ) { n = totalSize / minimal_chunk_size; if ( n > maxchunks ) n = maxchunks; if ( buildEqualChunks( &(chunks->data[nchunks]), f, last, n ) != 1 ) { freeChunks( chunks ); if ( _verbose_ ) fprintf( stderr, "%s: error when calculating chunks\n", proc ); return( -1 ); } totalSize = 0; continue; } /* after filling the bucket, there will be too much remaining data -> equal repartition in maxchunks / if ( (maxchunks <= 2chunks_bucket) && (fraction * totalSize) / chunks_bucket < ((1-fraction) * totalSize) / (maxchunks-chunks_bucket) ) { if ( buildEqualChunks( &(chunks->data[nchunks]), f, last, maxchunks ) != 1 ) { freeChunks( chunks ); if ( _verbose_ ) fprintf( stderr, "%s: error when calculating chunks\n", proc ); return( -1 ); } totalSize = 0; continue; } /* generic case / chunkSize = (fraction totalSize) / chunks_bucket; for (i=0; i<(size_t)chunks_bucket; i++, f+=chunkSize, totalSize-=chunkSize, nchunks++, maxchunks-- ) { chunks->data[ nchunks ].first = f; chunks->data[ nchunks ].last = f+chunkSize-1; } } return( 1 ); } /************************************************************ * * management * ***********************************************************/ void initChunk( typeChunk chunk ) { chunk->first = 1; chunk->last = 0; chunk->parameters = (void)NULL; chunk->ret = 0; } void initChunks( typeChunks chunks ) { chunks->data = (typeChunk)NULL; chunks->n_allocated_chunks = 0; chunks->ompScheduling = _DEFAULT_OMP_SCHEDULING_; } void freeChunks( typeChunks chunks ) { if ( chunks->data != (typeChunk)NULL ) vtfree( chunks->data ); initChunks( chunks ); } int allocChunks( typeChunks chunks, int n ) { char proc = "allocChunks"; int i; if ( n <= 0 ) { if ( _verbose_ ) fprintf( stderr, "%s: negative or null number of chunks\n", proc ); return( -1 ); } chunks->data = (typeChunk)vtmalloc( n sizeof(typeChunk), "chunks->data", proc ); if ( chunks->data == (typeChunk)NULL ) { if ( _verbose_ ) fprintf( stderr, "%s: error when allocating %d chunks\n", proc, n ); return( -1 ); } for ( i=0; i<n; i++ ) initChunk( &(chunks->data[i] ) ); chunks->n_allocated_chunks = n; return( 1 ); } void printChunks( FILE theFile, typeChunks chunks, char s ) { char proc = "printChunks"; int i; FILE f = theFile; if ( f == NULL ) f = stdout; if ( s != (char )NULL ) fprintf( f, "%s: information on '%s'\n", proc, s ); if ( chunks->n_allocated_chunks <= 0 \|\| chunks->data == (typeChunk)NULL ) { fprintf( f, "empty chunks\n" ); return; } for ( i=0; i<chunks->n_allocated_chunks; i++ ) fprintf( f, "#%3d [%12lu %12lu] = %12lu\n", i, chunks->data[i].first, chunks->data[i].last, chunks->data[i].last + 1 - chunks->data[i].first ); fprintf( f, "\n" ); } /*********************************************************** * * test * ************************************************************/
GB_emult_01_template.c	//------------------------------------------------------------------------------ // GB_emult_01_template: C=A.B, C<M or !M>=A.B when C is sparse/hyper //------------------------------------------------------------------------------ // SuiteSparse:GraphBLAS, Timothy A. Davis, (c) 2017-2021, All Rights Reserved. // SPDX-License-Identifier: Apache-2.0 //------------------------------------------------------------------------------ // Computes C=A.B, C<M>=A.B, or C<!M>=A.B when C is sparse or hypersparse: // phase1: does not compute C itself, but just counts the # of entries in each // vector of C. Fine tasks compute the # of entries in their slice of a // single vector of C, and the results are cumsum'd. // phase2: computes C, using the counts computed by phase1. // No input matrix can be jumbled, and C is constructed as unjumbled. // The following cases are handled: // ------------------------------------------ // C = A . B // ------------------------------------------ // sparse . sparse sparse (method: 01) // ------------------------------------------ // C <M>= A .* B // ------------------------------------------ // sparse sparse sparse sparse (method: 01) // sparse bitmap sparse sparse (method: 01) // sparse full sparse sparse (method: 01) // sparse sparse sparse bitmap (04a or 02a) // sparse sparse sparse full (04a or 02a) // sparse sparse bitmap sparse (04b or 02b) // sparse sparse full sparse (04b or 02b) // ------------------------------------------ // C <!M>= A .* B // ------------------------------------------ // sparse sparse sparse sparse (01: M later) // sparse bitmap sparse sparse (method: 01) // sparse full sparse sparse (method: 01) // The 04a and 04b methods are not yet implemented. This method handles // those cases. Methods 02a and 02b can be used as well, but only if M is // applied later. See GB_emult_sparsity for this decision. { int taskid ; #pragma omp parallel for num_threads(C_nthreads) schedule(dynamic,1) for (taskid = 0 ; taskid < C_ntasks ; taskid++) { //---------------------------------------------------------------------- // get the task descriptor //---------------------------------------------------------------------- int64_t kfirst = TaskList [taskid].kfirst ; int64_t klast = TaskList [taskid].klast ; bool fine_task = (klast == -1) ; int64_t len ; if (fine_task) { // a fine task operates on a slice of a single vector klast = kfirst ; len = TaskList [taskid].len ; } else { // a coarse task operates on one or more whole vectors len = vlen ; } //---------------------------------------------------------------------- // compute all vectors in this task //---------------------------------------------------------------------- for (int64_t k = kfirst ; k <= klast ; k++) { //------------------------------------------------------------------ // get j, the kth vector of C //------------------------------------------------------------------ int64_t j = GBH (Ch, k) ; #if defined ( GB_PHASE_1_OF_2 ) int64_t cjnz = 0 ; #else int64_t pC, pC_end ; if (fine_task) { // A fine task computes a slice of C(:,j) pC = TaskList [taskid ].pC ; pC_end = TaskList [taskid+1].pC ; ASSERT (Cp [k] <= pC && pC <= pC_end && pC_end <= Cp [k+1]) ; } else { // The vectors of C are never sliced for a coarse task. pC = Cp [k] ; pC_end = Cp [k+1] ; } int64_t cjnz = pC_end - pC ; if (cjnz == 0) continue ; #endif //------------------------------------------------------------------ // get A(:,j) //------------------------------------------------------------------ int64_t pA = -1, pA_end = -1 ; if (fine_task) { // A fine task operates on Ai,Ax [pA...pA_end-1], which is // a subset of the vector A(:,j) pA = TaskList [taskid].pA ; pA_end = TaskList [taskid].pA_end ; } else { // A coarse task operates on the entire vector A (:,j) int64_t kA = (Ch == Ah) ? k : ((C_to_A == NULL) ? j : C_to_A [k]) ; if (kA >= 0) { pA = GBP (Ap, kA, vlen) ; pA_end = GBP (Ap, kA+1, vlen) ; } } int64_t ajnz = pA_end - pA ; // nnz in A(:,j) for this slice int64_t pA_start = pA ; bool adense = (ajnz == len) ; // get the first and last indices in A(:,j) for this vector int64_t iA_first = -1 ; if (ajnz > 0) { iA_first = GBI (Ai, pA, vlen) ; } #if defined ( GB_PHASE_1_OF_2 ) \|\| defined ( GB_DEBUG ) int64_t iA_last = -1 ; if (ajnz > 0) { iA_last = GBI (Ai, pA_end-1, vlen) ; } #endif //------------------------------------------------------------------ // get B(:,j) //------------------------------------------------------------------ int64_t pB = -1, pB_end = -1 ; if (fine_task) { // A fine task operates on Bi,Bx [pB...pB_end-1], which is // a subset of the vector B(:,j) pB = TaskList [taskid].pB ; pB_end = TaskList [taskid].pB_end ; } else { // A coarse task operates on the entire vector B (:,j) int64_t kB = (Ch == Bh) ? k : ((C_to_B == NULL) ? j : C_to_B [k]) ; if (kB >= 0) { pB = GBP (Bp, kB, vlen) ; pB_end = GBP (Bp, kB+1, vlen) ; } } int64_t bjnz = pB_end - pB ; // nnz in B(:,j) for this slice int64_t pB_start = pB ; bool bdense = (bjnz == len) ; // get the first and last indices in B(:,j) for this vector int64_t iB_first = -1 ; if (bjnz > 0) { iB_first = GBI (Bi, pB, vlen) ; } #if defined ( GB_PHASE_1_OF_2 ) \|\| defined ( GB_DEBUG ) int64_t iB_last = -1 ; if (bjnz > 0) { iB_last = GBI (Bi, pB_end-1, vlen) ; } #endif //------------------------------------------------------------------ // get M(:,j) if M is sparse or hypersparse //------------------------------------------------------------------ int64_t pM = -1 ; int64_t pM_end = -1 ; if (M_is_sparse_or_hyper) { if (fine_task) { // A fine task operates on Mi,Mx [pM...pM_end-1], which is // a subset of the vector M(:,j) pM = TaskList [taskid].pM ; pM_end = TaskList [taskid].pM_end ; } else { int64_t kM = -1 ; if (Ch == Mh) { // Ch is the same as Mh (a shallow copy), or both NULL kM = k ; } else { kM = (C_to_M == NULL) ? j : C_to_M [k] ; } if (kM >= 0) { pM = GBP (Mp, kM, vlen) ; pM_end = GBP (Mp, kM+1, vlen) ; } } } //------------------------------------------------------------------ // C(:,j)<optional mask> = A (:,j) .* B (:,j) or subvector //------------------------------------------------------------------ #if defined ( GB_PHASE_1_OF_2 ) if (ajnz == 0 \|\| bjnz == 0) { //-------------------------------------------------------------- // A(:,j) and/or B(:,j) are empty //-------------------------------------------------------------- ; } else if (iA_last < iB_first \|\| iB_last < iA_first) { //-------------------------------------------------------------- // intersection of A(:,j) and B(:,j) is empty //-------------------------------------------------------------- // the last entry of A(:,j) comes before the first entry // of B(:,j), or visa versa ; } else #endif if (M == NULL) { //-------------------------------------------------------------- // C = A.B //-------------------------------------------------------------- // ------------------------------------------ // C = A . B // ------------------------------------------ // sparse . sparse sparse (method: 01) // sparse sparse sparse sparse (01 M later) // both A and B are sparse/hyper ASSERT (A_is_sparse \|\| A_is_hyper) ; ASSERT (B_is_sparse \|\| B_is_hyper) ; if (ajnz > 32 * bjnz) { //---------------------------------------------------------- // A(:,j) is much denser than B(:,j) //---------------------------------------------------------- for ( ; pB < pB_end ; pB++) { int64_t i = Bi [pB] ; // find i in A(:,j) int64_t pright = pA_end - 1 ; bool found ; GB_BINARY_SEARCH (i, Ai, pA, pright, found) ; if (found) { // C (i,j) = A (i,j) .* B (i,j) #if defined ( GB_PHASE_1_OF_2 ) cjnz++ ; #else ASSERT (pC < pC_end) ; Ci [pC] = i ; GB_GETA (aij, Ax, pA) ; GB_GETB (bij, Bx, pB) ; GB_BINOP (GB_CX (pC), aij, bij, i, j) ; pC++ ; #endif } } #if defined ( GB_PHASE_2_OF_2 ) ASSERT (pC == pC_end) ; #endif } else if (bjnz > 32 * ajnz) { //---------------------------------------------------------- // B(:,j) is much denser than A(:,j) //---------------------------------------------------------- for ( ; pA < pA_end ; pA++) { int64_t i = Ai [pA] ; // find i in B(:,j) int64_t pright = pB_end - 1 ; bool found ; GB_BINARY_SEARCH (i, Bi, pB, pright, found) ; if (found) { // C (i,j) = A (i,j) .* B (i,j) #if defined ( GB_PHASE_1_OF_2 ) cjnz++ ; #else ASSERT (pC < pC_end) ; Ci [pC] = i ; GB_GETA (aij, Ax, pA) ; GB_GETB (bij, Bx, pB) ; GB_BINOP (GB_CX (pC), aij, bij, i, j) ; pC++ ; #endif } } #if defined ( GB_PHASE_2_OF_2 ) ASSERT (pC == pC_end) ; #endif } else { //---------------------------------------------------------- // A(:,j) and B(:,j) about the sparsity //---------------------------------------------------------- // linear-time scan of A(:,j) and B(:,j) while (pA < pA_end && pB < pB_end) { int64_t iA = Ai [pA] ; int64_t iB = Bi [pB] ; if (iA < iB) { // A(i,j) exists but not B(i,j) pA++ ; } else if (iB < iA) { // B(i,j) exists but not A(i,j) pB++ ; } else { // both A(i,j) and B(i,j) exist // C (i,j) = A (i,j) .* B (i,j) #if defined ( GB_PHASE_1_OF_2 ) cjnz++ ; #else ASSERT (pC < pC_end) ; Ci [pC] = iB ; GB_GETA (aij, Ax, pA) ; GB_GETB (bij, Bx, pB) ; GB_BINOP (GB_CX (pC), aij, bij, iB, j) ; pC++ ; #endif pA++ ; pB++ ; } } #if defined ( GB_PHASE_2_OF_2 ) ASSERT (pC == pC_end) ; #endif } } else if (M_is_sparse_or_hyper) { //-------------------------------------------------------------- // C and M are sparse or hypersparse //-------------------------------------------------------------- // ------------------------------------------ // C <M>= A .* B // ------------------------------------------ // sparse sparse sparse sparse (method: 01) // sparse sparse sparse bitmap (04a or 02a) // sparse sparse sparse full (04a or 02a) // sparse sparse bitmap sparse (04b or 02b) // sparse sparse full sparse (04b or 02b) // Method 04 is not yet implemented; using this method // (GB_emult_01) instead. // ether A or B are sparse/hyper ASSERT (A_is_sparse \|\| A_is_hyper \|\| B_is_sparse \|\| B_is_hyper); for ( ; pM < pM_end ; pM++) { //---------------------------------------------------------- // get M(i,j) for A(i,j) .* B (i,j) //---------------------------------------------------------- int64_t i = GBI (Mi, pM, vlen) ; bool mij = GB_mcast (Mx, pM, msize) ; if (!mij) continue ; //---------------------------------------------------------- // get A(i,j) //---------------------------------------------------------- bool afound ; if (adense) { // A(:,j) is dense, bitmap, or full; use quick lookup pA = pA_start + i - iA_first ; afound = GBB (Ab, pA) ; } else { // A(:,j) is sparse; use binary search for A(i,j) int64_t apright = pA_end - 1 ; GB_BINARY_SEARCH (i, Ai, pA, apright, afound) ; } if (!afound) continue ; ASSERT (GBI (Ai, pA, vlen) == i) ; //---------------------------------------------------------- // get B(i,j) //---------------------------------------------------------- bool bfound ; if (bdense) { // B(:,j) is dense; use direct lookup for B(i,j) pB = pB_start + i - iB_first ; bfound = GBB (Bb, pB) ; } else { // B(:,j) is sparse; use binary search for B(i,j) int64_t bpright = pB_end - 1 ; GB_BINARY_SEARCH (i, Bi, pB, bpright, bfound) ; } if (!bfound) continue ; ASSERT (GBI (Bi, pB, vlen) == i) ; //---------------------------------------------------------- // C(i,j) = A(i,j) .* B(i,j) //---------------------------------------------------------- // C (i,j) = A (i,j) .* B (i,j) #if defined ( GB_PHASE_1_OF_2 ) cjnz++ ; #else Ci [pC] = i ; GB_GETA (aij, Ax, pA) ; GB_GETB (bij, Bx, pB) ; GB_BINOP (GB_CX (pC), aij, bij, i, j) ; pC++ ; #endif } #if defined ( GB_PHASE_2_OF_2 ) ASSERT (pC == pC_end) ; #endif } else { //-------------------------------------------------------------- // M is bitmap or full, for either C<M>=A.B or C<!M>=A.B //-------------------------------------------------------------- // ------------------------------------------ // C <M>= A .* B // ------------------------------------------ // sparse bitmap sparse sparse (method: 01) // sparse full sparse sparse (method: 01) // ------------------------------------------ // C <!M>= A .* B // ------------------------------------------ // sparse bitmap sparse sparse (method: 01) // sparse full sparse sparse (method: 01) // GB_GET_MIJ: get M(i,j) where M is bitmap or full #undef GB_GET_MIJ #define GB_GET_MIJ(i) \ int64_t pM = pM_start + i ; \ bool mij = GBB (Mb, pM) && GB_mcast (Mx, pM, msize) ; \ if (Mask_comp) mij = !mij ; // both A and B are sparse/hyper ASSERT (A_is_sparse \|\| A_is_hyper) ; ASSERT (B_is_sparse \|\| B_is_hyper) ; int64_t pM_start = j * vlen ; if (ajnz > 32 * bjnz) { //---------------------------------------------------------- // A(:,j) much denser than B(:,j), M bitmap/full //---------------------------------------------------------- for ( ; pB < pB_end ; pB++) { int64_t i = Bi [pB] ; GB_GET_MIJ (i) ; if (mij) { // find i in A(:,j) int64_t pright = pA_end - 1 ; bool found ; GB_BINARY_SEARCH (i, Ai, pA, pright, found) ; if (found) { // C (i,j) = A (i,j) .* B (i,j) #if defined ( GB_PHASE_1_OF_2 ) cjnz++ ; #else ASSERT (pC < pC_end) ; Ci [pC] = i ; GB_GETA (aij, Ax, pA) ; GB_GETB (bij, Bx, pB) ; GB_BINOP (GB_CX (pC), aij, bij, i, j) ; pC++ ; #endif } } } #if defined ( GB_PHASE_2_OF_2 ) ASSERT (pC == pC_end) ; #endif } else if (bjnz > 32 * ajnz) { //---------------------------------------------------------- // B(:,j) much denser than A(:,j), M bitmap/full //---------------------------------------------------------- for ( ; pA < pA_end ; pA++) { int64_t i = Ai [pA] ; GB_GET_MIJ (i) ; if (mij) { // find i in B(:,j) int64_t pright = pB_end - 1 ; bool found ; GB_BINARY_SEARCH (i, Bi, pB, pright, found) ; if (found) { // C (i,j) = A (i,j) .* B (i,j) #if defined ( GB_PHASE_1_OF_2 ) cjnz++ ; #else ASSERT (pC < pC_end) ; Ci [pC] = i ; GB_GETA (aij, Ax, pA) ; GB_GETB (bij, Bx, pB) ; GB_BINOP (GB_CX (pC), aij, bij, i, j) ; pC++ ; #endif } } } #if defined ( GB_PHASE_2_OF_2 ) ASSERT (pC == pC_end) ; #endif } else { //---------------------------------------------------------- // A(:,j) and B(:,j) about the same, M bitmap/full //---------------------------------------------------------- // linear-time scan of A(:,j) and B(:,j) while (pA < pA_end && pB < pB_end) { int64_t iA = Ai [pA] ; int64_t iB = Bi [pB] ; if (iA < iB) { // A(i,j) exists but not B(i,j) pA++ ; } else if (iB < iA) { // B(i,j) exists but not A(i,j) pB++ ; } else { // both A(i,j) and B(i,j) exist int64_t i = iA ; GB_GET_MIJ (i) ; if (mij) { // C (i,j) = A (i,j) .* B (i,j) #if defined ( GB_PHASE_1_OF_2 ) cjnz++ ; #else ASSERT (pC < pC_end) ; Ci [pC] = i ; GB_GETA (aij, Ax, pA) ; GB_GETB (bij, Bx, pB) ; GB_BINOP (GB_CX (pC), aij, bij, iB, j) ; pC++ ; #endif } pA++ ; pB++ ; } } #if defined ( GB_PHASE_2_OF_2 ) ASSERT (pC == pC_end) ; #endif } } //------------------------------------------------------------------ // final count of nnz (C (:,j)) //------------------------------------------------------------------ #if defined ( GB_PHASE_1_OF_2 ) if (fine_task) { TaskList [taskid].pC = cjnz ; } else { Cp [k] = cjnz ; } #endif } } }
GB_binop__times_int64.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__times_int64) // A.B function (eWiseMult): GB (_AemultB_08__times_int64) // A.B function (eWiseMult): GB (_AemultB_02__times_int64) // A.B function (eWiseMult): GB (_AemultB_04__times_int64) // A.B function (eWiseMult): GB (_AemultB_bitmap__times_int64) // AD function (colscale): GB (_AxD__times_int64) // DA function (rowscale): GB (_DxB__times_int64) // C+=B function (dense accum): GB (_Cdense_accumB__times_int64) // C+=b function (dense accum): GB (_Cdense_accumb__times_int64) // C+=A+B function (dense ewise3): GB (_Cdense_ewise3_accum__times_int64) // C=A+B function (dense ewise3): GB (_Cdense_ewise3_noaccum__times_int64) // C=scalar+B GB (_bind1st__times_int64) // C=scalar+B' GB (_bind1st_tran__times_int64) // C=A+scalar GB (_bind2nd__times_int64) // C=A'+scalar GB (_bind2nd_tran__times_int64) // C type: int64_t // A type: int64_t // A pattern? 0 // B type: int64_t // B pattern? 0 // BinaryOp: cij = (aij bij) #define GB_ATYPE \ int64_t #define GB_BTYPE \ int64_t #define GB_CTYPE \ int64_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) \ int64_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) \ int64_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) \ int64_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_TIMES \|\| GxB_NO_INT64 \|\| GxB_NO_TIMES_INT64) //------------------------------------------------------------------------------ // 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__times_int64) ( 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 //------------------------------------------------------------------------------ void GB (_Cdense_ewise3_noaccum__times_int64) ( 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__times_int64) ( 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__times_int64) ( 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 int64_t int64_t bwork = (((int64_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__times_int64) ( 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 int64_t restrict Cx = (int64_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__times_int64) ( GrB_Matrix C, const GrB_Matrix D, const GrB_Matrix B, int nthreads ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else int64_t restrict Cx = (int64_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__times_int64) ( 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) ; int64_t alpha_scalar ; int64_t beta_scalar ; if (is_eWiseUnion) { alpha_scalar = (((int64_t ) alpha_scalar_in)) ; beta_scalar = (((int64_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__times_int64) ( 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__times_int64) ( 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__times_int64) ( 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__times_int64) ( 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__times_int64) ( 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 int64_t Cx = (int64_t ) Cx_output ; int64_t x = (((int64_t ) x_input)) ; int64_t Bx = (int64_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 ; int64_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__times_int64) ( 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 ; int64_t Cx = (int64_t ) Cx_output ; int64_t Ax = (int64_t ) Ax_input ; int64_t y = (((int64_t ) y_input)) ; #pragma omp parallel for num_threads(nthreads) schedule(static) for (p = 0 ; p < anz ; p++) { if (!GBB (Ab, p)) continue ; int64_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) \ { \ int64_t aij = GBX (Ax, pA, false) ; \ Cx [pC] = (x * aij) ; \ } GrB_Info GB (_bind1st_tran__times_int64) ( 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 \ int64_t #if GB_DISABLE return (GrB_NO_VALUE) ; #else int64_t x = (((const int64_t ) x_input)) ; #include "GB_unop_transpose.c" return (GrB_SUCCESS) ; #endif #undef GB_ATYPE #define GB_ATYPE \ int64_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) \ { \ int64_t aij = GBX (Ax, pA, false) ; \ Cx [pC] = (aij * y) ; \ } GrB_Info GB (_bind2nd_tran__times_int64) ( 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 int64_t y = (((const int64_t ) y_input)) ; #include "GB_unop_transpose.c" return (GrB_SUCCESS) ; #endif } #endif
paint.c	/* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % PPPP AAA IIIII N N TTTTT % % P P A A I NN N T % % PPPP AAAAA I N N N T % % P A A I N NN T % % P A A IIIII N N T % % % % % % Methods to Paint on an Image % % % % Software Design % % Cristy % % July 1998 % % % % % % 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/artifact.h" #include "MagickCore/channel.h" #include "MagickCore/color.h" #include "MagickCore/color-private.h" #include "MagickCore/colorspace-private.h" #include "MagickCore/composite.h" #include "MagickCore/composite-private.h" #include "MagickCore/draw.h" #include "MagickCore/draw-private.h" #include "MagickCore/exception.h" #include "MagickCore/exception-private.h" #include "MagickCore/gem.h" #include "MagickCore/gem-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/resource_.h" #include "MagickCore/statistic.h" #include "MagickCore/string_.h" #include "MagickCore/string-private.h" #include "MagickCore/thread-private.h" / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % F l o o d f i l l P a i n t I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % FloodfillPaintImage() changes the color value of any pixel that matches % target and is an immediate neighbor. If the method FillToBorderMethod is % specified, the color value is changed for any neighbor pixel that does not % match the bordercolor member of image. % % By default target must match a particular pixel color exactly. However, % in many cases two colors may differ by a small amount. The fuzz member of % image defines how much tolerance is acceptable to consider two colors as % the same. For example, set fuzz to 10 and the color red at intensities of % 100 and 102 respectively are now interpreted as the same color for the % purposes of the floodfill. % % The format of the FloodfillPaintImage method is: % % MagickBooleanType FloodfillPaintImage(Image image, % const DrawInfo draw_info,const PixelInfo target, % const ssize_t x_offset,const ssize_t y_offset, % const MagickBooleanType invert,ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o draw_info: the draw info. % % o target: the RGB value of the target color. % % o x_offset,y_offset: the starting location of the operation. % % o invert: paint any pixel that does not match the target color. % % o exception: return any errors or warnings in this structure. % / MagickExport MagickBooleanType FloodfillPaintImage(Image image, const DrawInfo draw_info,const PixelInfo target,const ssize_t x_offset, const ssize_t y_offset,const MagickBooleanType invert, ExceptionInfo exception) { #define MaxStacksize 524288UL #define PushSegmentStack(up,left,right,delta) \ { \ if (s >= (segment_stack+MaxStacksize)) \ { \ segment_info=RelinquishVirtualMemory(segment_info); \ image_view=DestroyCacheView(image_view); \ floodplane_view=DestroyCacheView(floodplane_view); \ floodplane_image=DestroyImage(floodplane_image); \ ThrowBinaryException(DrawError,"SegmentStackOverflow",image->filename) \ } \ else \ { \ if ((((up)+(delta)) >= 0) && (((up)+(delta)) < (ssize_t) image->rows)) \ { \ s->x1=(double) (left); \ s->y1=(double) (up); \ s->x2=(double) (right); \ s->y2=(double) (delta); \ s++; \ } \ } \ } CacheView floodplane_view, image_view; Image floodplane_image; MagickBooleanType skip, status; MemoryInfo segment_info; PixelInfo fill_color, pixel; SegmentInfo s; SegmentInfo segment_stack; ssize_t offset, start, x1, x2, y; /* Check boundary conditions. / 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 ((x_offset < 0) \|\| (x_offset >= (ssize_t) image->columns)) return(MagickFalse); if ((y_offset < 0) \|\| (y_offset >= (ssize_t) image->rows)) return(MagickFalse); if (SetImageStorageClass(image,DirectClass,exception) == MagickFalse) return(MagickFalse); if (IsGrayColorspace(image->colorspace) != MagickFalse) (void) SetImageColorspace(image,sRGBColorspace,exception); if ((image->alpha_trait == UndefinedPixelTrait) && (draw_info->fill.alpha_trait != UndefinedPixelTrait)) (void) SetImageAlpha(image,OpaqueAlpha,exception); / Set floodfill state. / floodplane_image=CloneImage(image,0,0,MagickTrue,exception); if (floodplane_image == (Image ) NULL) return(MagickFalse); floodplane_image->alpha_trait=UndefinedPixelTrait; floodplane_image->colorspace=GRAYColorspace; (void) QueryColorCompliance("#000",AllCompliance, &floodplane_image->background_color,exception); (void) SetImageBackgroundColor(floodplane_image,exception); segment_info=AcquireVirtualMemory(MaxStacksize,sizeof(segment_stack)); if (segment_info == (MemoryInfo ) NULL) { floodplane_image=DestroyImage(floodplane_image); ThrowBinaryException(ResourceLimitError,"MemoryAllocationFailed", image->filename); } segment_stack=(SegmentInfo ) GetVirtualMemoryBlob(segment_info); / Push initial segment on stack. / status=MagickTrue; start=0; s=segment_stack; GetPixelInfo(image,&pixel); image_view=AcquireVirtualCacheView(image,exception); floodplane_view=AcquireAuthenticCacheView(floodplane_image,exception); PushSegmentStack(y_offset,x_offset,x_offset,1); PushSegmentStack(y_offset+1,x_offset,x_offset,-1); while (s > segment_stack) { const Quantum magick_restrict p; Quantum magick_restrict q; ssize_t x; / Pop segment off stack. / s--; x1=(ssize_t) s->x1; x2=(ssize_t) s->x2; offset=(ssize_t) s->y2; y=(ssize_t) s->y1+offset; / Recolor neighboring pixels. / p=GetCacheViewVirtualPixels(image_view,0,y,(size_t) (x1+1),1,exception); q=GetCacheViewAuthenticPixels(floodplane_view,0,y,(size_t) (x1+1),1, exception); if ((p == (const Quantum ) NULL) \|\| (q == (Quantum ) NULL)) break; p+=x1GetPixelChannels(image); q+=x1GetPixelChannels(floodplane_image); for (x=x1; x >= 0; x--) { if (GetPixelGray(floodplane_image,q) != 0) break; GetPixelInfoPixel(image,p,&pixel); if (IsFuzzyEquivalencePixelInfo(&pixel,target) == invert) break; SetPixelGray(floodplane_image,QuantumRange,q); p-=GetPixelChannels(image); q-=GetPixelChannels(floodplane_image); } if (SyncCacheViewAuthenticPixels(floodplane_view,exception) == MagickFalse) break; skip=x >= x1 ? MagickTrue : MagickFalse; if (skip == MagickFalse) { start=x+1; if (start < x1) PushSegmentStack(y,start,x1-1,-offset); x=x1+1; } do { if (skip == MagickFalse) { if (x < (ssize_t) image->columns) { p=GetCacheViewVirtualPixels(image_view,x,y,image->columns-x,1, exception); q=GetCacheViewAuthenticPixels(floodplane_view,x,y,image->columns- x,1,exception); if ((p == (const Quantum ) NULL) \|\| (q == (Quantum ) NULL)) break; for ( ; x < (ssize_t) image->columns; x++) { if (GetPixelGray(floodplane_image,q) != 0) break; GetPixelInfoPixel(image,p,&pixel); if (IsFuzzyEquivalencePixelInfo(&pixel,target) == invert) break; SetPixelGray(floodplane_image,QuantumRange,q); p+=GetPixelChannels(image); q+=GetPixelChannels(floodplane_image); } status=SyncCacheViewAuthenticPixels(floodplane_view,exception); if (status == MagickFalse) break; } PushSegmentStack(y,start,x-1,offset); if (x > (x2+1)) PushSegmentStack(y,x2+1,x-1,-offset); } skip=MagickFalse; x++; if (x <= x2) { p=GetCacheViewVirtualPixels(image_view,x,y,(size_t) (x2-x+1),1, exception); q=GetCacheViewAuthenticPixels(floodplane_view,x,y,(size_t) (x2-x+1),1, exception); if ((p == (const Quantum ) NULL) \|\| (q == (Quantum ) NULL)) break; for ( ; x <= x2; x++) { if (GetPixelGray(floodplane_image,q) != 0) break; GetPixelInfoPixel(image,p,&pixel); if (IsFuzzyEquivalencePixelInfo(&pixel,target) != invert) break; p+=GetPixelChannels(image); q+=GetPixelChannels(floodplane_image); } } start=x; } while (x <= x2); } status=MagickTrue; for (y=0; y < (ssize_t) image->rows; y++) { const Quantum magick_restrict p; Quantum magick_restrict q; ssize_t x; / Tile fill color onto floodplane. / if (status == MagickFalse) continue; p=GetCacheViewVirtualPixels(floodplane_view,0,y,image->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++) { if (GetPixelGray(floodplane_image,p) != 0) { GetFillColor(draw_info,x,y,&fill_color,exception); SetPixelViaPixelInfo(image,&fill_color,q); } p+=GetPixelChannels(floodplane_image); q+=GetPixelChannels(image); } if (SyncCacheViewAuthenticPixels(image_view,exception) == MagickFalse) status=MagickFalse; } floodplane_view=DestroyCacheView(floodplane_view); image_view=DestroyCacheView(image_view); segment_info=RelinquishVirtualMemory(segment_info); floodplane_image=DestroyImage(floodplane_image); return(status); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + G r a d i e n t I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GradientImage() applies a continuously smooth color transitions along a % vector from one color to another. % % Note, the interface of this method will change in the future to support % more than one transistion. % % The format of the GradientImage method is: % % MagickBooleanType GradientImage(Image image,const GradientType type, % const SpreadMethod method,const PixelInfo start_color, % const PixelInfo stop_color,ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o type: the gradient type: linear or radial. % % o spread: the gradient spread meathod: pad, reflect, or repeat. % % o start_color: the start color. % % o stop_color: the stop color. % % o exception: return any errors or warnings in this structure. % / MagickExport MagickBooleanType GradientImage(Image image, const GradientType type,const SpreadMethod method,const StopInfo stops, const size_t number_stops,ExceptionInfo exception) { const char artifact; DrawInfo draw_info; GradientInfo gradient; MagickBooleanType status; / Set gradient start-stop end points. / assert(image != (const Image ) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(stops != (const StopInfo ) NULL); assert(number_stops > 0); draw_info=AcquireDrawInfo(); gradient=(&draw_info->gradient); gradient->type=type; gradient->bounding_box.width=image->columns; gradient->bounding_box.height=image->rows; artifact=GetImageArtifact(image,"gradient:bounding-box"); if (artifact != (const char ) NULL) (void) ParseAbsoluteGeometry(artifact,&gradient->bounding_box); gradient->gradient_vector.x2=(double) image->columns-1; gradient->gradient_vector.y2=(double) image->rows-1; artifact=GetImageArtifact(image,"gradient:direction"); if (artifact != (const char ) NULL) { GravityType direction; direction=(GravityType) ParseCommandOption(MagickGravityOptions, MagickFalse,artifact); switch (direction) { case NorthWestGravity: { gradient->gradient_vector.x1=(double) image->columns-1; gradient->gradient_vector.y1=(double) image->rows-1; gradient->gradient_vector.x2=0.0; gradient->gradient_vector.y2=0.0; break; } case NorthGravity: { gradient->gradient_vector.x1=0.0; gradient->gradient_vector.y1=(double) image->rows-1; gradient->gradient_vector.x2=0.0; gradient->gradient_vector.y2=0.0; break; } case NorthEastGravity: { gradient->gradient_vector.x1=0.0; gradient->gradient_vector.y1=(double) image->rows-1; gradient->gradient_vector.x2=(double) image->columns-1; gradient->gradient_vector.y2=0.0; break; } case WestGravity: { gradient->gradient_vector.x1=(double) image->columns-1; gradient->gradient_vector.y1=0.0; gradient->gradient_vector.x2=0.0; gradient->gradient_vector.y2=0.0; break; } case EastGravity: { gradient->gradient_vector.x1=0.0; gradient->gradient_vector.y1=0.0; gradient->gradient_vector.x2=(double) image->columns-1; gradient->gradient_vector.y2=0.0; break; } case SouthWestGravity: { gradient->gradient_vector.x1=(double) image->columns-1; gradient->gradient_vector.y1=0.0; gradient->gradient_vector.x2=0.0; gradient->gradient_vector.y2=(double) image->rows-1; break; } case SouthGravity: { gradient->gradient_vector.x1=0.0; gradient->gradient_vector.y1=0.0; gradient->gradient_vector.x2=0.0; gradient->gradient_vector.y2=(double) image->columns-1; break; } case SouthEastGravity: { gradient->gradient_vector.x1=0.0; gradient->gradient_vector.y1=0.0; gradient->gradient_vector.x2=(double) image->columns-1; gradient->gradient_vector.y2=(double) image->rows-1; break; } default: break; } } artifact=GetImageArtifact(image,"gradient:angle"); if (artifact != (const char ) NULL) gradient->angle=StringToDouble(artifact,(char *) NULL); artifact=GetImageArtifact(image,"gradient:vector"); if (artifact != (const char ) NULL) (void) sscanf(artifact,"%lf%[ ,]%lf%[ ,]%lf%[ ,]%lf", &gradient->gradient_vector.x1,&gradient->gradient_vector.y1, &gradient->gradient_vector.x2,&gradient->gradient_vector.y2); if ((GetImageArtifact(image,"gradient:angle") == (const char ) NULL) && (GetImageArtifact(image,"gradient:direction") == (const char ) NULL) && (GetImageArtifact(image,"gradient:extent") == (const char ) NULL) && (GetImageArtifact(image,"gradient:vector") == (const char ) NULL)) if ((type == LinearGradient) && (gradient->gradient_vector.y2 != 0.0)) gradient->gradient_vector.x2=0.0; gradient->center.x=(double) gradient->gradient_vector.x2/2.0; gradient->center.y=(double) gradient->gradient_vector.y2/2.0; artifact=GetImageArtifact(image,"gradient:center"); if (artifact != (const char ) NULL) (void) sscanf(artifact,"%lf%[ ,]%lf",&gradient->center.x, &gradient->center.y); artifact=GetImageArtifact(image,"gradient:angle"); if ((type == LinearGradient) && (artifact != (const char ) NULL)) { double sine, cosine, distance; /* Reference https://drafts.csswg.org/css-images-3/#linear-gradients. / sine=sin((double) DegreesToRadians(gradient->angle-90.0)); cosine=cos((double) DegreesToRadians(gradient->angle-90.0)); distance=fabs((double) (image->columns-1.0)cosine)+ fabs((double) (image->rows-1.0)sine); gradient->gradient_vector.x1=0.5((image->columns-1.0)-distancecosine); gradient->gradient_vector.y1=0.5((image->rows-1.0)-distancesine); gradient->gradient_vector.x2=0.5((image->columns-1.0)+distancecosine); gradient->gradient_vector.y2=0.5((image->rows-1.0)+distancesine); } gradient->radii.x=(double) MagickMax((image->columns-1.0),(image->rows-1.0))/ 2.0; gradient->radii.y=gradient->radii.x; artifact=GetImageArtifact(image,"gradient:extent"); if (artifact != (const char ) NULL) { if (LocaleCompare(artifact,"Circle") == 0) { gradient->radii.x=(double) MagickMax((image->columns-1.0), (image->rows-1.0))/2.0; gradient->radii.y=gradient->radii.x; } if (LocaleCompare(artifact,"Diagonal") == 0) { gradient->radii.x=(double) (sqrt((double) (image->columns-1.0)* (image->columns-1.0)+(image->rows-1.0)(image->rows-1.0)))/2.0; gradient->radii.y=gradient->radii.x; } if (LocaleCompare(artifact,"Ellipse") == 0) { gradient->radii.x=(double) (image->columns-1.0)/2.0; gradient->radii.y=(double) (image->rows-1.0)/2.0; } if (LocaleCompare(artifact,"Maximum") == 0) { gradient->radii.x=(double) MagickMax((image->columns-1.0), (image->rows-1.0))/2.0; gradient->radii.y=gradient->radii.x; } if (LocaleCompare(artifact,"Minimum") == 0) { gradient->radii.x=(double) (MagickMin((image->columns-1.0), (image->rows-1.0)))/2.0; gradient->radii.y=gradient->radii.x; } } artifact=GetImageArtifact(image,"gradient:radii"); if (artifact != (const char ) NULL) (void) sscanf(artifact,"%lf%[ ,]%lf",&gradient->radii.x, &gradient->radii.y); gradient->radius=MagickMax(gradient->radii.x,gradient->radii.y); gradient->spread=method; / Define the gradient to fill between the stops. / gradient->number_stops=number_stops; gradient->stops=(StopInfo ) AcquireQuantumMemory(gradient->number_stops, sizeof(gradient->stops)); if (gradient->stops == (StopInfo ) NULL) ThrowBinaryException(ResourceLimitError,"MemoryAllocationFailed", image->filename); (void) memcpy(gradient->stops,stops,(size_t) number_stopssizeof(stops)); /* Draw a gradient on the image. / status=DrawGradientImage(image,draw_info,exception); draw_info=DestroyDrawInfo(draw_info); return(status); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % O i l P a i n t I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % OilPaintImage() applies a special effect filter that simulates an oil % painting. Each pixel is replaced by the most frequent color occurring % in a circular region defined by radius. % % The format of the OilPaintImage method is: % % Image OilPaintImage(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 circular neighborhood. % % o sigma: the standard deviation of the Gaussian, in pixels. % % o exception: return any errors or warnings in this structure. % / static size_t DestroyHistogramThreadSet(size_t histogram) { ssize_t i; assert(histogram != (size_t *) NULL); for (i=0; i < (ssize_t) GetMagickResourceLimit(ThreadResource); i++) if (histogram[i] != (size_t ) NULL) histogram[i]=(size_t ) RelinquishMagickMemory(histogram[i]); histogram=(size_t ) RelinquishMagickMemory(histogram); return(histogram); } static size_t AcquireHistogramThreadSet(const size_t count) { ssize_t i; size_t histogram, number_threads; number_threads=(size_t) GetMagickResourceLimit(ThreadResource); histogram=(size_t ) AcquireQuantumMemory(number_threads,sizeof(histogram)); if (histogram == (size_t ) NULL) return((size_t ) NULL); (void) memset(histogram,0,number_threadssizeof(histogram)); for (i=0; i < (ssize_t) number_threads; i++) { histogram[i]=(size_t ) AcquireQuantumMemory(count,sizeof(histogram)); if (histogram[i] == (size_t ) NULL) return(DestroyHistogramThreadSet(histogram)); } return(histogram); } MagickExport Image OilPaintImage(const Image image,const double radius, const double sigma,ExceptionInfo exception) { #define NumberPaintBins 256 #define OilPaintImageTag "OilPaint/Image" CacheView image_view, paint_view; Image linear_image, paint_image; MagickBooleanType status; MagickOffsetType progress; size_t histograms, width; ssize_t center, y; / Initialize painted 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); width=GetOptimalKernelWidth2D(radius,sigma); linear_image=CloneImage(image,0,0,MagickTrue,exception); paint_image=CloneImage(image,0,0,MagickTrue,exception); if ((linear_image == (Image ) NULL) \|\| (paint_image == (Image ) NULL)) { if (linear_image != (Image ) NULL) linear_image=DestroyImage(linear_image); if (paint_image != (Image ) NULL) linear_image=DestroyImage(paint_image); return((Image ) NULL); } if (SetImageStorageClass(paint_image,DirectClass,exception) == MagickFalse) { linear_image=DestroyImage(linear_image); paint_image=DestroyImage(paint_image); return((Image ) NULL); } histograms=AcquireHistogramThreadSet(NumberPaintBins); if (histograms == (size_t ) NULL) { linear_image=DestroyImage(linear_image); paint_image=DestroyImage(paint_image); ThrowImageException(ResourceLimitError,"MemoryAllocationFailed"); } / Oil paint image. / status=MagickTrue; progress=0; center=(ssize_t) GetPixelChannels(linear_image)(linear_image->columns+width)* (width/2L)+GetPixelChannels(linear_image)(width/2L); image_view=AcquireVirtualCacheView(linear_image,exception); paint_view=AcquireAuthenticCacheView(paint_image,exception); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(progress,status) \ magick_number_threads(linear_image,paint_image,linear_image->rows,1) #endif for (y=0; y < (ssize_t) linear_image->rows; y++) { const Quantum magick_restrict p; Quantum magick_restrict q; size_t histogram; ssize_t x; if (status == MagickFalse) continue; p=GetCacheViewVirtualPixels(image_view,-((ssize_t) width/2L),y-(ssize_t) (width/2L),linear_image->columns+width,width,exception); q=QueueCacheViewAuthenticPixels(paint_view,0,y,paint_image->columns,1, exception); if ((p == (const Quantum ) NULL) \|\| (q == (Quantum ) NULL)) { status=MagickFalse; continue; } histogram=histograms[GetOpenMPThreadId()]; for (x=0; x < (ssize_t) linear_image->columns; x++) { ssize_t i, u; size_t count; ssize_t j, k, n, v; /* Assign most frequent color. / k=0; j=0; count=0; (void) memset(histogram,0,NumberPaintBins sizeof(histogram)); for (v=0; v < (ssize_t) width; v++) { for (u=0; u < (ssize_t) width; u++) { n=(ssize_t) ScaleQuantumToChar(ClampToQuantum(GetPixelIntensity( linear_image,p+GetPixelChannels(linear_image)(u+k)))); histogram[n]++; if (histogram[n] > count) { j=k+u; count=histogram[n]; } } k+=(ssize_t) (linear_image->columns+width); } for (i=0; i < (ssize_t) GetPixelChannels(linear_image); i++) { PixelChannel channel = GetPixelChannelChannel(linear_image,i); PixelTrait traits = GetPixelChannelTraits(linear_image,channel); PixelTrait paint_traits=GetPixelChannelTraits(paint_image,channel); if ((traits == UndefinedPixelTrait) \|\| (paint_traits == UndefinedPixelTrait)) continue; if ((paint_traits & CopyPixelTrait) != 0) { SetPixelChannel(paint_image,channel,p[center+i],q); continue; } SetPixelChannel(paint_image,channel,p[jGetPixelChannels(linear_image)+ i],q); } p+=GetPixelChannels(linear_image); q+=GetPixelChannels(paint_image); } if (SyncCacheViewAuthenticPixels(paint_view,exception) == MagickFalse) status=MagickFalse; if (linear_image->progress_monitor != (MagickProgressMonitor) NULL) { MagickBooleanType proceed; #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp atomic #endif progress++; proceed=SetImageProgress(linear_image,OilPaintImageTag,progress, linear_image->rows); if (proceed == MagickFalse) status=MagickFalse; } } paint_view=DestroyCacheView(paint_view); image_view=DestroyCacheView(image_view); histograms=DestroyHistogramThreadSet(histograms); linear_image=DestroyImage(linear_image); if (status == MagickFalse) paint_image=DestroyImage(paint_image); return(paint_image); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % O p a q u e P a i n t I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % OpaquePaintImage() changes any pixel that matches color with the color % defined by fill argument. % % By default color must match a particular pixel color exactly. However, in % many cases two colors may differ by a small amount. Fuzz defines how much % tolerance is acceptable to consider two colors as the same. For example, % set fuzz to 10 and the color red at intensities of 100 and 102 respectively % are now interpreted as the same color. % % The format of the OpaquePaintImage method is: % % MagickBooleanType OpaquePaintImage(Image image,const PixelInfo target, % const PixelInfo fill,const MagickBooleanType invert, % ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o target: the RGB value of the target color. % % o fill: the replacement color. % % o invert: paint any pixel that does not match the target color. % % o exception: return any errors or warnings in this structure. % / MagickExport MagickBooleanType OpaquePaintImage(Image image, const PixelInfo target,const PixelInfo fill,const MagickBooleanType invert, ExceptionInfo exception) { #define OpaquePaintImageTag "Opaque/Image" CacheView image_view; MagickBooleanType status; MagickOffsetType progress; PixelInfo conform_fill, conform_target, zero; ssize_t y; assert(image != (Image ) NULL); assert(image->signature == MagickCoreSignature); assert(target != (PixelInfo ) NULL); assert(fill != (PixelInfo ) NULL); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); if (SetImageStorageClass(image,DirectClass,exception) == MagickFalse) return(MagickFalse); ConformPixelInfo(image,fill,&conform_fill,exception); ConformPixelInfo(image,target,&conform_target,exception); / Make image color opaque. / status=MagickTrue; progress=0; GetPixelInfo(image,&zero); 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++) { PixelInfo pixel; 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; } pixel=zero; for (x=0; x < (ssize_t) image->columns; x++) { GetPixelInfoPixel(image,q,&pixel); if (IsFuzzyEquivalencePixelInfo(&pixel,&conform_target) != invert) { PixelTrait traits; traits=GetPixelChannelTraits(image,RedPixelChannel); if ((traits & UpdatePixelTrait) != 0) SetPixelRed(image,(Quantum) conform_fill.red,q); traits=GetPixelChannelTraits(image,GreenPixelChannel); if ((traits & UpdatePixelTrait) != 0) SetPixelGreen(image,(Quantum) conform_fill.green,q); traits=GetPixelChannelTraits(image,BluePixelChannel); if ((traits & UpdatePixelTrait) != 0) SetPixelBlue(image,(Quantum) conform_fill.blue,q); traits=GetPixelChannelTraits(image,BlackPixelChannel); if ((traits & UpdatePixelTrait) != 0) SetPixelBlack(image,(Quantum) conform_fill.black,q); traits=GetPixelChannelTraits(image,AlphaPixelChannel); if ((traits & UpdatePixelTrait) != 0) SetPixelAlpha(image,(Quantum) conform_fill.alpha,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,OpaquePaintImageTag,progress, image->rows); if (proceed == MagickFalse) status=MagickFalse; } } image_view=DestroyCacheView(image_view); return(status); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % T r a n s p a r e n t P a i n t I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % TransparentPaintImage() changes the opacity value associated with any pixel % that matches color to the value defined by opacity. % % By default color must match a particular pixel color exactly. However, in % many cases two colors may differ by a small amount. Fuzz defines how much % tolerance is acceptable to consider two colors as the same. For example, % set fuzz to 10 and the color red at intensities of 100 and 102 respectively % are now interpreted as the same color. % % The format of the TransparentPaintImage method is: % % MagickBooleanType TransparentPaintImage(Image image, % const PixelInfo target,const Quantum opacity, % const MagickBooleanType invert,ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o target: the target color. % % o opacity: the replacement opacity value. % % o invert: paint any pixel that does not match the target color. % % o exception: return any errors or warnings in this structure. % / MagickExport MagickBooleanType TransparentPaintImage(Image image, const PixelInfo target,const Quantum opacity,const MagickBooleanType invert, ExceptionInfo exception) { #define TransparentPaintImageTag "Transparent/Image" CacheView image_view; MagickBooleanType status; MagickOffsetType progress; PixelInfo zero; ssize_t y; assert(image != (Image ) NULL); assert(image->signature == MagickCoreSignature); assert(target != (PixelInfo ) NULL); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); if (SetImageStorageClass(image,DirectClass,exception) == MagickFalse) return(MagickFalse); if (image->alpha_trait == UndefinedPixelTrait) (void) SetImageAlphaChannel(image,OpaqueAlphaChannel,exception); /* Make image color transparent. / status=MagickTrue; progress=0; GetPixelInfo(image,&zero); 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++) { PixelInfo pixel; ssize_t x; Quantum magick_restrict q; if (status == MagickFalse) continue; q=GetCacheViewAuthenticPixels(image_view,0,y,image->columns,1,exception); if (q == (Quantum ) NULL) { status=MagickFalse; continue; } pixel=zero; for (x=0; x < (ssize_t) image->columns; x++) { GetPixelInfoPixel(image,q,&pixel); if (IsFuzzyEquivalencePixelInfo(&pixel,target) != invert) SetPixelAlpha(image,opacity,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,TransparentPaintImageTag,progress, image->rows); if (proceed == MagickFalse) status=MagickFalse; } } image_view=DestroyCacheView(image_view); return(status); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % T r a n s p a r e n t P a i n t I m a g e C h r o m a % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % TransparentPaintImageChroma() changes the opacity value associated with any % pixel that matches color to the value defined by opacity. % % As there is one fuzz value for the all the channels, TransparentPaintImage() % is not suitable for the operations like chroma, where the tolerance for % similarity of two color component (RGB) can be different. Thus we define % this method to take two target pixels (one low and one high) and all the % pixels of an image which are lying between these two pixels are made % transparent. % % The format of the TransparentPaintImageChroma method is: % % MagickBooleanType TransparentPaintImageChroma(Image image, % const PixelInfo low,const PixelInfo high,const Quantum opacity, % const MagickBooleanType invert,ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o low: the low target color. % % o high: the high target color. % % o opacity: the replacement opacity value. % % o invert: paint any pixel that does not match the target color. % % o exception: return any errors or warnings in this structure. % / MagickExport MagickBooleanType TransparentPaintImageChroma(Image image, const PixelInfo low,const PixelInfo high,const Quantum opacity, const MagickBooleanType invert,ExceptionInfo exception) { #define TransparentPaintImageTag "Transparent/Image" CacheView image_view; MagickBooleanType status; MagickOffsetType progress; ssize_t y; assert(image != (Image ) NULL); assert(image->signature == MagickCoreSignature); assert(high != (PixelInfo ) NULL); assert(low != (PixelInfo ) NULL); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); if (SetImageStorageClass(image,DirectClass,exception) == MagickFalse) return(MagickFalse); if (image->alpha_trait == UndefinedPixelTrait) (void) SetImageAlphaChannel(image,OpaqueAlphaChannel,exception); / Make image color transparent. / 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++) { MagickBooleanType match; PixelInfo pixel; 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; } GetPixelInfo(image,&pixel); for (x=0; x < (ssize_t) image->columns; x++) { GetPixelInfoPixel(image,q,&pixel); match=((pixel.red >= low->red) && (pixel.red <= high->red) && (pixel.green >= low->green) && (pixel.green <= high->green) && (pixel.blue >= low->blue) && (pixel.blue <= high->blue)) ? MagickTrue : MagickFalse; if (match != invert) SetPixelAlpha(image,opacity,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,TransparentPaintImageTag,progress, image->rows); if (proceed == MagickFalse) status=MagickFalse; } } image_view=DestroyCacheView(image_view); return(status); }
dacemath.c	/****************************************************************************** * * * DIFFERENTIAL ALGEBRA CORE ENGINE * * * ******************************************************************************* * * * Copyright 2016 Politecnico di Milano (2014 Dinamica Srl) * * 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. * * * ******************************************************************************/ / * dacemath.c * * Created on: November 18, 2016 * Author: Politecnico di Milano / /* \addtogroup DACE Core * @{ / // MS C library needs this to trigger it to define math constants #define _USE_MATH_DEFINES #include <math.h> #include <stdlib.h> #include "dace/config.h" #include "dace/dacebase.h" #include "dace/daceaux.h" #include "dacecontrib.h" // define various math constants in case they have not been defined by math.h // these are non-standard C, but most C libraries have them #ifndef M_PI #define M_PI (3.14159265358979323846) #endif #ifndef M_PI_2 #define M_PI_2 (1.57079632679489661923) #endif /******************************************************************************* * Basic DACE arithmetic operations ********************************************************************************/ /! Perform addition of two DA objects. \param[in] ina Pointer to the first DA object to operate on \param[in] inb Pointer to the first DA object to operate on \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina or inb. / void daceAdd(const DACEDA ina, const DACEDA inb, DACEDA inc) { if(!daceIsSameObject(ina, inc) && !daceIsSameObject(inb, inc)) { daceWeightedSum(ina, 1.0, inb, 1.0, inc); } else { DACEDA idaadd; daceAllocateDA(&idaadd, 0); daceWeightedSum(ina, 1.0, inb, 1.0, &idaadd); daceCopy(&idaadd, inc); daceFreeDA(&idaadd); } } /! Perform subtraction of two DA objects. \param[in] ina Pointer to the first DA object to operate on \param[in] inb Pointer to the first DA object to operate on \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina or inb. / void daceSubtract(const DACEDA ina, const DACEDA inb, DACEDA inc) { if(!daceIsSameObject(ina, inc) && !daceIsSameObject(inb, inc)) { daceWeightedSum(ina, 1.0, inb, -1.0, inc); } else { DACEDA idasub; daceAllocateDA(&idasub, 0); daceWeightedSum(ina, 1.0, inb, -1.0, &idasub); daceCopy(&idasub, inc); daceFreeDA(&idasub); } } /! Perform multiplication of two DA objects. \param[in] ina Pointer to the first DA object to operate on \param[in] inb Pointer to the first DA object to operate on \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina or inb. / void daceMultiply(const DACEDA ina, const DACEDA inb, DACEDA inc) { // These should use thread local storage (TLS) for multithread safe implementations // see https://en.wikipedia.org/wiki/Thread-local_storage #if DACE_MEMORY_MODEL == DACE_MEMORY_STATIC static DACE_THREAD_LOCAL double cc[DACE_STATIC_NMMAX] = {0}; static DACE_THREAD_LOCAL extended_monomial emb[DACE_STATIC_NMMAX]; static DACE_THREAD_LOCAL extended_monomial ipbeg[DACE_STATIC_NOMAX+1]; static DACE_THREAD_LOCAL extended_monomial ipend[DACE_STATIC_NOMAX+1]; static DACE_THREAD_LOCAL unsigned int nomax = 0; static DACE_THREAD_LOCAL unsigned int nvmax = 0; // make sure static memory is correctly allocated if(UNLIKELY(nomax != DACECom.nomax \|\| nvmax != DACECom.nvmax)) { nomax = DACECom.nomax; nvmax = DACECom.nvmax; ipbeg[0] = &emb[0]; for(unsigned int i = 1; i <= DACECom.nomax; i++) ipbeg[i] = emb + daceCountMonomials(i - 1, DACECom.nvmax); } #else static DACE_THREAD_LOCAL double cc = NULL; static DACE_THREAD_LOCAL extended_monomial emb = NULL; static DACE_THREAD_LOCAL extended_monomial ipbeg = NULL; static DACE_THREAD_LOCAL extended_monomial ipend = NULL; static DACE_THREAD_LOCAL unsigned int nomax = 0; static DACE_THREAD_LOCAL unsigned int nvmax = 0; // make sure static memory is correctly allocated if(UNLIKELY(nomax != DACECom.nomax \|\| nvmax != DACECom.nvmax)) { nomax = DACECom.nomax; nvmax = DACECom.nvmax; dacefree(cc); dacefree(emb); dacefree(ipbeg); dacefree(ipend); cc = (double) dacecalloc(DACECom.nmmax, sizeof(double)); emb = (extended_monomial) dacecalloc(DACECom.nmmax, sizeof(extended_monomial)); ipbeg = (extended_monomial*) dacecalloc(DACECom.nomax+1, sizeof(extended_monomial)); ipend = (extended_monomial*) dacecalloc(DACECom.nomax+1, sizeof(extended_monomial)); ipbeg[0] = &emb[0]; for(unsigned int i = 1; i <= DACECom.nomax; i++) ipbeg[i] = emb + daceCountMonomials(i - 1, DACECom.nvmax); } #endif monomial ipoa; unsigned int ilma, illa; monomial ipob; unsigned int ilmb, illb; daceVariableInformation(ina, &ipoa, &ilma, &illa); daceVariableInformation(inb, &ipob, &ilmb, &illb); // sort so that ina is the short DA vector if(illa>illb) { unsigned int t1; t1 = illb; illb = illa; illa = t1; t1 = ilmb; ilmb = ilma; ilma = t1; monomial* t2; t2 = ipoa; ipoa = ipob; ipob = t2; } for(unsigned int i = 0; i <= DACECom_t.nocut; i++) ipend[i] = ipbeg[i]; // sort vector b by order for(monomial ib = ipob; ib < ipob+illb; ib++) { const unsigned int noib = DACECom.ieo[ib->ii]; if(noib > DACECom_t.nocut) continue; ipend[noib]->i1 = DACECom.ie1[ib->ii]; ipend[noib]->i2 = DACECom.ie2[ib->ii]; ipend[noib]->cc = ib->cc; ipend[noib]++; } // perform actual multiplication for(monomial ia = ipoa; ia < ipoa+illa; ia++) { const unsigned int i1ia = DACECom.ie1[ia->ii]; const unsigned int i2ia = DACECom.ie2[ia->ii]; const double ccia = ia->cc; // Note: all of these inner loops can safely be run in parallel //#pragma omp parallel for for(int noib = DACECom_t.nocut-DACECom.ieo[ia->ii]; noib >= 0; noib--) { for(extended_monomial ib = ipbeg[noib]; ib < ipend[noib]; ib++) { const unsigned int ic = DACECom.ia1[i1ia+ib->i1] + DACECom.ia2[i2ia+ib->i2]; cc[ic] += cciaib->cc; } } } dacePack(cc, inc); } /! Multiply two DA vectors component-wise, i.e. each monomial of ina with the corresponding monomial of inb \param[in] ina Pointer to the first DA object to operate on \param[in] inb Pointer to the first DA object to operate on \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina or inb. \sa daceEvalMonomials / void daceMultiplyMonomials(const DACEDA ina, const DACEDA inb, DACEDA inc) { monomial ipoa; unsigned int ilma, illa; monomial ipob; unsigned int ilmb, illb; monomial ipoc; unsigned int ilmc, illc; daceVariableInformation(ina, &ipoa, &ilma, &illa); daceVariableInformation(inb, &ipob, &ilmb, &illb); daceVariableInformation(inc, &ipoc, &ilmc, &illc); monomial ib = ipob, ic = ipoc; monomial const ibmax = ipob + ilmb, const icmax = ipoc + ilmc; for (monomial i = ipoa; i < ipoa + illa; i++) { while (ib->ii < i->ii && ib < ibmax) ib++; if (ib == ibmax) break; if (ib->ii == i->ii) { if (ic >= icmax) { daceSetError(__func__, DACE_ERROR, 21); break; } ic->cc = i->ccib->cc; ic->ii = i->ii; ic++; } } } /! Perform division of two DA objects. \param[in] ina Pointer to the first DA object to operate on \param[in] inb Pointer to the first DA object to operate on \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina or inb. / void daceDivide(const DACEDA ina, const DACEDA inb, DACEDA inc) { DACEDA idadiv; daceAllocateDA(&idadiv, 0); daceMultiplicativeInverse(inb, &idadiv); daceMultiply(ina, &idadiv, inc); daceFreeDA(&idadiv); } /! Square a DA object. \param[in] ina Pointer to the DA object to square \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. / void daceSquare(const DACEDA ina, DACEDA inb) { daceMultiply(ina, ina, inb); } /! Add constant to a DA object. \param[in] ina Pointer to the first DA object to operate on \param[in] ckon Constant value to add \param[out] inb Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inb can be the same as ina. / void daceAddDouble(const DACEDA ina, const double ckon, DACEDA inb) { if(!daceIsSameObject(ina, inb)) daceCopy(ina, inb); daceSetCoefficient0(inb, 0, daceGetConstant(inb)+ckon); } /! Subtract DA object from constant. \param[in] ina Pointer to the first DA object to operate on \param[in] ckon Constant value to subtract from \param[out] inb Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inb can be the same as ina. / void daceDoubleSubtract(const DACEDA ina, const double ckon, DACEDA inb) { daceMultiplyDouble(ina, -1.0, inb); daceSetCoefficient0(inb, 0, daceGetConstant(inb)+ckon); } /! Subtract constant from a DA object. \param[in] ina Pointer to the first DA object to operate on \param[in] ckon Constant value to subtract \param[out] inb Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inb can be the same as ina. / void daceSubtractDouble(const DACEDA ina, const double ckon, DACEDA inb) { daceAddDouble(ina, -ckon, inb); } /! Multiply constant and DA object. \param[in] ina Pointer to the first DA object to operate on \param[in] ckon Constant value to multiply by \param[out] inb Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inb can be the same as ina. / void daceMultiplyDouble(const DACEDA ina, const double ckon, DACEDA inb) { monomial ipoa; unsigned int ilma, illa; monomial ipob; unsigned int ilmb, illb; daceVariableInformation(ina, &ipoa, &ilma, &illa); daceVariableInformation(inb, &ipob, &ilmb, &illb); monomial ib = ipob; if(illa <= ilmb) { for(monomial ia = ipoa; ia < ipoa+illa; ia++) { if(DACECom.ieo[ia->ii] > DACECom_t.nocut) continue; const double c = ia->ccckon; if(fabs(c) < DACECom_t.eps) continue; ib->cc = c; ib->ii = ia->ii; ib++; } } else { monomial const ibmax = ipob+ilmb; for(monomial ia = ipoa; ia < ipoa+illa; ia++) { if(DACECom.ieo[ia->ii] > DACECom_t.nocut) continue; const double c = ia->ccckon; if(fabs(c) < DACECom_t.eps) continue; if(ib >= ibmax) { daceSetError(__func__, DACE_ERROR, 21); break; } ib->cc = c; ib->ii = ia->ii; ib++; } } daceSetLength(inb, ib-ipob); } /! Divide DA object by a constant. \param[in] ina Pointer to the first DA object to operate on \param[in] ckon Constant value to divide by \param[out] inb Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inb can be the same as ina. / void daceDivideDouble(const DACEDA ina, const double ckon, DACEDA inb) { if(ckon == 0.0) { daceSetError(__func__, DACE_ERROR, 41); daceCreateConstant(inb, 0.0); return; } daceMultiplyDouble(ina, 1.0/ckon, inb); } /! Divide constant by DA object. \param[in] ina Pointer to the first DA object to operate on \param[in] ckon Constant value to divide \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. / void daceDoubleDivide(const DACEDA ina, const double ckon, DACEDA inc) { daceMultiplicativeInverse(ina, inc); daceMultiplyDouble(inc, ckon, inc); } /! Divide a DA vector by a single variable to some power, if possible. \param[in] ina Pointer to the DA object to operate on \param[in] var Number of the independent variable by which to divide \param[in] p Power of independent variable \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. / void daceDivideByVariable(const DACEDA ina, const unsigned int var, const unsigned int p, DACEDA inc) { monomial ipoa; unsigned int ilma, illa; monomial ipoc; unsigned int ilmc, illc; daceVariableInformation(ina, &ipoa, &ilma, &illa); daceVariableInformation(inc, &ipoc, &ilmc, &illc); if(var < 1 \|\| var > DACECom.nvmax) { daceSetError(__func__, DACE_ERROR, 24); daceCreateConstant(inc, 0.0); return; } // treat a few special cases if(p == 0) { // dividing by 1 daceCopy(ina, inc); return; } else if(illa == 0) { // dividing 0 by anything daceCreateConstant(inc, 0.0); return; } else if(p > DACECom.nomax) { // dividing non-zero DA by too high a power daceSetError(__func__, DACE_ERROR, 42); daceCreateConstant(inc, 0.0); return; } const unsigned int ibase = DACECom.nomax+1; unsigned int j = var-1; if(var > DACECom.nv1) j = j-DACECom.nv1; const unsigned int idiv = npown(ibase, j); monomial ic = ipoc; monomial const icmax = ipoc+ilmc; if(var > DACECom.nv1) { for(monomial i = ipoa; i < ipoa+illa; i++) { const unsigned int ic1 = DACECom.ie1[i->ii]; const unsigned int ic2 = DACECom.ie2[i->ii]; const unsigned int ipow = (ic2/idiv)%ibase; if(ipow < p) { daceSetError(__func__, DACE_ERROR, 42); daceCreateConstant(inc, 0.0); return; } if(ic >= icmax) { daceSetError(__func__, DACE_ERROR, 21); break; } ic->ii = DACECom.ia1[ic1] + DACECom.ia2[ic2-pidiv]; ic->cc = i->cc; ic++; } } else { for(monomial i = ipoa; i < ipoa+illa; i++) { const unsigned int ic1 = DACECom.ie1[i->ii]; const unsigned int ic2 = DACECom.ie2[i->ii]; const unsigned int ipow = (ic1/idiv)%ibase; if(ipow < p) { daceSetError(__func__, DACE_ERROR, 42); daceCreateConstant(inc, 0.0); return; } if(ic >= icmax) { daceSetError(__func__, DACE_ERROR, 21); break; } ic->ii = DACECom.ia1[ic1-pidiv] + DACECom.ia2[ic2]; ic->cc = i->cc; ic++; } } daceSetLength(inc, ic-ipoc); } /! Derivative of DA object with respect to a given independent variable. \param[in] idif Number of the independent variable with respect to which the derivative is taken \param[in] ina Pointer to the DA object to operate on \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. / void daceDifferentiate(const unsigned int idif, const DACEDA ina, DACEDA inc) { monomial ipoa; unsigned int ilma, illa; monomial ipoc; unsigned int ilmc, illc; daceVariableInformation(ina, &ipoa, &ilma, &illa); daceVariableInformation(inc, &ipoc, &ilmc, &illc); if(idif < 1 \|\| idif > DACECom.nvmax) { daceSetError(__func__, DACE_ERROR, 24); daceCreateConstant(inc, 0.0); return; } const unsigned int ibase = DACECom.nomax+1; unsigned int j = idif-1; if(idif > DACECom.nv1) j = j-DACECom.nv1; const unsigned int idiv = npown(ibase, j); monomial ic = ipoc; monomial const icmax = ipoc+ilmc; if(idif > DACECom.nv1) { for(monomial i = ipoa; i < ipoa+illa; i++) { const unsigned int ic1 = DACECom.ie1[i->ii]; const unsigned int ic2 = DACECom.ie2[i->ii]; const unsigned int ipow = (ic2/idiv)%ibase; if(ipow == 0 \|\| DACECom.ieo[i->ii] > DACECom_t.nocut+1) continue; if(ic >= icmax) { daceSetError(__func__, DACE_ERROR, 21); break; } ic->ii = DACECom.ia1[ic1] + DACECom.ia2[ic2-idiv]; ic->cc = i->ccipow; ic++; } } else { for(monomial i = ipoa; i < ipoa+illa; i++) { const unsigned int ic1 = DACECom.ie1[i->ii]; const unsigned int ic2 = DACECom.ie2[i->ii]; const unsigned int ipow = (ic1/idiv)%ibase; if(ipow == 0 \|\| DACECom.ieo[i->ii] > DACECom_t.nocut+1) continue; if(ic >= icmax) { daceSetError(__func__, DACE_ERROR, 21); break; } ic->ii = DACECom.ia1[ic1-idiv] + DACECom.ia2[ic2]; ic->cc = i->ccipow; ic++; } } daceSetLength(inc, ic-ipoc); } /! Integral of DA object with respect to a given independent variable. \param[in] idif Number of the independent variable with respect to which the integral is taken \param[in] ina Pointer to the DA object to operate on \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. / void daceIntegrate(const unsigned int iint, const DACEDA ina, DACEDA inc) { monomial ipoa; unsigned int ilma, illa; monomial ipoc; unsigned int ilmc, illc; daceVariableInformation(ina, &ipoa, &ilma, &illa); daceVariableInformation(inc, &ipoc, &ilmc, &illc); if(iint < 1 \|\| iint > DACECom.nvmax) { daceSetError(__func__, DACE_ERROR, 24); daceCreateConstant(inc, 0.0); return; } const unsigned int ibase = DACECom.nomax+1; unsigned int j = iint-1; if(iint > DACECom.nv1) j = j-DACECom.nv1; const unsigned int idiv = npown(ibase, j); monomial ic = ipoc; monomial const icmax = ipoc+ilmc; if(iint > DACECom.nv1) { for(monomial i = ipoa; i < ipoa+illa; i++) { if(DACECom.ieo[i->ii] >= DACECom_t.nocut) continue; const unsigned int ic1 = DACECom.ie1[i->ii]; const unsigned int ic2 = DACECom.ie2[i->ii]; const unsigned int ipow = (ic2/idiv)%ibase; const double ccc = i->cc/(ipow+1); if(fabs(ccc) < DACECom_t.eps) continue; if(ic >= icmax) { daceSetError(__func__, DACE_ERROR, 21); break; } ic->ii = DACECom.ia1[ic1] + DACECom.ia2[ic2+idiv]; ic->cc = ccc; ic = ic+1; } } else { for(monomial i = ipoa; i < ipoa+illa; i++) { if(DACECom.ieo[i->ii] >= DACECom_t.nocut) continue; const unsigned int ic1 = DACECom.ie1[i->ii]; const unsigned int ic2 = DACECom.ie2[i->ii]; const unsigned int ipow = (ic1/idiv)%ibase; const double ccc = i->cc/(ipow+1); if(fabs(ccc) < DACECom_t.eps) continue; if(ic >= icmax) { daceSetError(__func__, DACE_ERROR, 21); break; } ic->ii = DACECom.ia1[ic1+idiv] + DACECom.ia2[ic2]; ic->cc = ccc; ic = ic+1; } } daceSetLength(inc, ic-ipoc); } /******************************************************************************* * DACE intrinsic function routines ********************************************************************************/ /! Truncate the constant part of a DA object to an integer. \param[in] ina Pointer to the DA object to operate on \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. / void daceTruncate(const DACEDA ina, DACEDA inc) { daceCopy(ina, inc); daceSetCoefficient0(inc, 0, rint(daceGetConstant(inc))); } /! Round the constant part of a DA object to an integer. \param[in] ina Pointer to the DA object to operate on \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. / void daceRound(const DACEDA ina, DACEDA inc) { daceCopy(ina, inc); daceSetCoefficient0(inc, 0, round(daceGetConstant(inc))); } /! Modulo the constant part of a DA object by p. \param[in] ina Pointer to the DA object to operate on \param[in] p Value with respect to which to compute the modulo \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. / void daceModulo(const DACEDA ina, const double p, DACEDA inc) { daceCopy(ina, inc); daceSetCoefficient0(inc, 0, fmod(daceGetConstant(inc),p)); } /! Raise a DA object to the p-th power. \param[in] ina Pointer to the DA object to operate on \param[in] p Power to which to raise the DA object \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. / void dacePowerDouble(const DACEDA ina, const double p, DACEDA inc) { // check simple cases if(p == 0.0) { daceCreateConstant(inc, 1.0); return; } else if(p == (int)p) { dacePower(ina, (int)p, inc); return; } const double a0 = daceGetConstant(ina); if(a0 <= 0.0) { daceSetError(__func__, DACE_ERROR, 43); daceCreateConstant(inc, 0.0); return; } #if DACE_MEMORY_MODEL == DACE_MEMORY_STATIC double xf[DACE_STATIC_NOMAX+1]; #else double xf = (double) dacecalloc(DACECom_t.nocut+1, sizeof(double)); #endif xf[0] = pow(a0, p); for(unsigned int i = 1; i < DACECom_t.nocut+1; i++) xf[i] = xf[i-1]/i(p-(i-1)); daceDivideDouble(ina, a0, inc); // more accurate than including a0 in series (uses non-linear part in EvaluateSeries) daceEvaluateSeries(inc, xf, inc); #if DACE_MEMORY_MODEL != DACE_MEMORY_STATIC dacefree(xf); #endif } /! Raise a DA object to the p-th integer power. \param[in] ina Pointer to the DA object to operate on \param[in] p Power to which to raise the DA object \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. / void dacePower(const DACEDA ina, const int np, DACEDA inc) { DACEDA itemp; // handle some common simple cases directly switch(np) { case 0: daceCreateConstant(inc, 1.0); return; case 1: daceCopy(ina, inc); return; case -1: daceMultiplicativeInverse(ina, inc); return; } // handle all other cases, again with common special cases hard coded switch(abs(np)) { case 2: daceSquare(ina, inc); break; case 3: daceAllocateDA(&itemp, 0); daceSquare(ina, &itemp); daceMultiply(ina, &itemp, inc); daceFreeDA(&itemp); break; case 4: daceAllocateDA(&itemp, 0); daceSquare(ina, &itemp); daceSquare(&itemp, inc); daceFreeDA(&itemp); break; default: daceAllocateDA(&itemp, 0); daceCopy(ina, &itemp); daceCreateConstant(inc, 1.0); unsigned int inp = abs(np); while(inp) { if(inp & 1u) daceMultiply(inc, &itemp, inc); inp >>= 1; if(inp) daceSquare(&itemp, &itemp); } daceFreeDA(&itemp); } if(np < 0) daceMultiplicativeInverse(inc, inc); } /! Take the np-th root of a DA object. \param[in] ina Pointer to the DA object to operate on \param[in] np Root to take of the DA object \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. / void daceRoot(const DACEDA ina, const int np, DACEDA inc) { if(np == 0) { daceSetError(__func__, DACE_ERROR, 44); daceCreateConstant(inc, 0.0); return; } const double a0 = daceGetConstant(ina); const unsigned int iodd = abs(np) & 1u; if((iodd == 0) && (a0 <= 0.0)) { daceSetError(__func__, DACE_ERROR, 45); daceCreateConstant(inc, 0.0); return; } else if((iodd == 1) && (a0 == 0.0)) { daceSetError(__func__, DACE_ERROR, 46); daceCreateConstant(inc, 0.0); return; } double cr = 1.0/np; #if DACE_MEMORY_MODEL == DACE_MEMORY_STATIC double xf[DACE_STATIC_NOMAX+1]; #else double xf = (double) dacecalloc(DACECom_t.nocut+1, sizeof(double)); #endif xf[0] = copysign(pow(fabs(a0), cr), a0); for(unsigned int i = 1; i < DACECom_t.nocut+1; i++) { xf[i] = xf[i-1]/icr; cr--; } daceDivideDouble(ina, a0, inc); // more accurate than including a0 in series (uses non-linear part in EvaluateSeries) daceEvaluateSeries(inc, xf, inc); #if DACE_MEMORY_MODEL != DACE_MEMORY_STATIC dacefree(xf); #endif } /! Compute the multiplicative inverse of a DA object. \param[in] ina Pointer to the DA object to operate on \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. / void daceMultiplicativeInverse(const DACEDA ina, DACEDA inc) { const double a0 = daceGetConstant(ina); if(a0 == 0.0) { daceSetError(__func__, DACE_ERROR, 41); daceCreateConstant(inc, 0.0); return; } if(DACECom_t.nocut < 5) { // lower orders: compute series directly daceMultiplicativeInverse0(ina, inc, a0); } else { // higher orders: use iteration const unsigned int nocut = DACECom_t.nocut; DACECom_t.nocut = 2; daceMultiplicativeInverse0(ina, inc, a0); DACEDA temp; daceAllocateDA(&temp, 0); for(unsigned int ord = 3; ord <= nocut; ord = 2) { DACECom_t.nocut = umin(nocut, 2ord-1); daceMultiply(ina, inc, &temp); daceDoubleSubtract(&temp, 2.0, &temp); daceMultiply(inc, &temp, inc); } daceFreeDA(&temp); } } /! Compute the multiplicative inverse of a DA object using series expansion. \param[in] ina Pointer to the DA object to operate on \param[out] inc Pointer to the DA object to store the result in \param[in] a0 Constant part of ina \note This routine is aliasing safe, i.e. inc can be the same as ina. / void daceMultiplicativeInverse0(const DACEDA ina, DACEDA inc, const double a0) { daceDivideDouble(ina, a0, inc); #if DACE_MEMORY_MODEL == DACE_MEMORY_STATIC double xf[DACE_STATIC_NOMAX+1]; #else double xf = (double) dacecalloc(DACECom_t.nocut+1, sizeof(double)); #endif xf[0] = 1.0/a0; for(unsigned int i = 1; i < DACECom_t.nocut+1; i++) xf[i] = -xf[i-1]; daceEvaluateSeries(inc, xf, inc); #if DACE_MEMORY_MODEL != DACE_MEMORY_STATIC dacefree(xf); #endif } /! Compute the square root of a DA object. \param[in] ina Pointer to the DA object to operate on \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. / void daceSquareRoot(const DACEDA ina, DACEDA inc) { daceRoot(ina, 2, inc); } /! Compute the inverse square root of a DA object. \param[in] ina Pointer to the DA object to operate on \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. / void daceInverseSquareRoot(const DACEDA ina, DACEDA inc) { daceRoot(ina, -2, inc); } /! Compute the cubic root of a DA object. \param[in] ina Pointer to the DA object to operate on \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. / void daceCubicRoot(const DACEDA ina, DACEDA inc) { daceRoot(ina, 3, inc); } /! Compute the inverse cubic root of a DA object. \param[in] ina Pointer to the DA object to operate on \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. / void daceInverseCubicRoot(const DACEDA ina, DACEDA inc) { daceRoot(ina, -3, inc); } /! Compute the hypothenuse of two DA objects. \param[in] ina Pointer to the first DA object to operate on \param[in] inb Pointer to the second DA object to operate on \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina or inb. / void daceHypotenuse(const DACEDA ina, const DACEDA inb, DACEDA inc) { DACEDA itemp1, itemp2; daceAllocateDA(&itemp1, 0); daceAllocateDA(&itemp2, 0); daceSquare(ina, &itemp1); daceSquare(inb, &itemp2); daceAdd(&itemp1, &itemp2, inc); daceRoot(inc, 2, inc); daceFreeDA(&itemp2); daceFreeDA(&itemp1); } /! Compute the exponential of a DA object. \param[in] ina Pointer to the DA object to operate on \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. / void daceExponential(const DACEDA ina, DACEDA inc) { #if DACE_MEMORY_MODEL == DACE_MEMORY_STATIC double xf[DACE_STATIC_NOMAX+1]; #else double* xf = (double) dacecalloc(DACECom_t.nocut+1, sizeof(double)); #endif xf[0] = exp(daceGetConstant(ina)); for(unsigned int i = 1; i < DACECom_t.nocut+1; i++) xf[i] = xf[i-1]/i; daceEvaluateSeries(ina, xf, inc); #if DACE_MEMORY_MODEL != DACE_MEMORY_STATIC dacefree(xf); #endif } /! Compute the natural logarithm root of a DA object. \param[in] ina Pointer to the DA object to operate on \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. / void daceLogarithm(const DACEDA ina, DACEDA inc) { const double a0 = daceGetConstant(ina); if(a0 <= 0) { daceSetError(__func__, DACE_ERROR, 47); daceCreateConstant(inc, 0.0); return; } #if DACE_MEMORY_MODEL == DACE_MEMORY_STATIC double xf[DACE_STATIC_NOMAX+1]; #else double xf = (double) dacecalloc(DACECom_t.nocut+1, sizeof(double)); #endif daceDivideDouble(ina, a0, inc); xf[0] = log(a0); xf[1] = 1.0; for(unsigned int i = 2; i < DACECom_t.nocut+1; i++) { xf[i] = -xf[i-1]/i(i-1); } daceEvaluateSeries(inc, xf, inc); #if DACE_MEMORY_MODEL != DACE_MEMORY_STATIC dacefree(xf); #endif } /! Compute the logarithm with respect to base b of a DA object. \param[in] ina Pointer to the DA object to operate on \param[in] b Base of the logarithm to use \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. / void daceLogarithmBase(const DACEDA ina, const double b, DACEDA inc) { if(b <= 0) { daceSetError(__func__, DACE_ERROR, 48); daceCreateConstant(inc, 0.0); return; } daceLogarithm(ina, inc); daceMultiplyDouble(inc, 1.0/log(b), inc); } /! Compute the decadic logarithm of a DA object. \param[in] ina Pointer to the DA object to operate on \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. / void daceLogarithm10(const DACEDA ina, DACEDA inc) { daceLogarithmBase(ina, 10.0, inc); } /! Compute the binary logarithm of a DA object. \param[in] ina Pointer to the DA object to operate on \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. / void daceLogarithm2(const DACEDA ina, DACEDA inc) { daceLogarithmBase(ina, 2.0, inc); } /! Compute the sine of a DA object. \param[in] ina Pointer to the DA object to operate on \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. / void daceSine(const DACEDA ina, DACEDA inc) { #if DACE_MEMORY_MODEL == DACE_MEMORY_STATIC double xf[DACE_STATIC_NOMAX+1]; #else double* xf = (double) dacecalloc(DACECom_t.nocut+1, sizeof(double)); #endif const double a0 = daceGetConstant(ina); xf[0] = sin(a0); xf[1] = cos(a0); for(unsigned int i = 2; i < DACECom_t.nocut+1; i++) { xf[i] = -xf[i-2]/(i(i-1)); } daceEvaluateSeries(ina, xf, inc); #if DACE_MEMORY_MODEL != DACE_MEMORY_STATIC dacefree(xf); #endif } /! Compute the cosine of a DA object. \param[in] ina Pointer to the DA object to operate on \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. / void daceCosine(const DACEDA ina, DACEDA inc) { #if DACE_MEMORY_MODEL == DACE_MEMORY_STATIC double xf[DACE_STATIC_NOMAX+1]; #else double* xf = (double) dacecalloc(DACECom_t.nocut+1, sizeof(double)); #endif const double a0 = daceGetConstant(ina); xf[0] = cos(a0); xf[1] = -sin(a0); for(unsigned int i = 2; i < DACECom_t.nocut+1; i++) { xf[i] = -xf[i-2]/(i(i-1)); } daceEvaluateSeries(ina, xf, inc); #if DACE_MEMORY_MODEL != DACE_MEMORY_STATIC dacefree(xf); #endif } /! Compute the tangent of a DA object. \param[in] ina Pointer to the DA object to operate on \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. / void daceTangent(const DACEDA ina, DACEDA inc) { DACEDA itemp; if(cos(daceGetConstant(ina)) == 0.0) { daceSetError(__func__, DACE_ERROR, 49); daceCreateConstant(inc, 0.0); return; } daceAllocateDA(&itemp, 0); daceSine(ina, &itemp); daceCosine(ina, inc); daceDivide(&itemp, inc, inc); daceFreeDA(&itemp); } /! Compute the arcsine of a DA object. \param[in] ina Pointer to the DA object to operate on \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. / void daceArcSine(const DACEDA ina, DACEDA inc) { DACEDA itemp; if(fabs(daceGetConstant(ina)) >= 1.0) { daceSetError(__func__, DACE_ERROR, 50); daceCreateConstant(inc, 0.0); return; } daceAllocateDA(&itemp, 0); daceSquare(ina, &itemp); daceDoubleSubtract(&itemp, 1.0, &itemp); daceSquareRoot(&itemp, &itemp); daceDivide(ina, &itemp, inc); daceArcTangent(inc, inc); daceFreeDA(&itemp); } /! Compute the arccosine of a DA object. \param[in] ina Pointer to the DA object to operate on \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. / void daceArcCosine(const DACEDA ina, DACEDA inc) { if(fabs(daceGetConstant(ina)) >= 1.0) { daceSetError(__func__, DACE_ERROR, 50); daceCreateConstant(inc, 0.0); return; } daceArcSine(ina, inc); daceDoubleSubtract(inc, M_PI_2, inc); } /! Compute the arctangent of a DA object. \param[in] ina Pointer to the DA object to operate on \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. / void daceArcTangent(const DACEDA ina, DACEDA inc) { DACEDA iarg; #if DACE_MEMORY_MODEL == DACE_MEMORY_STATIC double xf[DACE_STATIC_NOMAX+1] = {0}; #else double* xf = (double) dacecalloc(DACECom_t.nocut+1, sizeof(double)); #endif const double a0 = daceGetConstant(ina); daceAllocateDA(&iarg, 0); daceMultiplyDouble(ina, a0, &iarg); daceAddDouble(&iarg, 1.0, &iarg); daceSubtractDouble(ina, a0, inc); daceDivide(inc, &iarg, &iarg); double s = 1.0; xf[0] = atan(a0); for(unsigned int i = 1; i < DACECom_t.nocut+1; i+=2) { xf[i] = s/i; s = -s; } daceEvaluateSeries(&iarg, xf, inc); daceFreeDA(&iarg); #if DACE_MEMORY_MODEL != DACE_MEMORY_STATIC dacefree(xf); #endif } /! Arctangent of ina/inb with proper sign in [-pi, pi]. This function follows the C standard atan2(y,x) function syntax. \param[in] ina Pointer to the first DA object to operate on \param[in] ina Pointer to the second DA object to operate on \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. / void daceArcTangent2(const DACEDA ina, const DACEDA inb, DACEDA inc) { const double cx = daceGetConstant(inb); const double cy = daceGetConstant(ina); if(cx == 0.0 && cy == 0.0) { daceCreateConstant(inc, 0.0); } else { if(fabs(cy) > fabs(cx)) { daceDivide(inb, ina, inc); daceArcTangent(inc, inc); if(cy < 0.0) { daceDoubleSubtract(inc, -M_PI_2, inc); } else { daceDoubleSubtract(inc, M_PI_2, inc); } } else { daceDivide(ina, inb, inc); daceArcTangent(inc, inc); if(cx < 0.0) { if(cy > 0.0) { daceAddDouble(inc, M_PI, inc); } else { daceAddDouble(inc, -M_PI, inc); } } } } } /! Compute the hyperbolic sine of a DA object. \param[in] ina Pointer to the DA object to operate on \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. / void daceHyperbolicSine(const DACEDA ina, DACEDA inc) { #if DACE_MEMORY_MODEL == DACE_MEMORY_STATIC double xf[DACE_STATIC_NOMAX+1]; #else double* xf = (double) dacecalloc(DACECom_t.nocut+1, sizeof(double)); #endif const double a0 = daceGetConstant(ina); xf[0] = sinh(a0); xf[1] = cosh(a0); for(unsigned int i = 2; i < DACECom_t.nocut+1; i++) { xf[i] = xf[i-2]/(i(i-1)); } daceEvaluateSeries(ina, xf, inc); #if DACE_MEMORY_MODEL != DACE_MEMORY_STATIC dacefree(xf); #endif } /! Compute the hyperbolic cosine of a DA object. \param[in] ina Pointer to the DA object to operate on \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. / void daceHyperbolicCosine(const DACEDA ina, DACEDA inc) { #if DACE_MEMORY_MODEL == DACE_MEMORY_STATIC double xf[DACE_STATIC_NOMAX+1]; #else double* xf = (double) dacecalloc(DACECom_t.nocut+1, sizeof(double)); #endif const double a0 = daceGetConstant(ina); xf[0] = cosh(a0); xf[1] = sinh(a0); for(unsigned int i = 2; i < DACECom_t.nocut+1; i++) { xf[i] = xf[i-2]/(i(i-1)); } daceEvaluateSeries(ina, xf, inc); #if DACE_MEMORY_MODEL != DACE_MEMORY_STATIC dacefree(xf); #endif } /! Compute the hyperbolic tangent of a DA object. \param[in] ina Pointer to the DA object to operate on \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. / void daceHyperbolicTangent(const DACEDA ina, DACEDA inc) { DACEDA itemp; daceAllocateDA(&itemp, 0); daceHyperbolicSine(ina, &itemp); daceHyperbolicCosine(ina, inc); daceDivide(&itemp, inc, inc); daceFreeDA(&itemp); } /! Compute the hyperbolic arcsince of a DA object. \param[in] ina Pointer to the DA object to operate on \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. / void daceHyperbolicArcSine(const DACEDA ina, DACEDA inc) { DACEDA itemp; daceAllocateDA(&itemp, 0); daceSquare(ina, inc); daceAddDouble(inc, 1.0, &itemp); daceSquareRoot(&itemp, inc); daceAdd(ina, inc, &itemp); daceLogarithm(&itemp, inc); daceFreeDA(&itemp); } /! Compute the hyperbolic arccosine of a DA object. \param[in] ina Pointer to the DA object to operate on \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. / void daceHyperbolicArcCosine(const DACEDA ina, DACEDA inc) { DACEDA itemp; if(daceGetConstant(ina) < 1.0) { daceSetError(__func__, DACE_ERROR, 50); daceCreateConstant(inc, 0.0); return; } daceAllocateDA(&itemp, 0); daceSquare(ina, inc); daceSubtractDouble(inc, 1.0, &itemp); daceSquareRoot(&itemp, inc); daceAdd(ina, inc, &itemp); daceLogarithm(&itemp, inc); daceFreeDA(&itemp); } /! Compute the hyperbolic arctangent of a DA object. \param[in] ina Pointer to the DA object to operate on \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. / void daceHyperbolicArcTangent(const DACEDA ina, DACEDA inc) { DACEDA itemp; if(fabs(daceGetConstant(ina)) >= 1.0) { daceSetError(__func__, DACE_ERROR, 50); daceCreateConstant(inc, 0.0); return; } daceAllocateDA(&itemp, 0); daceAddDouble(ina, 1.0, &itemp); daceDoubleSubtract(ina, 1.0, inc); daceDivide(&itemp, inc, inc); daceLogarithm(inc, &itemp); daceMultiplyDouble(&itemp, 0.5, inc); daceFreeDA(&itemp); } /! Compute the error function of a DA object. \param[in] ina Pointer to the DA object to operate on \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. / void daceErrorFunction(const DACEDA ina, DACEDA inc) { #if DACE_MEMORY_MODEL == DACE_MEMORY_STATIC double xf[DACE_STATIC_NOMAX+1]; #else double* xf = (double) dacecalloc(DACECom_t.nocut+1, sizeof(double)); #endif const double a0 = daceGetConstant(ina); double factor = 2.0exp(-a0a0)/sqrt(M_PI); xf[0] = erf(a0); xf[1] = factor; double Hi2 = 1.0; // Hermite polynomial H_{i-2} = H_0 double Hi1 = 2.0a0; // Hermite polynomial H_{i-1} = H_1 for(unsigned int i = 2; i < DACECom_t.nocut+1; i++) { factor /= -((double)i); xf[i] = factorHi1; const double temp = 2.0a0Hi1 - 2.0(i-1)Hi2; // recursion relation: H_i = 2xH_{i-1} - 2(i-1)H_{i-2} Hi2 = Hi1; Hi1 = temp; } daceEvaluateSeries(ina, xf, inc); #if DACE_MEMORY_MODEL != DACE_MEMORY_STATIC dacefree(xf); #endif } /! Compute the complementary error function of a DA object. \param[in] ina Pointer to the DA object to operate on \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. / void daceComplementaryErrorFunction(const DACEDA ina, DACEDA inc) { #if DACE_MEMORY_MODEL == DACE_MEMORY_STATIC double xf[DACE_STATIC_NOMAX+1]; #else double xf = (double) dacecalloc(DACECom_t.nocut+1, sizeof(double)); #endif const double a0 = daceGetConstant(ina); double factor = -2.0exp(-a0a0)/sqrt(M_PI); xf[0] = erfc(a0); xf[1] = factor; double Hi2 = 1.0; // Hermite polynomial H_{i-2} = H_0 double Hi1 = 2.0a0; // Hermite polynomial H_{i-1} = H_1 for(unsigned int i = 2; i < DACECom_t.nocut+1; i++) { factor /= -((double)i); xf[i] = factorHi1; const double temp = 2.0a0Hi1 - 2.0(i-1)Hi2; // recursion relation: H_i = 2xH_{i-1} - 2(i-1)H_{i-2} Hi2 = Hi1; Hi1 = temp; } daceEvaluateSeries(ina, xf, inc); #if DACE_MEMORY_MODEL != DACE_MEMORY_STATIC dacefree(xf); #endif } /// @cond // Wrappers for contributed netlib Bessel functions (not for public use) /! Compute value of Bessel functions J_n, Y_n for n in [n0, n1]. \param[in] x function argument (non-negative) \param[in] n0 Lowest order of the Bessel functions to calculate (n0 <= n1) \param[in] n1 Highest order of the Bessel functions to calculate (n0 <= n1) \param[in] type Type of function to evaluate: -1: Bessel J function 1: Bessel Y function \param[out] bz Array of size n1-n0+1 containing the values of B_{n0}, B_{n0+1}, ..., B_{n1} \return Returns 0 if all values are calculated accurately, -1 if x is too large to calculate the result or another error occured, or +1 if some of the results are of reduced accuracy. / int BesselWrapper(const double x, const int n0, const int n1, const int type, double bz) { long int nb = (abs(n0) > abs(n1) ? abs(n0) : abs(n1))+1, ncalc; double xx = x, alpha = 0.0; #if DACE_MEMORY_MODEL == DACE_MEMORY_STATIC #define DACE_STATIC_MAX_BESSEL_ORDER 100 if( DACE_STATIC_MAX_BESSEL_ORDER < nb ) return -1; double b[DACE_STATIC_MAX_BESSEL_ORDER]; #else double* b = (double) dacecalloc(nb, sizeof(double)); #endif if(type < 0) rjbesl_(&xx, &alpha, &nb, b, &ncalc); else rybesl_(&xx, &alpha, &nb, b, &ncalc); // discombobulate results if(ncalc >= 0) { ncalc = (ncalc == nb ? 0 : 1); double s = (n0%2 == 0 ? 1.0 : -1.0); for(int i = n0; i <= n1; i++) { if(i >= 0) (bz++) = b[i]; else { (bz++) = sb[-i]; // for integer orders considered here, (-1)^n J_n = J_{-n}, and (-1)^n Y_n = Y_{-n} s = -1.0; } } } #if DACE_MEMORY_MODEL != DACE_MEMORY_STATIC dacefree(b); #endif return ncalc < 0 ? -1 : ncalc; } /! Compute value of modified Bessel functions I_n, K_n for n in [n0, n1]. \param[in] x function argument (non-negative) \param[in] n0 Lowest order of the Bessel functions to calculate (n0 <= n1) \param[in] n1 Highest order of the Bessel functions to calculate (n0 <= n1) \param[in] type Type of function to evaluate: -2: Bessel I function, scaled (i.e. exp(-x)I_n(x)) -1: Bessel I function 1: Bessel K function 2: Bessel K function, scaled (i.e. exp(x)K_n(x)) \param[out] bz Array of size n1-n0+1 containing the values of B_{n0}, B_{n0+1}, ..., B_{n1} \return Returns 0 if all values are calculated accurately, -1 if x is too large to calculate the result or another error occured, or +1 if some of the results are of reduced accuracy. / int ModifiedBesselWrapper(const double x, const int n0, const int n1, const int type, double bz) { long int nb = (abs(n0) > abs(n1) ? abs(n0) : abs(n1))+1, ize = abs(type), ncalc; double xx = x, alpha = 0.0; #if DACE_MEMORY_MODEL == DACE_MEMORY_STATIC #define DACE_STATIC_MAX_BESSEL_ORDER 100 if( DACE_STATIC_MAX_BESSEL_ORDER < nb ) return -1; double b[DACE_STATIC_MAX_BESSEL_ORDER]; #else double* b = (double) dacecalloc(nb, sizeof(double)); #endif if(type < 0) ribesl_(&xx, &alpha, &nb, &ize, b, &ncalc); else rkbesl_(&xx, &alpha, &nb, &ize, b, &ncalc); // discombobulate results if(ncalc >= 0) { ncalc = (ncalc == nb ? 0 : 1); for(int i = n0; i <= n1; i++) (bz++) = b[abs(i)]; // for integer orders considered here, I_n = I_{-n}, and for all orders K_n = K_{-n} } #if DACE_MEMORY_MODEL != DACE_MEMORY_STATIC dacefree(b); #endif return ncalc < 0 ? -1 : ncalc; } /// @endcond /! Compute the modified Bessel function I_n of a DA object. \param[in] ina Pointer to the DA object to operate on (constant part >= 0) \param[in] n Order of the Bessel function \param[in] scaled If true, the scaled Bessel function is computed (i.e. exp(-x)I_n(x)) \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. / void daceBesselIFunction(const DACEDA ina, const int n, const bool scaled, DACEDA inc) { const double a0 = daceGetConstant(ina); if(a0 <= 0.0) { daceSetError(__func__, DACE_ERROR, 50); daceCreateConstant(inc, 0.0); return; } #if DACE_MEMORY_MODEL == DACE_MEMORY_STATIC double bz[2DACE_STATIC_NOMAX+1]; #else double* bz = (double) dacecalloc(2DACECom_t.nocut+1, sizeof(double)); #endif const int res = ModifiedBesselWrapper(a0, n-DACECom_t.nocut, n+DACECom_t.nocut, scaled ? -2 : -1, bz); if(res >= 0) { if(scaled) daceEvaluateScaledModifiedBesselFunction(ina, bz, 1.0, inc); else daceEvaluateBesselFunction(ina, bz, 1.0, 1.0, inc); } else { daceSetError(__func__, DACE_ERROR, 50); daceCreateConstant(inc, 0.0); } #if DACE_MEMORY_MODEL != DACE_MEMORY_STATIC dacefree(bz); #endif } /! Compute the modified Bessel function K_n of a DA object. \param[in] ina Pointer to the DA object to operate on (constant part >= 0) \param[in] n Order of the Bessel function \param[in] scaled If true, the scaled Bessel function is computed (i.e. exp(x)K_n(x)) \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. / void daceBesselKFunction(const DACEDA ina, const int n, const bool scaled, DACEDA inc) { const double a0 = daceGetConstant(ina); if(a0 <= 0.0) { daceSetError(__func__, DACE_ERROR, 50); daceCreateConstant(inc, 0.0); return; } #if DACE_MEMORY_MODEL == DACE_MEMORY_STATIC double bz[2DACE_STATIC_NOMAX+1]; #else double* bz = (double) dacecalloc(2DACECom_t.nocut+1, sizeof(double)); #endif const int res = ModifiedBesselWrapper(a0, n-DACECom_t.nocut, n+DACECom_t.nocut, scaled ? 2 : 1, bz); if(res >= 0) { if(scaled) daceEvaluateScaledModifiedBesselFunction(ina, bz, -1.0, inc); else daceEvaluateBesselFunction(ina, bz, 1.0, -1.0, inc); } else { daceSetError(__func__, DACE_ERROR, 50); daceCreateConstant(inc, 0.0); } #if DACE_MEMORY_MODEL != DACE_MEMORY_STATIC dacefree(bz); #endif } /! Compute the Bessel function J_n of a DA object. \param[in] ina Pointer to the DA object to operate on (constant part >= 0) \param[in] n Order of the Bessel function \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. / void daceBesselJFunction(const DACEDA ina, const int n, DACEDA inc) { const double a0 = daceGetConstant(ina); if(a0 <= 0.0) { daceSetError(__func__, DACE_ERROR, 50); daceCreateConstant(inc, 0.0); return; } #if DACE_MEMORY_MODEL == DACE_MEMORY_STATIC double bz[2DACE_STATIC_NOMAX+1]; #else double bz = (double) dacecalloc(2DACECom_t.nocut+1, sizeof(double)); #endif const int res = BesselWrapper(a0, n-DACECom_t.nocut, n+DACECom_t.nocut, -1, bz); if(res >= 0) daceEvaluateBesselFunction(ina, bz, -1.0, 1.0, inc); else { daceSetError(__func__, DACE_ERROR, 50); daceCreateConstant(inc, 0.0); } #if DACE_MEMORY_MODEL != DACE_MEMORY_STATIC dacefree(bz); #endif } /! Compute the Bessel function Y_n of a DA object. \param[in] ina Pointer to the DA object to operate on (constant part >= 0) \param[in] n Order of the Bessel function \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. / void daceBesselYFunction(const DACEDA ina, const int n, DACEDA inc) { const double a0 = daceGetConstant(ina); if(a0 <= 0.0) { daceSetError(__func__, DACE_ERROR, 50); daceCreateConstant(inc, 0.0); return; } #if DACE_MEMORY_MODEL == DACE_MEMORY_STATIC double bz[2DACE_STATIC_NOMAX+1]; #else double bz = (double) dacecalloc(2DACECom_t.nocut+1, sizeof(double)); #endif const int res = BesselWrapper(a0, n-DACECom_t.nocut, n+DACECom_t.nocut, 1, bz); if(res >= 0) daceEvaluateBesselFunction(ina, bz, -1.0, 1.0, inc); else { daceSetError(__func__, DACE_ERROR, 50); daceCreateConstant(inc, 0.0); } #if DACE_MEMORY_MODEL != DACE_MEMORY_STATIC dacefree(bz); #endif } /! Evaluate a Bessel function with coefficients bz with the non-constant part of ina. \param[in] ina Pointer to the DA object to operate on \param[in] bz C array of 2nocut+1 elements containing Bessel functions of orders n-nocut, ..., n+nocut \param[in] type Either -1.0 for normal Bessel functions, or +1.0 for modified Bessel functions. \param[in] ktype Either -1.0 for modified Bessel K function, or +1.0 for all other Bessel functions. \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. / void daceEvaluateBesselFunction(const DACEDA ina, const double bz[], const double type, const double ktype, DACEDA inc) { #if DACE_MEMORY_MODEL == DACE_MEMORY_STATIC double xf[DACE_STATIC_NOMAX+1]; double binomial[DACE_STATIC_NOMAX+1]; #else double xf = (double) dacecalloc(DACECom_t.nocut+1, sizeof(double)); double binomial = (double) dacecalloc(DACECom_t.nocut+1, sizeof(double)); #endif xf[0] = bz[DACECom_t.nocut]; binomial[0] = 1.0; double factor = 1.0; for(unsigned int i = 1; i < DACECom_t.nocut+1; i++) { factor = ktype0.5/i; // calculate binomial coefficients i choose j based on previously calculated i-1 choose j. binomial[i] = 1.0; for(unsigned int j = i-1; j > 0; j--) binomial[j] += binomial[j-1]; // Calculate n-th derivative of Bessel function C, see http://dlmf.nist.gov/10.6 // bz contains values of C_{n-o} to C_{n+o} of constant part of ina double sign = 1.0, c = 0.0; xf[i] = 0.0; for(unsigned int j = 0; j <= i; j++) { // use Kahan summation, since signs oscillate and magnitudes can also vary greatly const double y = binomial[j]signbz[DACECom_t.nocut-i+2j] - c; const double t = xf[i] + y; c = (t - xf[i]) - y; xf[i] = t; // in infinite precision the above is equivalent to: // xf[i] += binomial[j]signbz[DACECom_t.nocut-i+2j]; sign = type; } xf[i] = factor; } daceEvaluateSeries(ina, xf, inc); #if DACE_MEMORY_MODEL != DACE_MEMORY_STATIC dacefree(binomial); dacefree(xf); #endif } /! Evaluate a scaled modified Bessel function with coefficients bz with the non-constant part of ina. \param[in] ina Pointer to the DA object to operate on \param[in] bz C array of 2nocut+1 elements containing modified Bessel functions of orders n-nocut, ..., n+nocut \param[in] ktype Either -1.0 for scaled Bessel K function, or +1.0 for scaled Bessel I function \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. / void daceEvaluateScaledModifiedBesselFunction(const DACEDA ina, const double bz[], const double ktype, DACEDA inc) { #if DACE_MEMORY_MODEL == DACE_MEMORY_STATIC double xf[DACE_STATIC_NOMAX+1]; double binomial[2DACE_STATIC_NOMAX+1]; #else double xf = (double) dacecalloc(DACECom_t.nocut+1, sizeof(double)); double binomial = (double) dacecalloc(2DACECom_t.nocut+1, sizeof(double)); #endif xf[0] = bz[DACECom_t.nocut]; binomial[0] = 1.0; double factor = 1.0; for(unsigned int i = 1; i < DACECom_t.nocut+1; i++) { factor = ktype0.5/i; // calculate binomial coefficients 2i-1 choose j based on previously calculated 2i-2 choose j. binomial[2i-1] = 1.0; for(unsigned int j = 2i-2; j > 0; j--) binomial[j] += binomial[j-1]; // calculate binomial coefficients 2i choose j based on previously calculated 2i-1 choose j. binomial[2i] = 1.0; for(unsigned int j = 2i-1; j > 0; j--) binomial[j] += binomial[j-1]; // Calculate n-th derivative of Bessel function C // bz contains values of C_{n-o} to C_{n+o} of constant part of ina double sign = 1.0, c = 0.0; xf[i] = 0.0; for(unsigned int j = 0; j <= 2i; j++) { // use Kahan summation, since signs oscillate and magnitudes can also vary greatly const double y = binomial[j]signbz[DACECom_t.nocut-i+j] - c; const double t = xf[i] + y; c = (t - xf[i]) - y; xf[i] = t; // in infinite precision the above is equivalent to: // xf[i] += binomial[j]signbz[DACECom_t.nocut-i+j]; sign = -1.0; } xf[i] = factor; } daceEvaluateSeries(ina, xf, inc); #if DACE_MEMORY_MODEL != DACE_MEMORY_STATIC dacefree(binomial); dacefree(xf); #endif } /! Compute the partial Logarithmic Gamma function of a DA object (without constant part). \param[in] ina Pointer to the DA object to operate on (constant part != 0, -1, -2, ...) \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. \note No argument checking is performed to ensure values are within allowable range. / void daceLogGammaFunction0(const DACEDA ina, const double a0, DACEDA inc) { #if DACE_MEMORY_MODEL == DACE_MEMORY_STATIC double xf[DACE_STATIC_NOMAX+1]; #else double xf = (double) dacecalloc(DACECom_t.nocut+1, sizeof(double)); #endif xf[0] = 0.0; xf[1] = psi_(&a0); double s = 1.0; for(unsigned int i = 2; i < DACECom_t.nocut+1; i++) { xf[i] = (s/i)zeta_(i, a0, NULL); s = -1.0; } daceEvaluateSeries(ina, xf, inc); #if DACE_MEMORY_MODEL != DACE_MEMORY_STATIC dacefree(xf); #endif } /! Compute the Logarithmic Gamma function of a DA object. \param[in] ina Pointer to the DA object to operate on (constant part != 0, -1, -2, ...) \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. / void daceLogGammaFunction(const DACEDA ina, DACEDA inc) { const double a0 = daceGetConstant(ina); if(a0 <= 0.0 && trunc(a0) == a0) { daceSetError(__func__, DACE_ERROR, 50); daceCreateConstant(inc, 0.0); return; } daceLogGammaFunction0(ina, a0, inc); daceSetCoefficient0(inc, 0, log(dgamma_(&a0))); } /! Compute the Gamma function of a DA object. \param[in] ina Pointer to the DA object to operate on (constant part != 0, -1, -2, ...) \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. / void daceGammaFunction(const DACEDA ina, DACEDA inc) { const double a0 = daceGetConstant(ina); if(a0 <= 0.0 && trunc(a0) == a0) { daceSetError(__func__, DACE_ERROR, 50); daceCreateConstant(inc, 0.0); return; } daceLogGammaFunction0(ina, a0, inc); daceExponential(inc, inc); daceMultiplyDouble(inc, dgamma_(&a0), inc); } /! Compute the n-th Psi function (i.e. the n+1 derivative of the logarithmic gamma function) of a DA object. \param[in] ina Pointer to the DA object to operate on (constant part != 0, -1, -2, ...) \param[in] n Order of the Psi function (n >= 0) \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. / void dacePsiFunction(const DACEDA ina, const unsigned int n, DACEDA inc) { const double a0 = daceGetConstant(ina); if(a0 <= 0.0 && trunc(a0) == a0) { daceSetError(__func__, DACE_ERROR, 50); daceCreateConstant(inc, 0.0); return; } #if DACE_MEMORY_MODEL == DACE_MEMORY_STATIC double xf[DACE_STATIC_NOMAX+1]; #else double xf = (double) dacecalloc(DACECom_t.nocut+1, sizeof(double)); #endif if(n == 0) { xf[0] = psi_(&a0); double s = 1.0; for(unsigned int i = 1; i < DACECom_t.nocut+1; i++) { xf[i] = szeta_(i+1, a0, NULL); s = -1.0; } } else { double fac = (n%2 ? 1.0 : -1.0); for(unsigned int i = 2; i <= n; i++) fac = i; for(unsigned int i = 0; i < DACECom_t.nocut+1; i++) { xf[i] = faczeta_(n+i+1, a0, NULL); fac = -(fac/(i+1))(n+i+1); } } daceEvaluateSeries(ina, xf, inc); #if DACE_MEMORY_MODEL != DACE_MEMORY_STATIC dacefree(xf); #endif } /! Evaluate a polynomial with coefficients xf with the non-constant part of ina. \param[in] ina Pointer to the DA object to operate on \param[in] xf C array of nocut+1 elements containing the coefficients of the polynomial \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. / void daceEvaluateSeries(const DACEDA ina, const double xf[], DACEDA inc) { DACEDA inon; const unsigned int nocut = DACECom_t.nocut; daceAllocateDA(&inon, 0); daceCopy(ina, &inon); daceSetCoefficient0(&inon, 0, 0.0); DACECom_t.nocut = 1; daceMultiplyDouble(&inon, xf[nocut], inc); daceAddDouble(inc, xf[nocut-1], inc); // evaluate series for(int i = nocut-2; i >= 0; i--) { DACECom_t.nocut = nocut-i; daceMultiply(&inon, inc, inc); daceAddDouble(inc, xf[i], inc); } DACECom_t.nocut = nocut; daceFreeDA(&inon); } /! Compute the weighted sum of two DA objects. \param[in] ina Pointer to the first DA object to operate on \param[in] afac Weighting factor to multiply ina by \param[in] inb Pointer to the second DA object to operate on \param[in] bfac Weighting factor to multiply inb by \param[out] inc Pointer to the DA object to store the result in \note This routine is NOT aliasing safe! So inc MUST BE DIFFERENT from ina and inb. / void daceWeightedSum(const DACEDA ina, const double afac, const DACEDA inb, const double bfac, DACEDA inc) { monomial ipoa; unsigned int ilma, illa; monomial ipob; unsigned int ilmb, illb; monomial ipoc; unsigned int ilmc, illc; daceVariableInformation(ina, &ipoa, &ilma, &illa); daceVariableInformation(inb, &ipob, &ilmb, &illb); daceVariableInformation(inc, &ipoc, &ilmc, &illc); monomial ia = ipoa, ib = ipob, ic = ipoc; monomial const iamax = ipoa+illa, const ibmax = ipob+illb, const icmax = ipoc+ilmc; if(illa > 0 && illb > 0) { // both polynomials have coefficients, merge until one runs out unsigned int ja = ia->ii; unsigned int jb = ib->ii; while(true) { if(ja == jb) { // add the two terms if(DACECom.ieo[ja] <= DACECom_t.nocut) { const double ccc = ia->ccafac + ib->ccbfac; if(fabs(ccc) >= DACECom_t.eps) { if(ic >= icmax) { daceSetError(__func__, DACE_ERROR, 21); daceSetLength(inc, ilmc); return; } ic->cc = ccc; ic->ii = ia->ii; ic++; } } ia++; ib++; if(ia >= iamax \|\| ib >= ibmax) break; ja = ia->ii; jb = ib->ii; } else if(ja < jb) { // store term a if(DACECom.ieo[ja] <= DACECom_t.nocut) { const double ccc = ia->ccafac; if(fabs(ccc) >= DACECom_t.eps) { if(ic >= icmax) { daceSetError(__func__, DACE_ERROR, 21); daceSetLength(inc, ilmc); return; } ic->cc = ccc; ic->ii = ia->ii; ic++; } } ia++; if(ia >= iamax) break; ja = ia->ii; } else { // store term b if(DACECom.ieo[jb] <= DACECom_t.nocut) { const double ccc = ib->ccbfac; if(fabs(ccc) >= DACECom_t.eps) { if(ic >= icmax) { daceSetError(__func__, DACE_ERROR, 21); daceSetLength(inc, ilmc); return; } ic->cc = ccc; ic->ii = ib->ii; ic++; } } ib++; if(ib >= ibmax) break; jb = ib->ii; } } } // copy any remaining terms from either ina or inb monomial ismin, ismax; double fac; if(ia < iamax) { ismin = ia; ismax = iamax; fac = afac; } else { ismin = ib; ismax = ibmax; fac = bfac; } for(monomial is = ismin; is < ismax; is++) { if(DACECom.ieo[is->ii] <= DACECom_t.nocut) { const double ccc = is->ccfac; if(fabs(ccc) >= DACECom_t.eps) { if(ic >= icmax) { daceSetError(__func__, DACE_ERROR, 21); daceSetLength(inc, ilmc); return; } ic->cc = ccc; ic->ii = is->ii; ic++; } } } daceSetLength(inc, ic-ipoc); } /** @}*/
yolov2.h	#ifndef YOLOV2_H #define YOLOV2_H #include <stdio.h> #include <stdlib.h> #include <iostream> #include <math.h> #include <fcntl.h> #include <string.h> #include <assert.h> #define STB_IMAGE_IMPLEMENTATION #include "stb_image.h" #define STB_IMAGE_WRITE_IMPLEMENTATION #include "stb_image_write.h" //#include "yolo_hls.h" typedef enum{ LOGISTIC, RELU, RELIE, LINEAR, RAMP, TANH, PLSE, LEAKY, ELU, LOGGY, STAIR, HARDTAN, LHTAN } ACTIVATION; typedef enum { CONVOLUTIONAL, DECONVOLUTIONAL, CONNECTED, MAXPOOL, SOFTMAX, DETECTION, DROPOUT, CROP, ROUTE, COST, NORMALIZATION, AVGPOOL, LOCAL, SHORTCUT, ACTIVE, RNN, GRU, LSTM, CRNN, BATCHNORM, NETWORK, XNOR, REGION, YOLO, REORG, UPSAMPLE, LOGXENT, L2NORM, BLANK } LAYER_TYPE; struct network; typedef struct network network; struct layer; typedef struct layer layer; struct layer{ LAYER_TYPE type; ACTIVATION activation; void (forward) (struct layer, struct network); int batch_normalize; int shortcut; int batch; int forced; int flipped; int inputs; int outputs; int nweights; int nbiases; int extra; int truths; int h,w,c; int out_h, out_w, out_c; int n; int max_boxes; int groups; int size; int side; int stride; int reverse; int flatten; int spatial; int pad; int sqrt; int flip; int index; int binary; int xnor; int steps; int hidden; int truth; float smooth; float dot; float angle; float jitter; float saturation; float exposure; float shift; float ratio; float learning_rate_scale; float clip; int softmax; int classes; int coords; int background; int rescore; int objectness; int joint; int noadjust; int reorg; int log; int tanh; int mask; int total; float alpha; float beta; float kappa; float coord_scale; float object_scale; float noobject_scale; float mask_scale; float class_scale; int bias_match; int random; float ignore_thresh; float truth_thresh; float thresh; float focus; int classfix; int absolute; int onlyforward; int stopbackward; // int dontload; int dontsave; // int dontloadscales; float temperature; float probability; float scale; char * cweights; int * indexes; int * input_layers; int * input_sizes; int * map; float * rand; float * cost; float * state; float * prev_state; float * forgot_state; float * forgot_delta; float * state_delta; float * combine_cpu; float * combine_delta_cpu; float * concat; float * concat_delta; float * binary_weights; float * biases; float * bias_updates; float * scales; float * scale_updates; float * weights; float * weight_updates; float * delta; float * output; float * loss; float * squared; float * norms; float * spatial_mean; float * mean; float * variance; float * mean_delta; float * variance_delta; float * rolling_mean; float * rolling_variance; float * x; float * x_norm; float * m; float * v; float * bias_m; float * bias_v; float * scale_m; float * scale_v; float z_cpu; float r_cpu; float h_cpu; float prev_state_cpu; float temp_cpu; float temp2_cpu; float temp3_cpu; float dh_cpu; float hh_cpu; float prev_cell_cpu; float cell_cpu; float f_cpu; float i_cpu; float g_cpu; float o_cpu; float c_cpu; float dc_cpu; float binary_input; struct layer input_layer; struct layer self_layer; struct layer output_layer; struct layer reset_layer; struct layer update_layer; struct layer state_layer; struct layer input_gate_layer; struct layer state_gate_layer; struct layer input_save_layer; struct layer state_save_layer; struct layer input_state_layer; struct layer state_state_layer; struct layer input_z_layer; struct layer state_z_layer; struct layer input_r_layer; struct layer state_r_layer; struct layer input_h_layer; struct layer state_h_layer; struct layer wz; struct layer uz; struct layer wr; struct layer ur; struct layer wh; struct layer uh; struct layer uo; struct layer wo; struct layer uf; struct layer wf; struct layer ui; struct layer wi; struct layer ug; struct layer wg; //tree softmax_tree; size_t workspace_size; }; void free_layer(layer l) { if(l.cweights) free(l.cweights); if(l.indexes) free(l.indexes); if(l.input_layers) free(l.input_layers); if(l.input_sizes) free(l.input_sizes); if(l.map) free(l.map); if(l.rand) free(l.rand); if(l.cost) free(l.cost); if(l.state) free(l.state); if(l.prev_state) free(l.prev_state); if(l.forgot_state) free(l.forgot_state); if(l.forgot_delta) free(l.forgot_delta); if(l.state_delta) free(l.state_delta); if(l.concat) free(l.concat); if(l.concat_delta) free(l.concat_delta); if(l.binary_weights) free(l.binary_weights); if(l.biases) free(l.biases); if(l.bias_updates) free(l.bias_updates); if(l.scales) free(l.scales); if(l.scale_updates) free(l.scale_updates); if(l.weights) free(l.weights); if(l.weight_updates) free(l.weight_updates); if(l.delta) free(l.delta); if(l.output) free(l.output); if(l.squared) free(l.squared); if(l.norms) free(l.norms); if(l.spatial_mean) free(l.spatial_mean); if(l.mean) free(l.mean); if(l.variance) free(l.variance); if(l.mean_delta) free(l.mean_delta); if(l.variance_delta) free(l.variance_delta); if(l.rolling_mean) free(l.rolling_mean); if(l.rolling_variance) free(l.rolling_variance); if(l.x) free(l.x); if(l.x_norm) free(l.x_norm); if(l.m) free(l.m); if(l.v) free(l.v); if(l.z_cpu) free(l.z_cpu); if(l.r_cpu) free(l.r_cpu); if(l.h_cpu) free(l.h_cpu); if(l.binary_input) free(l.binary_input); } //void free_layer(layer); typedef enum { CONSTANT, STEP, EXP, POLY, STEPS, SIG, RANDOM } learning_rate_policy; typedef struct network{ int n; int batch; size_t seen; int t; float epoch; int subdivisions; layer layers; float output; learning_rate_policy policy; float learning_rate; float momentum; float decay; float gamma; float scale; float power; int time_steps; int step; int max_batches; float scales; int steps; int num_steps; int burn_in; int adam; float B1; float B2; float eps; int inputs; int outputs; int truths; int notruth; int h, w, c; int max_crop; int min_crop; float max_ratio; float min_ratio; int center; float angle; float aspect; float exposure; float saturation; float hue; int random; int gpu_index; // tree hierarchy; float input; float truth; float delta; float workspace; int train; int index; float cost; float clip; } network; network make_network(int n); layer get_network_output_layer(network net); typedef struct { int w; int h; float scale; float rad; float dx; float dy; float aspect; } augment_args; typedef struct { int w; int h; int c; float data; } image; typedef struct{ float x, y, w, h; } box; typedef struct detection{ box bbox; int classes; float prob; float mask; float objectness; int sort_class; } detection; typedef struct matrix{ int rows, cols; float *vals; } matrix; typedef struct{ int w, h; matrix X; matrix y; int shallow; int num_boxes; box boxes; } data; typedef enum { CLASSIFICATION_DATA, DETECTION_DATA, CAPTCHA_DATA, REGION_DATA, IMAGE_DATA, COMPARE_DATA, WRITING_DATA, SWAG_DATA, TAG_DATA, OLD_CLASSIFICATION_DATA, STUDY_DATA, DET_DATA, SUPER_DATA, LETTERBOX_DATA, REGRESSION_DATA, SEGMENTATION_DATA, INSTANCE_DATA } data_type; typedef struct load_args{ int threads; char paths; char path; int n; int m; char labels; int h; int w; int out_w; int out_h; int nh; int nw; int num_boxes; int min, max, size; int classes; int background; int scale; int center; int coords; float jitter; float angle; float aspect; float saturation; float exposure; float hue; data d; image im; image resized; data_type type; // tree hierarchy; } load_args; typedef struct{ int id; float x,y,w,h; float left, right, top, bottom; } box_label; //network load_network(char cfg, char weights, int clear); //load_args get_base_args(network net); //void free_data(data d); typedef struct{ char key; char val; int used; } kvp; typedef struct node{ void val; struct node next; struct node prev; } node; typedef struct list{ int size; node front; node back; } list; void error(const char s) { perror(s); assert(0); exit(-1); } void malloc_error() { fprintf(stderr, "Malloc error\n"); exit(-1); } void file_error(char s) { fprintf(stderr, "Couldn't open file: %s\n", s); exit(0); } /////////////////list begin list make_list() { list l = (list )malloc(sizeof(list)); l->size = 0; l->front = 0; l->back = 0; return l; } void list_pop(list l){ if(!l->back) return 0; node b = l->back; void val = b->val; l->back = b->prev; if(l->back) l->back->next = 0; free(b); --l->size; return val; } void list_insert(list l, void val) { node new_node = (node )malloc(sizeof(node)); new_node->val = val; new_node->next = 0; if(!l->back){ l->front = new_node; new_node->prev = 0; }else{ l->back->next = new_node; new_node->prev = l->back; } l->back = new_node; ++l->size; } void free_node(node n) { node next; while(n) { next = n->next; free(n); n = next; } } void free_list(list l) { free_node(l->front); free(l); } void free_list_contents(list l) { node n = l->front; while(n){ free(n->val); n = n->next; } } void *list_to_array(list l) { void a = (void )calloc(l->size, sizeof(void)); int count = 0; node n = l->front; while(n){ a[count++] = n->val; n = n->next; } return a; } /////////////////list end /////////////////////utils begin void del_arg(int argc, char *argv, int index) { int i; for(i = index; i < argc-1; ++i) argv[i] = argv[i+1]; argv[i] = 0; } int find_arg(int argc, char argv[], char arg) { int i; for(i = 0; i < argc; ++i) { if(!argv[i]) continue; if(0==strcmp(argv[i], arg)) { del_arg(argc, argv, i); return 1; } } return 0; } int find_int_arg(int argc, char argv, char arg, int def) { int i; for(i = 0; i < argc-1; ++i){ if(!argv[i]) continue; if(0==strcmp(argv[i], arg)){ def = atoi(argv[i+1]); del_arg(argc, argv, i); del_arg(argc, argv, i); break; } } return def; } float find_float_arg(int argc, char *argv, char arg, float def) { int i; for(i = 0; i < argc-1; ++i){ if(!argv[i]) continue; if(0==strcmp(argv[i], arg)){ def = atof(argv[i+1]); del_arg(argc, argv, i); del_arg(argc, argv, i); break; } } return def; } char find_char_arg(int argc, char argv, char arg, char def) { int i; for(i = 0; i < argc-1; ++i){ if(!argv[i]) continue; if(0==strcmp(argv[i], arg)){ def = argv[i+1]; del_arg(argc, argv, i); del_arg(argc, argv, i); break; } } return def; } unsigned char read_file(char filename) { FILE fp = fopen(filename, "rb"); size_t size; fseek(fp, 0, SEEK_END); size = ftell(fp); fseek(fp, 0, SEEK_SET); unsigned char text = (unsigned char )calloc(size+1, sizeof(unsigned char)); fread(text, 1, size, fp); fclose(fp); return text; } list split_str(char s, char delim) { size_t i; size_t len = strlen(s); list l = make_list(); list_insert(l, s); for(i = 0; i < len; ++i){ if(s[i] == delim){ s[i] = '\0'; list_insert(l, &(s[i+1])); } } return l; } void strip(char s) { size_t i; size_t len = strlen(s); size_t offset = 0; for(i = 0; i < len; ++i){ char c = s[i]; if(c==' '\|\|c=='\t'\|\|c=='\n') ++offset; else s[i-offset] = c; } s[len-offset] = '\0'; } void strip_char(char s, char bad) { size_t i; size_t len = strlen(s); size_t offset = 0; for(i = 0; i < len; ++i){ char c = s[i]; if(c==bad) ++offset; else s[i-offset] = c; } s[len-offset] = '\0'; } void free_ptrs(void ptrs, int n) { int i; for(i = 0; i < n; ++i) free(ptrs[i]); free(ptrs); } char fgetl(FILE fp) { if(feof(fp)) return 0; size_t size = 512; char line = (char )malloc(sizesizeof(char)); if(!fgets(line, size, fp)){ free(line); return 0; } size_t curr = strlen(line); while((line[curr-1] != '\n') && !feof(fp)){ if(curr == size-1){ size = 2; line = (char )realloc(line, sizesizeof(char)); if(!line) { printf("%ld\n", size); malloc_error(); } } size_t readsize = size-curr; if(readsize > INT_MAX) readsize = INT_MAX-1; fgets(&line[curr], readsize, fp); curr = strlen(line); } if(line[curr-1] == '\n') line[curr-1] = '\0'; return line; } /////////////////////utils end ////////////////////option_list begin void option_insert(list l, char key, char val) { kvp p = (kvp )malloc(sizeof(kvp)); p->key = key; p->val = val; p->used = 0; list_insert(l, p); } int read_option(char s, list options) { size_t i; size_t len = strlen(s); char val = 0; for(i = 0; i < len; ++i){ if(s[i] == '='){ s[i] = '\0'; val = s+i+1; break; } } if(i == len-1) return 0; char key = s; option_insert(options, key, val); return 1; } void option_unused(list l) { node n = l->front; while(n){ kvp p = (kvp )n->val; if(!p->used){ fprintf(stderr, "Unused field: '%s = %s'\n", p->key, p->val); } n = n->next; } } char option_find(list l, char key) { node n = l->front; while(n){ kvp p = (kvp )n->val; if(strcmp(p->key, key) == 0){ p->used = 1; return p->val; } n = n->next; } return 0; } char option_find_str(list l, char key, char def) { char v = option_find(l, key); if(v) return v; if(def) fprintf(stderr, "%s: Using default '%s'\n", key, def); return def; } int option_find_int(list l, char key, int def) { char v = option_find(l, key); if(v) return atoi(v); fprintf(stderr, "%s: Using default '%d'\n", key, def); return def; } int option_find_int_quiet(list l, char key, int def) { char v = option_find(l, key); if(v) return atoi(v); return def; } float option_find_float_quiet(list l, char key, float def) { char v = option_find(l, key); if(v) return atof(v); return def; } float option_find_float(list l, char key, float def) { char v = option_find(l, key); if(v) return atof(v); fprintf(stderr, "%s: Using default '%lf'\n", key, def); return def; } list read_data_cfg(char filename) { FILE file = fopen(filename, "r"); if(file == 0) file_error(filename); char line; int nu = 0; list options = make_list(); while((line=fgetl(file)) != 0){ ++ nu; strip(line); switch(line[0]){ case '\0': case '#': case ';': free(line); break; default: if(!read_option(line, options)){ fprintf(stderr, "Config file error line %d, could parse: %s\n", nu, line); free(line); } break; } } fclose(file); return options; } ///////////////////option_list end image make_empty_image(int w, int h, int c) { image out; out.data = 0; out.h = h; out.w = w; out.c = c; return out; } list get_paths(char filename) { char path; FILE file = fopen(filename, "r"); if(!file) file_error(filename); list lines = make_list(); while((path=fgetl(file))){ list_insert(lines, path); } fclose(file); return lines; } char get_labels(char filename) { list plist = get_paths(filename); char labels = (char )list_to_array(plist); free_list(plist); return labels; } image make_image(int w, int h, int c) { image out = make_empty_image(w,h,c); out.data = (float )calloc(hwc, sizeof(float)); return out; } static float get_pixel(image m, int x, int y, int c) { assert(x < m.w && y < m.h && c < m.c); return m.data[cm.hm.w + ym.w + x]; } static void set_pixel(image m, int x, int y, int c, float val) { if (x < 0 \|\| y < 0 \|\| c < 0 \|\| x >= m.w \|\| y >= m.h \|\| c >= m.c) return; assert(x < m.w && y < m.h && c < m.c); m.data[cm.hm.w + ym.w + x] = val; } static void add_pixel(image m, int x, int y, int c, float val) { assert(x < m.w && y < m.h && c < m.c); m.data[cm.hm.w + ym.w + x] += val; } void free_image(image m) { if(m.data){ free(m.data); } } image resize_image(image im, int w, int h) { image resized = make_image(w, h, im.c); image part = make_image(w, im.h, im.c); int r, c, k; float w_scale = (float)(im.w - 1) / (w - 1); float h_scale = (float)(im.h - 1) / (h - 1); for(k = 0; k < im.c; ++k){ for(r = 0; r < im.h; ++r){ for(c = 0; c < w; ++c){ float val = 0; if(c == w-1 \|\| im.w == 1){ val = get_pixel(im, im.w-1, r, k); } else { float sx = cw_scale; int ix = (int) sx; float dx = sx - ix; val = (1 - dx) * get_pixel(im, ix, r, k) + dx * get_pixel(im, ix+1, r, k); } set_pixel(part, c, r, k, val); } } } for(k = 0; k < im.c; ++k){ for(r = 0; r < h; ++r){ float sy = rh_scale; int iy = (int) sy; float dy = sy - iy; for(c = 0; c < w; ++c){ float val = (1-dy) get_pixel(part, c, iy, k); set_pixel(resized, c, r, k, val); } if(r == h-1 \|\| im.h == 1) continue; for(c = 0; c < w; ++c){ float val = dy * get_pixel(part, c, iy+1, k); add_pixel(resized, c, r, k, val); } } } free_image(part); return resized; } void fill_image(image m, float s) { int i; for(i = 0; i < m.hm.wm.c; ++i) m.data[i] = s; } void embed_image(image source, image dest, int dx, int dy) { int x,y,k; for(k = 0; k < source.c; ++k){ for(y = 0; y < source.h; ++y){ for(x = 0; x < source.w; ++x){ float val = get_pixel(source, x,y,k); set_pixel(dest, dx+x, dy+y, k, val); } } } } image letterbox_image(image im, int w, int h) { int new_w = im.w; int new_h = im.h; if (((float)w/im.w) < ((float)h/im.h)) { new_w = w; new_h = (im.h * w)/im.w; } else { new_h = h; new_w = (im.w * h)/im.h; } image resized = resize_image(im, new_w, new_h); image boxed = make_image(w, h, im.c); fill_image(boxed, .5); //int i; //for(i = 0; i < boxed.wboxed.hboxed.c; ++i) boxed.data[i] = 0; embed_image(resized, boxed, (w-new_w)/2, (h-new_h)/2); free_image(resized); return boxed; } image load_image_stb(char filename, int channels) { int w, h, c; unsigned char data = stbi_load(filename, &w, &h, &c, channels); if (!data) { fprintf(stderr, "Cannot load image \"%s\"\nSTB Reason: %s\n", filename, stbi_failure_reason()); exit(0); } if(channels) c = channels; int i,j,k; image im = make_image(w, h, c); for(k = 0; k < c; ++k){ for(j = 0; j < h; ++j){ for(i = 0; i < w; ++i){ int dst_index = i + wj + whk; int src_index = k + ci + cwj; im.data[dst_index] = (float)data[src_index]/255.; } } } free(data); return im; } void save_image_png(image im, const char name) { char buff[256]; //sprintf(buff, "%s (%d)", name, windows); sprintf(buff, "%s.png", name); unsigned char data = (unsigned char )calloc(im.wim.him.c, sizeof(char)); int i,k; for(k = 0; k < im.c; ++k){ for(i = 0; i < im.wim.h; ++i){ data[iim.c+k] = (unsigned char) (255im.data[i + kim.wim.h]); } } int success = stbi_write_png(buff, im.w, im.h, im.c, data, im.wim.c); free(data); if(!success) fprintf(stderr, "Failed to write image %s\n", buff); } image load_alphabet() { int i, j; const int nsize = 8; image alphabets = (image )calloc(nsize, sizeof(image)); for(j = 0; j < nsize; ++j){ alphabets[j] = (image )calloc(128, sizeof(image)); for(i = 32; i < 127; ++i){ char buff[256]; sprintf(buff, "labels/%d_%d.png", i, j); //alphabets[j][i] = load_image_color(buff, 0, 0); alphabets[j][i] = load_image_stb(buff, 3); } } return alphabets; } ///////////////////activation begin static inline float stair_activate(float x) { int n = floor(x); if (n%2 == 0) return floor(x/2.); else return (x - n) + floor(x/2.); } static inline float hardtan_activate(float x) { if (x < -1) return -1; if (x > 1) return 1; return x; } static inline float linear_activate(float x){return x;} static inline float logistic_activate(float x){return 1./(1. + exp(-x));} static inline float loggy_activate(float x){return 2./(1. + exp(-x)) - 1;} static inline float relu_activate(float x){return x(x>0);} static inline float elu_activate(float x){return (x >= 0)x + (x < 0)(exp(x)-1);} static inline float relie_activate(float x){return (x>0) ? x : .01x;} static inline float ramp_activate(float x){return x(x>0)+.1x;} static inline float leaky_activate(float x){return (x>0) ? x : .1x;} static inline float tanh_activate(float x){return (exp(2x)-1)/(exp(2x)+1);} static inline float plse_activate(float x) { if(x < -4) return .01 (x + 4); if(x > 4) return .01 * (x - 4) + 1; return .125x + .5; } static inline float lhtan_activate(float x) { if(x < 0) return .001x; if(x > 1) return .001(x-1) + 1; return x; } static inline float lhtan_gradient(float x) { if(x > 0 && x < 1) return 1; return .001; } static inline float hardtan_gradient(float x) { if (x > -1 && x < 1) return 1; return 0; } static inline float linear_gradient(float x){return 1;} static inline float logistic_gradient(float x){return (1-x)x;} static inline float loggy_gradient(float x) { float y = (x+1.)/2.; return 2(1-y)y; } static inline float stair_gradient(float x) { if (floor(x) == x) return 0; return 1; } static inline float relu_gradient(float x){return (x>0);} static inline float elu_gradient(float x){return (x >= 0) + (x < 0)(x + 1);} static inline float relie_gradient(float x){return (x>0) ? 1 : .01;} static inline float ramp_gradient(float x){return (x>0)+.1;} static inline float leaky_gradient(float x){return (x>0) ? 1 : .1;} static inline float tanh_gradient(float x){return 1-xx;} static inline float plse_gradient(float x){return (x < 0 \|\| x > 1) ? .01 : .125;} char get_activation_string(ACTIVATION a) { switch(a){ case LOGISTIC: return "logistic"; case LOGGY: return "loggy"; case RELU: return "relu"; case ELU: return "elu"; case RELIE: return "relie"; case RAMP: return "ramp"; case LINEAR: return "linear"; case TANH: return "tanh"; case PLSE: return "plse"; case LEAKY: return "leaky"; case STAIR: return "stair"; case HARDTAN: return "hardtan"; case LHTAN: return "lhtan"; default: break; } return "relu"; } ACTIVATION get_activation(char s) { if (strcmp(s, "logistic")==0) return LOGISTIC; if (strcmp(s, "loggy")==0) return LOGGY; if (strcmp(s, "relu")==0) return RELU; if (strcmp(s, "elu")==0) return ELU; if (strcmp(s, "relie")==0) return RELIE; if (strcmp(s, "plse")==0) return PLSE; if (strcmp(s, "hardtan")==0) return HARDTAN; if (strcmp(s, "lhtan")==0) return LHTAN; if (strcmp(s, "linear")==0) return LINEAR; if (strcmp(s, "ramp")==0) return RAMP; if (strcmp(s, "leaky")==0) return LEAKY; if (strcmp(s, "tanh")==0) return TANH; if (strcmp(s, "stair")==0) return STAIR; fprintf(stderr, "Couldn't find activation function %s, going with ReLU\n", s); return RELU; } float activate(float x, ACTIVATION a) { switch(a){ case LINEAR: return linear_activate(x); case LOGISTIC: return logistic_activate(x); case LOGGY: return loggy_activate(x); case RELU: return relu_activate(x); case ELU: return elu_activate(x); case RELIE: return relie_activate(x); case RAMP: return ramp_activate(x); case LEAKY: return leaky_activate(x); case TANH: return tanh_activate(x); case PLSE: return plse_activate(x); case STAIR: return stair_activate(x); case HARDTAN: return hardtan_activate(x); case LHTAN: return lhtan_activate(x); } return 0; } void activate_array(float x, const int n, const ACTIVATION a) { int i; for(i = 0; i < n; ++i){ x[i] = activate(x[i], a); } } float gradient(float x, ACTIVATION a) { switch(a){ case LINEAR: return linear_gradient(x); case LOGISTIC: return logistic_gradient(x); case LOGGY: return loggy_gradient(x); case RELU: return relu_gradient(x); case ELU: return elu_gradient(x); case RELIE: return relie_gradient(x); case RAMP: return ramp_gradient(x); case LEAKY: return leaky_gradient(x); case TANH: return tanh_gradient(x); case PLSE: return plse_gradient(x); case STAIR: return stair_gradient(x); case HARDTAN: return hardtan_gradient(x); case LHTAN: return lhtan_gradient(x); } return 0; } ///////////////////activation end void copy_cpu(int N, float X, int INCX, float Y, int INCY) { int i; for(i = 0; i < N; ++i) Y[iINCY] = X[iINCX]; } void fill_cpu(int N, float ALPHA, float X, int INCX) { int i; for(i = 0; i < N; ++i) X[iINCX] = ALPHA; } void shortcut_cpu(int batch, int w1, int h1, int c1, float add, int w2, int h2, int c2, float s1, float s2, float out) { int stride = w1/w2; int sample = w2/w1; assert(stride == h1/h2); assert(sample == h2/h1); //printf("shorcut_layer batch=%d,stride=%d,sample=%d\n",batch,stride,sample); if(stride < 1) stride = 1; if(sample < 1) sample = 1; int minw = (w1 < w2) ? w1 : w2; int minh = (h1 < h2) ? h1 : h2; int minc = (c1 < c2) ? c1 : c2; int i,j,k,b; for(b = 0; b < batch; ++b){ for(k = 0; k < minc; ++k){ for(j = 0; j < minh; ++j){ for(i = 0; i < minw; ++i){ int out_index = isample + w2(jsample + h2(k + c2b)); int add_index = istride + w1(jstride + h1(k + c1b)); out[out_index] = s1out[out_index] + s2add[add_index]; } } } } } void forward_shortcut_layer(const layer l, network net) { //copy_cpu(l.outputsl.batch, net.input, 1, l.output, 1); //shortcut_cpu(l.batch, l.w, l.h, l.c, net.layers[l.index].output, l.out_w, l.out_h, l.out_c, l.alpha, l.beta, l.output); //activate_array(l.output, l.outputsl.batch, l.activation); int w = l.w; int h = l.h; int c = l.c; float add = net.layers[l.index].output; float out = l.output; float in = net.input; int i,j,k; for(k = 0; k < c; ++k){ for(j = 0; j < h; ++j){ for(i = 0; i < w; ++i){ int index = i + w(j + hk ); out[index] = in[index] + add[index]; } } } } layer make_shortcut_layer(int batch, int index, int w, int h, int c, int w2, int h2, int c2) { fprintf(stderr, "res %3d %4d x%4d x%4d -> %4d x%4d x%4d\n",index, w2,h2,c2, w,h,c); layer l; memset(&l,0,sizeof(layer)); l.type = SHORTCUT; l.batch = batch; l.w = w2; l.h = h2; l.c = c2; l.out_w = w; l.out_h = h; l.out_c = c; l.outputs = whc; l.inputs = l.outputs; l.index = index; l.output = (float )calloc(l.outputsbatch, sizeof(float));; l.forward = forward_shortcut_layer; return l; } int convolutional_out_height(layer l) { return (l.h + 2l.pad - l.size) / l.stride + 1; } int convolutional_out_width(layer l) { return (l.w + 2l.pad - l.size) / l.stride + 1; } static size_t get_workspace_size(layer l){ return (size_t)l.out_hl.out_wl.sizel.sizel.c/l.groupssizeof(float); } void add_bias(float output, float biases, int batch, int n, int size) { int i,j,b; for(b = 0; b < batch; ++b){ for(i = 0; i < n; ++i){ for(j = 0; j < size; ++j){ output[(bn + i)size + j] += biases[i]; } } } } void scale_bias(float output, float scales, int batch, int n, int size) { int i,j,b; for(b = 0; b < batch; ++b){ for(i = 0; i < n; ++i){ for(j = 0; j < size; ++j){ output[(bn + i)size + j] = scales[i]; } } } } float im2col_get_pixel(float 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 + heightchannel)]; } //From Berkeley Vision's Caffe! //https://github.com/BVLC/caffe/blob/master/LICENSE void im2col_cpu(float data_im, int channels, int height, int width, int ksize, int stride, int pad, float* data_col) { int c,h,w; int height_col = (height + 2pad - ksize) / stride + 1; int width_col = (width + 2pad - 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(data_im, height, width, channels, im_row, im_col, c_im, pad); } } } } void gemm_nn(int M, int N, int K, float ALPHA, float A, int lda, float B, int ldb, float C, int ldc) { int i,j,k; #pragma omp parallel for for(i = 0; i < M; ++i){ for(k = 0; k < K; ++k){ register float A_PART = ALPHAA[ilda+k]; for(j = 0; j < N; ++j){ C[ildc+j] += A_PARTB[kldb+j]; } } } } void gemm_cpu(int TA, int TB, int M, int N, int K, float ALPHA, float A, int lda, float B, int ldb, float BETA, float C, int ldc) { //printf("cpu: %d %d %d %d %d %f %d %d %f %d\n",TA, TB, M, N, K, ALPHA, lda, ldb, BETA, ldc); int i, j; for(i = 0; i < M; ++i){ for(j = 0; j < N; ++j){ C[ildc + j] = BETA; } } if(!TA && !TB) gemm_nn(M, N, K, ALPHA,A,lda, B, ldb,C,ldc); //else if(TA && !TB) // gemm_tn(M, N, K, ALPHA,A,lda, B, ldb,C,ldc); //else if(!TA && TB) // gemm_nt(M, N, K, ALPHA,A,lda, B, ldb,C,ldc); //else // gemm_tt(M, N, K, ALPHA,A,lda, B, ldb,C,ldc); } void gemm(int TA, int TB, int M, int N, int K, float ALPHA, float A, int lda, float B, int ldb, float BETA, float C, int ldc) { gemm_cpu( TA, TB, M, N, K, ALPHA,A,lda, B, ldb,BETA,C,ldc); } void normalize_cpu(float x, float mean, float variance, int batch, int filters, int spatial) { int b, f, i; for(b = 0; b < batch; ++b){ for(f = 0; f < filters; ++f){ for(i = 0; i < spatial; ++i){ int index = bfiltersspatial + fspatial + i; x[index] = (x[index] - mean[f])/(sqrt(variance[f]) + .000001f); } } } } void forward_batchnorm_layer(layer l, network net)//for conv { normalize_cpu(l.output, l.rolling_mean, l.rolling_variance, l.batch, l.out_c, l.out_hl.out_w); scale_bias(l.output, l.scales, l.batch, l.out_c, l.out_hl.out_w); add_bias(l.output, l.biases, l.batch, l.out_c, l.out_hl.out_w); } void CONV_Padding_Relu(float Input,float Output,float Weight,const int InFM_num,const int OutFM_num,const int Kernel_size,const int Kernel_stride,const int Input_w,const int Input_h,const int Padding) { // (output_w - 1)Kernel_stride + Kernel_size = Input_w const int output_w = (Input_w - Kernel_size + 2Padding)/Kernel_stride + 1 ; const int output_h = (Input_h - Kernel_size + 2Padding)/Kernel_stride + 1 ; int x, y, of, inf; int m,n; for( of = 0; of < OutFM_num; of++){ for( y = 0; y < output_h; y++) { for( x = 0; x < output_w; x++){ float tmp = 0.0; for(inf = 0;inf < InFM_num; inf++) { int intput_offset = infInput_wInput_h + (yKernel_stride - Padding)Input_w + xKernel_stride - Padding; for(m = 0;m < Kernel_size; m++) { for(n = 0;n < Kernel_size; n++) { int kernel_offset = ofInFM_numKernel_sizeKernel_size + infKernel_sizeKernel_size; bool inFM_width = ((xKernel_stride + n - Padding) >= 0)&&((xKernel_stride + n - Padding) < Input_w); bool inFM_height = ((yKernel_stride + m - Padding) >= 0)&&((yKernel_stride + m - Padding) < Input_h); if(inFM_width&&inFM_height) tmp += Weight[kernel_offset + mKernel_size + n]Input[intput_offset + mInput_w + n]; } } } Output[ofoutput_woutput_h + youtput_w + x] = tmp; } } } } void forward_convolutional_layer(layer l, network net) { int i, j; fill_cpu(l.outputsl.batch, 0, l.output, 1); //printf("c=%d,n=%d,size=%d,stride=%d,w=%d,h=%d,pad=%d\n",l.c,l.n,l.size,l.stride,l.w,l.h,l.pad); //int m = l.n/l.groups; //int k = l.sizel.sizel.c/l.groups; //int n = l.out_wl.out_h; //for(i = 0; i < l.batch; ++i){ // for(j = 0; j < l.groups; ++j){ // float a = l.weights + jl.nweights/l.groups; // float b = net.workspace; // float c = l.output + (il.groups + j)nm; // im2col_cpu(net.input + (il.groups + j)l.c/l.groupsl.hl.w, // l.c/l.groups, l.h, l.w, l.size, l.stride, l.pad, b); // gemm(0,0,m,n,k,1,a,k,b,n,1,c,n); // } //} int m = l.n; int k = l.sizel.sizel.c; int n = l.out_wl.out_h; float a = l.weights; float b = net.workspace; float c = l.output; im2col_cpu(net.input,l.c, l.h, l.w, l.size, l.stride, l.pad, b); gemm(0,0,m,n,k,1,a,k,b,n,1,c,n); //CONV_Padding_Relu(net.input,l.output,l.weights,l.c,l.n,l.size,l.stride,l.w,l.h,l.pad); if(l.batch_normalize){ forward_batchnorm_layer(l, net); } else { add_bias(l.output, l.biases, l.batch, l.n, l.out_hl.out_w); } activate_array(l.output, l.outputsl.batch, l.activation); } layer make_convolutional_layer(int batch, int h, int w, int c, int n, int groups, int size, int stride, int padding, ACTIVATION activation, int batch_normalize, int binary, int xnor, int adam) { int i; layer l; memset(&l,0,sizeof(layer)); l.type = CONVOLUTIONAL; l.groups = groups; l.h = h; l.w = w; l.c = c; l.n = n; l.binary = binary; l.xnor = xnor; l.batch = batch; l.stride = stride; l.size = size; l.pad = padding; l.batch_normalize = batch_normalize; // l.weights = (float )calloc(c/groupsnsizesize, sizeof(float)); // l.biases = (float )calloc(n, sizeof(float)); l.nweights = c/groupsnsizesize; l.nbiases = n; int out_w = convolutional_out_width(l); int out_h = convolutional_out_height(l); l.out_h = out_h; l.out_w = out_w; l.out_c = n; l.outputs = l.out_h * l.out_w * l.out_c; l.inputs = l.w * l.h * l.c; // l.output = (float )calloc(l.batchl.outputs, sizeof(float)); l.forward = forward_convolutional_layer; if(batch_normalize){ // l.scales = (float )calloc(n, sizeof(float)); // l.rolling_mean = (float )calloc(n, sizeof(float)); //l.rolling_variance = (float )calloc(n, sizeof(float)); } l.workspace_size = get_workspace_size(l); l.activation = activation; fprintf(stderr, "conv %5d %2d x%2d /%2d %4d x%4d x%4d -> %4d x%4d x%4d %5.3f BFLOPs\n", n, size, size, stride, w, h, c, l.out_w, l.out_h, l.out_c, (2.0 l.n * l.sizel.sizel.c/l.groups * l.out_hl.out_w)/1000000000.); return l; } void upsample_cpu(float in, int w, int h, int c, int batch, int stride, int forward, float scale, float out) { int i, j, k, b; for(b = 0; b < batch; ++b){ for(k = 0; k < c; ++k){ for(j = 0; j < hstride; ++j){ for(i = 0; i < wstride; ++i){ int in_index = bwhc + kwh + (j/stride)w + i/stride; int out_index = bwhcstridestride + kwhstridestride + jwstride + i; if(forward) out[out_index] = scalein[in_index]; else in[in_index] += scaleout[out_index]; } } } } } void forward_upsample_layer(const layer l, network net) { //fill_cpu(l.outputsl.batch, 0, l.output, 1); //upsample_cpu(net.input, l.w, l.h, l.c, l.batch, l.stride, 1, l.scale, l.output); int c = l.c; int h = l.h; int w = l.w; int stride = l.stride; float in = net.input; float out = l.output; int i, j, k; for(k = 0; k < c; ++k){ for(j = 0; j < hstride; ++j){ for(i = 0; i < wstride; ++i){ int in_index = kwh + (j/stride)w + i/stride; int out_index = kwhstridestride + jwstride + i; out[out_index] = in[in_index]; } } } } layer make_upsample_layer(int batch, int w, int h, int c, int stride) { layer l; memset(&l,0,sizeof(layer)); l.type = UPSAMPLE; l.batch = batch; l.w = w; l.h = h; l.c = c; l.out_w = wstride; l.out_h = hstride; l.out_c = c; if(stride < 0){ stride = -stride; l.reverse=1; l.out_w = w/stride; l.out_h = h/stride; } l.stride = stride; l.outputs = l.out_wl.out_hl.out_c; l.inputs = l.wl.hl.c; l.output = (float )calloc(l.outputsbatch, sizeof(float));; l.forward = forward_upsample_layer; if(l.reverse) fprintf(stderr, "downsample %2dx %4d x%4d x%4d -> %4d x%4d x%4d\n", stride, w, h, c, l.out_w, l.out_h, l.out_c); else fprintf(stderr, "upsample %2dx %4d x%4d x%4d -> %4d x%4d x%4d\n", stride, w, h, c, l.out_w, l.out_h, l.out_c); return l; } void forward_route_layer(const layer l, network net) { int i, j; int offset = 0; for(i = 0; i < l.n; ++i){ int index = l.input_layers[i]; float input = net.layers[index].output; int input_size = l.input_sizes[i]; copy_cpu(input_size, input, 1, l.output + offset, 1); offset += input_size; } } layer make_route_layer(int batch, int n, int input_layers, int input_sizes) { fprintf(stderr,"route "); layer l; memset(&l,0,sizeof(layer)); l.type = ROUTE; l.batch = batch; l.n = n; l.input_layers = input_layers; l.input_sizes = input_sizes; int i; int outputs = 0; for(i = 0; i < n; ++i){ fprintf(stderr," %d", input_layers[i]); outputs += input_sizes[i]; } fprintf(stderr, "\n"); l.outputs = outputs; l.inputs = outputs; // l.output = (float )calloc(outputsbatch, sizeof(float));; l.forward = forward_route_layer; return l; } static int entry_index(layer l, int batch, int location, int entry) { int n = location / (l.wl.h); int loc = location % (l.wl.h); return batchl.outputs + nl.wl.h(4+l.classes+1) + entryl.wl.h + loc; } void forward_yolo_layer(const layer l, network net) { int i,j,b,t,n; //char line[256]; //FILE fp3; //char filename[256]; //sprintf(filename, "yolo_layer_%d.txt", l.outputs); //printf("YOLO_layer:outputs=%d,%s\n",l.outputs,filename); // if( (fp3 = fopen(filename, "w")) == NULL)fprintf(stderr,"CANNOT OPEN\n"); //int x; // for( x = 0; x < l.outputs; x++) //{ // sprintf(line, "%f\n", net.input[x]); // if(fputs(line,fp3)<0)fprintf(stderr,"write FILE failed\n"); // } // fclose(fp3); memcpy(l.output, net.input, l.outputsl.batchsizeof(float)); for (b = 0; b < l.batch; ++b){ for(n = 0; n < l.n; ++n){ int index = entry_index(l, b, nl.wl.h, 0); activate_array(l.output + index, 2l.wl.h, LOGISTIC); index = entry_index(l, b, nl.wl.h, 4); activate_array(l.output + index, (1+l.classes)l.wl.h, LOGISTIC); } } return ; } layer make_yolo_layer(int batch, int w, int h, int n, int total, int mask, int classes) { int i; layer l; memset(&l,0,sizeof(layer)); l.type = YOLO; l.n = n; l.total = total; l.batch = batch; l.h = h; l.w = w; l.c = n(classes + 4 + 1); l.out_w = l.w; l.out_h = l.h; l.out_c = l.c; l.classes = classes; //l.cost = (float )calloc(1, sizeof(float)); l.biases = (float )calloc(total2, sizeof(float)); if(mask) l.mask = mask; else{ l.mask = (int )calloc(n, sizeof(int)); for(i = 0; i < n; ++i){ l.mask[i] = i; } } //l.bias_updates = (float )calloc(n2, sizeof(float)); l.outputs = hwn(classes + 4 + 1); l.inputs = l.outputs; //l.truths = 90(4 + 1); //l.delta = (float )calloc(batchl.outputs, sizeof(float)); l.output = (float )calloc(batchl.outputs, sizeof(float)); for(i = 0; i < total2; ++i){ l.biases[i] = .5; } l.forward = forward_yolo_layer; fprintf(stderr, "detection\n"); srand(0); return l; } /////////////////praser begin typedef struct{ char type; list options; }section; list read_cfg(char filename); LAYER_TYPE string_to_layer_type(char type) { if (strcmp(type, "[shortcut]")==0) return SHORTCUT; if (strcmp(type, "[crop]")==0) return CROP; if (strcmp(type, "[cost]")==0) return COST; if (strcmp(type, "[detection]")==0) return DETECTION; if (strcmp(type, "[region]")==0) return REGION; if (strcmp(type, "[yolo]")==0) return YOLO; if (strcmp(type, "[local]")==0) return LOCAL; if (strcmp(type, "[conv]")==0 \|\| strcmp(type, "[convolutional]")==0) return CONVOLUTIONAL; if (strcmp(type, "[deconv]")==0 \|\| strcmp(type, "[deconvolutional]")==0) return DECONVOLUTIONAL; if (strcmp(type, "[activation]")==0) return ACTIVE; if (strcmp(type, "[logistic]")==0) return LOGXENT; if (strcmp(type, "[l2norm]")==0) return L2NORM; if (strcmp(type, "[net]")==0 \|\| strcmp(type, "[network]")==0) return NETWORK; if (strcmp(type, "[crnn]")==0) return CRNN; if (strcmp(type, "[gru]")==0) return GRU; if (strcmp(type, "[lstm]") == 0) return LSTM; if (strcmp(type, "[rnn]")==0) return RNN; if (strcmp(type, "[conn]")==0 \|\| strcmp(type, "[connected]")==0) return CONNECTED; if (strcmp(type, "[max]")==0 \|\| strcmp(type, "[maxpool]")==0) return MAXPOOL; if (strcmp(type, "[reorg]")==0) return REORG; if (strcmp(type, "[avg]")==0 \|\| strcmp(type, "[avgpool]")==0) return AVGPOOL; if (strcmp(type, "[dropout]")==0) return DROPOUT; if (strcmp(type, "[lrn]")==0 \|\| strcmp(type, "[normalization]")==0) return NORMALIZATION; if (strcmp(type, "[batchnorm]")==0) return BATCHNORM; if (strcmp(type, "[soft]")==0 \|\| strcmp(type, "[softmax]")==0) return SOFTMAX; if (strcmp(type, "[route]")==0) return ROUTE; if (strcmp(type, "[upsample]")==0) return UPSAMPLE; return BLANK; } void free_section(section s) { free(s->type); node n = s->options->front; while(n){ kvp pair = (kvp )n->val; free(pair->key); free(pair); node next = n->next; free(n); n = next; } free(s->options); free(s); } void parse_data(char data, float a, int n) { int i; if(!data) return; char curr = data; char next = data; int done = 0; for(i = 0; i < n && !done; ++i){ while(++next !='\0' && next != ','); if(next == '\0') done = 1; next = '\0'; sscanf(curr, "%g", &a[i]); curr = next+1; } } typedef struct size_params{ int batch; int inputs; int h; int w; int c; int index; int time_steps; network net; } size_params; layer parse_convolutional(list options, size_params params) { int n = option_find_int(options, "filters",1); int size = option_find_int(options, "size",1); int stride = option_find_int(options, "stride",1); int pad = option_find_int_quiet(options, "pad",0); int padding = option_find_int_quiet(options, "padding",0); int groups = option_find_int_quiet(options, "groups", 1); if(pad) padding = size/2; char activation_s = option_find_str(options, "activation", "logistic"); ACTIVATION activation = get_activation(activation_s); int batch,h,w,c; h = params.h; w = params.w; c = params.c; batch=params.batch; if(!(h && w && c)) error("Layer before convolutional layer must output image."); int batch_normalize = option_find_int_quiet(options, "batch_normalize", 0); int binary = option_find_int_quiet(options, "binary", 0); int xnor = option_find_int_quiet(options, "xnor", 0); layer l = make_convolutional_layer(batch,h,w,c,n,groups,size,stride,padding,activation, batch_normalize, binary, xnor, params.net->adam); l.flipped = option_find_int_quiet(options, "flipped", 0); l.dot = option_find_float_quiet(options, "dot", 0); return l; } int parse_yolo_mask(char a, int num) { int mask = 0; if(a){ int len = strlen(a); int n = 1; int i; for(i = 0; i < len; ++i){ if (a[i] == ',') ++n; } mask = (int )calloc(n, sizeof(int)); for(i = 0; i < n; ++i){ int val = atoi(a); mask[i] = val; a = strchr(a, ',')+1; } num = n; } return mask; } layer parse_yolo(list options, size_params params) { int classes = option_find_int(options, "classes", 20); int total = option_find_int(options, "num", 1); int num = total; char a = option_find_str(options, "mask", 0); int mask = parse_yolo_mask(a, &num); layer l = make_yolo_layer(params.batch, params.w, params.h, num, total, mask, classes); assert(l.outputs == params.inputs); l.max_boxes = option_find_int_quiet(options, "max",90); l.jitter = option_find_float(options, "jitter", .2); l.ignore_thresh = option_find_float(options, "ignore_thresh", .5); l.truth_thresh = option_find_float(options, "truth_thresh", 1); l.random = option_find_int_quiet(options, "random", 0); a = option_find_str(options, "anchors", 0); if(a){ int len = strlen(a); int n = 1; int i; for(i = 0; i < len; ++i){ if (a[i] == ',') ++n; } for(i = 0; i < n; ++i){ float bias = atof(a); l.biases[i] = bias; a = strchr(a, ',')+1; } } return l; } layer parse_shortcut(list options, size_params params, network net) { char l = option_find(options, "from"); int index = atoi(l); if(index < 0) index = params.index + index; int batch = params.batch; layer from = net->layers[index]; layer s = make_shortcut_layer(batch, index, params.w, params.h, params.c, from.out_w, from.out_h, from.out_c); char activation_s = option_find_str(options, "activation", "linear"); ACTIVATION activation = get_activation(activation_s); s.activation = activation; s.alpha = option_find_float_quiet(options, "alpha", 1); s.beta = option_find_float_quiet(options, "beta", 1); return s; } layer parse_upsample(list options, size_params params, network net) { int stride = option_find_int(options, "stride",2); layer l = make_upsample_layer(params.batch, params.w, params.h, params.c, stride); l.scale = option_find_float_quiet(options, "scale", 1); return l; } layer parse_route(list options, size_params params, network net) { char l = option_find(options, "layers"); int len = strlen(l); if(!l) error("Route Layer must specify input layers"); int n = 1; int i; for(i = 0; i < len; ++i){ if (l[i] == ',') ++n; } int layers = (int )calloc(n, sizeof(int)); int sizes = (int )calloc(n, sizeof(int)); for(i = 0; i < n; ++i){ int index = atoi(l); l = strchr(l, ',')+1; if(index < 0) index = params.index + index; layers[i] = index; sizes[i] = net->layers[index].outputs; } int batch = params.batch; layer route_layer = make_route_layer(batch, n, layers, sizes); layer first = net->layers[layers[0]]; route_layer.out_w = first.out_w; route_layer.out_h = first.out_h; route_layer.out_c = first.out_c; for(i = 1; i < n; ++i){ int index = layers[i]; layer next = net->layers[index]; if(next.out_w == first.out_w && next.out_h == first.out_h){ route_layer.out_c += next.out_c; }else{ route_layer.out_h = route_layer.out_w = route_layer.out_c = 0; } } return route_layer; } void softmax(float input, int n, float temp, int stride, float output) { int i; float sum = 0; float largest = -FLT_MAX; for(i = 0; i < n; ++i){ if(input[istride] > largest) largest = input[istride]; } for(i = 0; i < n; ++i){ float e = exp(input[istride]/temp - largest/temp); sum += e; output[istride] = e; } for(i = 0; i < n; ++i){ output[istride] /= sum; } } void softmax_cpu(float input, int n, int batch, int batch_offset, int groups, int group_offset, int stride, float temp, float output) { int g, b; for(b = 0; b < batch; ++b){ for(g = 0; g < groups; ++g){ softmax(input + bbatch_offset + ggroup_offset, n, temp, stride, output + bbatch_offset + ggroup_offset); } } } void forward_region_layer(const layer l, network net) { int i,j,b,t,n; memcpy(l.output, net.input, l.outputsl.batchsizeof(float)); #ifndef GPU for (b = 0; b < l.batch; ++b){ for(n = 0; n < l.n; ++n){ int index = entry_index(l, b, nl.wl.h, 0); activate_array(l.output + index, 2l.wl.h, LOGISTIC); index = entry_index(l, b, nl.wl.h, l.coords); if(!l.background) activate_array(l.output + index, l.wl.h, LOGISTIC); index = entry_index(l, b, nl.wl.h, l.coords + 1); //if(!l.softmax) activate_array(l.output + index, l.classesl.wl.h, LOGISTIC); } } if (l.softmax){ int index = entry_index(l, 0, 0, l.coords + !l.background); softmax_cpu(net.input + index, l.classes + l.background, l.batchl.n, l.inputs/l.n, l.wl.h, 1, l.wl.h, 1, l.output + index); } char line[256]; FILE fp3; char filename[256]; sprintf(filename, "yolo_layer_%d.txt", 123123); printf("YOLO_layer:outputs=%d,%s\n",l.outputs,filename); if( (fp3 = fopen(filename, "w")) == NULL)fprintf(stderr,"CANNOT OPEN\n"); int x; for( x = 0; x < l.outputs; x++) { sprintf(line, "%f\n", net.input[x]); if(fputs(line,fp3)<0)fprintf(stderr,"write FILE failed\n"); } fclose(fp3); #endif if(!net.train) return; } layer make_region_layer(int batch, int w, int h, int n, int classes, int coords) { layer l; memset(&l,0,sizeof(layer)); l.type = REGION; l.n = n; l.batch = batch; l.h = h; l.w = w; l.c = n(classes + coords + 1); l.out_w = l.w; l.out_h = l.h; l.out_c = l.c; l.classes = classes; l.coords = coords; l.biases = (float )calloc(n2, sizeof(float)); l.outputs = hwn(classes + coords + 1); l.inputs = l.outputs; l.truths = 30(l.coords + 1); l.output = (float )calloc(batchl.outputs, sizeof(float)); int i; for(i = 0; i < n2; ++i){ l.biases[i] = .5; } l.forward = forward_region_layer; fprintf(stderr, "detection\n"); srand(0); return l; } layer parse_region(list options, size_params params) { int coords = option_find_int(options, "coords", 4); int classes = option_find_int(options, "classes", 20); int num = option_find_int(options, "num", 1); layer l = make_region_layer(params.batch, params.w, params.h, num, classes, coords); assert(l.outputs == params.inputs); l.log = option_find_int_quiet(options, "log", 0); l.sqrt = option_find_int_quiet(options, "sqrt", 0); l.softmax = option_find_int(options, "softmax", 0); l.background = option_find_int_quiet(options, "background", 0); l.max_boxes = option_find_int_quiet(options, "max",30); l.jitter = option_find_float(options, "jitter", .2); l.rescore = option_find_int_quiet(options, "rescore",0); l.thresh = option_find_float(options, "thresh", .5); l.classfix = option_find_int_quiet(options, "classfix", 0); l.absolute = option_find_int_quiet(options, "absolute", 0); l.random = option_find_int_quiet(options, "random", 0); l.coord_scale = option_find_float(options, "coord_scale", 1); l.object_scale = option_find_float(options, "object_scale", 1); l.noobject_scale = option_find_float(options, "noobject_scale", 1); l.mask_scale = option_find_float(options, "mask_scale", 1); l.class_scale = option_find_float(options, "class_scale", 1); l.bias_match = option_find_int_quiet(options, "bias_match",0); char tree_file = option_find_str(options, "tree", 0); // if (tree_file) l.softmax_tree = read_tree(tree_file); char map_file = option_find_str(options, "map", 0); // if (map_file) l.map = read_map(map_file); char a = option_find_str(options, "anchors", 0); if(a){ int len = strlen(a); int n = 1; int i; for(i = 0; i < len; ++i){ if (a[i] == ',') ++n; } for(i = 0; i < n; ++i){ float bias = atof(a); l.biases[i] = bias; a = strchr(a, ',')+1; } } return l; } void reorg_cpu(float x, int w, int h, int c, int batch, int stride, int forward, float out) { int b,i,j,k; int out_c = c/(stridestride); for(b = 0; b < batch; ++b){ for(k = 0; k < c; ++k){ for(j = 0; j < h; ++j){ for(i = 0; i < w; ++i){ int in_index = i + w(j + h(k + cb)); int c2 = k % out_c; int offset = k / out_c; int w2 = istride + offset % stride; int h2 = jstride + offset / stride; int out_index = w2 + wstride(h2 + hstride(c2 + out_cb)); if(forward) out[out_index] = x[in_index]; else out[in_index] = x[out_index]; } } } } } void forward_reorg_layer(const layer l, network net) { int i; //if(l.flatten){ // memcpy(l.output, net.input, l.outputsl.batchsizeof(float)); // if(l.reverse){ // flatten(l.output, l.wl.h, l.c, l.batch, 0); // }else{ // flatten(l.output, l.wl.h, l.c, l.batch, 1); // } //} else if (l.extra) { // for(i = 0; i < l.batch; ++i){ // copy_cpu(l.inputs, net.input + il.inputs, 1, l.output + il.outputs, 1); // } //} else if (l.reverse){ // reorg_cpu(net.input, l.w, l.h, l.c, l.batch, l.stride, 1, l.output); //} else { reorg_cpu(net.input, l.w, l.h, l.c, l.batch, l.stride, 0, l.output); //} } layer make_reorg_layer(int batch, int w, int h, int c, int stride, int reverse, int flatten, int extra) { layer l; memset(&l,0,sizeof(layer)); l.type = REORG; l.batch = batch; l.stride = stride; l.extra = extra; l.h = h; l.w = w; l.c = c; l.flatten = flatten; if(reverse){ l.out_w = wstride; l.out_h = hstride; l.out_c = c/(stridestride); }else{ l.out_w = w/stride; l.out_h = h/stride; l.out_c = c(stridestride); } l.reverse = reverse; l.outputs = l.out_h * l.out_w * l.out_c; l.inputs = hwc; if(l.extra){ l.out_w = l.out_h = l.out_c = 0; l.outputs = l.inputs + l.extra; } if(extra){ fprintf(stderr, "reorg %4d -> %4d\n", l.inputs, l.outputs); } else { fprintf(stderr, "reorg /%2d %4d x%4d x%4d -> %4d x%4d x%4d\n", stride, w, h, c, l.out_w, l.out_h, l.out_c); } int output_size = l.outputs * batch; //l.output = (float )calloc(output_size, sizeof(float)); l.forward = forward_reorg_layer; return l; } layer parse_reorg(list options, size_params params) { int stride = option_find_int(options, "stride",1); int reverse = option_find_int_quiet(options, "reverse",0); int flatten = option_find_int_quiet(options, "flatten",0); int extra = option_find_int_quiet(options, "extra",0); int batch,h,w,c; h = params.h; w = params.w; c = params.c; batch=params.batch; if(!(h && w && c)) error("Layer before reorg layer must output image."); layer layer = make_reorg_layer(batch,w,h,c,stride,reverse, flatten, extra); return layer; } void forward_maxpool_layer(layer l, network net) { 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; for(b = 0; b < l.batch; ++b){ for(k = 0; k < c; ++k){ for(i = 0; i < h; ++i){ for(j = 0; j < w; ++j){ int out_index = j + w(i + h(k + cb)); float max = -FLT_MAX; int max_i = -1; for(n = 0; n < l.size; ++n){ for(m = 0; m < l.size; ++m){ int cur_h = h_offset + il.stride + n; int cur_w = w_offset + jl.stride + m; int index = cur_w + l.w(cur_h + l.h(k + bl.c)); int valid = (cur_h >= 0 && cur_h < l.h && cur_w >= 0 && cur_w < l.w); float val = (valid != 0) ? net.input[index] : -FLT_MAX; max_i = (val > max) ? index : max_i; max = (val > max) ? val : max; } } l.output[out_index] = max; l.indexes[out_index] = max_i; } } } } } //layer make_maxpool_layer(int batch, int h, int w, int c, int size, int stride, int padding) //{ // layer l; // memset(&l,0,sizeof(layer)); // l.type = MAXPOOL; // l.batch = batch; // l.h = h; // l.w = w; // l.c = c; // l.pad = padding; // l.out_w = (w + 2padding)/stride; // l.out_h = (h + 2padding)/stride; // l.out_c = c; // l.outputs = l.out_h * l.out_w * l.out_c; // l.inputs = hwc; // l.size = size; // l.stride = stride; // int output_size = l.out_h * l.out_w * l.out_c * batch; // //l.indexes = (int )calloc(output_size, sizeof(int)); // //l.output = (float )calloc(output_size, sizeof(float)); // l.forward = forward_maxpool_layer; // // fprintf(stderr, "max %d x %d / %d %4d x%4d x%4d -> %4d x%4d x%4d\n", size, size, stride, w, h, c, l.out_w, l.out_h, l.out_c); // return l; //} layer make_maxpool_layer(int batch, int h, int w, int c, int size, int stride, int padding) { layer l; memset(&l,0,sizeof(layer)); l.type = MAXPOOL; l.batch = batch; l.h = h; l.w = w; l.c = c; l.pad = padding; l.out_w = (w + padding - size)/stride + 1; l.out_h = (h + padding - size)/stride + 1; l.out_c = c; l.outputs = l.out_h * l.out_w * l.out_c; l.inputs = hwc; l.size = size; l.stride = stride; int output_size = l.out_h * l.out_w * l.out_c * batch; //l.indexes = calloc(output_size, sizeof(int)); //l.output = calloc(output_size, sizeof(float)); //l.delta = calloc(output_size, sizeof(float)); l.forward = forward_maxpool_layer; //l.backward = backward_maxpool_layer; fprintf(stderr, "max %d x %d / %d %4d x%4d x%4d -> %4d x%4d x%4d\n", size, size, stride, w, h, c, l.out_w, l.out_h, l.out_c); return l; } layer parse_maxpool(list options, size_params params) { int stride = option_find_int(options, "stride",1); int size = option_find_int(options, "size",stride); int padding = option_find_int_quiet(options, "padding", size-1); int batch,h,w,c; h = params.h; w = params.w; c = params.c; batch=params.batch; if(!(h && w && c)) error("Layer before maxpool layer must output image."); layer maxpool_layer = make_maxpool_layer(batch,h,w,c,size,stride,padding); return maxpool_layer; } learning_rate_policy get_policy(char s) { if (strcmp(s, "random")==0) return RANDOM; if (strcmp(s, "poly")==0) return POLY; if (strcmp(s, "constant")==0) return CONSTANT; if (strcmp(s, "step")==0) return STEP; if (strcmp(s, "exp")==0) return EXP; if (strcmp(s, "sigmoid")==0) return SIG; if (strcmp(s, "steps")==0) return STEPS; fprintf(stderr, "Couldn't find policy %s, going with constant\n", s); return CONSTANT; } void parse_net_options(list options, network net) { net->batch = option_find_int(options, "batch",1); net->learning_rate = option_find_float(options, "learning_rate", .001); net->momentum = option_find_float(options, "momentum", .9); net->decay = option_find_float(options, "decay", .0001); int subdivs = option_find_int(options, "subdivisions",1); net->time_steps = option_find_int_quiet(options, "time_steps",1); net->notruth = option_find_int_quiet(options, "notruth",0); net->batch /= subdivs; net->batch = net->time_steps; net->subdivisions = subdivs; net->random = option_find_int_quiet(options, "random", 0); net->adam = option_find_int_quiet(options, "adam", 0); if(net->adam){ net->B1 = option_find_float(options, "B1", .9); net->B2 = option_find_float(options, "B2", .999); net->eps = option_find_float(options, "eps", .0000001); } net->h = option_find_int_quiet(options, "height",0); net->w = option_find_int_quiet(options, "width",0); net->c = option_find_int_quiet(options, "channels",0); net->inputs = option_find_int_quiet(options, "inputs", net->h net->w * net->c); net->max_crop = option_find_int_quiet(options, "max_crop",net->w2); net->min_crop = option_find_int_quiet(options, "min_crop",net->w); net->max_ratio = option_find_float_quiet(options, "max_ratio", (float) net->max_crop / net->w); net->min_ratio = option_find_float_quiet(options, "min_ratio", (float) net->min_crop / net->w); net->center = option_find_int_quiet(options, "center",0); net->clip = option_find_float_quiet(options, "clip", 0); net->angle = option_find_float_quiet(options, "angle", 0); net->aspect = option_find_float_quiet(options, "aspect", 1); net->saturation = option_find_float_quiet(options, "saturation", 1); net->exposure = option_find_float_quiet(options, "exposure", 1); net->hue = option_find_float_quiet(options, "hue", 0); if(!net->inputs && !(net->h && net->w && net->c)) error("No input parameters supplied"); char policy_s = option_find_str(options, "policy", "constant"); net->policy = get_policy(policy_s); net->burn_in = option_find_int_quiet(options, "burn_in", 0); net->power = option_find_float_quiet(options, "power", 4); if(net->policy == STEP){ net->step = option_find_int(options, "step", 1); net->scale = option_find_float(options, "scale", 1); } else if (net->policy == STEPS){ char l = option_find(options, "steps"); char p = option_find(options, "scales"); if(!l \|\| !p) error("STEPS policy must have steps and scales in cfg file"); int len = strlen(l); int n = 1; int i; for(i = 0; i < len; ++i){ if (l[i] == ',') ++n; } int steps = (int )calloc(n, sizeof(int)); float scales = (float )calloc(n, sizeof(float)); for(i = 0; i < n; ++i){ int step = atoi(l); float scale = atof(p); l = strchr(l, ',')+1; p = strchr(p, ',')+1; steps[i] = step; scales[i] = scale; } net->scales = scales; net->steps = steps; net->num_steps = n; } else if (net->policy == EXP){ net->gamma = option_find_float(options, "gamma", 1); } else if (net->policy == SIG){ net->gamma = option_find_float(options, "gamma", 1); net->step = option_find_int(options, "step", 1); } else if (net->policy == POLY \|\| net->policy == RANDOM){ } net->max_batches = option_find_int(options, "max_batches", 0); } int is_network(section s) { return (strcmp(s->type, "[net]")==0 \|\| strcmp(s->type, "[network]")==0); } network parse_network_cfg(char filename) { list sections = read_cfg(filename); node n = sections->front; if(!n) error("Config file has no sections"); network net = make_network(sections->size - 1); net->gpu_index = -1; size_params params; section s = (section )n->val; list options = s->options; if(!is_network(s)) error("First section must be [net] or [network]"); parse_net_options(options, net); params.h = net->h; params.w = net->w; params.c = net->c; params.inputs = net->inputs; params.batch = net->batch; params.time_steps = net->time_steps; params.net = net; size_t workspace_size = 0; n = n->next; int count = 0; free_section(s); fprintf(stderr, "layer filters size input output\n"); while(n){ params.index = count; fprintf(stderr, "%5d ", count); s = (section )n->val; options = s->options; //layer l = {0}; layer l; memset(&l,0,sizeof(layer)); LAYER_TYPE lt = string_to_layer_type(s->type); if(lt == CONVOLUTIONAL){ l = parse_convolutional(options, params); }else if(lt == YOLO){ l = parse_yolo(options, params); }else if(lt == ROUTE){ l = parse_route(options, params, net); }else if(lt == UPSAMPLE){ l = parse_upsample(options, params, net); }else if(lt == SHORTCUT){ l = parse_shortcut(options, params, net); }else if(lt == REGION){ l = parse_region(options, params); }else if(lt == YOLO){ l = parse_yolo(options, params); }else if(lt == MAXPOOL){ l = parse_maxpool(options, params); }else if(lt == REORG){ l = parse_reorg(options, params); }else{ fprintf(stderr, "Type not recognized: %s\n", s->type); } l.clip = net->clip; l.truth = option_find_int_quiet(options, "truth", 0); l.onlyforward = option_find_int_quiet(options, "onlyforward", 0); l.stopbackward = option_find_int_quiet(options, "stopbackward", 0); l.dontsave = option_find_int_quiet(options, "dontsave", 0); // l.dontload = option_find_int_quiet(options, "dontload", 0); // l.dontloadscales = option_find_int_quiet(options, "dontloadscales", 0); //l.learning_rate_scale = option_find_float_quiet(options, "learning_rate", 1); l.smooth = option_find_float_quiet(options, "smooth", 0); option_unused(options); net->layers[count] = l; if (l.workspace_size > workspace_size) workspace_size = l.workspace_size; free_section(s); n = n->next; ++count; if(n){ params.h = l.out_h; params.w = l.out_w; params.c = l.out_c; params.inputs = l.outputs; } } free_list(sections); layer out = get_network_output_layer(net); net->outputs = out.outputs; net->output = out.output; //net->input = (float )calloc(net->inputsnet->batch, sizeof(float)); workspace_size = 0;//donot calloc workspace //if(workspace_size){ // //printf("%ld\n", workspace_size); // net->workspace = (float )calloc(1, workspace_size); //} return net; } list read_cfg(char filename) { FILE file = fopen(filename, "r"); if(file == 0) file_error(filename); char line; int nu = 0; list options = make_list(); section current = 0; while((line=fgetl(file)) != 0){ ++ nu; strip(line); switch(line[0]){ case '[': current = (section )malloc(sizeof(section)); list_insert(options, current); current->options = make_list(); current->type = line; break; case '\0': case '#': case ';': free(line); break; default: if(!read_option(line, current->options)){ fprintf(stderr, "Config file error line %d, could parse: %s\n", nu, line); free(line); } break; } } fclose(file); return options; } void load_convolutional_weights(layer l, FILE fp) { int num = l.nweights; fread(l.biases, sizeof(float), l.n, fp); if (l.batch_normalize){ fread(l.scales, sizeof(float), l.n, fp); fread(l.rolling_mean, sizeof(float), l.n, fp); fread(l.rolling_variance, sizeof(float), l.n, fp); } fread(l.weights, sizeof(float), num, fp); } void load_weights_upto(network net, char filename, int start, int cutoff) { fprintf(stderr, "Loading weights from %s...", filename); fflush(stdout); FILE fp = fopen(filename, "rb"); if(!fp) file_error(filename); int major; int minor; int revision; fread(&major, sizeof(int), 1, fp); fread(&minor, sizeof(int), 1, fp); fread(&revision, sizeof(int), 1, fp); printf("major=%d;minor=%d;revision=%d\n",major,minor,revision);// 0 2 0 printf("if true ro false:%d\n",(major10 + minor) >= 2 && major < 1000 && minor < 1000); if ((major10 + minor) >= 2 && major < 1000 && minor < 1000){ //fread(net->seen, sizeof(size_t), 1, fp); fread(net->seen, sizeof(size_t), 1, fp); fread(net->seen, sizeof(size_t), 1, fp); }else { int iseen = 0; fread(&iseen, sizeof(int), 1, fp); net->seen = iseen; } //printf("sizeof(size_t)=%u\n",sizeof(size_t));// in my PC is 4 int i; for(i = start; i < net->n && i < cutoff; ++i){ layer l = net->layers[i]; if(l.type == CONVOLUTIONAL){ load_convolutional_weights(l, fp); } } fprintf(stderr, "Done!\n"); fclose(fp); } void load_weights(network net, char filename) { load_weights_upto(net, filename, 0, net->n); } /////////////////praser end /////////////////network begin load_args get_base_args(network net) { load_args args = {0}; args.w = net->w; args.h = net->h; args.size = net->w; args.min = net->min_crop; args.max = net->max_crop; args.angle = net->angle; args.aspect = net->aspect; args.exposure = net->exposure; args.center = net->center; args.saturation = net->saturation; args.hue = net->hue; return args; } network load_network(char cfg, char weights, int clear) { network net = parse_network_cfg(cfg); //if(weights && weights[0] != 0){ // load_weights(net, weights); //} if(clear) (net->seen) = 0; return net; } char get_layer_string(LAYER_TYPE a) { switch(a){ case CONVOLUTIONAL: return "convolutional"; case ACTIVE: return "activation"; case LOCAL: return "local"; case DECONVOLUTIONAL: return "deconvolutional"; case CONNECTED: return "connected"; case RNN: return "rnn"; case GRU: return "gru"; case LSTM: return "lstm"; case CRNN: return "crnn"; case MAXPOOL: return "maxpool"; case REORG: return "reorg"; case AVGPOOL: return "avgpool"; case SOFTMAX: return "softmax"; case DETECTION: return "detection"; case REGION: return "region"; case YOLO: return "yolo"; case DROPOUT: return "dropout"; case CROP: return "crop"; case COST: return "cost"; case ROUTE: return "route"; case SHORTCUT: return "shortcut"; case NORMALIZATION: return "normalization"; case BATCHNORM: return "batchnorm"; default: break; } return "none"; } network make_network(int n) { network net = (network )calloc(1, sizeof(network)); net->n = n; net->layers = (layer )calloc(net->n, sizeof(layer)); net->seen = (size_t )calloc(1, sizeof(size_t)); net->t = (int )calloc(1, sizeof(int)); net->cost = (float )calloc(1, sizeof(float)); return net; } void forward_network(network netp) { network net = netp; int i; for(i = 0; i < net.n; ++i){ net.index = i; layer l = net.layers[i]; l.forward(l, net); net.input = l.output; // printf("layer [%d]\n",i); } } void set_temp_network(network net, float t) { int i; for(i = 0; i < net->n; ++i){ net->layers[i].temperature = t; } } void set_batch_network(network net, int b) { net->batch = b; int i; for(i = 0; i < net->n; ++i){ net->layers[i].batch = b; } } float network_predict(network net, float input) { network orig = net; net->input = input; net->truth = 0; net->train = 0; net->delta = 0; forward_network(net); float out = net->output; net = orig; return out; } int yolo_num_detections(layer l, float thresh) { int i, n; int count = 0; for (i = 0; i < l.wl.h; ++i){ for(n = 0; n < l.n; ++n){ int obj_index = entry_index(l, 0, nl.wl.h + i, 4); if(l.output[obj_index] > thresh){ ++count; } } } return count; } int num_detections(network net, float thresh) { int i; int s = 0; for(i = 0; i < net->n; ++i){ layer l = net->layers[i]; if(l.type == YOLO){ s += yolo_num_detections(l, thresh); } if(l.type == DETECTION \|\| l.type == REGION){ s += l.wl.hl.n; } } return s; } detection make_network_boxes(network net, float thresh, int num) { layer l = net->layers[net->n - 1]; int i; int nboxes = num_detections(net, thresh); //printf("num_detections nboxes = %d\n",nboxes); if(num) num = nboxes; detection dets = (detection )calloc(nboxes, sizeof(detection)); for(i = 0; i < nboxes; ++i){ dets[i].prob = (float )calloc(l.classes, sizeof(float)); } return dets; } box get_yolo_box(float x, float biases, int n, int index, int i, int j, int lw, int lh, int w, int h, int stride) { box b; b.x = (i + x[index + 0stride]) / lw; b.y = (j + x[index + 1stride]) / lh; b.w = exp(x[index + 2stride]) biases[2n] / w; b.h = exp(x[index + 3stride]) * biases[2n+1] / h; return b; } void correct_yolo_boxes(detection dets, int n, int w, int h, int netw, int neth, int relative) { int i; int new_w=0; int new_h=0; if (((float)netw/w) < ((float)neth/h)) { new_w = netw; new_h = (h * netw)/w; } else { new_h = neth; new_w = (w * neth)/h; } for (i = 0; i < n; ++i){ box b = dets[i].bbox; b.x = (b.x - (netw - new_w)/2./netw) / ((float)new_w/netw); b.y = (b.y - (neth - new_h)/2./neth) / ((float)new_h/neth); b.w = (float)netw/new_w; b.h = (float)neth/new_h; if(!relative){ b.x = w; b.w = w; b.y = h; b.h = h; } dets[i].bbox = b; } } int get_yolo_detections(layer l, int w, int h, int netw, int neth, float thresh, int map, int relative, detection dets) { int i,j,n; float predictions = l.output; // if (l.batch == 2) avg_flipped_yolo(l); int count = 0; for (i = 0; i < l.wl.h; ++i){ int row = i / l.w; int col = i % l.w; for(n = 0; n < l.n; ++n){ int obj_index = entry_index(l, 0, nl.wl.h + i, 4); float objectness = predictions[obj_index]; if(objectness <= thresh) continue; int box_index = entry_index(l, 0, nl.wl.h + i, 0); dets[count].bbox = get_yolo_box(predictions, l.biases, l.mask[n], box_index, col, row, l.w, l.h, netw, neth, l.wl.h); dets[count].objectness = objectness; dets[count].classes = l.classes; for(j = 0; j < l.classes; ++j){ int class_index = entry_index(l, 0, nl.wl.h + i, 4 + 1 + j); float prob = objectnesspredictions[class_index]; dets[count].prob[j] = (prob > thresh) ? prob : 0; } ++count; } } correct_yolo_boxes(dets, count, w, h, netw, neth, relative); return count; } box get_region_box(float x, float biases, int n, int index, int i, int j, int w, int h, int stride) { box b; b.x = (i + x[index + 0stride]) / w; b.y = (j + x[index + 1stride]) / h; b.w = exp(x[index + 2stride]) biases[2n] / w; b.h = exp(x[index + 3stride]) * biases[2n+1] / h; return b; } void correct_region_boxes(detection dets, int n, int w, int h, int netw, int neth, int relative) { int i; int new_w=0; int new_h=0; if (((float)netw/w) < ((float)neth/h)) { new_w = netw; new_h = (h * netw)/w; } else { new_h = neth; new_w = (w * neth)/h; } for (i = 0; i < n; ++i){ box b = dets[i].bbox; b.x = (b.x - (netw - new_w)/2./netw) / ((float)new_w/netw); b.y = (b.y - (neth - new_h)/2./neth) / ((float)new_h/neth); b.w = (float)netw/new_w; b.h = (float)neth/new_h; if(!relative){ b.x = w; b.w = w; b.y = h; b.h = h; } dets[i].bbox = b; } } void get_region_detections(layer l, int w, int h, int netw, int neth, float thresh, int map, float tree_thresh, int relative, detection dets) { int i,j,n,z; float predictions = l.output; if (l.batch == 2) { float flip = l.output + l.outputs; for (j = 0; j < l.h; ++j) { for (i = 0; i < l.w/2; ++i) { for (n = 0; n < l.n; ++n) { for(z = 0; z < l.classes + l.coords + 1; ++z){ int i1 = zl.wl.hl.n + nl.wl.h + jl.w + i; int i2 = zl.wl.hl.n + nl.wl.h + jl.w + (l.w - i - 1); float swap = flip[i1]; flip[i1] = flip[i2]; flip[i2] = swap; if(z == 0){ flip[i1] = -flip[i1]; flip[i2] = -flip[i2]; } } } } } for(i = 0; i < l.outputs; ++i){ l.output[i] = (l.output[i] + flip[i])/2.; } } for (i = 0; i < l.wl.h; ++i){ int row = i / l.w; int col = i % l.w; for(n = 0; n < l.n; ++n){ int index = nl.wl.h + i; for(j = 0; j < l.classes; ++j){ dets[index].prob[j] = 0; } int obj_index = entry_index(l, 0, nl.wl.h + i, l.coords); int box_index = entry_index(l, 0, nl.wl.h + i, 0); int mask_index = entry_index(l, 0, nl.wl.h + i, 4); float scale = l.background ? 1 : predictions[obj_index]; dets[index].bbox = get_region_box(predictions, l.biases, n, box_index, col, row, l.w, l.h, l.wl.h); dets[index].objectness = scale > thresh ? scale : 0; if(dets[index].mask){ for(j = 0; j < l.coords - 4; ++j){ dets[index].mask[j] = l.output[mask_index + jl.wl.h]; } } int class_index = entry_index(l, 0, nl.wl.h + i, l.coords + !l.background); if(dets[index].objectness){ for(j = 0; j < l.classes; ++j){ int class_index = entry_index(l, 0, nl.wl.h + i, l.coords + 1 + j); float prob = scalepredictions[class_index]; dets[index].prob[j] = (prob > thresh) ? prob : 0; } } } } correct_region_boxes(dets, l.wl.hl.n, w, h, netw, neth, relative); } void fill_network_boxes(network net, int w, int h, float thresh, float hier, int map, int relative, detection dets) { int j; for(j = 0; j < net->n; ++j){ layer l = net->layers[j]; if(l.type == YOLO){ int count = get_yolo_detections(l, w, h, net->w, net->h, thresh, map, relative, dets); dets += count; } if(l.type == REGION){ get_region_detections(l, w, h, net->w, net->h, thresh, map, hier, relative, dets); dets += l.wl.hl.n; } } } detection get_network_boxes(network net, int w, int h, float thresh, float hier, int map, int relative, int num) { detection dets = make_network_boxes(net, thresh, num); fill_network_boxes(net, w, h, thresh, hier, map, relative, dets); return dets; } void free_detections(detection dets, int n) { int i; for(i = 0; i < n; ++i){ free(dets[i].prob); if(dets[i].mask) free(dets[i].mask); } free(dets); } int network_width(network net){return net->w;} int network_height(network net){return net->h;} layer get_network_output_layer(network net) { int i; for(i = net->n - 1; i >= 0; --i){ if(net->layers[i].type != COST) break; } return net->layers[i]; } void free_network(network net) { int i; for(i = 0; i < net->n; ++i){ free_layer(net->layers[i]); } free(net->layers); if(net->input) free(net->input); if(net->truth) free(net->truth); free(net); } layer network_output_layer(network net) { int i; for(i = net->n - 1; i >= 0; --i){ if(net->layers[i].type != COST) break; } return net->layers[i]; } int network_inputs(network net) { return net->layers[0].inputs; } int network_outputs(network net) { return network_output_layer(net).outputs; } float network_output(network net) { return network_output_layer(net).output; } //////////////////network end //////////////////////box begin int nms_comparator(const void pa, const void pb) { detection a = (detection )pa; detection b = (detection )pb; float diff = 0; if(b.sort_class >= 0){ diff = a.prob[b.sort_class] - b.prob[b.sort_class]; } else { diff = a.objectness - b.objectness; } if(diff < 0) return 1; else if(diff > 0) return -1; return 0; } float overlap(float x1, float w1, float x2, float w2) { float l1 = x1 - w1/2; float l2 = x2 - w2/2; float left = l1 > l2 ? l1 : l2; float r1 = x1 + w1/2; float r2 = x2 + w2/2; float right = r1 < r2 ? r1 : r2; return right - left; } float box_intersection(box a, box b) { float w = overlap(a.x, a.w, b.x, b.w); float h = overlap(a.y, a.h, b.y, b.h); if(w < 0 \|\| h < 0) return 0; float area = wh; return area; } float box_union(box a, box b) { float i = box_intersection(a, b); float u = a.wa.h + b.wb.h - i; return u; } float box_iou(box a, box b) { return box_intersection(a, b)/box_union(a, b); } void do_nms_sort(detection dets, int total, int classes, float thresh) { int i, j, k; k = total-1; for(i = 0; i <= k; ++i){ if(dets[i].objectness == 0){ detection swap = dets[i]; dets[i] = dets[k]; dets[k] = swap; --k; --i; } } total = k+1; for(k = 0; k < classes; ++k){ for(i = 0; i < total; ++i){ dets[i].sort_class = k; } qsort(dets, total, sizeof(detection), nms_comparator); for(i = 0; i < total; ++i){ if(dets[i].prob[k] == 0) continue; box a = dets[i].bbox; for(j = i+1; j < total; ++j){ box b = dets[j].bbox; if (box_iou(a, b) > thresh){ dets[j].prob[k] = 0; } } } } } //////////////////////box end //////////////////////image begin float colors[6][3] = { {1,0,1}, {0,0,1},{0,1,1},{0,1,0},{1,1,0},{1,0,0} }; float get_color(int c, int x, int max) { float ratio = ((float)x/max)5; int i = floor(ratio); int j = ceil(ratio); ratio -= i; float r = (1-ratio) * colors[i][c] + ratiocolors[j][c]; //printf("%f\n", r); return r; } static float get_pixel_extend(image m, int x, int y, int c) { if(x < 0 \|\| x >= m.w \|\| y < 0 \|\| y >= m.h) return 0; / if(x < 0) x = 0; if(x >= m.w) x = m.w-1; if(y < 0) y = 0; if(y >= m.h) y = m.h-1; / if(c < 0 \|\| c >= m.c) return 0; return get_pixel(m, x, y, c); } void composite_image(image source, image dest, int dx, int dy) { int x,y,k; for(k = 0; k < source.c; ++k){ for(y = 0; y < source.h; ++y){ for(x = 0; x < source.w; ++x){ float val = get_pixel(source, x, y, k); float val2 = get_pixel_extend(dest, dx+x, dy+y, k); set_pixel(dest, dx+x, dy+y, k, val val2); } } } } image border_image(image a, int border) { image b = make_image(a.w + 2border, a.h + 2border, a.c); int x,y,k; for(k = 0; k < b.c; ++k){ for(y = 0; y < b.h; ++y){ for(x = 0; x < b.w; ++x){ float val = get_pixel_extend(a, x - border, y - border, k); if(x - border < 0 \|\| x - border >= a.w \|\| y - border < 0 \|\| y - border >= a.h) val = 1; set_pixel(b, x, y, k, val); } } } return b; } image copy_image(image p) { image copy = p; copy.data = (float )calloc(p.hp.wp.c, sizeof(float)); memcpy(copy.data, p.data, p.hp.wp.csizeof(float)); return copy; } image tile_images(image a, image b, int dx) { if(a.w == 0) return copy_image(b); image c = make_image(a.w + b.w + dx, (a.h > b.h) ? a.h : b.h, (a.c > b.c) ? a.c : b.c); fill_cpu(c.wc.hc.c, 1, c.data, 1); embed_image(a, c, 0, 0); composite_image(b, c, a.w + dx, 0); return c; } image get_label(image *characters, char string, int size) { size = size/10; if(size > 7) size = 7; image label = make_empty_image(0,0,0); while(string){ image l = characters[size][(int)string]; image n = tile_images(label, l, -size - 1 + (size+1)/2); free_image(label); label = n; ++string; } image b = border_image(label, label.h.25); free_image(label); return b; } void draw_label(image a, int r, int c, image label, const float rgb) { int w = label.w; int h = label.h; if (r - h >= 0) r = r - h; int i, j, k; for(j = 0; j < h && j + r < a.h; ++j){ for(i = 0; i < w && i + c < a.w; ++i){ for(k = 0; k < label.c; ++k){ float val = get_pixel(label, i, j, k); set_pixel(a, i+c, j+r, k, rgb[k] * val); } } } } void draw_box(image a, int x1, int y1, int x2, int y2, float r, float g, float b) { //normalize_image(a); int i; if(x1 < 0) x1 = 0; if(x1 >= a.w) x1 = a.w-1; if(x2 < 0) x2 = 0; if(x2 >= a.w) x2 = a.w-1; if(y1 < 0) y1 = 0; if(y1 >= a.h) y1 = a.h-1; if(y2 < 0) y2 = 0; if(y2 >= a.h) y2 = a.h-1; for(i = x1; i <= x2; ++i){ a.data[i + y1a.w + 0a.wa.h] = r; a.data[i + y2a.w + 0a.wa.h] = r; a.data[i + y1a.w + 1a.wa.h] = g; a.data[i + y2a.w + 1a.wa.h] = g; a.data[i + y1a.w + 2a.wa.h] = b; a.data[i + y2a.w + 2a.wa.h] = b; } for(i = y1; i <= y2; ++i){ a.data[x1 + ia.w + 0a.wa.h] = r; a.data[x2 + ia.w + 0a.wa.h] = r; a.data[x1 + ia.w + 1a.wa.h] = g; a.data[x2 + ia.w + 1a.wa.h] = g; a.data[x1 + ia.w + 2a.wa.h] = b; a.data[x2 + ia.w + 2a.wa.h] = b; } } void draw_box_width(image a, int x1, int y1, int x2, int y2, int w, float r, float g, float b) { int i; for(i = 0; i < w; ++i){ draw_box(a, x1+i, y1+i, x2-i, y2-i, r, g, b); } } image float_to_image(int w, int h, int c, float data) { image out = make_empty_image(w,h,c); out.data = data; return out; } image threshold_image(image im, float thresh) { int i; image t = make_image(im.w, im.h, im.c); for(i = 0; i < im.wim.him.c; ++i){ t.data[i] = im.data[i]>thresh ? 1 : 0; } return t; } void draw_detections(image im, detection dets, int num, float thresh, char names, image alphabet, int classes) { int i,j; for(i = 0; i < num; ++i){ char labelstr[4096] = {0}; int class_t = -1; for(j = 0; j < classes; ++j){ if (dets[i].prob[j] > thresh){ if (class_t < 0) { strcat(labelstr, names[j]); class_t = j; } else { strcat(labelstr, ", "); strcat(labelstr, names[j]); } printf("%s: %.0f%%\n", names[j], dets[i].prob[j]100); } } if(class_t >= 0){ int width = im.h .006; //printf("%d %s: %.0f%%\n", i, names[class], prob100); int offset = class_t123457 % classes; float red = get_color(2,offset,classes); float green = get_color(1,offset,classes); float blue = get_color(0,offset,classes); float rgb[3]; //width = prob20+2; rgb[0] = red; rgb[1] = green; rgb[2] = blue; box b = dets[i].bbox; //printf("%f %f %f %f\n", b.x, b.y, b.w, b.h); int left = (b.x-b.w/2.)im.w; int right = (b.x+b.w/2.)im.w; int top = (b.y-b.h/2.)im.h; int bot = (b.y+b.h/2.)im.h; if(left < 0) left = 0; if(right > im.w-1) right = im.w-1; if(top < 0) top = 0; if(bot > im.h-1) bot = im.h-1; draw_box_width(im, left, top, right, bot, width, red, green, blue); if (alphabet) { image label = get_label(alphabet, labelstr, (im.h.03)); draw_label(im, top + width, left, label, rgb); free_image(label); } if (dets[i].mask){ image mask = float_to_image(14, 14, 1, dets[i].mask); image resized_mask = resize_image(mask, b.wim.w, b.him.h); image tmask = threshold_image(resized_mask, .5); embed_image(tmask, im, left, top); free_image(mask); free_image(resized_mask); free_image(tmask); } } } } //////////////////////image end ///////////////////////////////////////////////////////////////////////20181108 reorg WeightQ BetaQ ok InputQ ok start #define MAX(x,y) ((x)>(y)?(x):(y)) #define MIN(x,y) ((x)<(y)?(x):(y)) #define S 2 #define K 3 #define Tn 4 #define Tm 32 #define Tr 26 #define Tc 26 #define OnChipIB_Width ((Tc-1)S+K) #define OnChipIB_Height ((Tr-1)S+K) #define MAX_BETA_LENGTH (1024) //////////////////////////////////////////////////T3 start void input_load(float input,float input_buffer[Tn][OnChipIB_Height][OnChipIB_Width],int r,int c,int n,int Kernel_stride,int Padding,int TRow,int TCol,int Input_w,int Input_h,int TN_MIN,int IHxIW,int LayerType) { int t1,t2,t3,t4; int xoffset; int yoffset; static float input_memcpy_buffer[TnOnChipIB_HeightOnChipIB_Width]; const int Coffset = cKernel_stride - Padding; const int Roffset = rKernel_stride - Padding; const int CurrentOffset = nIHxIW + RoffsetInput_w + Coffset; float pad_value = 0; if(LayerType==1) pad_value = -10241024; int input_mmcpy_offset = 0; for(t1 = 0;t1 < TN_MIN; t1++) for(t2 = 0;t2 < TRow; t2++) { memcpy((float )(input_memcpy_buffer + input_mmcpy_offset),(float )(input + CurrentOffset + t1IHxIW + t2Input_w),TColsizeof(float)); input_mmcpy_offset += TCol; } input_mmcpy_offset = 0; for(t1 = 0;t1 < Tn; t1++) for(t2 = 0;t2 < TRow; t2++) for(t3 = 0;t3 < TCol; t3++) { xoffset = Coffset + t3; yoffset = Roffset + t2; bool XEnable = (xoffset >= 0)&&(xoffset < Input_w); bool YEnable = (yoffset >= 0)&&(yoffset < Input_h); bool PaddingEnable = XEnable&&YEnable; if(PaddingEnable&&(t1 < TN_MIN)) input_buffer[t1][t2][t3] = input_memcpy_buffer[input_mmcpy_offset]; else input_buffer[t1][t2][t3] = pad_value; input_mmcpy_offset++; } } void weight_load_reorg(int Weight,float weight_buffer[Tm][Tn][K][K],bool weight_load_enable,int m,int n,int IFM_numxKxK,int KxK,int Kernel_size,int TM_MIN,int TN_MIN,const int WeightQ) { int t1,t2,t3,t4; static int weight_memcpy_buffer[TmTnKK/2]; static int Woffset; if(!weight_load_enable) return; if(m==0&&n==0) Woffset = 0; if((TM_MINTN_MINKxK)%2) printf("weight % error\n"); memcpy(weight_memcpy_buffer,(int )(Weight + Woffset),TM_MINTN_MINKxK/2sizeof(int)); Woffset += TM_MINTN_MINKxK/2; int weight_memcpy_offset = 0; int cnt = 0; short input_array[2]; float input_value; for(t3 = 0;t3 <Kernel_size; t3++) for(t4 = 0;t4 <Kernel_size; t4++) for(t1 = 0;t1 < Tm; t1++) for(t2 = 0;t2 < Tn; t2++) { bool Enable = (t1 < TM_MIN)&&(t2 < TN_MIN); if(Enable) { if(cnt==0) { input_array[0] = weight_memcpy_buffer[weight_memcpy_offset]; input_array[1] = weight_memcpy_buffer[weight_memcpy_offset] >> 16; weight_memcpy_offset++; } input_value = input_array[cnt]pow(2.0,-WeightQ); weight_buffer[t1][t2][t3][t4] = input_value; cnt++; if(cnt==2) cnt = 0; } else weight_buffer[t1][t2][t3][t4] = 0; } } void copy_input_weight(float input,int Weight,int InFM_num,int Input_w,int Input_h,int OutFM_num,int Kernel_size,int Kernel_stride,int r,int c,int m,int n, int TM_MIN,int TN,int TRow,int TCol,int Padding,float input_buffer[Tn][OnChipIB_Height][OnChipIB_Width],float weight_buffer[Tm][Tn][K][K],int TMP_N_next[1], bool enable,bool weight_load_enable,bool initialize,const int IHxIW,const int KxK,const int IFM_numxKxK,const int LayerType,const int WeightQ) { if(!enable) return ; const int TN_MIN = MIN(TN,InFM_num - n); TMP_N_next[0] = n; input_load(input, input_buffer, r, c, n, Kernel_stride, Padding, TRow, TCol, Input_w, Input_h, TN_MIN, IHxIW, LayerType); weight_load_reorg(Weight,weight_buffer,weight_load_enable,m,n,IFM_numxKxK,KxK,Kernel_size,TM_MIN,TN_MIN,WeightQ); } void copy_local_beta(float beta_buffer[MAX_BETA_LENGTH],float local_beta_buffer[MAX_BETA_LENGTH],const int TM_MIN,int m) { int offset; int tm; for(tm = 0,offset = m;tm < TM_MIN;tm++) { local_beta_buffer[tm] = beta_buffer[offset]; offset++; } } void nonlinear_leaky(float Input[Tm][Tr][Tc],const int TM_MIN,const int TR_MIN,const int TC_MIN,const bool IsNL) { int tr,tc,tm; if(!IsNL) return ; for(tm = 0;tm < TM_MIN;tm++) #pragma HLS LOOP_TRIPCOUNT min=1 max=1 for(tr = 0;tr < TR_MIN;tr++) #pragma HLS LOOP_TRIPCOUNT min=1 max=14 for(tc = 0;tc < TC_MIN;tc++) { #pragma HLS LOOP_TRIPCOUNT min=14 max=14 #pragma HLS PIPELINE float tmp = Input[tm][tr][tc]; if(tmp < 0) Input[tm][tr][tc] = tmp0.1; } } void compute(float input_buffer[Tn][OnChipIB_Height][OnChipIB_Width],float output_buffer[Tm][Tr][Tc], float weight_buffer[Tm][Tn][K][K],float beta_buffer[MAX_BETA_LENGTH],int TMP_N_next[1], const int Kernel_size,const int Kernel_stride,int TMP_M, const int TM_MIN,const int TR_MIN,const int TC_MIN,bool enable,const bool IsNL,const bool reluenable) { static float local_beta_buffer[Tm]; #pragma HLS ARRAY_PARTITION variable=local_beta_buffer complete dim=1 if(!enable) { copy_local_beta(beta_buffer,local_beta_buffer,TM_MIN,TMP_M); return; } int i,j,tr,tc,tm,tn; int n = TMP_N_next[0]; float partial_mul[Tm][Tn]; float partial_add[Tm]; for(i =0;i < Kernel_size; i++) #pragma HLS LOOP_TRIPCOUNT min=1 max=5 for(j = 0;j < Kernel_size; j++) #pragma HLS LOOP_TRIPCOUNT min=1 max=5 for(tr = 0;tr < TR_MIN;tr++) #pragma HLS LOOP_TRIPCOUNT min=14 max=14 for(tc = 0;tc < TC_MIN;tc++) { #pragma HLS LOOP_TRIPCOUNT min=14 max=14 #pragma HLS PIPELINE for(tm = 0;tm < Tm;tm++) { if(i==0&&j==0&&n==0) partial_add[tm] = local_beta_buffer[tm]; else partial_add[tm] = output_buffer[tm][tr][tc]; } for(tm = 0;tm < Tm;tm++) for(tn = 0;tn <Tn;tn++) { partial_mul[tm][tn] = weight_buffer[tm][tn][i][j]input_buffer[tn][Kernel_stridetr+i][Kernel_stridetc+j]; } for(tm = 0;tm < Tm;tm++) { float partial_sum = 0; for(tn = 0;tn <Tn;tn++) { partial_sum += partial_mul[tm][tn]; } output_buffer[tm][tr][tc] = partial_add[tm] + partial_sum; } } if(reluenable) nonlinear_leaky(output_buffer,TM_MIN,TR_MIN,TC_MIN,IsNL); } void write_back_output_reorg(float output_buffer[Tm][Tr][Tc],float Output,int r,int c,int m,const int Output_w,const int Output_h, const int TM_MIN,const int TR_MIN,const int TC_MIN,const int OHxOW,bool write_flag) { if(!write_flag) return; const int offset = mOHxOW + rOutput_w + c; int tr,tm; //for(tm = 0;tm < TM_MIN;tm++) // for(tr = 0;tr < TR_MIN;tr++) // for(tc = 0;tc < TC_MIN;tc++) // { // Output[tmOHxOW + trOutput_w + tc + offset] = output_buffer[tm][tr][tc]; // } for(tm = 0;tm < TM_MIN;tm++) for(tr = 0;tr < TR_MIN;tr++) { memcpy((float )(Output + tmOHxOW + trOutput_w + offset),output_buffer[tm][tr],TC_MINsizeof(float)); } } void pool_yolo2(float Input[Tn][OnChipIB_Height][OnChipIB_Width],float Output[Tm][Tr][Tc], const int Kernel_size,const int Kernel_stride, const int TM_MIN,const int TR_MIN,const int TC_MIN,bool enable) { if(!enable) return; int i,j,tr,tc,of; float tmp[Tn]; for(tr = 0;tr < TR_MIN;tr++) for(tc = 0;tc < TC_MIN;tc++) for(i =0;i < Kernel_size; i++) for(j = 0;j < Kernel_size; j++) { #pragma HLS PIPELINE for( of = 0; of < Tn; of++) { if(i==0&&j==0) tmp[of] = -10241024; if(Input[of][trKernel_stride+i][tcKernel_stride+j] > tmp[of]) tmp[of] = Input[of][trKernel_stride+i][tcKernel_stride+j]; if(i==1&&j==1) Output[of][tr][tc] = tmp[of]; } } } void reorg_yolo2(float Input[Tn][OnChipIB_Height][OnChipIB_Width],float Output[Tm][Tr][Tc], const int Kernel_size,const int Kernel_stride, const int TM_MIN,const int TR_MIN,const int TC_MIN,bool enable) { int x, y,kx,ky; unsigned char Yoffset; unsigned char Xoffset; if(!enable) return; for( y = 0; y < TR_MIN; y++) for( x = 0; x < TC_MIN; x++) for(ky= 0;ky < 2; ky++) for(kx = 0;kx < 2; kx++) { #pragma HLS PIPELINE Yoffset = (y << 1) + ky; Xoffset = (x << 1) + kx; int in_index = (ky << 1) + kx; Output[in_index][y][x] = Input[0][Yoffset][Xoffset]; } } void intra_pingpong_wrapper(float Input,int Weight, float output_buffer[Tm][Tr][Tc],float beta_buffer[MAX_BETA_LENGTH], float input_buffer0[Tn][OnChipIB_Height][OnChipIB_Width],float input_buffer1[Tn][OnChipIB_Height][OnChipIB_Width], int InFM_num,int Input_w,int Input_h,int OutFM_num,int Kernel_size,int Kernel_stride, int TMP_R,int TMP_C,int TMP_M,int m,int TM_MIN,int TR_MIN,int TC_MIN,int TN,int TRow,int TCol,int Padding, int IHxIW,int KxK,int IFM_numxKxK,int nLoops,bool IsNL,int LayerType,int TM,int TMP_X_next[1],int TX_MIN_next[1],bool pingpongx,bool input_flag,bool process_flag, int WeightQ) { static float weight_buffer0[Tm][Tn][K][K]; #pragma HLS ARRAY_PARTITION variable=weight_buffer0 complete dim=1 #pragma HLS ARRAY_PARTITION variable=weight_buffer0 complete dim=2 static float weight_buffer1[Tm][Tn][K][K]; #pragma HLS ARRAY_PARTITION variable=weight_buffer1 complete dim=1 #pragma HLS ARRAY_PARTITION variable=weight_buffer1 complete dim=2 static int NOP[1]; static int tmp_x; static int tmp_tx_min; if(LayerType==0) { if(!input_flag) return; TMP_X_next[0] = TMP_M;//consider by the inner-out loop TX_MIN_next[0] = TM_MIN;// like above bool pingpong = 0; int TMP_N_next0[1]; int TMP_N_next1[1]; int n; int TMP_N; for(TMP_N = 0,n = 0;n < nLoops+1; n++,TMP_N += TN) { if(pingpong == 1) { copy_input_weight(Input,Weight,InFM_num,Input_w,Input_h,OutFM_num,Kernel_size,Kernel_stride,TMP_R,TMP_C,TMP_M,TMP_N, TM_MIN,TN,TRow,TCol,Padding,input_buffer1,weight_buffer1,TMP_N_next1,n!=nLoops,1,(m==0)&&(n==0),IHxIW,KxK,IFM_numxKxK,LayerType,WeightQ); compute(input_buffer0,output_buffer,weight_buffer0,beta_buffer,TMP_N_next0,Kernel_size,Kernel_stride,TMP_M,TM_MIN,TR_MIN,TC_MIN,n!=0,IsNL,n==nLoops); pingpong = 0; }else { copy_input_weight(Input,Weight,InFM_num,Input_w,Input_h,OutFM_num,Kernel_size,Kernel_stride,TMP_R,TMP_C,TMP_M,TMP_N, TM_MIN,TN,TRow,TCol,Padding,input_buffer0,weight_buffer0,TMP_N_next0,n!=nLoops,1,(m==0)&&(n==0),IHxIW,KxK,IFM_numxKxK,LayerType,WeightQ); compute(input_buffer1,output_buffer,weight_buffer1,beta_buffer,TMP_N_next1,Kernel_size,Kernel_stride,TMP_M,TM_MIN,TR_MIN,TC_MIN,n!=0,IsNL,n==nLoops); pingpong = 1; } } } else if(LayerType==1) { if(pingpongx==0) { TMP_X_next[0] = tmp_x; TX_MIN_next[0] = tmp_tx_min; tmp_x = TMP_M; tmp_tx_min = TM_MIN; copy_input_weight(Input,Weight,InFM_num,Input_w,Input_h,OutFM_num,Kernel_size,Kernel_stride,TMP_R,TMP_C,TMP_M,TMP_M, TM_MIN,TM,TRow,TCol,0,input_buffer0,NULL,NOP,input_flag,0,0,IHxIW,KxK,IFM_numxKxK,LayerType,WeightQ); pool_yolo2(input_buffer1,output_buffer,Kernel_size,Kernel_stride,TX_MIN_next[0],TR_MIN,TC_MIN,process_flag); }else { TMP_X_next[0] = tmp_x; TX_MIN_next[0] = tmp_tx_min; tmp_x = TMP_M; tmp_tx_min = TM_MIN; copy_input_weight(Input,Weight,InFM_num,Input_w,Input_h,OutFM_num,Kernel_size,Kernel_stride,TMP_R,TMP_C,TMP_M,TMP_M, TM_MIN,TM,TRow,TCol,0,input_buffer1,NULL,NOP,input_flag,0,0,IHxIW,KxK,IFM_numxKxK,LayerType,WeightQ); pool_yolo2(input_buffer0,output_buffer,Kernel_size,Kernel_stride,TX_MIN_next[0],TR_MIN,TC_MIN,process_flag); } } else if(LayerType==2) { if(pingpongx==0) { TMP_X_next[0] = tmp_x; TX_MIN_next[0] = tmp_tx_min; tmp_x = TMP_M; tmp_tx_min = TM_MIN; copy_input_weight(Input,Weight,InFM_num,Input_w,Input_h,OutFM_num,Kernel_size,Kernel_stride,TMP_R,TMP_C,TMP_M,TMP_M, TM_MIN,TM,TRow,TCol,0,input_buffer0,NULL,NOP,input_flag,0,0,IHxIW,KxK,IFM_numxKxK,LayerType,WeightQ); reorg_yolo2(input_buffer1,output_buffer,Kernel_size,Kernel_stride,TX_MIN_next[0],TR_MIN,TC_MIN,process_flag); }else { TMP_X_next[0] = tmp_x; TX_MIN_next[0] = tmp_tx_min; tmp_x = TMP_M; tmp_tx_min = TM_MIN; copy_input_weight(Input,Weight,InFM_num,Input_w,Input_h,OutFM_num,Kernel_size,Kernel_stride,TMP_R,TMP_C,TMP_M,TMP_M, TM_MIN,TM,TRow,TCol,0,input_buffer1,NULL,NOP,input_flag,0,0,IHxIW,KxK,IFM_numxKxK,LayerType,WeightQ); reorg_yolo2(input_buffer0,output_buffer,Kernel_size,Kernel_stride,TX_MIN_next[0],TR_MIN,TC_MIN,process_flag); } } } void copy_beta(float beta_buffer[MAX_BETA_LENGTH],int Beta,const int OFM_NUM,const int BetaQ) { static int beta_tmp[MAX_BETA_LENGTH/2]; int NUM = (OFM_NUM+1)/2; memcpy(beta_tmp,(int )Beta,NUMsizeof(int)); int x; for(x = 0;x < NUM;x++) { beta_buffer[2x] = ((short)(beta_tmp[x]))pow(2.0,-BetaQ); beta_buffer[2x+1] = ((short)(beta_tmp[x]>>16))pow(2.0,-BetaQ); } } void YOLO2_FPGA(float Input,float Output,int Weight,int Beta,const int InFM_num,const int OutFM_num, const int Kernel_size,const int Kernel_stride, const int Input_w,const int Input_h,const int Padding,const bool IsNL,const bool IsBN, const int TM,const int TN,const int TR,const int TC, const int mLoops,const int nLoops,const int rLoops,const int cLoops,const int LayerType, const int WeightQ,const int BetaQ) { //const int output_w = (Input_w - Kernel_size + 2Padding)/Kernel_stride + 1 ; //const int output_h = (Input_h - Kernel_size + 2Padding)/Kernel_stride + 1 ; int output_w = (Input_w - Kernel_size + (Padding << 1))/Kernel_stride + 1 ; int output_h = (Input_h - Kernel_size + (Padding << 1))/Kernel_stride + 1 ; if(LayerType==1) { output_w = (Input_w - 1)/Kernel_stride + 1 ; output_h = (Input_h - 1)/Kernel_stride + 1 ; } const int OHxOW = output_houtput_w; const int TRow = (TR-1)Kernel_stride+Kernel_size; const int TCol = (TC-1)Kernel_stride+Kernel_size; const int IHxIW = Input_hInput_w; const int KxK = Kernel_sizeKernel_size; const int IFM_numxKxK = InFM_numKxK; const int mLoops_bound = LayerType ? (mLoops + 2): (mLoops + 1); static float input_buffer0[Tn][OnChipIB_Height][OnChipIB_Width]; #pragma HLS ARRAY_PARTITION variable=input_buffer0 complete dim=1 static float input_buffer1[Tn][OnChipIB_Height][OnChipIB_Width]; #pragma HLS ARRAY_PARTITION variable=input_buffer1 complete dim=1 static float output_buffer[Tm][Tr][Tc]; #pragma HLS ARRAY_PARTITION variable=output_buffer complete dim=1 static float output_buffer1[Tm][Tr][Tc]; #pragma HLS ARRAY_PARTITION variable=output_buffer1 complete dim=1 static float beta_buffer[MAX_BETA_LENGTH]; int r,c,m; /////////////////////////////////param int TMP_R,TMP_C,TMP_M; int TM_MIN,TR_MIN,TC_MIN; /////////////////////////////////////// int TMP_M_next0[1]; int TMP_M_next1[1]; int TM_MIN_next0[1]; int TM_MIN_next1[1]; bool pingpongm; if(LayerType==0) copy_beta(beta_buffer,Beta,OutFM_num,BetaQ); for(TMP_R = 0,r = 0; r < rLoops; r++, TMP_R += TR) { TR_MIN = MIN(TR,output_h -TMP_R); for(TMP_C = 0,c = 0; c < cLoops; c++,TMP_C += TC) { TC_MIN = MIN(TC,output_w -TMP_C); pingpongm = 0; for(TMP_M = 0, m = 0; m < mLoops_bound; m++,TMP_M += TM) { TM_MIN = MIN(TM,OutFM_num-TMP_M); bool MneZero = (m!=0); bool MneOne = (m!=1); bool MnemLoops = (m!=mLoops); bool MneMLoopsaddOne = (m!=(mLoops+1)); bool input_flag = LayerType ? MnemLoops&&MneMLoopsaddOne: MnemLoops; bool process_flag = LayerType ? MneZero&&MneMLoopsaddOne : MnemLoops; bool write_flag = LayerType ? MneZero&&MneOne : MneZero; if(pingpongm==0) { intra_pingpong_wrapper(Input,Weight,output_buffer1,beta_buffer,input_buffer0,input_buffer1, InFM_num, Input_w, Input_h, OutFM_num, Kernel_size, Kernel_stride, TMP_R, TMP_C, TMP_M, m, TM_MIN, TR_MIN, TC_MIN, TN, TRow, TCol, Padding,IHxIW,KxK,IFM_numxKxK,nLoops,IsNL,LayerType,TM, TMP_M_next1,TM_MIN_next1, pingpongm, input_flag, process_flag, WeightQ); write_back_output_reorg(output_buffer,Output,TMP_R,TMP_C,TMP_M_next0[0],output_w,output_h,TM_MIN_next0[0],TR_MIN,TC_MIN,OHxOW,write_flag); pingpongm = 1; }else { intra_pingpong_wrapper(Input,Weight,output_buffer,beta_buffer,input_buffer0,input_buffer1, InFM_num, Input_w, Input_h, OutFM_num, Kernel_size, Kernel_stride, TMP_R, TMP_C, TMP_M, m, TM_MIN, TR_MIN, TC_MIN, TN, TRow, TCol, Padding,IHxIW,KxK,IFM_numxKxK,nLoops,IsNL,LayerType,TM, TMP_M_next0,TM_MIN_next0, pingpongm, input_flag, process_flag, WeightQ); write_back_output_reorg(output_buffer1,Output,TMP_R,TMP_C,TMP_M_next1[0],output_w,output_h,TM_MIN_next1[0],TR_MIN,TC_MIN,OHxOW,write_flag); pingpongm = 0; } } } } } #define MIN_VALUE (-102410241024) #define MAX_VALUE (102410241024) int quantize(float in,float out,int offset,int layer_num,float ap16_range,int maxQ_array) { int i; int offset_index = 0; int woffset = 0; for(i=0;i<layer_num;i++) { if(offset[offset_index]==0) return i; printf("Layer %2d;weight num=%12d ",i,offset[offset_index]); int j; float min,max; min = MAX_VALUE; max = MIN_VALUE; for(j=0;j<offset[offset_index];j++) { float tmp_in_float = in[woffset+j]; if(tmp_in_float<min) min = tmp_in_float; if(tmp_in_float>max) max = tmp_in_float; } printf("float min=%.7lf,max=%.7lf ",min,max);//find float min max int k; int maxQ = -1; for(k=0;k<16;k++)//find maxQ { if(min>ap16_range[2k]&&max<ap16_range[2k+1]) { maxQ = k; } else if(k==0) { printf("beyond Q0 min=%.7lf,max=%.7lf ",min,max); break; } } printf("maxQ=%d ",maxQ); maxQ_array[i] = maxQ; double max_error,min_error,sum_error; sum_error = 0; max_error = MIN_VALUE; min_error = MAX_VALUE; for(j=0;j<offset[offset_index];j++) { float tmp_in_float = in[woffset+j]; short tmp_fixed = (short)(tmp_in_floatpow(2.0,maxQ)); float tmp_out_float = (float)tmp_fixedpow(2.0,-maxQ); double error = (tmp_out_float - tmp_in_float)(tmp_out_float - tmp_in_float); error = sqrt(error); sum_error += error; if(error<min_error) min_error = error; if(error>max_error) max_error = error; out[woffset+j] = tmp_out_float; } printf("sum2_error = %.7lf,min_error=%.7lf,max_error=%.7lf",sum_error,min_error,max_error); printf("\n"); woffset += offset[offset_index]; offset_index++; } return 0; } void yolov2_hls_ps(network net, float input) { int x; network orig = net; net->input = input; int weight_offset[32] = {864, 18432, 73728, 8192, 73728, 294912, 32768, 294912, 1179648, 131072, 1179648, 131072, 1179648, 4718592, 524288, 4718592, 524288, 4718592, 9437184, 9437184, 32768, 11796480, 435200, 0, 0, 0, 0, 0, 0, 0, 0, 0}; int beta_offset[32] = {32, 64, 128, 64, 128, 256, 128, 256, 512, 256, 512, 256, 512, 1024, 512, 1024, 512, 1024, 1024, 1024, 64, 1024, 425, 0, 0, 0, 0, 0, 0, 0, 0, 0}; int offset_index = 0; int Weight_buf = (int )calloc(203767168/4/2,sizeof(int)); int Beta_buf = (int )calloc((43044+4)/4/2,sizeof(int)); FILE fp_w = fopen("weightsv2_comb_reorg_ap16.bin", "rb"); if(!fp_w) file_error("weightsv2_comb_reorg_ap16.bin"); FILE fp_b = fopen("biasv2_comb_ap16.bin", "rb"); if(!fp_b) file_error("biasv2_comb_ap16.bin"); fread(Weight_buf, sizeof(int), 203767168/4/2, fp_w); fread(Beta_buf, sizeof(int), (43044+4)/4/2, fp_b); fclose(fp_w); fclose(fp_b); #define QNUM 23 short ap16_min = 0x8000; short ap16_max = 0x7fff; printf("ap16_min = %d \nap16_max = %d\n",ap16_min,ap16_max); float ap16_range[162]; for(x=0;x<16;x++) { printf("Q%2d:",x); ap16_range[2x] = (float)ap16_minpow((float)2,-x);//min ap16_range[2x+1] = (float)ap16_maxpow((float)2,-x);//max printf("min=%.7lf,max=%.7lf\n",ap16_range[2x],ap16_range[2x+1]); } int maxQarray[QNUM+1]; int weightQ[QNUM]; int betaQ[QNUM]; FILE Qin; Qin = fopen("weightsv2_comb_reorg_ap16_maxQ_23.bin","rb"); if(!Qin) file_error("Qin error 2\n"); fread(weightQ,sizeof(int),QNUM,Qin); fclose(Qin); for(x=0;x<QNUM;x++) printf("[%2d weightQ]=%2d\n",x,weightQ[x]); Qin = fopen("biasv2_comb_ap16_maxQ_23.bin","rb"); if(!Qin) file_error("Qin error 4\n"); fread(betaQ,sizeof(int),QNUM,Qin); fclose(Qin); for(x=0;x<QNUM;x++) printf("[%2d betaQ]=%2d\n",x,betaQ[x]); #define MEM_LEN (41641632+20820832) float Memory_buf = (float)calloc(MEM_LEN+1024+1024,sizeof(float)); float Memory_top = Memory_buf+1024; float Memory_bottom = Memory_top + MEM_LEN; //memcpy(Memory_top,input,4164163sizeof(float));//416x416x3 input_pic for(x=0;x<4164163;x++)//1st Layer input Q14 { Memory_top[x] = ((short)(input[x]pow(2.0,14)))pow(2.0,-14); } float inout_fixed_buf = (float )calloc(sizeof(float),41641632); maxQarray[0] = 14;//1st layer input Q14 float in_ptr[32]; float* out_ptr[32]; #define ROUTE16_LEN (2626512) #define CONV27_LEN (1313256) #define CONV24_LEN (13131024) for(x=0;x<18;x++) { if(x%2==0) { in_ptr[x] = Memory_top; out_ptr[x] = Memory_bottom - net->layers[x].outputs ; } else { in_ptr[x] = out_ptr[x-1]; out_ptr[x] = Memory_top; } } for(x=18;x<25;x++) { if(x%2==0) { in_ptr[x] = Memory_top; out_ptr[x] = Memory_bottom - ROUTE16_LEN - net->layers[x].outputs; }else { in_ptr[x] = out_ptr[x-1]; out_ptr[x] = Memory_top; } } in_ptr[26] = Memory_bottom - ROUTE16_LEN; out_ptr[26] = Memory_top; in_ptr[27] = Memory_top; out_ptr[27] = Memory_bottom - ROUTE16_LEN - CONV24_LEN - CONV27_LEN; in_ptr[29] = out_ptr[27]; out_ptr[29] = Memory_top; in_ptr[30] = Memory_top; out_ptr[30] = Memory_bottom - net->layers[30].outputs; in_ptr[31] = out_ptr[30]; network netp = net; int i; int woffset = 0; int aoffset = 0; int boffset = 0; int TR,TC,TM,TN; int output_w,output_h; int rLoops,cLoops,mLoops,nLoops; double sum_gop = 0.0; for(i = 0; i < netp.n; ++i) { netp.index = i; layer l = netp.layers[i]; printf("Layer[%2d]: ",i); switch(l.type) { case CONVOLUTIONAL: printf("outputMemory:%8d;BN=%d;Activation=%d;conv %5d %2d x%2d /%2d %4d x%4d x%4d -> %4d x%4d x%4d %5.3f BFLOPs\n",l.outputs,l.batch_normalize,l.activation, l.n, l.size, l.size, l.stride, l.w, l.h, l.c, l.out_w, l.out_h, l.out_c, (2.0 l.n * l.sizel.sizel.c/l.groups * l.out_hl.out_w)/1000000000.); sum_gop += (2.0 l.n * l.sizel.sizel.c/l.groups * l.out_hl.out_w)/1000000000.; output_w = (l.w - l.size + 2l.pad)/l.stride + 1 ; output_h = (l.h - l.size + 2l.pad)/l.stride + 1 ; TR = MIN(((OnChipIB_Height-l.size)/l.stride+1),Tr);//keep Kernel_stride>=1 TR = MIN(output_h,TR); TC = MIN(((OnChipIB_Width-l.size)/l.stride+1),Tc); TC = MIN(output_w,TC); TM = MIN(l.n,Tm); TN = MIN(l.c,Tn); rLoops = (int)ceil(((float)output_h)/TR); cLoops = (int)ceil(((float)output_w)/TC); mLoops = (int)ceil(((float)l.n)/TM); nLoops = (int)ceil(((float)l.c)/TN); YOLO2_FPGA(in_ptr[i],out_ptr[i],Weight_buf+woffset/2,Beta_buf+boffset/2, l.c,l.n,l.size, l.stride,l.w,l.h,l.pad,l.activation==LEAKY?1:0,l.batch_normalize?1:0, TM,TN,TR,TC, mLoops,nLoops,rLoops,cLoops,0, weightQ[offset_index],betaQ[offset_index]); quantize(out_ptr[i],inout_fixed_buf,&l.outputs, 1,ap16_range,&maxQarray[offset_index+1]); memcpy(out_ptr[i],inout_fixed_buf,l.outputssizeof(float)); printf("TR=%d,TC=%d,TM=%d,TN=%d,rLoops=%d,cLoops=%d,mLoops=%d,nLoops=%d\n",TR,TC,TM,TN,rLoops,cLoops,mLoops,nLoops); woffset += weight_offset[offset_index]; boffset += beta_offset[offset_index]; offset_index++; break; case MAXPOOL: printf("outputMemory:%8d;max %d x %d / %d %4d x%4d x%4d -> %4d x%4d x%4d\n",l.outputs, l.size, l.size, l.stride, l.w, l.h, l.c, l.out_w, l.out_h, l.out_c); //output_w = (l.w - l.size)/l.stride + 1 ; //output_h = (l.h - l.size)/l.stride + 1 ; output_w = l.out_h; output_h = l.out_w; TR = MIN(((OnChipIB_Height-l.size)/l.stride+1),Tr);//keep Kernel_stride>=1 TC = MIN(((OnChipIB_Width-l.size)/l.stride+1),Tc); TR = MIN(output_h,TR); TC = MIN(output_w,TC); TM = MIN(Tm,Tn); TM = MIN(l.c,TM); rLoops = (int)ceil(((float)output_h)/TR); cLoops = (int)ceil(((float)output_w)/TC); mLoops = (int)ceil(((float)l.c)/TM); YOLO2_FPGA(in_ptr[i],out_ptr[i],NULL,NULL,l.c,l.c, l.size,l.stride,l.w,l.h,l.pad,0,0,TM,0,TR,TC,mLoops,0,rLoops,cLoops,1, 0,0); break; case REORG: printf("outputMemory:%8d;reorg /%2d %4d x%4d x%4d -> %4d x%4d x%4d\n",l.outputs, l.stride, l.w, l.h, l.c, l.out_w, l.out_h, l.out_c); output_w = 26; output_h = 3213; TR = MIN(((OnChipIB_Height-l.stride)/l.stride+1),Tr);//keep Kernel_stride>=1 TR = MIN(output_h,TR); TC = MIN(((OnChipIB_Width-l.stride)/l.stride+1),Tc); TC = MIN(output_w,TC); TM = 4; rLoops = (int)ceil(((float)output_h)/TR); cLoops = (int)ceil(((float)output_w)/TC); mLoops = 1; YOLO2_FPGA(in_ptr[i],out_ptr[i],NULL,NULL,1,4, l.stride,l.stride,52,3226,0,0,0,TM,0,TR,TC,mLoops,0,rLoops,cLoops,2, 0,0); break; case ROUTE: printf("outputMemory:%8d;route ",l.outputs); int j; for(j = 0; j < l.n; ++j){ printf(" %d", l.input_layers[j]); } printf("\n"); break; case REGION: printf("outputMemory:%8d;Detection\n",l.outputs); netp.input = in_ptr[i]; forward_region_layer(l,netp); break; } netp.input = l.output; } printf("SUM_GOP=%g\n",sum_gop); net = orig; for(i=0;i<QNUM+1;i++) { printf("[%2d layer input maxQ]=%2d\n",i,maxQarray[i]); } FILE fout; char layer_num_string[256]; char s[256]; sprintf(s,"yolov2_ap16_inout_maxQ_%s.bin",itoa(QNUM+1,layer_num_string,10)); printf("%s\n",s); fout = fopen(s,"wb"); if(!fout) printf("fopen %s error\n",s); fwrite(maxQarray,sizeof(int), QNUM+1,fout); fclose(fout); free(Memory_buf); free(Weight_buf); free(Beta_buf); } ///////////////////////////////////////////////////////////////////////20181108 reorg WeightQ BetaQ ok InputQ ok end #endif
GB_binop__bshift_int8.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__bshift_int8) // A.B function (eWiseMult): GB (_AemultB_01__bshift_int8) // A.B function (eWiseMult): GB (_AemultB_02__bshift_int8) // A.B function (eWiseMult): GB (_AemultB_03__bshift_int8) // A.B function (eWiseMult): GB (_AemultB_bitmap__bshift_int8) // AD function (colscale): GB ((none)) // DA function (rowscale): GB ((none)) // C+=B function (dense accum): GB (_Cdense_accumB__bshift_int8) // C+=b function (dense accum): GB (_Cdense_accumb__bshift_int8) // C+=A+B function (dense ewise3): GB ((none)) // C=A+B function (dense ewise3): GB (_Cdense_ewise3_noaccum__bshift_int8) // C=scalar+B GB (_bind1st__bshift_int8) // C=scalar+B' GB (_bind1st_tran__bshift_int8) // C=A+scalar GB (_bind2nd__bshift_int8) // C=A'+scalar GB (_bind2nd_tran__bshift_int8) // C type: int8_t // A type: int8_t // B,b type: int8_t // BinaryOp: cij = GB_bitshift_int8 (aij, bij) #define GB_ATYPE \ int8_t #define GB_BTYPE \ int8_t #define GB_CTYPE \ int8_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) \ int8_t aij = GBX (Ax, pA, A_iso) // bij = Bx [pB] #define GB_GETB(bij,Bx,pB,B_iso) \ int8_t bij = GBX (Bx, pB, B_iso) // declare scalar of the same type as C #define GB_CTYPE_SCALAR(t) \ int8_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_bitshift_int8 (x, y) ; // true if the binop must be flipped #define GB_BINOP_FLIP \ 1 // 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_BSHIFT \|\| GxB_NO_INT8 \|\| GxB_NO_BSHIFT_INT8) //------------------------------------------------------------------------------ // 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 //------------------------------------------------------------------------------ GrB_Info GB (_Cdense_ewise3_noaccum__bshift_int8) ( 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__bshift_int8) ( 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__bshift_int8) ( 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 int8_t int8_t bwork = (((int8_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 //------------------------------------------------------------------------------ #if 0 GrB_Info GB ((none)) ( 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 int8_t restrict Cx = (int8_t ) C->x ; #include "GB_AxB_colscale_template.c" return (GrB_SUCCESS) ; #endif } #endif //------------------------------------------------------------------------------ // C = DB, row scale with diagonal D matrix //------------------------------------------------------------------------------ #if 0 GrB_Info GB ((none)) ( 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 int8_t restrict Cx = (int8_t ) C->x ; #include "GB_AxB_rowscale_template.c" return (GrB_SUCCESS) ; #endif } #endif //------------------------------------------------------------------------------ // eWiseAdd: C = A+B or C<M> = A+B //------------------------------------------------------------------------------ GrB_Info GB (_AaddB__bshift_int8) ( 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__bshift_int8) ( 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__bshift_int8) ( 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__bshift_int8) ( 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__bshift_int8) ( 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__bshift_int8) ( 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 int8_t Cx = (int8_t ) Cx_output ; int8_t x = (((int8_t ) x_input)) ; int8_t Bx = (int8_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 ; int8_t bij = GBX (Bx, p, false) ; Cx [p] = GB_bitshift_int8 (x, bij) ; } return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // Cx = op (Ax,y): apply a binary operator to a matrix with scalar bind2nd //------------------------------------------------------------------------------ GrB_Info GB (_bind2nd__bshift_int8) ( 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 ; int8_t Cx = (int8_t ) Cx_output ; int8_t Ax = (int8_t ) Ax_input ; int8_t y = (((int8_t ) y_input)) ; #pragma omp parallel for num_threads(nthreads) schedule(static) for (p = 0 ; p < anz ; p++) { if (!GBB (Ab, p)) continue ; int8_t aij = GBX (Ax, p, false) ; Cx [p] = GB_bitshift_int8 (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) \ { \ int8_t aij = GBX (Ax, pA, false) ; \ Cx [pC] = GB_bitshift_int8 (x, aij) ; \ } GrB_Info GB (_bind1st_tran__bshift_int8) ( 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 \ int8_t #if GB_DISABLE return (GrB_NO_VALUE) ; #else int8_t x = (((const int8_t ) x_input)) ; #include "GB_unop_transpose.c" return (GrB_SUCCESS) ; #endif #undef GB_ATYPE #define GB_ATYPE \ int8_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) \ { \ int8_t aij = GBX (Ax, pA, false) ; \ Cx [pC] = GB_bitshift_int8 (aij, y) ; \ } GrB_Info GB (_bind2nd_tran__bshift_int8) ( 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 int8_t y = (((const int8_t ) y_input)) ; #include "GB_unop_transpose.c" return (GrB_SUCCESS) ; #endif } #endif
reconstruction.h	/* Multi-view Image Restoration "Multi-view Image Restoration From Plenoptic Raw Images" Shan Xu, Zhi-Liang Zhou and Nicholas Devaney In Asian Conference on Computer Vision 2014 Emerging Topics In Image Restoration and Enhancement workshop Author: Shan Xu <xushan2011@gmail.com> Copyright (C) 2014-2018 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. 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. / #ifndef _RECONSTRUCTION #define _RECONSTRUCTION #include <opencv2/opencv.hpp> #include "config.h" #include "misc.h" using namespace std; using namespace cv; unsigned short bilinear(unsigned short data, float index_y, float index_x, int W){ float value; float cof[4]; float a,b,c,d; int y = int(index_y); int x = int(index_x); int base = yW+x; a = data[base]; b = data[base+1]; c = data[base+W]; d = data[base+W+1]; cof[0]=(1-(index_y-y))(1-(index_x-x)); cof[1]=(1-(index_y-y))(index_x-x); cof[2]= (index_y-y)(1-(index_x-x)); cof[3]= (index_y-y)(index_x-x); value= (cof[0]a+cof[1]b+cof[2]c+cof[3]d); return (unsigned short) value; } bool grad_difference (unsigned short img, size_t j, size_t i, int WHST, size_t IMG_W, size_t T,size_t S, int m, int n){ int ii = ((j%2)==0) ? (i-1)/2 : i/2; int c = ((j%2)==0) ? 2 : 0; //ugly implementation float grad_x_max=0; float grad_y_max=0; for (int k=0; k<3; k++){ float grad_x = abs( img[kWHST+(jT+m)IMG_WS+iiS+n]- img[kWHST+(jT+m)IMG_WS+(ii-1+c)S+n]); if (grad_x>grad_x_max) grad_x_max = grad_x; float grad_y = abs( img[kWHST+((j-1)T+m)IMG_WS+(ii)S+n]- img[kWHST+((j+1)T+m)IMG_WS+(ii)S+n]); if (grad_y>grad_y_max) grad_y_max = grad_y; } bool value = ((4grad_y_max < grad_x_max)?true:false); return value; } void devig_simple(Mat raw, Mat raw_ref, Mat& rawc){ unsigned short rawc_ptr = (unsigned short) rawc.data; Mat img, img2; raw_ref.convertTo(img, CV_32F); raw.convertTo(img2, CV_32F); Scalar mean,stddev; //float min= int(percentage2value ((float) img.data, img.total(), 0.001));//<<endl; //float max= int(percentage2value ((float) img.data, img.total(), 0.999));//<<endl; clamp_normalize_mat( (float) img.data, img.total(), 4095.0); meanStdDev(img,mean,stddev,cv::Mat()); //float mean50= percentage2value ((float) img.data, img.total(), 0.50);//<<endl; gen_vig_mat((float) img.data, img.total(), mean.val[0]); devig((float) img2.data, (float) img.data, img.total()); double min, max; minMaxLoc(img2, &min, &max); gamma(rawc_ptr, (float) img2.data, 4095, 0.50, img2.total()); } void decode(Mat img_colour, Mat& multiview, GRID grid, PARA para){ size_t IMG_W = para.ML_W2; //final image is 2 times larger due to hexgonal interpolation size_t IMG_H = para.ML_H; size_t ML_W = para.ML_W; size_t ML_H = para.ML_H; size_t S = para.S; size_t T = para.T; int WHST = IMG_WIMG_HST; unsigned short lf_buf = new unsigned short[3WHST]; unsigned short multiview_buf = new unsigned short[3WHST]; multiview = Mat::zeros(IMG_HT, IMG_WS, CV_16UC3); Mat bgr[3]; //destination array split(img_colour,bgr);//split source //4D array registration #pragma omp parallel for for (size_t j=0; j<ML_H; j++){ for (size_t i=0; i<ML_W; i++){ float index_y,index_x; if (grid.pt_dst2.size()>0){ index_y= grid.pt_dst2[jML_W+i].y; //_dst2 index_x= grid.pt_dst2[jML_W+i].x; } else{ index_y= grid.pt_dst1[jML_W+i].y; //pt2 index_x= grid.pt_dst1[jML_W+i].x; } int ix = int (index_x); int iy = int (index_y); Mat subimg; for (int k=0; k<3; k++){ resize(bgr[k](Rect(ix-5,iy-5,11,11)),subimg,Size(),4,4, INTER_CUBIC); //cout<<subimg<<endl; int idx_new = 22+int(4(index_x-ix)); int idy_new = 22+int(4(index_y-iy)); for (int m=-4; m<5; m++) for (int n=-4; n<5; n++){ int temp_index = (jT+(m+4))ML_WS + iS + (n+4); lf_buf[temp_index+ kWHST/2] = subimg.at<unsigned short>(idy_new+4m, idx_new+4n); } } } } bool grad_h_v; //cout<<"=============================================="<<endl; for (size_t j=1; j<(IMG_H-1); j++){ for (size_t i=1; i<(IMG_W-1); i++){ if ((j%2)==0){ // o x o x o x if ((i%2)==1){ // interpolate for (size_t m=0; m<T; m++){ for (size_t n=0; n<S; n++){ grad_h_v= grad_difference (lf_buf, j, i, WHST/2, ML_W, T, S, m, n); for (size_t k=0; k<3; k++){ multiview_buf[kWHST+(jT+m)IMG_WS+iS+n] = grad_h_v? (lf_buf[kWHST/2+((j-1)T+m)ML_WS+(i-1)/2S+n] +lf_buf[kWHST/2+((j+1)T+m)ML_WS+(i-1)/2S+n])/2: ( lf_buf[kWHST/2+(jT+m)ML_WS+(i-1)/2S+n] +lf_buf[kWHST/2+(jT+m)ML_WS+(i+1)/2S+n])/2; } } } } else{ for (size_t m=0; m<T; m++){ for (size_t n=0; n<S; n++){ for (size_t k=0; k<3; k++){ multiview_buf[kWHST+(jT+m)IMG_WS+iS+n] = lf_buf[kWHST/2+(jT+m)ML_WS+(i/2)S+n]; } } } } } else{ // x o x o x o if((i%2)==0){ //interpolate for (size_t m=0; m<T; m++){ for (size_t n=0; n<S; n++){ grad_h_v= grad_difference (lf_buf,j,i,WHST/2,ML_W,T,S,m,n); for(size_t k=0; k<3; k++){ multiview_buf[kWHST+(jT+m)IMG_WS+iS+n] = grad_h_v? (lf_buf[kWHST/2+((j-1)T+m)ML_WS+i/2S+n] +lf_buf[kWHST/2+((j+1)T+m)ML_WS+i/2S+n])/2: (lf_buf[kWHST/2+(jT+m)ML_WS+(i/2-1)S+n] +lf_buf[kWHST/2+(jT+m)ML_WS+i/2S+n])/2; } } } } else{ //copy for (size_t m=0; m<T; m++){ for (size_t n=0; n<S; n++){ for(size_t k=0; k<3; k++){ multiview_buf[kWHST+(jT+m)IMG_WS+iS+n] = lf_buf[kWHST/2+(jT+m)ML_WS+(i-1)/2S+n]; } } } } } } } //ml array->multiview for (size_t j=0; j<IMG_H; j++){ for (size_t i=0; i<IMG_W; i++){ for (size_t m=0; m<T; m++){ for (size_t n=0; n<S; n++){ int index_2=(jT+m)IMG_WS + iS+n; multiview.at<Vec3w>(mIMG_H+j, nIMG_W +i) = Vec3w(multiview_buf[index_2],multiview_buf[WHST+index_2],multiview_buf[2WHST+index_2]); //if ((multiview_buf[2WHST+index_2]==212)&&(multiview_buf[WHST+index_2]==67)) // cout<<j<<" "<<i<<" "<<m<<" "<<n<<endl; } } } } } #endif
timer.h	#ifndef SPLATT_TIMER_H #define SPLATT_TIMER_H /****************************************************************************** * INCLUDES ***************************************************************************/ #include <time.h> #include <stddef.h> #include <stdbool.h> #ifdef __MACH__ #include <mach/mach.h> #include <mach/mach_time.h> #endif /**************************************************************************** * STRUCTURES ***************************************************************************/ / * @brief Represents a wall-clock timer. / typedef struct { bool running; double seconds; double start; double stop; } sp_timer_t; /* * @brief timer_id provides easy indexing into timers[]. / typedef enum { TIMER_LVL0, / LEVEL 0 / TIMER_ALL, TIMER_CPD, TIMER_REORDER, TIMER_CONVERT, TIMER_LVL1, / LEVEL 1 / TIMER_MTTKRP, TIMER_ADMM, TIMER_CHOLESKY, TIMER_BACKSOLVE, TIMER_INV, TIMER_FIT, TIMER_MATMUL, TIMER_ATA, TIMER_MATNORM, TIMER_IO, TIMER_PART, TIMER_LVL2, / LEVEL 2 / #ifdef SPLATT_USE_MPI TIMER_MPI, TIMER_MPI_IDLE, TIMER_MPI_COMM, TIMER_MPI_ATA, TIMER_MPI_REDUCE, TIMER_MPI_PARTIALS, TIMER_MPI_NORM, TIMER_MPI_UPDATE, TIMER_MPI_FIT, / timer max / TIMER_MTTKRP_MAX, TIMER_MPI_MAX, TIMER_MPI_IDLE_MAX, TIMER_MPI_COMM_MAX, #endif TIMER_SPLATT, TIMER_GIGA, TIMER_DFACTO, TIMER_TTBOX, TIMER_SORT, TIMER_TILE, TIMER_MISC, TIMER_NTIMERS / LEVEL N / } timer_id; / globals / extern int timer_lvl; extern sp_timer_t timers[TIMER_NTIMERS]; /***************************************************************************** * PUBLIC FUNCTIONS ***************************************************************************/ #define init_timers splatt_init_timers / * @brief Call timer_reset() on all of timers[]. / void init_timers(void); #define report_times splatt_report_times /* * @brief Output a summary of all used timers. / void report_times(void); #define timer_inc_verbose splatt_timer_inc_verbose /* * @brief Increment timer verbosity to the next level; / void timer_inc_verbose(void); /* * @brief Return the number of seconds since an unspecified time (e.g., Unix * epoch). This is accomplished with a high-resolution monotonic timer, * suitable for performance timing. * * @return The number of seconds. / static inline double monotonic_seconds() { #ifdef __MACH__ / OSX / static mach_timebase_info_data_t info; static double seconds_per_unit; if(seconds_per_unit == 0) { #pragma omp critical { mach_timebase_info(&info); seconds_per_unit = (info.numer / info.denom) / 1e9; } } return seconds_per_unit mach_absolute_time(); #else /* Linux systems / struct timespec ts; clock_gettime(CLOCK_MONOTONIC, &ts); return ts.tv_sec + ts.tv_nsec 1e-9; #endif } /** * @brief Reset all fields of a sp_timer_t. * * @param timer The timer to reset. / static inline void timer_reset(sp_timer_t const timer) { timer->running = false; timer->seconds = 0; timer->start = 0; timer->stop = 0; } /** * @brief Start a sp_timer_t. NOTE: this does not reset the timer. * * @param timer The timer to start. / static inline void timer_start(sp_timer_t const timer) { if(!timer->running) { timer->running = true; timer->start = monotonic_seconds(); } } /** * @brief Stop a sp_timer_t and update its time. * * @param timer The timer to stop. / static inline void timer_stop(sp_timer_t const timer) { timer->running = false; timer->stop = monotonic_seconds(); timer->seconds += timer->stop - timer->start; } /** * @brief Give a sp_timer_t a fresh start by resetting and starting it. * * @param timer The timer to refresh. / static inline void timer_fstart(sp_timer_t const timer) { timer_reset(timer); timer_start(timer); } #endif
md5_bmark-par.c	/* * MD5 Benchmark * ------------- * File: md5_bmark.c * * This is the main file for the md5 benchmark kernel. This benchmark was * written as part of the StarBENCH benchmark suite at TU Berlin. It performs * MD5 computation on a number of self-generated input buffers in parallel, * automatically measuring execution time. * * Copyright (C) 2011 Michael Andersch * * 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 3 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, see <http://www.gnu.org/licenses/>. * / #include <stdio.h> #include <stdlib.h> #include <stdint.h> #include <unistd.h> #include <string.h> #include <sys/time.h> #include <omp.h> #include "md5.h" #include "md5_bmark.h" typedef struct timeval timer; #define TIME(x) gettimeofday(&x, NULL) / Function declarations / int initialize(md5bench_t args); int finalize(md5bench_t* args); void run(md5bench_t* args); void process(uint8_t* in, uint8_t* out, int bufsize); void listInputs(); long timediff(timer* starttime, timer* finishtime); // Input configurations static data_t datasets[] = { {64, 512, 0}, {64, 1024, 0}, {64, 2048, 0}, {64, 4096, 0}, {128, 1024512, 1}, {128, 10241024, 1}, {128, 10242048, 1}, {128, 10244096, 1}, }; int nt_global; /* * Function: initialize * -------------------- * To initialize the benchmark parameters. Generates the input buffers from random data. / int initialize(md5bench_t args) { int index = args->input_set; if(index < 0 \|\| index >= sizeof(datasets)/sizeof(datasets[0])) { fprintf(stderr, "Invalid input set specified! Clamping to set 0\n"); index = 0; } args->numinputs = datasets[index].numbufs; args->size = datasets[index].bufsize; args->inputs = (uint8_t*)calloc(args->numinputs, sizeof(uint8_t)); args->out = (uint8_t)calloc(args->numinputs, DIGEST_SIZE); if(args->inputs == NULL \|\| args->out == NULL) { fprintf(stderr, "Memory Allocation Error\n"); return -1; } //fprintf(stderr, "Reading input set: %d buffers, %d bytes per buffer\n", datasets[index].numbufs, datasets[index].bufsize); // Now the input buffers need to be generated, for replicability, use same seed srand(datasets[index].rseed); for(int i = 0; i < args->numinputs; i++) { args->inputs[i] = (uint8_t)malloc(sizeof(uint8_t)datasets[index].bufsize); uint8_t p = args->inputs[i]; if(p == NULL) { fprintf(stderr, "Memory Allocation Error\n"); return -1; } for(int j = 0; j < datasets[index].bufsize; j++) p++ = rand() % 255; } return 0; } / * Function: process * ----------------- * Processes one input buffer, delivering the digest into out. / void process(uint8_t in, uint8_t* out, int bufsize) { MD5_CTX context; uint8_t digest[16]; MD5_Init(&context); MD5_Update(&context, in, bufsize); MD5_Final(digest, &context); memcpy(out, digest, DIGEST_SIZE); } /* * Function: run * -------------------- * Main benchmarking function. If called, processes buffers with MD5 * until no more buffers available. The resulting message digests * are written into consecutive locations in the preallocated output * buffer. / void run(md5bench_t args) { #pragma omp parallel num_threads(nt_global) for(int i = 0; i < args->iterations; i++) { int buffers_to_process = args->numinputs; int next = 0; uint8_t** in = args->inputs; uint8_t* out = args->out; #pragma omp single nowait while(buffers_to_process > 0) { uint8_t* aux = out+nextDIGEST_SIZE; #pragma omp task depend(in: in[next:1]) depend(out: aux) process(in[next], aux, args->size); next++; buffers_to_process--; } #pragma omp taskwait } } / * Function: finalize * ------------------ * Cleans up memory used by the benchmark for input and output buffers. / int finalize(md5bench_t args) { char buffer[64]; int offset = 0; for(int i = 0; i < args->numinputs; i++) { #ifdef DEBUG sprintf(buffer, "Buffer %d has checksum ", i); fwrite(buffer, sizeof(char), strlen(buffer)+1, stdout); #endif for(int j = 0; j < DIGEST_SIZE2; j+=2) { sprintf(buffer+j, "%x", args->out[DIGEST_SIZEi+j/2] & 0xf); sprintf(buffer+j+1, "%x", args->out[DIGEST_SIZEi+j/2] & 0xf0); } buffer[32] = '\0'; #ifdef DEBUG fwrite(buffer, sizeof(char), 32, stdout); fputc('\n', stdout); #else printf("%s ", buffer); #endif } #ifndef DEBUG printf("\n"); #endif if(args->inputs) { for(int i = 0; i < args->numinputs; i++) { if(args->inputs[i]) free(args->inputs[i]); } free(args->inputs); } if(args->out) free(args->out); return 0; } / * Function: timediff * ------------------ * Compute the difference between timers starttime and finishtime in msecs. / long timediff(timer starttime, timer* finishtime) { long msec; msec=(finishtime->tv_sec-starttime->tv_sec)1000; msec+=(finishtime->tv_usec-starttime->tv_usec)/1000; return msec; } /* MAIN / int main(int argc, char argv) { timer b_start, b_end; md5bench_t args; //nt = number of threads int nt; //Receber parâmetros scanf("%d", &nt); scanf("%d", &args.input_set); scanf("%d", &args.iterations); args.outflag = 1; nt_global = nt; // Parameter initialization if(initialize(&args)) { fprintf(stderr, "Initialization Error\n"); exit(EXIT_FAILURE); } TIME(b_start); run(&args); TIME(b_end); // Free memory if(finalize(&args)) { fprintf(stderr, "Finalization Error\n"); exit(EXIT_FAILURE); } double b_time = (double)timediff(&b_start, &b_end)/1000; printf("%.3f\n", b_time); return 0; }
zip_fmt_plug.c	/* * ZIP cracker patch for JtR. Hacked together during June of 2011 * by Dhiru Kholia <dhiru.kholia at gmail.com> for GSoC. * * This software is Copyright (c) 2011, 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. * * http://www.winzip.com/aes_info.htm (There is a 1 in 65,536 chance that an * incorrect password will yield a matching verification value; therefore, a * matching verification value cannot be absolutely relied on to indicate a * correct password.). The alternative is to implement/use a full unzip engine. * * This format significantly improved, Summer of 2014, JimF. Changed the signature * to the $zip2$, and added logic to properly make this format work. Now there is no * false positives any more. Now it properly cracks the passwords. There is * an hmac-sha1 'key' that is also processed (and the decryption key), in the pbkdf2 * call. Now we use this hmac-sha1 key, process the compressed and encrypted buffer, * compare to a 10 byte checksum (which is now the binary blob), and we KNOW that we * have cracked or not cracked the key. The $zip$ was broken before, so that signature * has simply been retired as DOA. This format is now much like the pkzip format. * it may have all data contained within the hash string, OR it may have some, and * have a file pointer on where to get the rest of the data. * * optimizations still that can be done. * 1. decrypt and inflate some data for really large buffers, BEFORE doing the * hmac-sha1 call. The inflate algorithm is pretty self checking for 'valid' * data, so a few hundred bytes of checking and we are 99.999% sure we have the * right password, before starting an expensive hmac (for instance if the zip blob * was 50mb). * 2. Put in the 'file magic' logic we have for pkzip. There is a place holder for it, * but the logic has not been added. / #if FMT_EXTERNS_H extern struct fmt_main fmt_zip; #elif FMT_REGISTERS_H john_register_one(&fmt_zip); #else #include <string.h> #include <assert.h> #include <errno.h> #include <ctype.h> #include "arch.h" #include "crc32.h" #include "misc.h" #include "params.h" #include "common.h" #include "formats.h" #include "johnswap.h" #include "memory.h" #include "pkzip.h" #include "pbkdf2_hmac_sha1.h" #include "dyna_salt.h" #ifdef _OPENMP #include <omp.h> #ifndef OMP_SCALE #define OMP_SCALE 1 // Tuned on core i7 #endif static int omp_t = 1; #endif #include "hmac_sha.h" #include "memdbg.h" #define KEY_LENGTH(mode) (8 ((mode) & 3) + 8) #define SALT_LENGTH(mode) (4 * ((mode) & 3) + 4) typedef struct my_salt_t { dyna_salt dsalt; uint32_t comp_len; struct { uint16_t type : 4; uint16_t mode : 4; } v; unsigned char passverify[2]; unsigned char salt[SALT_LENGTH(3)]; //uint64_t data_key; // MSB of md5(data blob). We lookup using this. unsigned char datablob[1]; } my_salt; #define FORMAT_LABEL "ZIP" #define FORMAT_NAME "WinZip" #ifdef SIMD_COEF_32 #define ALGORITHM_NAME "PBKDF2-SHA1 " SHA1_ALGORITHM_NAME #else #define ALGORITHM_NAME "PBKDF2-SHA1 32/" ARCH_BITS_STR #endif #define PLAINTEXT_LENGTH 125 #define BINARY_ALIGN sizeof(ARCH_WORD_32) #define SALT_SIZE sizeof(my_salt) #define SALT_ALIGN sizeof(my_salt) #ifdef SIMD_COEF_32 #define MIN_KEYS_PER_CRYPT SSE_GROUP_SZ_SHA1 #define MAX_KEYS_PER_CRYPT SSE_GROUP_SZ_SHA1 #else #define MIN_KEYS_PER_CRYPT 1 #define MAX_KEYS_PER_CRYPT 1 #endif static char (saved_key)[PLAINTEXT_LENGTH + 1]; static unsigned char (crypt_key)[((WINZIP_BINARY_SIZE+3)/4)4]; static my_salt saved_salt; // filename:$zip2$TyMoMaSaVaLeDFAu$/zip2$ // Ty = type (0) and ignored. // Mo = mode (1 2 3 for 128/192/256 bit // Ma = magic (file magic). This is reserved for now. See pkzip_fmt_plug.c or zip2john.c for information. // For now, this must be a '0' // Sa = salt(hex). 8, 12 or 16 bytes of salt (depends on mode) // Va = Verification bytes(hex) (2 byte quick checker) // Le = real compr len (hex) length of compressed/encrypted data (field DF) // DF = compressed data DF can be L2 hex bytes, and if so, then it is the ENTIRE file blob written 'inline'. // However, if the data blob is too long, then a .zip ZIPDATA_FILE_PTR_RECORD structure will be the 'contents' of DF // Au = Authentication code (hex) a 10 byte hex value that is the hmac-sha1 of data over D. This is the binary() value // ZIPDATA_FILE_PTR_RECORD (this can be the 'DF' of this above hash line. // ZFILEFnOhOb* (Note, the leading and trailing * are the * that 'wrap' the DF object. // ZFILE This is the literal string ZFILE // Fn This is the name of the .zip file. NOTE the user will need to keep the .zip file in proper locations (same as // was seen when running zip2john. If the file is removed, this hash line will no longer be valid. // Oh Offset to the zip central header record for this blob. // Ob Offset to the start of the blob data static void init(struct fmt_main self) { #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(self->params.max_keys_per_crypt, sizeof(saved_key)); crypt_key = mem_calloc(self->params.max_keys_per_crypt, sizeof(crypt_key)); } static void done(void) { MEM_FREE(crypt_key); MEM_FREE(saved_key); } static void get_salt(char ciphertext) { int i; my_salt salt, psalt; static unsigned char ptr; /* extract data from "ciphertext" / c8 copy_mem = strdup(ciphertext); c8 cp, p; if (!ptr) ptr = mem_alloc_tiny(sizeof(my_salt),sizeof(my_salt)); p = copy_mem + WINZIP_TAG_LENGTH+1; /* skip over "$zip2$" / memset(&salt, 0, sizeof(salt)); cp = strtokm(p, ""); // type salt.v.type = atoi((const char)cp); cp = strtokm(NULL, ""); // mode salt.v.mode = atoi((const char)cp); cp = strtokm(NULL, ""); // file_magic enum (ignored) cp = strtokm(NULL, ""); // salt for (i = 0; i < SALT_LENGTH(salt.v.mode); i++) salt.salt[i] = (atoi16[ARCH_INDEX(cp[i<<1])]<<4) \| atoi16[ARCH_INDEX(cp[(i<<1)+1])]; cp = strtokm(NULL, ""); // validator salt.passverify[0] = (atoi16[ARCH_INDEX(cp[0])]<<4) \| atoi16[ARCH_INDEX(cp[1])]; salt.passverify[1] = (atoi16[ARCH_INDEX(cp[2])]<<4) \| atoi16[ARCH_INDEX(cp[3])]; cp = strtokm(NULL, ""); // data len sscanf((const char )cp, "%x", &salt.comp_len); // later we will store the data blob in our own static data structure, and place the 64 bit LSB of the // MD5 of the data blob into a field in the salt. For the first POC I store the entire blob and just // make sure all my test data is small enough to fit. cp = strtokm(NULL, ""); // data blob // Ok, now create the allocated salt record we are going to return back to John, using the dynamic // sized data buffer. psalt = (my_salt)mem_calloc(1, sizeof(my_salt) + salt.comp_len); psalt->v.type = salt.v.type; psalt->v.mode = salt.v.mode; psalt->comp_len = salt.comp_len; psalt->dsalt.salt_alloc_needs_free = 1; // we used mem_calloc, so JtR CAN free our pointer when done with them. memcpy(psalt->salt, salt.salt, sizeof(salt.salt)); psalt->passverify[0] = salt.passverify[0]; psalt->passverify[1] = salt.passverify[1]; // set the JtR core linkage stuff for this dyna_salt psalt->dsalt.salt_cmp_offset = SALT_CMP_OFF(my_salt, comp_len); psalt->dsalt.salt_cmp_size = SALT_CMP_SIZE(my_salt, comp_len, datablob, psalt->comp_len); if (strcmp((const char)cp, "ZFILE")) { for (i = 0; i < psalt->comp_len; i++) psalt->datablob[i] = (atoi16[ARCH_INDEX(cp[i<<1])]<<4) \| atoi16[ARCH_INDEX(cp[(i<<1)+1])]; } else { c8 Fn, Oh, Ob; long len; uint32_t id; FILE fp; Fn = strtokm(NULL, ""); Oh = strtokm(NULL, ""); Ob = strtokm(NULL, ""); fp = fopen((const char)Fn, "rb"); if (!fp) { psalt->v.type = 1; // this will tell the format to 'skip' this salt, it is garbage goto Bail; } sscanf((const char)Oh, "%lx", &len); if (fseek(fp, len, SEEK_SET)) { fclose(fp); psalt->v.type = 1; goto Bail; } id = fget32LE(fp); if (id != 0x04034b50U) { fclose(fp); psalt->v.type = 1; goto Bail; } sscanf((const char)Ob, "%lx", &len); if (fseek(fp, len, SEEK_SET)) { fclose(fp); psalt->v.type = 1; goto Bail; } if (fread(psalt->datablob, 1, psalt->comp_len, fp) != psalt->comp_len) { fclose(fp); psalt->v.type = 1; goto Bail; } fclose(fp); } Bail:; MEM_FREE(copy_mem); memcpy(ptr, &psalt, sizeof(my_salt)); return (void)ptr; } static void set_salt(void salt) { saved_salt = ((my_salt*)salt); } static void set_key(char key, int index) { int saved_len = strlen(key); if (saved_len > PLAINTEXT_LENGTH) saved_len = PLAINTEXT_LENGTH; memcpy(saved_key[index], key, saved_len); saved_key[index][saved_len] = 0; } static char get_key(int index) { return saved_key[index]; } static int get_hash_0(int index) { return ((ARCH_WORD_32)&(crypt_key[index]))[0] & PH_MASK_0; } static int get_hash_1(int index) { return ((ARCH_WORD_32)&(crypt_key[index]))[0] & PH_MASK_1; } static int get_hash_2(int index) { return ((ARCH_WORD_32)&(crypt_key[index]))[0] & PH_MASK_2; } static int get_hash_3(int index) { return ((ARCH_WORD_32)&(crypt_key[index]))[0] & PH_MASK_3; } static int get_hash_4(int index) { return ((ARCH_WORD_32)&(crypt_key[index]))[0] & PH_MASK_4; } static int get_hash_5(int index) { return ((ARCH_WORD_32)&(crypt_key[index]))[0] & PH_MASK_5; } static int get_hash_6(int index) { return ((ARCH_WORD_32)&(crypt_key[index]))[0] & PH_MASK_6; } static int crypt_all(int pcount, struct db_salt salt) { int count = pcount; int index; if (saved_salt->v.type) { // This salt passed valid() but failed get_salt(). // Should never happen. memset(crypt_key, 0, count WINZIP_BINARY_SIZE); return count; } #ifdef _OPENMP #pragma omp parallel for default(none) private(index) shared(count, saved_key, saved_salt, crypt_key) #endif for (index = 0; index < count; index += MAX_KEYS_PER_CRYPT) { #ifdef SIMD_COEF_32 unsigned char pwd_ver[(2+64)MAX_KEYS_PER_CRYPT]; int lens[MAX_KEYS_PER_CRYPT], i; unsigned char pin[MAX_KEYS_PER_CRYPT], pout[MAX_KEYS_PER_CRYPT]; for (i = 0; i < MAX_KEYS_PER_CRYPT; ++i) { lens[i] = strlen(saved_key[i+index]); pin[i] = (unsigned char)saved_key[i+index]; pout[i] = &pwd_ver[i(2+2KEY_LENGTH(saved_salt->v.mode))]; } pbkdf2_sha1_sse((const unsigned char *)pin, lens, saved_salt->salt, SALT_LENGTH(saved_salt->v.mode), KEYING_ITERATIONS, pout, 2+2KEY_LENGTH(saved_salt->v.mode), 0); for (i = 0; i < MAX_KEYS_PER_CRYPT; ++i) { if (!memcmp(&(pout[i][KEY_LENGTH(saved_salt->v.mode)<<1]), saved_salt->passverify, 2)) { hmac_sha1(&(pout[i][KEY_LENGTH(saved_salt->v.mode)]), KEY_LENGTH(saved_salt->v.mode), (const unsigned char)saved_salt->datablob, saved_salt->comp_len, crypt_key[index+i], WINZIP_BINARY_SIZE); } else memset(crypt_key[index+i], 0, WINZIP_BINARY_SIZE); } #else int LEN = 2+2KEY_LENGTH(saved_salt->v.mode); union { unsigned char pwd_ver[4+64]; ARCH_WORD_32 w; } x; unsigned char pwd_ver = x.pwd_ver; pbkdf2_sha1((unsigned char )saved_key[index], strlen(saved_key[index]), saved_salt->salt, SALT_LENGTH(saved_salt->v.mode), KEYING_ITERATIONS, pwd_ver, LEN, 0); if (!memcmp(&(pwd_ver[KEY_LENGTH(saved_salt->v.mode)<<1]), saved_salt->passverify, 2)) { hmac_sha1(&(pwd_ver[KEY_LENGTH(saved_salt->v.mode)]), KEY_LENGTH(saved_salt->v.mode), (const unsigned char)saved_salt->datablob, saved_salt->comp_len, crypt_key[index], WINZIP_BINARY_SIZE); } else memset(crypt_key[index], 0, WINZIP_BINARY_SIZE); #endif } return count; } static int cmp_all(void binary, int count) { int i; for (i = 0; i < count; i++) if (((ARCH_WORD_32)&(crypt_key[i]))[0] == ((ARCH_WORD_32)binary)[0]) return 1; return 0; } static int cmp_one(void binary, int index) { return (((ARCH_WORD_32)&(crypt_key[index]))[0] == ((ARCH_WORD_32)binary)[0]); } static int cmp_exact(char source, int index) { void b = winzip_common_binary(source); return !memcmp(b, crypt_key[index], sizeof(crypt_key[index])); } struct fmt_main fmt_zip = { { FORMAT_LABEL, FORMAT_NAME, ALGORITHM_NAME, WINZIP_BENCHMARK_COMMENT, WINZIP_BENCHMARK_LENGTH, 0, PLAINTEXT_LENGTH, 4, // WINZIP_BINARY_SIZE, BINARY_ALIGN, SALT_SIZE, SALT_ALIGN, MIN_KEYS_PER_CRYPT, MAX_KEYS_PER_CRYPT, FMT_CASE \| FMT_8_BIT \| FMT_OMP \| FMT_DYNA_SALT, { NULL }, winzip_common_tests }, { init, done, fmt_default_reset, fmt_default_prepare, winzip_common_valid, fmt_default_split, winzip_common_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 }, fmt_default_dyna_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 */
omp2.c	// RUN: mlir-clang %s --function=* -fopenmp -S \| FileCheck %s void square2(double** x, int sstart, int send, int sinc, int tstart, int tend, int tinc) { #pragma omp parallel for collapse(2) for(int i=sstart; i < send; i+= sinc) { for(int j=tstart; j < tend; j+= tinc) { x[i][j] = i + j; } } } // CHECK: func @square2(%arg0: memref<?xmemref<?xf64>>, %arg1: i32, %arg2: i32, %arg3: i32, %arg4: i32, %arg5: i32, %arg6: i32) attributes {llvm.linkage = #llvm.linkage<external>} { // CHECK-NEXT: %c-1_i32 = arith.constant -1 : i32 // CHECK-NEXT: %0 = arith.index_cast %arg1 : i32 to index // CHECK-NEXT: %1 = arith.index_cast %arg4 : i32 to index // CHECK-NEXT: %2 = arith.subi %arg2, %arg1 : i32 // CHECK-NEXT: %3 = arith.addi %2, %c-1_i32 : i32 // CHECK-NEXT: %4 = arith.addi %3, %arg3 : i32 // CHECK-NEXT: %5 = arith.divui %4, %arg3 : i32 // CHECK-NEXT: %6 = arith.muli %5, %arg3 : i32 // CHECK-NEXT: %7 = arith.addi %arg1, %6 : i32 // CHECK-NEXT: %8 = arith.index_cast %7 : i32 to index // CHECK-NEXT: %9 = arith.subi %arg5, %arg4 : i32 // CHECK-NEXT: %10 = arith.addi %9, %c-1_i32 : i32 // CHECK-NEXT: %11 = arith.addi %10, %arg6 : i32 // CHECK-NEXT: %12 = arith.divui %11, %arg6 : i32 // CHECK-NEXT: %13 = arith.muli %12, %arg6 : i32 // CHECK-NEXT: %14 = arith.addi %arg4, %13 : i32 // CHECK-NEXT: %15 = arith.index_cast %14 : i32 to index // CHECK-NEXT: %16 = arith.index_cast %arg3 : i32 to index // CHECK-NEXT: %17 = arith.index_cast %arg6 : i32 to index // CHECK-NEXT: scf.parallel (%arg7, %arg8) = (%0, %1) to (%8, %15) step (%16, %17) { // CHECK-NEXT: %18 = arith.index_cast %arg7 : index to i64 // CHECK-NEXT: %19 = arith.index_cast %arg8 : index to i64 // CHECK-NEXT: %20 = memref.load %arg0[%arg7] : memref<?xmemref<?xf64>> // CHECK-NEXT: %21 = arith.addi %18, %19 : i64 // CHECK-NEXT: %22 = arith.sitofp %21 : i64 to f64 // CHECK-NEXT: memref.store %22, %20[%arg8] : memref<?xf64> // CHECK-NEXT: scf.yield // CHECK-NEXT: } // CHECK-NEXT: return // CHECK-NEXT: }
matvec.c	/* * matvec.c: Example of matrix-vector product in OpenMP. * * (C) 2015 Mikhail Kurnosov <mkurnosov@gmail.com> / #include <stdio.h> #include <stdlib.h> #include <inttypes.h> #include <omp.h> #include <sys/time.h> / * Memory consumption: O(m * n + n + m) / enum { m = 20000, n = 20000 }; void xmalloc(size_t size) { void p = malloc(size); if (!p) { fprintf(stderr, "malloc failed\n"); exit(EXIT_FAILURE); } return p; } double wtime() { struct timeval t; gettimeofday(&t, NULL); return (double)t.tv_sec + (double)t.tv_usec 1E-6; } /* matrix_vector_product: Compute matrix-vector product c[m] = a[m][n] * b[n] / void matrix_vector_product(double a, double b, double c, int m, int n) { for (int i = 0; i < m; i++) { c[i] = 0.0; for (int j = 0; j < n; j++) c[i] += a[i * n + j] * b[j]; } } /* matrix_vector_product_omp: Compute matrix-vector product c[m] = a[m][n] * b[n] in OpenMP / void matrix_vector_product_omp(double a, double b, double c, int m, int n) { #pragma omp parallel { int nthreads = omp_get_num_threads(); int threadid = omp_get_thread_num(); int items_per_thread = m / nthreads; int lb = threadid * items_per_thread; int ub = (threadid == nthreads - 1) ? (m - 1) : (lb + items_per_thread - 1); for (int i = lb; i <= ub; i++) { c[i] = 0.0; for (int j = 0; j < n; j++) c[i] += a[i * n + j] * b[j]; } } } double run_serial() { double a, b, c; // Allocate memory for 2-d array a[m, n] a = xmalloc(sizeof(a) * m * n); b = xmalloc(sizeof(b) n); c = xmalloc(sizeof(c) m); for (int i = 0; i < m; i++) { for (int j = 0; j < n; j++) a[i * n + j] = i + j; } for (int j = 0; j < n; j++) b[j] = j; double t = wtime(); matrix_vector_product(a, b, c, m, n); t = wtime() - t; printf("Elapsed time (serial): %.6f sec.\n", t); free(a); free(b); free(c); return t; } double run_parallel() { double a, b, c; // Allocate memory for 2-d array a[m, n] a = xmalloc(sizeof(a) * m * n); b = xmalloc(sizeof(b) n); c = xmalloc(sizeof(c) m); // Initialize and allocate pages from NUMA-nodes of threads (first-touch policy). #pragma omp parallel { int nthreads = omp_get_num_threads(); int threadid = omp_get_thread_num(); int items_per_thread = m / nthreads; int lb = threadid * items_per_thread; int ub = (threadid == nthreads - 1) ? (m - 1) : (lb + items_per_thread - 1); for (int i = lb; i <= ub; i++) { for (int j = 0; j < n; j++) a[i * n + j] = i + j; c[i] = 0.0; } } for (int j = 0; j < n; j++) b[j] = j; double t = wtime(); matrix_vector_product_omp(a, b, c, m, n); t = wtime() - t; printf("Elapsed time (parallel): %.6f sec.\n", t); free(a); free(b); free(c); return t; } int main(int argc, char *argv) { printf("Matrix-vector product (c[m] = a[m, n] b[n]; m = %d, n = %d)\n", m, n); printf("Memory used: %" PRIu64 " MiB\n", (uint64_t)(((double)m * n + m + n) * sizeof(double)) >> 20); double tser = run_serial(); double tpar = run_parallel(); printf("Speedup: %.2f\n", tser / tpar); return 0; }
fig4.77-reduction.c	/* DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS HEADER. Copyright 2009 Sun Microsystems, Inc. All rights reserved. The contents of this file are subject to the terms of the BSD License("BSD")(the "License"). You can obtain a copy of the License at: http://www.opensparc.net/pubs/t1/licenses/BSD+_License.txt The BSD License Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistribution of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistribution 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 Sun Microsystems, Inc. or the names of contributors may be used to endorse or promote products derived from this software without specific prior written permission. This software is provided "AS IS," without a warranty of any kind. ALL EXPRESS OR IMPLIED CONDITIONS, REPRESENTATIONS AND WARRANTIES, INCLUDING ANY IMPLIED WARRANTY OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE OR NON-INFRINGEMENT, ARE HEREBY EXCLUDED. SUN MICROSYSTEMS, INC. ("SUN") AND ITS LICENSORS SHALL NOT BE LIABLE FOR ANY DAMAGES SUFFERED BY LICENSEE AS A RESULT OF USING, MODIFYING OR DISTRIBUTING THIS SOFTWARE OR ITS DERIVATIVES. IN NO EVENT WILL SUN OR ITS LICENSORS BE LIABLE FOR ANY LOST REVENUE, PROFIT OR DATA, OR FOR DIRECT, INDIRECT, SPECIAL, CONSEQUENTIAL, INCIDENTAL OR PUNITIVE DAMAGES, HOWEVER CAUSED AND REGARDLESS OF THE THEORY OF LIABILITY, ARISING OUT OF THE USE OF OR INABILITY TO USE THIS SOFTWARE, EVEN IF SUN HAS BEEN ADVISED OF THE POSSIBILITY OF SUCH DAMAGES. You acknowledge that this software is not designed, licensed or intended for use in the design, construction, operation or maintenance of any nuclear facility. / #include <stdio.h> #include <stdlib.h> #ifdef _OPENMP #include <omp.h> #define TRUE 1 #define FALSE 0 #else #define omp_get_thread_num() 0 #define omp_get_num_threads() 1 #endif #define SUM_INIT 0 int main() { int i, n = 25; int sum, a[n]; int ref = SUM_INIT + (n-1)n/2; #ifdef _OPENMP (void) omp_set_dynamic(FALSE); if (omp_get_dynamic()) {printf("Warning: dynamic adjustment of threads has been set\n");} (void) omp_set_num_threads(3); #endif for (i=0; i<n; i++) a[i] = i; #pragma omp parallel { #pragma omp single printf("Number of threads is %d\n",omp_get_num_threads()); } sum = SUM_INIT; printf("Value of sum prior to parallel region: %d\n",sum); #pragma omp parallel for default(none) shared(n,a) \ reduction(+:sum) for (i=0; i<n; i++) sum += a[i]; /-- End of parallel reduction --/ printf("Value of sum after parallel region: %d\n",sum); printf("Check results: sum = %d (should be %d)\n",sum,ref); return(0); }
tdbjac2.c	#include "dbjac2.h" #include "wnrme.h" #include "rnd.h" #include "timer.h" int main(int argc, char argv[]) { if (4 != argc) { (void)fprintf(stderr, "%s filename 2^{batch_size} #batches\n", argv); return EXIT_FAILURE; } const size_t n = ((size_t)1u << atoz(argv[2u])); if (n % VDL) { (void)fprintf(stderr, "batch_size has to be a multiple of %u.\n", VDL); return EXIT_FAILURE; } int th = 0; #ifdef _OPENMP th = omp_get_max_threads(); if (n % th) { (void)fprintf(stderr, "batch_size has to be a multiple of %d.\n", th); return EXIT_FAILURE; } #endif /* _OPENMP / const size_t b = atoz(argv[3u]); if (!b) return EXIT_SUCCESS; const size_t nl = strlen(argv[1u]), nl1 = (nl + 1u); char const fn = calloc((nl + 3u), sizeof(char)); assert(fn); strcpy(fn, argv[1u])[nl] = '.'; int fm = O_RDONLY; #ifdef _LARGEFILE64_SOURCE fm \|= O_LARGEFILE; #endif /* _LARGEFILE64_SOURCE / fn[nl1] = 'k'; const int fk = open(fn, fm); if (-1 >= fk) { (void)fprintf(stderr, "Cannot open %s for reading!\n", fn); return EXIT_FAILURE; } fn[nl1] = 'l'; const int fl = open(fn, fm); if (-1 >= fl) { (void)fprintf(stderr, "Cannot open %s for reading!\n", fn); return EXIT_FAILURE; } fn[nl1] = 'f'; const int ff = open(fn, fm); if (-1 >= ff) { (void)fprintf(stderr, "Cannot open %s for reading!\n", fn); return EXIT_FAILURE; } fn[nl1] = 'g'; const int fg = open(fn, fm); if (-1 >= fg) { (void)fprintf(stderr, "Cannot open %s for reading!\n", fn); return EXIT_FAILURE; } fn[nl1] = 'h'; const int fh = open(fn, fm); if (-1 >= fh) { (void)fprintf(stderr, "Cannot open %s for reading!\n", fn); return EXIT_FAILURE; } const size_t nt = n sizeof(double); double const a11 = (double)aligned_alloc(VA, nt), const a22 = (double)aligned_alloc(VA, nt), const a21 = (double)aligned_alloc(VA, nt), const c = (double)aligned_alloc(VA, nt), const at = (double)aligned_alloc(VA, nt), const l1 = (double)aligned_alloc(VA, nt), const l2 = (double)aligned_alloc(VA, nt); assert(a11); assert(a22); assert(a21); assert(c); assert(at); assert(l1); assert(l2); unsigned const p = (unsigned)malloc((n >> VDLlg) * sizeof(unsigned)); assert(p); unsigned rd[2u] = { 0u, 0u }; uint64_t hz = tsc_get_freq_hz_(rd), be[2u] = { UINT64_C(0), UINT64_C(0) }; (void)fprintf(stderr, "TSC frequency: %llu+(%u/%u) Hz.\n", (unsigned long long)hz, rd[0u], rd[1u]); (void)fflush(stderr); (void)fprintf(stdout, "\"B\",\"Ts\",\"ORT\",\"REN\",\"RLN\",\"RLX\",\"RLM\"\n"); (void)fflush(stdout); const char bf = (const char)NULL; if (b <= 10u) bf = "%1zu"; else if (b <= 100u) bf = "%2zu"; else if (b <= 1000u) bf = "%3zu"; else // b > 1000 bf = "%zu"; const size_t n_t = n / imax(th, 1); const size_t cnt = n_t * sizeof(double); char a[31u] = { '\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' }; for (size_t j = 0u; j < b; ++j) { (void)fprintf(stdout, bf, j); (void)fflush(stdout); const size_t jn = j * n; #ifdef _OPENMP #pragma omp parallel default(none) shared(ff,fg,fh,a11,a22,a21,n,n_t,cnt,jn) #endif /* _OPENMP / { const int mt = #ifdef _OPENMP omp_get_thread_num() #else / !_OPENMP / 0 #endif / ?_OPENMP / ; const size_t tnt = mt n_t; const off_t off = (jn + tnt) * sizeof(double); if ((ssize_t)cnt != pread(ff, (a11 + tnt), cnt, off)) exit(EXIT_FAILURE); if ((ssize_t)cnt != pread(fg, (a22 + tnt), cnt, off)) exit(EXIT_FAILURE); if ((ssize_t)cnt != pread(fh, (a21 + tnt), cnt, off)) exit(EXIT_FAILURE); } (void)fprintf(stdout, ","); (void)fflush(stdout); be[0u] = rdtsc_beg(rd); const fint _n = -(fint)n; (void)dbjac2_(&_n, a11, a22, a21, c, at, l1, l2, p); be[1u] = rdtsc_end(rd); (void)fprintf(stdout, "%15.9Lf,", tsc_lap(hz, be[0u], be[1u])); (void)fflush(stdout); wide o = W_ZERO, r = W_ZERO; #ifdef _OPENMP #pragma omp parallel for default(none) shared(n,a11,a22,a21,c,at,l1,l2) reduction(max:o,r) #endif /* _OPENMP / for (size_t i = 0u; i < n; ++i) { const wide CS = (wide)(c[i]); const wide SN = (wide)(at[i]); wide AE = W_ZERO, AN = W_ZERO; o = fmaxw(o, worr(CS, SN)); r = fmaxw(r, wrer(a11[i], a22[i], a21[i], CS, SN, l1[i], l2[i], &AE, &AN)); } (void)fprintf(stdout, "%s,", xtoa(a, (long double)o)); (void)fprintf(stdout, "%s", xtoa(a, (long double)r)); (void)fflush(stdout); #ifdef _OPENMP #pragma omp parallel default(none) shared(fk,fl,c,at,n,n_t,cnt,jn) #endif / _OPENMP / { const int mt = #ifdef _OPENMP omp_get_thread_num() #else / !_OPENMP / 0 #endif / ?_OPENMP / ; const size_t tnt = mt n_t; const off_t off = (jn + tnt) * sizeof(double); if ((ssize_t)cnt != pread(fk, (c + tnt), cnt, off)) exit(EXIT_FAILURE); if ((ssize_t)cnt != pread(fl, (at + tnt), cnt, off)) exit(EXIT_FAILURE); } (void)fprintf(stdout, ","); (void)fflush(stdout); wide x = W_ZERO, m = W_ZERO; r = W_ZERO; #ifdef _OPENMP #pragma omp parallel for default(none) shared(n,l1,l2,c,at) reduction(max:r,x,m) #endif /* _OPENMP */ for (size_t i = 0u; i < n; ++i) { wide AE = W_ZERO, AN = W_ZERO; const wide RE = wlam(l1[i], l2[i], c[i], at[i], &AE, &AN); r = fmaxw(r, RE); x = fmaxw(x, AE); m = fmaxw(m, AN); } (void)fprintf(stdout, "%s,", xtoa(a, (long double)r)); (void)fprintf(stdout, "%s,", xtoa(a, (long double)x)); (void)fprintf(stdout, "%s\n", xtoa(a, (long double)m)); (void)fflush(stdout); } (void)close(fh); (void)close(fg); (void)close(ff); (void)close(fl); (void)close(fk); free(p); free(l2); free(l1); free(at); free(c); free(a21); free(a22); free(a11); free(fn); return EXIT_SUCCESS; }
SE3P_direct_rsrc.c	#include <math.h> #include "mex.h" #define IDX prhs[0] #define X prhs[1] // Source locations #define Q prhs[2] // Source strengths #define OPT prhs[3] // Parameters #define PHI plhs[0] // Output #ifndef VERBOSE #define VERBOSE 0 #endif #define PI 3.141592653589793 typedef struct { double box[3]; double xi; int layers; double rc; } ewald_opts; void unpack_opt(ewald_opts* opt, const mxArray* mx_opt) { // mandatory options -- will trigger core dump if missing opt->xi = mxGetScalar(mxGetField(mx_opt,0,"xi")); double* box = mxGetPr(mxGetField(mx_opt,0,"box")); opt->box[0] = box[0]; opt->box[1] = box[1]; opt->box[2] = box[2]; // layers: mandatory for ewald sums that are truncated const mxArray* mx_layers = mxGetField(mx_opt,0,"layers"); if(mx_layers) opt->layers = (int)mxGetScalar(mx_layers); else opt->layers = -1; // rc: mandatory for short-range real sum const mxArray* mx_rc = mxGetField(mx_opt,0,"real_cutoff"); if(mx_rc) opt->rc = mxGetScalar(mx_rc); else opt->rc = -1; } // MATLAB (one-based, doubles) to C (zero-based, integers) index translation void index_translation(int* idx, const double* idx_d, int N) { for(int i=0; i<N; i++) idx[i] = (int)idx_d[i] - 1; } void SE3P_direct_real_rc(double* restrict phi, const int* restrict idx, int nidx, const double* restrict x, const double* restrict q, int N, const ewald_opts opt) { double rvec[3]; double qn; double p, r; #ifdef _OPENMP #pragma omp parallel for private(rvec, qn, p, r) #endif for(int m=0; m<nidx; m++) { p = 0; for(int n=0; n<N; n++) { rvec[0] = x[idx[m] ]-x[n ]; rvec[1] = x[idx[m]+N ]-x[n+N ]; rvec[2] = x[idx[m]+2N]-x[n+2N]; qn = q[n]; for(int p0 = -opt.layers; p0<=opt.layers; p0++) for(int p1 = -opt.layers; p1<=opt.layers; p1++) for(int p2 = -opt.layers; p2<=opt.layers; p2++) { if(idx[m] == n && p2 == 0 && p1 == 0 && p0 == 0) continue; r = sqrt((rvec[0]+p0opt.box[0]) (rvec[0]+p0opt.box[0])+ (rvec[1]+p1opt.box[1])* (rvec[1]+p1opt.box[1])+ (rvec[2]+p2opt.box[2])* (rvec[2]+p2opt.box[2])); if(r > opt.rc) continue; p += qnerfc(opt.xir)/r; } } phi[m] += p; } } / no input checking is done / void mexFunction(int nlhs, mxArray plhs[], int nrhs, const mxArray prhs[] ) { // input dims const int N = mxGetM(X); const int num_eval = mxGetN(IDX); // FIXME: indices assumed to be row vec const double idx_d = mxGetPr(IDX); int* idx = mxMalloc(num_evalsizeof(int)); index_translation(idx, idx_d, num_eval); const double x = mxGetPr(X); const double* q = mxGetPr(Q); PHI = mxCreateDoubleMatrix(num_eval, 1, mxREAL); double* restrict phi = mxGetPr(PHI); ewald_opts opt; unpack_opt(&opt, OPT); if(VERBOSE) { mexPrintf("[EWALD (%s)] MEX N=(%d,%d) ","RSRC3P",N,num_eval); mexPrintf("xi = %.2f [rc = %.2f, layers=%d]\n", opt.xi,opt.rc,opt.layers); } // call kernel SE3P_direct_real_rc(phi, idx, num_eval, x, q, N, opt); mxFree(idx); }
threading.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_UTILS_THREADING_H_ #define LIGHTGBM_UTILS_THREADING_H_ #include <LightGBM/meta.h> #include <LightGBM/utils/common.h> #include <LightGBM/utils/openmp_wrapper.h> #include <algorithm> #include <functional> #include <vector> namespace LightGBM { class Threading { public: template <typename INDEX_T> static inline void BlockInfo(INDEX_T cnt, INDEX_T min_cnt_per_block, int out_nblock, INDEX_T* block_size) { int num_threads = OMP_NUM_THREADS(); BlockInfo<INDEX_T>(num_threads, cnt, min_cnt_per_block, out_nblock, block_size); } template <typename INDEX_T> static inline void BlockInfo(int num_threads, INDEX_T cnt, INDEX_T min_cnt_per_block, int* out_nblock, INDEX_T* block_size) { out_nblock = std::min<int>( num_threads, static_cast<int>((cnt + min_cnt_per_block - 1) / min_cnt_per_block)); if (out_nblock > 1) { block_size = SIZE_ALIGNED((cnt + (out_nblock) - 1) / (out_nblock)); } else { block_size = cnt; } } template <typename INDEX_T> static inline void BlockInfo(int num_threads, INDEX_T cnt, INDEX_T min_cnt_per_block, INDEX_T max_cnt_per_block, int* out_nblock, INDEX_T* block_size) { CHECK(max_cnt_per_block >= min_cnt_per_block); out_nblock = std::min<int>( num_threads, static_cast<int>((cnt + min_cnt_per_block - 1) / min_cnt_per_block)); out_nblock = std::max<int>( out_nblock, static_cast<int>((cnt + max_cnt_per_block - 1) / max_cnt_per_block)); if (out_nblock > 1) { block_size = SIZE_ALIGNED((cnt + (out_nblock) - 1) / (out_nblock)); } else { block_size = cnt; } } template <typename INDEX_T> static inline void BlockInfoForceSize(int num_threads, INDEX_T cnt, INDEX_T min_cnt_per_block, int* out_nblock, INDEX_T* block_size) { out_nblock = std::min<int>( num_threads, static_cast<int>((cnt + min_cnt_per_block - 1) / min_cnt_per_block)); if (out_nblock > 1) { block_size = (cnt + (out_nblock) - 1) / (out_nblock); // force the block size to the times of min_cnt_per_block block_size = (block_size + min_cnt_per_block - 1) / min_cnt_per_block min_cnt_per_block; } else { block_size = cnt; } } template <typename INDEX_T> static inline void BlockInfoForceSize(INDEX_T cnt, INDEX_T min_cnt_per_block, int out_nblock, INDEX_T* block_size) { int num_threads = OMP_NUM_THREADS(); BlockInfoForceSize<INDEX_T>(num_threads, cnt, min_cnt_per_block, out_nblock, block_size); } template <typename INDEX_T> static inline int For( INDEX_T start, INDEX_T end, INDEX_T min_block_size, const std::function<void(int, INDEX_T, INDEX_T)>& inner_fun) { int n_block = 1; INDEX_T num_inner = end - start; BlockInfo<INDEX_T>(num_inner, min_block_size, &n_block, &num_inner); OMP_INIT_EX(); #pragma omp parallel for schedule(static, 1) for (int i = 0; i < n_block; ++i) { OMP_LOOP_EX_BEGIN(); INDEX_T inner_start = start + num_inner * i; INDEX_T inner_end = std::min(end, inner_start + num_inner); inner_fun(i, inner_start, inner_end); OMP_LOOP_EX_END(); } OMP_THROW_EX(); return n_block; } }; template <typename INDEX_T, bool TWO_BUFFER> class ParallelPartitionRunner { public: ParallelPartitionRunner(INDEX_T num_data, INDEX_T min_block_size) : min_block_size_(min_block_size) { num_threads_ = OMP_NUM_THREADS(); left_.resize(num_data); if (TWO_BUFFER) { right_.resize(num_data); } offsets_.resize(num_threads_); left_cnts_.resize(num_threads_); right_cnts_.resize(num_threads_); left_write_pos_.resize(num_threads_); right_write_pos_.resize(num_threads_); } ~ParallelPartitionRunner() {} void ReSize(INDEX_T num_data) { left_.resize(num_data); if (TWO_BUFFER) { right_.resize(num_data); } } template<bool FORCE_SIZE> INDEX_T Run( INDEX_T cnt, const std::function<INDEX_T(int, INDEX_T, INDEX_T, INDEX_T, INDEX_T)>& func, INDEX_T* out) { int nblock = 1; INDEX_T inner_size = cnt; if (FORCE_SIZE) { Threading::BlockInfoForceSize<INDEX_T>(num_threads_, cnt, min_block_size_, &nblock, &inner_size); } else { Threading::BlockInfo<INDEX_T>(num_threads_, cnt, min_block_size_, &nblock, &inner_size); } OMP_INIT_EX(); #pragma omp parallel for schedule(static, 1) num_threads(num_threads_) for (int i = 0; i < nblock; ++i) { OMP_LOOP_EX_BEGIN(); INDEX_T cur_start = i * inner_size; INDEX_T cur_cnt = std::min(inner_size, cnt - cur_start); offsets_[i] = cur_start; if (cur_cnt <= 0) { left_cnts_[i] = 0; right_cnts_[i] = 0; continue; } auto left_ptr = left_.data() + cur_start; INDEX_T* right_ptr = nullptr; if (TWO_BUFFER) { right_ptr = right_.data() + cur_start; } // split data inner, reduce the times of function called INDEX_T cur_left_count = func(i, cur_start, cur_cnt, left_ptr, right_ptr); if (!TWO_BUFFER) { // reverse for one buffer std::reverse(left_ptr + cur_left_count, left_ptr + cur_cnt); } left_cnts_[i] = cur_left_count; right_cnts_[i] = cur_cnt - cur_left_count; OMP_LOOP_EX_END(); } OMP_THROW_EX(); left_write_pos_[0] = 0; right_write_pos_[0] = 0; for (int i = 1; i < nblock; ++i) { left_write_pos_[i] = left_write_pos_[i - 1] + left_cnts_[i - 1]; right_write_pos_[i] = right_write_pos_[i - 1] + right_cnts_[i - 1]; } data_size_t left_cnt = left_write_pos_[nblock - 1] + left_cnts_[nblock - 1]; auto right_start = out + left_cnt; #pragma omp parallel for schedule(static, 1) num_threads(num_threads_) for (int i = 0; i < nblock; ++i) { std::copy_n(left_.data() + offsets_[i], left_cnts_[i], out + left_write_pos_[i]); if (TWO_BUFFER) { std::copy_n(right_.data() + offsets_[i], right_cnts_[i], right_start + right_write_pos_[i]); } else { std::copy_n(left_.data() + offsets_[i] + left_cnts_[i], right_cnts_[i], right_start + right_write_pos_[i]); } } return left_cnt; } private: int num_threads_; INDEX_T min_block_size_; std::vector<INDEX_T> left_; std::vector<INDEX_T> right_; std::vector<INDEX_T> offsets_; std::vector<INDEX_T> left_cnts_; std::vector<INDEX_T> right_cnts_; std::vector<INDEX_T> left_write_pos_; std::vector<INDEX_T> right_write_pos_; }; } // namespace LightGBM #endif // LightGBM_UTILS_THREADING_H_
recon3d.c	#include <stdlib.h> #include <stdio.h> #include <math.h> #include <time.h> #include <sys/time.h> #include <string.h> #include <omp.h> #include "mbir_ct.h" #include "MBIRModularDefs.h" #include "MBIRModularUtils.h" #include "allocate.h" #include "icd3d.h" #include "heap.h" #include "A_comp.h" #include "initialize.h" #include "recon3d.h" #define c_ratio 0.07 #define convergence_rho 0.7 /* Internal functions / void super_voxel_recon(int jj,struct SVParams svpar,unsigned long NumUpdates,float totalValue,float totalChange,int iter, char phaseMap,long order,int indexList,float w,float e, struct AValues_char A_Padded_Map,float Aval_max_ptr,struct heap_node headNodeArray, struct SinoParams3DParallel sinoparams,struct ReconParams reconparams,struct Image3D Image, float voxelsBuffer1,float voxelsBuffer2,char group_array,int group_id); void coordinateShuffle(int order1, int order2,int len); void three_way_shuffle(long order1, char order2, struct heap_node headNodeArray,int len); float MAPCostFunction3D(float *e,struct Image3D Image,struct Sino3DParallel sinogram,struct ReconParams reconparams); void MBIRReconstruct3D( struct Image3D Image, struct Sino3DParallel sinogram, float *e, / e=y-Ax, error / struct ReconParams reconparams, struct SVParams svpar, struct AValues_char * A_Padded_Map, float Aval_max_ptr, char ImageReconMask, char verboseLevel) { int i,j,jj,p,t,iter,it_print=1; int NumMaskVoxels=0; //float *x; / image data / //float y; / sinogram projections data / float w; / projections weights data / float voxelsBuffer1; /* the first N entries are the voxel values. / float voxelsBuffer2; unsigned long NumUpdates=0; float totalValue=0,totalChange=0,equits=0; float avg_update,avg_update_rel; struct heap priorityheap; initialize_heap(&priorityheap); long order; char phaseMap; //struct tm1,tm2; //x = Image->image; /* x is the image vector / //y = sinogram->sino; / y is the sinogram vector / w = sinogram->weight; / vector of weights for each sinogram measurement / int Nx = Image->imgparams.Nx; int Ny = Image->imgparams.Ny; int Nxy = NxNy; int Nz = Image->imgparams.Nz; int MaxIterations = reconparams.MaxIterations; float StopThreshold = reconparams.StopThreshold; int SVLength = svpar.SVLength; int overlappingDistance = svpar.overlap; int SV_depth = svpar.SVDepth; int SV_per_Z = svpar.SV_per_Z; int SVsPerRow = svpar.SVsPerRow; int sum = svpar.Nsv; //int pieceLength = svpar.pieceLength; //struct minStruct * bandMinMap = svpar.bandMinMap; //struct maxStruct * bandMaxMap = svpar.bandMaxMap; int rep_num=(int)ceil(1/(4c_ratioconvergence_rho)); for(j=0;j<Nxy;j++) if(ImageReconMask[j]) NumMaskVoxels++; #if 0 //#ifdef find_RMSE float golden; golden = (float )multialloc(sizeof(float), 2, Nz,Nxy); // note this needs to be updated read_golden(cmdline->ReconImageDataFile,golden,Nz,Nxy,Image); float updatedVoxelsList[300]; float sumOfSE=0; for(i=0;i<Nz;i++) for(j=0;j<Nxy;j++) sumOfSE+=(Image->image[i][j]-golden[i][j])(Image->image[i][j]-golden[i][j]); float MSE=sumOfSE/Nxy/Nz; float RMSE=sqrt(MSE); fprintf(stdout,"Rho: %f initial_RMSE: %f \n",convergence_rho,RMSE); #endif order = (long ) mget_spc(sumSV_per_Z,sizeof(long)); / Order of pixel updates need NOT be raster order, just initialize / t=0; for(p=0;p<Nz;p+=SV_depth) for(i=0;i<Ny;i+=(SVLength2-overlappingDistance)) for(j=0;j<Nx;j+=(SVLength2-overlappingDistance)) { order[t]=(long)pNxy+iNx+j; / order is the first voxel coordinate, not the center / t++; } phaseMap = (char ) mget_spc(sumSV_per_Z,sizeof(char)); #pragma omp parallel for private(jj) schedule(dynamic) for(i=0;i<SV_per_Z;i++) for(jj=0;jj<sum;jj++) { if((jj/SVsPerRow)%2==0) { if((jj%SVsPerRow)%2==0) phaseMap[isum+jj]=0; else phaseMap[isum+jj]=1; } else { if((jj%SVsPerRow)%2==0) phaseMap[isum+jj]=2; else phaseMap[isum+jj]=3; } } char group_id_list[SV_per_Z][4]; for(i=0;i<SV_per_Z;i++){ if(i%4==0){ group_id_list[i][0]=0; group_id_list[i][1]=3; group_id_list[i][2]=1; group_id_list[i][3]=2; } else if(i%4==1){ group_id_list[i][0]=3; group_id_list[i][1]=0; group_id_list[i][2]=2; group_id_list[i][3]=1; } else if(i%4==2){ group_id_list[i][0]=1; group_id_list[i][1]=2; group_id_list[i][2]=3; group_id_list[i][3]=0; } else{ group_id_list[i][0]=2; group_id_list[i][1]=1; group_id_list[i][2]=0; group_id_list[i][3]=3; } } srand(time(NULL)); //struct heap_node headNodeArray[sumSV_per_Z]; //This allocation crashed silently for a large problem struct heap_node headNodeArray; headNodeArray = (struct heap_node ) mget_spc(sumSV_per_Z,sizeof(struct heap_node)); for(i=0;i<SV_per_Z;i++) for(jj=0;jj<sum;jj++) { headNodeArray[isum+jj].pt=isum+jj; headNodeArray[isum+jj].x=0.0; } int indexList_size=(int) sumSV_per_Z4c_ratio(1-convergence_rho); int indexList[indexList_size]; #ifdef ICC voxelsBuffer1 = (float )_mm_malloc(Nxysizeof(float),64); voxelsBuffer2 = (float )_mm_malloc(Nxysizeof(float),64); #else voxelsBuffer1 = (float ) malloc(Nxysizeof(float)); voxelsBuffer2 = (float ) malloc(Nxysizeof(float)); //voxelsBuffer1 = (float ) aligned_alloc(64,Nxysizeof(float)); //voxelsBuffer2 = (float ) aligned_alloc(64,Nxysizeof(float)); //voxelsBuffer1 = (float ) _aligned_malloc(Nxysizeof(float),64); //voxelsBuffer2 = (float ) _aligned_malloc(Nxysizeof(float),64); #endif for(i=0;i<Nxy;i++) voxelsBuffer1[i]=0; for(i=0;i<Nxy;i++) voxelsBuffer2[i]=0; iter=0; //coordinateShuffle(&order[0],&phaseMap[0],sumSV_per_Z); long tmp_long; char tmp_char; for(i=0; i<sumSV_per_Z-1; i++) { j = i + (rand() % (sumSV_per_Z-i)); tmp_long = order[j]; order[j] = order[i]; order[i] = tmp_long; tmp_char = phaseMap[j]; phaseMap[j] = phaseMap[i]; phaseMap[i] = tmp_char; } int startIndex=0; int endIndex=0; //gettimeofday(&tm1,NULL); char stop_FLAG=0; #pragma omp parallel { while(stop_FLAG==0 && equits<MaxIterations && iter<100MaxIterations) { #pragma omp single { if(iter==0) { startIndex=0; endIndex=sumSV_per_Z; } else { if((iter-1)%(2rep_num)==0 && iter!=1) three_way_shuffle(&order[0],&phaseMap[0],&headNodeArray[0],sumSV_per_Z); if(iter%2==1) { //SJK: This is a memory leak!! //initialize_heap(&priorityheap); priorityheap.size=0; for(jj=0;jj<sumSV_per_Z;jj++){ heap_insert(&priorityheap, &(headNodeArray[jj])); } startIndex=0; endIndex=indexList_size; for(i=0;i<endIndex;i++){ struct heap_node tempNode; get_heap_max(&priorityheap, &tempNode); indexList[i]=tempNode.pt; } } else{ startIndex=((iter-2)/2)%rep_numsumSV_per_Z/rep_num; endIndex=(((iter-2)/2)%rep_num+1)sumSV_per_Z/rep_num; } } } int group=0; for (group = 0; group < 4; group++) { #pragma omp for schedule(dynamic) reduction(+:NumUpdates) reduction(+:totalValue) reduction(+:totalChange) for (jj = startIndex; jj < endIndex; jj+=1) super_voxel_recon(jj,svpar,&NumUpdates,&totalValue,&totalChange,iter,&phaseMap[0],order,&indexList[0],w,e,A_Padded_Map,&Aval_max_ptr[0],&headNodeArray[0],sinogram->sinoparams,reconparams,Image,voxelsBuffer1,voxelsBuffer2,&group_id_list[0][0],group); } #pragma omp single { if(NumUpdates>0) { avg_update = totalChange/NumUpdates; float avg_value = totalValue/NumUpdates; avg_update_rel = avg_update/avg_value * 100; //printf("avg_update %f, avg_value %f, avg_update_rel %f\n",avg_update,avg_value,avg_update_rel); } /* float cost = MAPCostFunction3D(e, Image, sinogram, &reconparams); fprintf(stdout, "it %d cost = %-15f, avg_update %f \n", iter, cost, avg_update); / #if 0 //#ifdef find_RMSE float sumOfSE=0; for(i=0;i<Nz;i++) for(j=0;j<Nxy;j++) sumOfSE+=(Image->image[i][j]-golden[i][j])(Image->image[i][j]-golden[i][j]); float MSE=sumOfSE/Nxy/Nz; float RMSE=sqrt(MSE); if(iter<300) { updatedVoxelsList[iter]=NumUpdates1.0/Nxy/Nz; fprintf(stdout,"Rho: %f Equits: %f RMSE: %f \n",convergence_rho,updatedVoxelsList[iter],RMSE); } #endif if (avg_update_rel < StopThreshold && (endIndex!=0)) stop_FLAG = 1; iter++; equits += (float)NumUpdates/((float)NumMaskVoxelsNz); if(verboseLevel) if(equits > it_print) { fprintf(stdout,"\titeration %d, average change %.4f %%\n",it_print,avg_update_rel); it_print++; } NumUpdates=0; totalValue=0; totalChange=0; } } } //gettimeofday(&tm2,NULL); //unsigned long long tt = 1000 * (tm2.tv_sec - tm1.tv_sec) + (tm2.tv_usec - tm1.tv_usec) / 1000; //printf("\trun time %llu ms (iterations only)\n", tt); if(verboseLevel) { if(StopThreshold <= 0) fprintf(stdout,"\tNo stopping condition--running fixed iterations\n"); else if(stop_FLAG == 1) fprintf(stdout,"\tReached stopping condition\n"); else fprintf(stdout,"\tWarning: Didn't reach stopping condition\n"); } if(verboseLevel>1) { fprintf(stdout,"\tEquivalent iterations = %.1f, (non-homogeneous iterations = %d)\n",equits,iter); fprintf(stdout,"\tAverage update in last iteration (relative) = %f %%\n",avg_update_rel); fprintf(stdout,"\tAverage update in last iteration (magnitude) = %.4g\n",avg_update); } #ifdef ICC _mm_free((void )voxelsBuffer1); _mm_free((void )voxelsBuffer2); #else free((void )voxelsBuffer1); free((void )voxelsBuffer2); //_aligned_free((void )voxelsBuffer1); //_aligned_free((void )voxelsBuffer2); #endif free((void )headNodeArray); free_heap((void )&priorityheap); free((void )phaseMap); free((void )order); #ifdef find_RMSE multifree(golden,2); #endif } /* END MBIRReconstruct3D() / void forwardProject2D( float e, float x, struct AValues_char * A_Padded_Map, float Aval_max_ptr, struct SinoParams3DParallel sinoparams, struct ImageParams3D imgparams, struct SVParams svpar) { int jx,jy,i,r,j,p; int SVLength = svpar.SVLength; int overlappingDistance = svpar.overlap; struct minStruct bandMinMap = svpar.bandMinMap; int pieceLength = svpar.pieceLength; int SVsPerRow = svpar.SVsPerRow; int NViewSets = sinoparams->NViews/pieceLength; int Nx = imgparams->Nx; int Ny = imgparams->Ny; int NChannels = sinoparams->NChannels; int M = sinoparams->NViewssinoparams->NChannels; for (i = 0; i < M; i++) e[i] = 0.0; for (jy = 0; jy < Ny; jy++) for (jx = 0; jx < Nx; jx++) { int SV_ind_y = jy/(2SVLength-overlappingDistance); int SV_ind_x = jx/(2SVLength-overlappingDistance); int SVPosition = SV_ind_ySVsPerRow + SV_ind_x; int SV_jy = SV_ind_y(2SVLength-overlappingDistance); int SV_jx = SV_ind_x(2SVLength-overlappingDistance); int VoxelPosition = (jy-SV_jy)(2SVLength+1)+(jx-SV_jx); // fprintf(stdout,"jy %d jx %d SVPosition %d SV_jy %d SV_jx %d VoxelPosition %d \n",jy,jx,SVPosition,SV_jy,SV_jx,VoxelPosition); // I think the second condition will always be true if (A_Padded_Map[SVPosition][VoxelPosition].length > 0 && VoxelPosition < ((2SVLength+1)(2SVLength+1))) { unsigned char A_padd_Tr_ptr = &A_Padded_Map[SVPosition][VoxelPosition].val[0]; float rescale = Aval_max_ptr[jyNx+jx](1.0/255); float xval = x[jyNx+jx]; for(p=0;p<NViewSets;p++) { int myCount = A_Padded_Map[SVPosition][VoxelPosition].pieceWiseWidth[p]; int pieceWiseMin = A_Padded_Map[SVPosition][VoxelPosition].pieceWiseMin[p]; int position = ppieceLengthNChannels + pieceWiseMin; for(r=0;r<myCount;r++) for(j=0;j<pieceLength;j++) { int bandMin = bandMinMap[SVPosition].bandMin[ppieceLength+j]; int proj_idx = position + jNChannels + bandMin + r; if((pieceWiseMin + bandMin + r) >= NChannels \|\| proj_idx >= M ) { fprintf(stderr,"forwardProject() out of bounds: p %d r %d j %d\n",p,r,j); fprintf(stderr,"forwardProject() out of bounds: total_1 %d total_2 %d\n",pieceWiseMin+bandMin+r,proj_idx); exit(-1); } else e[proj_idx] += A_padd_Tr_ptr[rpieceLength+j]rescale xval; } A_padd_Tr_ptr += myCountpieceLength; } } } } / END forwardProject2D() / void super_voxel_recon( int jj, struct SVParams svpar, unsigned long NumUpdates, float totalValue, float totalChange, int iter, char phaseMap, long order, int indexList, float w, float e, struct AValues_char * A_Padded_Map, float Aval_max_ptr, struct heap_node headNodeArray, struct SinoParams3DParallel sinoparams, struct ReconParams reconparams, struct Image3D Image, float voxelsBuffer1, float voxelsBuffer2, char group_array, int group_id) { int jy,jx,p,i,q,t,j,currentSlice,startSlice; int SV_depth_modified; int NumUpdates_loc=0; float totalValue_loc=0,totalChange_loc=0; float image = Image->image; float proximalmap = reconparams.proximalmap; struct ImageParams3D imgparams = Image->imgparams; int Nx = imgparams.Nx; int Ny = imgparams.Ny; int Nz = imgparams.Nz; char PositivityFlag = reconparams.Positivity; int SVLength = svpar.SVLength; int overlappingDistance = svpar.overlap; int SV_depth = svpar.SVDepth; int SVsPerRow = svpar.SVsPerRow; struct minStruct * bandMinMap = svpar.bandMinMap; struct maxStruct * bandMaxMap = svpar.bandMaxMap; int pieceLength = svpar.pieceLength; int NViewSets = sinoparams.NViews/pieceLength; int jj_new; if(iter%2==0) jj_new=jj; else jj_new=indexList[jj]; startSlice = order[jj_new] / Nx / Ny; jy = (order[jj_new] - startSlice* Nx * Ny) / Nx; jx = (order[jj_new] - startSlice* Nx * Ny) % Nx; if(phaseMap[jj_new]!=group_array[startSlice/SV_depth4+group_id]) return; if((startSlice+SV_depth)>Nz) SV_depth_modified=Nz-startSlice; else SV_depth_modified=SV_depth; int SVPosition=jy/(2SVLength-overlappingDistance)SVsPerRow+jx/(2SVLength-overlappingDistance); int countNumber=0; /XW: the number of voxels chosen for a certain radius of circle/ int radius =SVLength; /XW: choose the circle radius/ int coordinateSize=1; /XW: CoordinateSize is the size of a minimum square enclosing the circle. For the baseline code, coordinateSize=1 because only 1 voxel/ /XW: imagine that this is a minimum square enclosing the circle. The square "touches" the circle on 4 coordinate points. CoordianteSize is the possible * maximum number of voxels for a certain radius of circle / if(radius!=0) coordinateSize=(2radius+1)(2radius+1); int k_newCoordinate[coordinateSize]; int j_newCoordinate[coordinateSize]; int j_newAA=0; int k_newAA=0; int voxelIncrement=0; /XW: choosing the voxels locations in a circle/ for(j_newAA=jy;j_newAA<=(jy+2radius);j_newAA++) for(k_newAA=jx;k_newAA<=(jx+2radius);k_newAA++) { if(j_newAA>=0 && k_newAA >=0 && j_newAA <Ny && k_newAA < Nx) { if(A_Padded_Map[SVPosition][voxelIncrement].length >0) { j_newCoordinate[countNumber]=j_newAA; k_newCoordinate[countNumber]=k_newAA; countNumber++; } } voxelIncrement++; } /XW: if no voxel chosen, we skip this loop iteration/ if(countNumber==0) return; coordinateShuffle(&j_newCoordinate[0],&k_newCoordinate[0],countNumber); /XW: for a supervoxel, bandMin records the starting position of the sinogram band at each view/ /XW: for a supervoxel, bandMax records the end position of the sinogram band at each view / channel_t bandMin[sinoparams.NViews]__attribute__((aligned(32))); channel_t bandMax[sinoparams.NViews]__attribute__((aligned(32))); channel_t bandWidthTemp[sinoparams.NViews]__attribute__((aligned(32))); channel_t bandWidth[NViewSets]__attribute__((aligned(32))); #ifdef ICC _intel_fast_memcpy(&bandMin[0],&bandMinMap[SVPosition].bandMin[0],sizeof(channel_t)(sinoparams.NViews)); _intel_fast_memcpy(&bandMax[0],&bandMaxMap[SVPosition].bandMax[0],sizeof(channel_t)(sinoparams.NViews)); #else memcpy(&bandMin[0],&bandMinMap[SVPosition].bandMin[0],sizeof(channel_t)(sinoparams.NViews)); memcpy(&bandMax[0],&bandMaxMap[SVPosition].bandMax[0],sizeof(channel_t)(sinoparams.NViews)); #endif #pragma vector aligned for(p=0;p< sinoparams.NViews;p++) bandWidthTemp[p]=bandMax[p]-bandMin[p]; for (p = 0; p < NViewSets; p++) { int bandWidthMax=bandWidthTemp[ppieceLength]; for(t=0;t<pieceLength;t++){ if(bandWidthTemp[ppieceLength+t]>bandWidthMax) bandWidthMax=bandWidthTemp[ppieceLength+t]; } bandWidth[p]=bandWidthMax; } float * newWArray = (float *)malloc(sizeof(float ) * NViewSets); float newEArray = (float )malloc(sizeof(float ) NViewSets); float CopyNewEArray = (float )malloc(sizeof(float ) NViewSets); for (p = 0; p < NViewSets; p++) { newWArray[p] = (float )malloc(sizeof(float)bandWidth[p]pieceLengthSV_depth_modified); newEArray[p] = (float )malloc(sizeof(float)bandWidth[p]pieceLengthSV_depth_modified); CopyNewEArray[p] = (float )malloc(sizeof(float)bandWidth[p]pieceLengthSV_depth_modified); } float newWArrayPointer=&newWArray[0][0]; float newEArrayPointer=&newEArray[0][0]; /XW: copy the interlaced we into the memory buffer/ for (p = 0; p < NViewSets; p++) { newWArrayPointer=&newWArray[p][0]; newEArrayPointer=&newEArray[p][0]; for(i=0;i<SV_depth_modified;i++) for(q=0;q<pieceLength;q++) { #ifdef ICC _intel_fast_memcpy(newWArrayPointer,&w[startSlice+i][ppieceLengthsinoparams.NChannels+qsinoparams.NChannels+bandMin[ppieceLength+q]],sizeof(float)(bandWidth[p])); _intel_fast_memcpy(newEArrayPointer,&e[startSlice+i][ppieceLengthsinoparams.NChannels+qsinoparams.NChannels+bandMin[ppieceLength+q]],sizeof(float)(bandWidth[p])); #else memcpy(newWArrayPointer,&w[startSlice+i][ppieceLengthsinoparams.NChannels+qsinoparams.NChannels+bandMin[ppieceLength+q]],sizeof(float)(bandWidth[p])); memcpy(newEArrayPointer,&e[startSlice+i][ppieceLengthsinoparams.NChannels+qsinoparams.NChannels+bandMin[ppieceLength+q]],sizeof(float)(bandWidth[p])); #endif newWArrayPointer+=bandWidth[p]; newEArrayPointer+=bandWidth[p]; } } for (p = 0; p < NViewSets; p++) { #ifdef ICC _intel_fast_memcpy(&CopyNewEArray[p][0],&newEArray[p][0],sizeof(float)bandWidth[p]pieceLengthSV_depth_modified); #else memcpy(&CopyNewEArray[p][0],&newEArray[p][0],sizeof(float)bandWidth[p]pieceLengthSV_depth_modified); #endif } float newWArrayTransposed = (float )malloc(sizeof(float ) NViewSets); float newEArrayTransposed = (float )malloc(sizeof(float ) NViewSets); for (p = 0; p < NViewSets; p++) { newWArrayTransposed[p] = (float )malloc(sizeof(float)bandWidth[p]pieceLengthSV_depth_modified); newEArrayTransposed[p] = (float )malloc(sizeof(float)bandWidth[p]pieceLengthSV_depth_modified); } float WTransposeArrayPointer=&newWArrayTransposed[0][0]; float ETransposeArrayPointer=&newEArrayTransposed[0][0]; for (p = 0; p < NViewSets; p++) for(currentSlice=0;currentSlice<(SV_depth_modified);currentSlice++) { WTransposeArrayPointer=&newWArrayTransposed[p][currentSlicebandWidth[p]pieceLength]; ETransposeArrayPointer=&newEArrayTransposed[p][currentSlicebandWidth[p]pieceLength]; newEArrayPointer=&newEArray[p][currentSlicebandWidth[p]pieceLength]; newWArrayPointer=&newWArray[p][currentSlicebandWidth[p]pieceLength]; for(q=0;q<bandWidth[p];q++) { #pragma vector aligned for(t=0;t<pieceLength;t++) { ETransposeArrayPointer[qpieceLength+t]=newEArrayPointer[bandWidth[p]t+q]; WTransposeArrayPointer[qpieceLength+t]=newWArrayPointer[bandWidth[p]t+q]; } } } WTransposeArrayPointer=&newWArrayTransposed[0][0]; ETransposeArrayPointer=&newEArrayTransposed[0][0]; newEArrayPointer=&newEArray[0][0]; for (p = 0; p < NViewSets; p++) free((void )newWArray[p]); free((void )newWArray); / Turn off zero-skipping for 1st iteration / char zero_skip_enable=0; // 1: enable, 0: disable if(iter>0 && PositivityFlag) zero_skip_enable=1; /XW: the start of the loop to compute theta1, theta2/ for(i=0;i<countNumber;i++) { const short j_new = j_newCoordinate[i]; /XW: get the voxel's x,y location/ const short k_new = k_newCoordinate[i]; float Aval_max = Aval_max_ptr[j_newNx+k_new]; float tempV[SV_depth_modified]; float tempProxMap[SV_depth_modified]; float neighbors[SV_depth_modified][10]; char zero_skip_FLAG[SV_depth_modified]; float diff[SV_depth_modified]; float THETA1[SV_depth_modified]; float THETA2[SV_depth_modified]; memset(&THETA1[0],0.0, sizeof(THETA1)); memset(&THETA2[0],0.0, sizeof(THETA2)); int theVoxelPosition=(j_new-jy)(2SVLength+1)+(k_new-jx); unsigned char * A_padd_Tranpose_pointer = &A_Padded_Map[SVPosition][theVoxelPosition].val[0]; for(currentSlice=0;currentSlice<SV_depth_modified;currentSlice++) { tempV[currentSlice] = (float)(image[startSlice+currentSlice][j_newNx+k_new]); /XW: current voxel's value/ zero_skip_FLAG[currentSlice] = 0; if(reconparams.ReconType == MBIR_MODULAR_RECONTYPE_QGGMRF_3D) { ExtractNeighbors3D(&neighbors[currentSlice][0],k_new,j_new,&image[startSlice+currentSlice][0],imgparams); if((startSlice+currentSlice)==0) neighbors[currentSlice][8]=voxelsBuffer1[j_newNx+k_new]; else neighbors[currentSlice][8]=image[startSlice+currentSlice-1][j_newNx+k_new]; if((startSlice+currentSlice)<(Nz-1)) neighbors[currentSlice][9]=image[startSlice+currentSlice+1][j_newNx+k_new]; else neighbors[currentSlice][9]=voxelsBuffer2[j_newNx+k_new]; if(zero_skip_enable) if(tempV[currentSlice] == 0.0) { zero_skip_FLAG[currentSlice] = 1; for (j = 0; j < 10; j++) { if (neighbors[currentSlice][j] != 0.0) { zero_skip_FLAG[currentSlice] = 0; break; } } } } if(reconparams.ReconType == MBIR_MODULAR_RECONTYPE_PandP) tempProxMap[currentSlice] = proximalmap[startSlice+currentSlice][j_newNx+k_new]; } A_padd_Tranpose_pointer = &A_Padded_Map[SVPosition][theVoxelPosition].val[0]; for(p=0;p<NViewSets;p++) { const int myCount=A_Padded_Map[SVPosition][theVoxelPosition].pieceWiseWidth[p]; const int pieceMin=A_Padded_Map[SVPosition][theVoxelPosition].pieceWiseMin[p]; #pragma vector aligned for(currentSlice=0;currentSlice<SV_depth_modified;currentSlice++) if(zero_skip_FLAG[currentSlice] == 0) { WTransposeArrayPointer=&newWArrayTransposed[p][currentSlicebandWidth[p]pieceLength]; ETransposeArrayPointer=&newEArrayTransposed[p][currentSlicebandWidth[p]pieceLength]; WTransposeArrayPointer+=pieceMinpieceLength; ETransposeArrayPointer+=pieceMinpieceLength; float tempTHETA1=0.0; float tempTHETA2=0.0; //Not finding evidence this makes a difference --SJK //Deprecated by Intel anyway //#pragma vector aligned //#pragma simd reduction(+:tempTHETA2,tempTHETA1) for(t=0;t<myCountpieceLength;t++) { / summing over voxels which are not skipped or masked/ tempTHETA1 += A_padd_Tranpose_pointer[t]WTransposeArrayPointer[t]ETransposeArrayPointer[t]; tempTHETA2 += A_padd_Tranpose_pointer[t]WTransposeArrayPointer[t]A_padd_Tranpose_pointer[t]; } THETA1[currentSlice]+=tempTHETA1; THETA2[currentSlice]+=tempTHETA2; } A_padd_Tranpose_pointer += myCountpieceLength; } for(currentSlice=0;currentSlice<SV_depth_modified;currentSlice++) { THETA1[currentSlice]=-THETA1[currentSlice]Aval_max(1.0/255); THETA2[currentSlice]=THETA2[currentSlice]Aval_max(1.0/255)Aval_max(1.0/255); } ETransposeArrayPointer=&newEArrayTransposed[0][0]; A_padd_Tranpose_pointer = &A_Padded_Map[SVPosition][theVoxelPosition].val[0]; for(currentSlice=0;currentSlice<SV_depth_modified;currentSlice++) if(zero_skip_FLAG[currentSlice] == 0) { float pixel,step; if(reconparams.ReconType == MBIR_MODULAR_RECONTYPE_QGGMRF_3D) { step = QGGMRF3D_Update(reconparams,tempV[currentSlice],&neighbors[currentSlice][0],THETA1[currentSlice],THETA2[currentSlice]); } else if(reconparams.ReconType == MBIR_MODULAR_RECONTYPE_PandP) { step = PandP_Update(reconparams,tempV[currentSlice],tempProxMap[currentSlice],THETA1[currentSlice],THETA2[currentSlice]); } else { fprintf(stderr,"Error** Unrecognized ReconType in ICD update\n"); exit(-1); } pixel = tempV[currentSlice] + step; /* can apply over-relaxation to the step size here / if(PositivityFlag) image[startSlice+currentSlice][j_newNx+k_new] = ((pixel < 0.0) ? 0.0 : pixel); else image[startSlice+currentSlice][j_newNx+k_new] = pixel; diff[currentSlice] = image[startSlice+currentSlice][j_newNx+k_new] - tempV[currentSlice]; totalChange_loc += fabs(diff[currentSlice]); totalValue_loc += fabs(tempV[currentSlice]); NumUpdates_loc++; diff[currentSlice]=diff[currentSlice]Aval_max(1.0/255); } for(p=0;p<NViewSets;p++) { const int myCount=A_Padded_Map[SVPosition][theVoxelPosition].pieceWiseWidth[p]; const int pieceMin=A_Padded_Map[SVPosition][theVoxelPosition].pieceWiseMin[p]; #pragma vector aligned for(currentSlice=0;currentSlice<SV_depth_modified;currentSlice++) if(diff[currentSlice]!=0 && zero_skip_FLAG[currentSlice] == 0) { ETransposeArrayPointer=&newEArrayTransposed[p][currentSlicebandWidth[p]pieceLength]; ETransposeArrayPointer+=pieceMinpieceLength; #pragma vector aligned for(t=0;t<(myCountpieceLength);t++) ETransposeArrayPointer[t]= ETransposeArrayPointer[t]-A_padd_Tranpose_pointer[t]diff[currentSlice]; } A_padd_Tranpose_pointer+=myCountpieceLength; } } for (p = 0; p < NViewSets; p++) free((void )newWArrayTransposed[p]); free((void )newWArrayTransposed); headNodeArray[jj_new].x=totalChange_loc; for (p = 0; p < NViewSets; p++) for(currentSlice=0;currentSlice<SV_depth_modified;currentSlice++) { ETransposeArrayPointer=&newEArrayTransposed[p][currentSlicebandWidth[p]pieceLength]; newEArrayPointer=&newEArray[p][currentSlicebandWidth[p]pieceLength]; for(q=0;q<bandWidth[p];q++) { #pragma vector aligned for(t=0;t<pieceLength;t++) newEArrayPointer[bandWidth[p]t+q]=ETransposeArrayPointer[qpieceLength+t]; } } for (p = 0; p < NViewSets; p++) free((void )newEArrayTransposed[p]); free((void *)newEArrayTransposed); newEArrayPointer=&newEArray[0][0]; float CopyNewEArrayPointer=&CopyNewEArray[0][0]; float* eArrayPointer=&e[0][0]; for (p = 0; p < NViewSets; p++) /XW: update the error term in the memory buffer/ { newEArrayPointer=&newEArray[p][0]; CopyNewEArrayPointer=&CopyNewEArray[p][0]; for (currentSlice=0; currentSlice< SV_depth_modified;currentSlice++) { #pragma vector aligned for(q=0;q<pieceLength;q++) { eArrayPointer=&e[startSlice+currentSlice][ppieceLengthsinoparams.NChannels+qsinoparams.NChannels+bandMin[ppieceLength+q]]; for(t=0;t<bandWidth[p];t++) { #pragma omp atomic eArrayPointer += (newEArrayPointer)-(CopyNewEArrayPointer); newEArrayPointer++; CopyNewEArrayPointer++; eArrayPointer++; } } } } for (p = 0; p < NViewSets; p++) { free((void )newEArray[p]); free((void )CopyNewEArray[p]); } free((void )newEArray); free((void )CopyNewEArray); NumUpdates += NumUpdates_loc; totalValue += totalValue_loc; totalChange += totalChange_loc; } /* END super_voxel_recon() / void coordinateShuffle(int order1, int order2,int len) { int i, j, tmp1,tmp2; for (i = 0; i < len-1; i++) { j = i + (rand() % (len-i)); tmp1 = order1[j]; tmp2 = order2[j]; order1[j] = order1[i]; order2[j] = order2[i]; order1[i] = tmp1; order2[i] = tmp2; } } void three_way_shuffle(long order1, char order2, struct heap_node headNodeArray, int len) { int i,j; long tmp_long; char tmp_char; float temp_x; for (i = 0; i < len-1; i++) { j = i + (rand() % (len-i)); tmp_long = order1[j]; order1[j] = order1[i]; order1[i] = tmp_long; tmp_char = order2[j]; order2[j] = order2[i]; order2[i] = tmp_char; temp_x=headNodeArray[j].x; headNodeArray[j].x=headNodeArray[i].x; headNodeArray[i].x=temp_x; } } float MAPCostFunction3D(float *e,struct Image3D Image,struct Sino3DParallel sinogram,struct ReconParams reconparams) { int i, M, j, jx, jy, jz, Nx, Ny, Nz, plusx, minusx, plusy, plusz ; float x ; float w ; float nloglike, nlogprior_nearest, nlogprior_diag, nlogprior_interslice ; x = Image->image; w = sinogram->weight; M = sinogram->sinoparams.NViews * sinogram->sinoparams.NChannels ; Nx = Image->imgparams.Nx; Ny = Image->imgparams.Ny; Nz = Image->imgparams.Nz; nloglike = 0.0; for (i = 0; i <sinogram->sinoparams.NSlices; i++){ for (j = 0; j < M; j++) nloglike += e[i][j]w[i][j]e[i][j]; } nloglike /= 2.0; nlogprior_nearest = 0.0; nlogprior_diag = 0.0; nlogprior_interslice = 0.0; for (jz = 0; jz < Nz; jz++) for (jy = 0; jy < Ny; jy++) for (jx = 0; jx < Nx; jx++) { plusx = jx + 1; plusx = ((plusx < Nx) ? plusx : 0); minusx = jx - 1; minusx = ((minusx < 0) ? Nx-1 : minusx); plusy = jy + 1; plusy = ((plusy < Ny) ? plusy : 0); plusz = jz + 1; plusz = ((plusz < Nz) ? plusz : 0); j = jyNx + jx; nlogprior_nearest += QGGMRF_Potential((x[jz][j] - x[jz][jyNx+plusx]), reconparams); nlogprior_nearest += QGGMRF_Potential((x[jz][j] - x[jz][plusyNx+jx]),reconparams); nlogprior_diag += QGGMRF_Potential((x[jz][j] - x[jz][plusyNx+minusx]),reconparams); nlogprior_diag += QGGMRF_Potential((x[jz][j] - x[jz][plusyNx+plusx]),reconparams); nlogprior_interslice += QGGMRF_Potential((x[jz][j] - x[plusz][jyNx+jx]),reconparams); } return (nloglike + reconparams->b_nearest * nlogprior_nearest + reconparams->b_diag * nlogprior_diag + reconparams->b_interslice * nlogprior_interslice) ; } #if 0 // NOTE this needs to be updated void read_golden(char fname,float golden,int Nz,int N, struct Image3D Image) { FILE fp; int i; char slicefname[1024]; char sliceindex; sliceindex= (char )malloc(MBIR_MODULAR_MAX_NUMBER_OF_SLICE_DIGITS); for(i=0;i<Nz;i++){ sprintf(sliceindex,"%.d",MBIR_MODULAR_MAX_NUMBER_OF_SLICE_DIGITS,Image->imgparams.FirstSliceNumber+i); /* Obtain file name for the given slice / strcpy(slicefname,fname); strcat(slicefname,"_slice"); strcat(slicefname,sliceindex); / append slice index */ strcat(slicefname,".2Dimgdata"); if ((fp = fopen(slicefname, "r")) == NULL) { fprintf(stderr, "ERROR in read golden: can't open file %s.\n", slicefname); exit(-1); } fread(&golden[i][0],sizeof(float),N,fp); fclose(fp); } } #endif #if 0 static __inline__ unsigned long long rdtsc() { unsigned hi,lo; __asm __volatile__ ("rdtsc" : "=a"(lo),"=d"(hi)); return ( (unsigned long long)lo)\|( ((unsigned long long)hi)<<32 ); } #endif
lastPrivate.c	#include <stdio.h> #include <stdlib.h> #include <omp.h> int main(void){ int i; int x; x=44; #pragma omp parallel #pragma omp for lastprivate(x) for(i=0;i<=10;i++){ x=i; printf("Thread number: %d x: %d\n",omp_get_thread_num(),x); } printf("x is %d\n", x); }
j3d27pt.gold.h	#include <cstring> using std::memcpy; template <class T> void jacobi_gold(T fout, const T fin, double h2inv, double a, double b, int L, int M, int N) { double (out)[M][N] = (double ()[M][N]) fout; double (in)[M][N] = (double ()[M][N]) fin; auto ftemp1 = new T[L * M * N]; auto ftemp2 = new T[L * M * N]; memset(ftemp1, 0, sizeof(T)LMN); memset(ftemp2, 0, sizeof(T)LMN); double (temp1)[M][N] = (T ()[M][N]) ftemp1; double (temp2)[M][N] = (T ()[M][N]) ftemp2; memcpy(ftemp1, fin, sizeof(T)LMN); double c = b h2inv; double d = c * 0.5; double e = c * 0.125; double f = c * 0.3; for (int t = 0; t < 8; t++) { #pragma omp parallel for for (int k = 1; k < L - 1; ++k) { for (int j = 1; j < M - 1; ++j) { for (int i = 1; i < N - 1; ++i) { if (!(t%2)) { temp2[k][j][i] = atemp1[k][j][i] - d(temp1[k-1][j-1][i-1] + temp1[k-1][j-1][i+1] + temp1[k-1][j+1][i-1] + temp1[k-1][j+1][i+1] + temp1[k+1][j-1][i-1] + temp1[k+1][j-1][i+1] + temp1[k+1][j+1][i-1] + temp1[k+1][j+1][i+1]) + e(temp1[k-1][j-1][i] + temp1[k-1][j][i-1] + temp1[k-1][j][i+1] + temp1[k-1][j+1][i] + temp1[k][j-1][i-1] + temp1[k][j-1][i+1] + temp1[k][j+1][i-1] + temp1[k][j+1][i+1] + temp1[k+1][j-1][i] + temp1[k+1][j][i-1] + temp1[k+1][j][i+1] + temp1[k][j+1][i]) + f(temp1[k-1][j][i] + temp1[k][j-1][i] + temp1[k][j][i-1] + temp1[k][j][i+1] + temp1[k][j+1][i] + temp1[k+1][j][i]) + 0.13temp1[k][j][i]; } else { temp1[k][j][i] = atemp2[k][j][i] - d(temp2[k-1][j-1][i-1] + temp2[k-1][j-1][i+1] + temp2[k-1][j+1][i-1] + temp2[k-1][j+1][i+1] + temp2[k+1][j-1][i-1] + temp2[k+1][j-1][i+1] + temp2[k+1][j+1][i-1] + temp2[k+1][j+1][i+1]) + e(temp2[k-1][j-1][i] + temp2[k-1][j][i-1] + temp2[k-1][j][i+1] + temp2[k-1][j+1][i] + temp2[k][j-1][i-1] + temp2[k][j-1][i+1] + temp2[k][j+1][i-1] + temp2[k][j+1][i+1] + temp2[k+1][j-1][i] + temp2[k+1][j][i-1] + temp2[k+1][j][i+1] + temp2[k][j+1][i]) + f(temp2[k-1][j][i] + temp2[k][j-1][i] + temp2[k][j][i-1] + temp2[k][j][i+1] + temp2[k][j+1][i] + temp2[k+1][j][i]) + 0.13temp2[k][j][i]; } } } } } memcpy(fout, ftemp1, sizeof(T)LM*N); }
GB_AxB_dot2_template.c	//------------------------------------------------------------------------------ // GB_AxB_dot2_template: C=A'B, C<!M>=A'B, or C<M>=A'B via dot products //------------------------------------------------------------------------------ // SuiteSparse:GraphBLAS, Timothy A. Davis, (c) 2017-2021, All Rights Reserved. // SPDX-License-Identifier: Apache-2.0 //------------------------------------------------------------------------------ // A and B are sparse, bitmap, or full; never hypersparse. If the input // matrices A and/or B are hypersparse, they are converted into hyper_shallow // sparse matrices, and C is converted from bitmap to sparse/hypersparse when // done. // If A_NOT_TRANSPOSED is #defined, the C=AB or C<#M>=AB is computed. // In this case A is bitmap or full, and B is sparse. // GB_DOT_ALWAYS_SAVE_CIJ: C(i,j) = cij #undef GB_DOT_ALWAYS_SAVE_CIJ #if GB_C_IS_FULL #define GB_DOT_ALWAYS_SAVE_CIJ \ { \ GB_PUTC (cij, pC) ; \ } #else #define GB_DOT_ALWAYS_SAVE_CIJ \ { \ GB_PUTC (cij, pC) ; \ Cb [pC] = 1 ; \ task_cnvals++ ; \ } #endif // GB_DOT_SAVE_CIJ: C(i,j) = cij, unless already done by GB_DOT #undef GB_DOT_SAVE_CIJ #if GB_IS_ANY_MONOID // for the ANY monoid, GB_DOT saves C(i,j) as soon as a value is found #define GB_DOT_SAVE_CIJ #else // all other monoids: C(i,j) = cij if it exists #define GB_DOT_SAVE_CIJ \ { \ if (GB_CIJ_EXISTS) \ { \ GB_DOT_ALWAYS_SAVE_CIJ ; \ } \ } #endif #if ( !GB_A_IS_HYPER && !GB_B_IS_HYPER ) { //-------------------------------------------------------------------------- // C=A'B, C<M>=A'B, or C<!M>=A'B where C is bitmap //-------------------------------------------------------------------------- int tid ; #if GB_C_IS_FULL #pragma omp parallel for num_threads(nthreads) schedule(dynamic,1) #else #pragma omp parallel for num_threads(nthreads) schedule(dynamic,1) \ reduction(+:cnvals) #endif for (tid = 0 ; tid < ntasks ; tid++) { //---------------------------------------------------------------------- // get the task descriptor //---------------------------------------------------------------------- const int a_tid = tid / nbslice ; const int b_tid = tid % nbslice ; const int64_t kA_start = A_slice [a_tid] ; const int64_t kA_end = A_slice [a_tid+1] ; const int64_t kB_start = B_slice [b_tid] ; const int64_t kB_end = B_slice [b_tid+1] ; #if (!GB_C_IS_FULL) int64_t task_cnvals = 0 ; #endif //---------------------------------------------------------------------- // C=A'B, C<M>=A'B, or C<!M>=A'B via dot products //---------------------------------------------------------------------- for (int64_t j = kB_start ; j < kB_end ; j++) { //------------------------------------------------------------------ // get C(:,j) //------------------------------------------------------------------ const int64_t pC_start = j * cvlen ; //------------------------------------------------------------------ // get B(:,j) //------------------------------------------------------------------ #if GB_B_IS_SPARSE // B is sparse (never hypersparse) const int64_t pB_start = Bp [j] ; const int64_t pB_end = Bp [j+1] ; const int64_t bjnz = pB_end - pB_start ; if (bjnz == 0) { // no work to do if B(:,j) is empty, except to clear Cb memset (&Cb [pC_start + kA_start], 0, kA_end - kA_start) ; continue ; } #if GB_A_IS_SPARSE // Both A and B are sparse; get first and last in B(:,j) const int64_t ib_first = Bi [pB_start] ; const int64_t ib_last = Bi [pB_end-1] ; #endif #else // B is bitmap or full const int64_t pB_start = j * vlen ; #endif //------------------------------------------------------------------ // C(:,j)<#M(:,j)> = A'B(:,j), or C(:,j) = A'B(:,j) if no mask //------------------------------------------------------------------ for (int64_t i = kA_start ; i < kA_end ; i++) { //-------------------------------------------------------------- // get C(i,j), M(i,j), and clear the C(i,j) bitmap //-------------------------------------------------------------- int64_t pC = pC_start + i ; // C is bitmap #if defined ( GB_ANY_SPECIALIZED ) // M is bitmap and structural; Mask_comp true Cb [pC] = 0 ; if (!Mb [pC]) #elif defined ( GB_MASK_IS_PRESENT ) bool mij ; if (M_is_bitmap) { // M is bitmap mij = Mb [pC] && GB_mcast (Mx, pC, msize) ; } else if (M_is_full) { // M is full mij = GB_mcast (Mx, pC, msize) ; } else // M is sparse or hyper { // M has been scattered into the C bitmap mij = (Cb [pC] > 1) ; } Cb [pC] = 0 ; if (mij ^ Mask_comp) #elif GB_C_IS_FULL // C is full; nothing to do #else // M is not present Cb [pC] = 0 ; #endif { //---------------------------------------------------------- // the mask allows C(i,j) to be computed //---------------------------------------------------------- #if GB_A_IS_SPARSE // A is sparse int64_t pA = Ap [i] ; const int64_t pA_end = Ap [i+1] ; const int64_t ainz = pA_end - pA ; #if (!GB_C_IS_FULL) if (ainz > 0) // skip this test if C is full #endif #else // A is bitmap or full #ifdef GB_A_NOT_TRANSPOSED // A(i,:) starts at position i const int64_t pA = i ; #else // A(:,i) starts at position i * vlen const int64_t pA = i * vlen ; #endif #endif { // C(i,j) = A(:,i)'B(:,j) or A(i,:)B(:,j) bool cij_exists = false ; GB_CIJ_DECLARE (cij) ; #include "GB_AxB_dot_cij.c" } } } } #if (!GB_C_IS_FULL) cnvals += task_cnvals ; #endif } } #endif #undef GB_A_IS_SPARSE #undef GB_A_IS_HYPER #undef GB_A_IS_BITMAP #undef GB_A_IS_FULL #undef GB_B_IS_SPARSE #undef GB_B_IS_HYPER #undef GB_B_IS_BITMAP #undef GB_B_IS_FULL #undef GB_DOT_ALWAYS_SAVE_CIJ #undef GB_DOT_SAVE_CIJ
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 <nnvm/node.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))); } } void ExecuteMonInputCallback( const nnvm::IndexedGraph &idx, const std::vector<NDArray > &state_arrays, size_t nid, const std::function<void(const char , const char , void )> &monitor_callback); void ExecuteMonOutputCallback( const nnvm::IndexedGraph &idx, const std::vector<NDArray > &state_arrays, size_t nid, const std::function<void(const char , const char , void )> &monitor_callback); /! \brief This is function can return the output names of a NodeEntry. */ static inline std::string GetOutputName(const nnvm::NodeEntry& e) { nnvm::Symbol sym; sym.outputs.push_back(e); return sym.ListOutputNames()[0]; } inline mxnet::TShape CanonicalizeAxes(const mxnet::TShape& src) { // convert negative axes to positive values const int ndim = src.ndim(); mxnet::TShape axes = src; for (int i = 0; i < ndim; ++i) { if (axes[i] < 0) { axes[i] += ndim; } CHECK(axes[i] >= 0 && axes[i] < ndim) << "axes[" << i << "]=" << axes[i] << " exceeds the range [" << 0 << ", " << ndim << ")"; } return axes; } inline bool is_float(const int dtype) { return dtype == mshadow::kFloat32 \|\| dtype == mshadow::kFloat64 \|\| dtype == mshadow::kFloat16; } } // namespace common } // namespace mxnet #endif // MXNET_COMMON_UTILS_H_
dqp3.c	/! @copyright (c) 2017 King Abdullah University of Science and Technology (KAUST). All rights reserved. * * STARS-H is a software package, provided by King Abdullah * University of Science and Technology (KAUST) * * @file src/backends/openmp/blrm/dqp3.c * @version 1.3.0 * @author Aleksandr Mikhalev * @date 2017-11-07 * / #include "common.h" #include "starsh.h" int starsh_blrm__dqp3_omp(STARSH_blrm matrix, STARSH_blrf format, int maxrank, double tol, int onfly) //! Approximate each tile of BLR matrix with RRQR (GEQP3 function). /! @param[out] matrix: Address of pointer to @ref STARSH_blrm object. * @param[in] format: Block low-rank format. * @param[in] maxrank: Maximum possible rank. * @param[in] tol: Relative error tolerance. * @param[in] onfly: Whether not to store dense blocks. * @return Error code @ref STARSH_ERRNO. * @ingroup blrm * / { STARSH_blrf F = format; STARSH_problem P = F->problem; STARSH_kernel kernel = P->kernel; STARSH_int nblocks_far = F->nblocks_far; STARSH_int nblocks_near = F->nblocks_near; // Shortcuts to information about clusters STARSH_cluster RC = F->row_cluster; STARSH_cluster CC = F->col_cluster; void RD = RC->data, CD = CC->data; // Following values default to given block low-rank format F, but they are // changed when there are false far-field blocks. STARSH_int new_nblocks_far = nblocks_far; STARSH_int new_nblocks_near = nblocks_near; STARSH_int block_far = F->block_far; STARSH_int block_near = F->block_near; // Places to store low-rank factors, dense blocks and ranks Array far_U = NULL, far_V = NULL, *near_D = NULL; int far_rank = NULL; double alloc_U = NULL, alloc_V = NULL, alloc_D = NULL; size_t offset_U = 0, offset_V = 0, offset_D = 0; STARSH_int bi, bj = 0; const int oversample = starsh_params.oversample; // Init buffers to store low-rank factors of far-field blocks if needed if(nblocks_far > 0) { STARSH_MALLOC(far_U, nblocks_far); STARSH_MALLOC(far_V, nblocks_far); STARSH_MALLOC(far_rank, nblocks_far); size_t size_U = 0, size_V = 0; // Simple cycle over all far-field blocks for(bi = 0; bi < nblocks_far; bi++) { // Get indexes of corresponding block row and block column STARSH_int i = block_far[2bi]; STARSH_int j = block_far[2bi+1]; // Get corresponding sizes and minimum of them size_U += RC->size[i]; size_V += CC->size[j]; } size_U = maxrank; size_V = maxrank; STARSH_MALLOC(alloc_U, size_U); STARSH_MALLOC(alloc_V, size_V); for(bi = 0; bi < nblocks_far; bi++) { // Get indexes of corresponding block row and block column STARSH_int i = block_far[2bi]; STARSH_int j = block_far[2bi+1]; // Get corresponding sizes and minimum of them size_t nrows = RC->size[i], ncols = CC->size[j]; int shape_U[] = {nrows, maxrank}; int shape_V[] = {ncols, maxrank}; double U = alloc_U+offset_U, V = alloc_V+offset_V; offset_U += nrowsmaxrank; offset_V += ncolsmaxrank; array_from_buffer(far_U+bi, 2, shape_U, 'd', 'F', U); array_from_buffer(far_V+bi, 2, shape_V, 'd', 'F', V); } offset_U = 0; offset_V = 0; } // Work variables int info; // Simple cycle over all far-field admissible blocks #pragma omp parallel for schedule(dynamic,1) for(bi = 0; bi < nblocks_far; bi++) { // Get indexes of corresponding block row and block column STARSH_int i = block_far[2bi]; STARSH_int j = block_far[2bi+1]; // Get corresponding sizes and minimum of them int nrows = RC->size[i]; int ncols = CC->size[j]; int mn = nrows < ncols ? nrows : ncols; int mn2 = maxrank+oversample; if(mn2 > mn) mn2 = mn; // Get size of temporary arrays int lwork = 3ncols+1, lwork_sdd = (4(size_t)mn2+7)mn2; if(lwork_sdd > lwork) lwork = lwork_sdd; lwork += (size_t)mn2(2ncols+mn2+1)+mn; int liwork = ncols, liwork_sdd = 8mn2; if(liwork_sdd > liwork) liwork = liwork_sdd; double D, work; int iwork; int info; // Allocate temporary arrays STARSH_PMALLOC(D, (size_t)nrows(size_t)ncols, info); STARSH_PMALLOC(iwork, liwork, info); STARSH_PMALLOC(work, lwork, info); // Compute elements of a block kernel(nrows, ncols, RC->pivot+RC->start[i], CC->pivot+CC->start[j], RD, CD, D, nrows); starsh_dense_dlrqp3(nrows, ncols, D, nrows, far_U[bi]->data, nrows, far_V[bi]->data, ncols, far_rank+bi, maxrank, oversample, tol, work, lwork, iwork); // Free temporary arrays free(D); free(work); free(iwork); } // Get number of false far-field blocks STARSH_int nblocks_false_far = 0; STARSH_int false_far = NULL; for(bi = 0; bi < nblocks_far; bi++) if(far_rank[bi] == -1) nblocks_false_far++; if(nblocks_false_far > 0) { // IMPORTANT: `false_far` must to be in ascending order for later code // to work normally STARSH_MALLOC(false_far, nblocks_false_far); bj = 0; for(bi = 0; bi < nblocks_far; bi++) if(far_rank[bi] == -1) false_far[bj++] = bi; } // Update lists of far-field and near-field blocks using previously // generated list of false far-field blocks if(nblocks_false_far > 0) { // Update list of near-field blocks new_nblocks_near = nblocks_near+nblocks_false_far; STARSH_MALLOC(block_near, 2new_nblocks_near); // At first get all near-field blocks, assumed to be dense #pragma omp parallel for schedule(static) for(bi = 0; bi < 2nblocks_near; bi++) block_near[bi] = F->block_near[bi]; // Add false far-field blocks #pragma omp parallel for schedule(static) for(bi = 0; bi < nblocks_false_far; bi++) { STARSH_int bj = false_far[bi]; block_near[2(bi+nblocks_near)] = F->block_far[2bj]; block_near[2(bi+nblocks_near)+1] = F->block_far[2bj+1]; } // Update list of far-field blocks new_nblocks_far = nblocks_far-nblocks_false_far; if(new_nblocks_far > 0) { STARSH_MALLOC(block_far, 2new_nblocks_far); bj = 0; for(bi = 0; bi < nblocks_far; bi++) { // `false_far` must be in ascending order for this to work if(far_rank[bi] == -1) { bj++; } else { block_far[2(bi-bj)] = F->block_far[2bi]; block_far[2(bi-bj)+1] = F->block_far[2bi+1]; } } } // Update format by creating new format STARSH_blrf F2; info = starsh_blrf_new_from_coo(&F2, P, F->symm, RC, CC, new_nblocks_far, block_far, new_nblocks_near, block_near, F->type); // Swap internal data of formats and free unnecessary data STARSH_blrf tmp_blrf = F; F = F2; F2 = tmp_blrf; STARSH_WARNING("`F` was modified due to false far-field blocks"); starsh_blrf_free(F2); } // Compute near-field blocks if needed if(onfly == 0 && new_nblocks_near > 0) { STARSH_MALLOC(near_D, new_nblocks_near); size_t size_D = 0; // Simple cycle over all near-field blocks for(bi = 0; bi < new_nblocks_near; bi++) { // Get indexes of corresponding block row and block column STARSH_int i = block_near[2bi]; STARSH_int j = block_near[2bi+1]; // Get corresponding sizes and minimum of them size_t nrows = RC->size[i]; size_t ncols = CC->size[j]; // Update size_D size_D += nrowsncols; } STARSH_MALLOC(alloc_D, size_D); // For each near-field block compute its elements #pragma omp parallel for schedule(dynamic,1) for(bi = 0; bi < new_nblocks_near; bi++) { // Get indexes of corresponding block row and block column STARSH_int i = block_near[2bi]; STARSH_int j = block_near[2bi+1]; // Get corresponding sizes and minimum of them int nrows = RC->size[i]; int ncols = CC->size[j]; int shape[2] = {nrows, ncols}; double D; #pragma omp critical { D = alloc_D+offset_D; array_from_buffer(near_D+bi, 2, shape, 'd', 'F', D); offset_D += near_D[bi]->size; } kernel(nrows, ncols, RC->pivot+RC->start[i], CC->pivot+CC->start[j], RD, CD, D, nrows); } } // Change sizes of far_rank, far_U and far_V if there were false // far-field blocks if(nblocks_false_far > 0 && new_nblocks_far > 0) { bj = 0; for(bi = 0; bi < nblocks_far; bi++) { if(far_rank[bi] == -1) bj++; else { int shape_U[2] = {far_U[bi]->shape[0], far_rank[bi]}; int shape_V[2] = {far_V[bi]->shape[0], far_rank[bi]}; array_from_buffer(far_U+bi-bj, 2, shape_U, 'd', 'F', far_U[bi]->data); array_from_buffer(far_V+bi-bj, 2, shape_V, 'd', 'F', far_V[bi]->data); far_rank[bi-bj] = far_rank[bi]; } } STARSH_REALLOC(far_rank, new_nblocks_far); STARSH_REALLOC(far_U, new_nblocks_far); STARSH_REALLOC(far_V, new_nblocks_far); //STARSH_REALLOC(alloc_U, offset_U); //STARSH_REALLOC(alloc_V, offset_V); } // If all far-field blocks are false, then dealloc buffers if(new_nblocks_far == 0 && nblocks_far > 0) { block_far = NULL; free(far_rank); far_rank = NULL; free(far_U); far_U = NULL; free(far_V); far_V = NULL; free(alloc_U); alloc_U = NULL; free(alloc_V); alloc_V = NULL; } // Dealloc list of false far-field blocks if it is not empty if(nblocks_false_far > 0) free(false_far); // Finish with creating instance of Block Low-Rank Matrix with given // buffers return starsh_blrm_new(matrix, F, far_rank, far_U, far_V, onfly, near_D, alloc_U, alloc_V, alloc_D, '1'); }
GB_AxB_dot3.c	//------------------------------------------------------------------------------ // GB_AxB_dot3: compute C<M> = A'B in parallel //------------------------------------------------------------------------------ // SuiteSparse:GraphBLAS, Timothy A. Davis, (c) 2017-2020, All Rights Reserved. // http://suitesparse.com See GraphBLAS/Doc/License.txt for license. //------------------------------------------------------------------------------ // This function only computes C<M>=A'B. The mask must be present, and not // complemented. The mask is always applied. #include "GB_mxm.h" #ifndef GBCOMPACT #include "GB_AxB__include.h" #endif #define GB_FREE_WORK \ { \ GB_FREE_MEMORY (TaskList, max_ntasks+1, sizeof (GB_task_struct)) ; \ } #define GB_FREE_ALL \ { \ GB_FREE_WORK ; \ GB_MATRIX_FREE (Chandle) ; \ } GrB_Info GB_AxB_dot3 // C<M> = A'B using dot product method ( GrB_Matrix Chandle, // output matrix const GrB_Matrix M, // mask matrix const bool Mask_struct, // if true, use the only structure of M const GrB_Matrix A, // input matrix const GrB_Matrix B, // input matrix const GrB_Semiring semiring, // semiring that defines C=AB const bool flipxy, // if true, do z=fmult(b,a) vs fmult(a,b) GB_Context Context ) { //-------------------------------------------------------------------------- // check inputs //-------------------------------------------------------------------------- GrB_Info info ; ASSERT (Chandle != NULL) ; ASSERT (Chandle == NULL) ; ASSERT_MATRIX_OK (M, "M for dot3 A'B", GB0) ; ASSERT_MATRIX_OK (A, "A for dot3 A'B", GB0) ; ASSERT_MATRIX_OK (B, "B for dot3 A'B", GB0) ; ASSERT (!GB_PENDING (M)) ; ASSERT (!GB_ZOMBIES (M)) ; ASSERT (!GB_PENDING (A)) ; ASSERT (!GB_ZOMBIES (A)) ; ASSERT (!GB_PENDING (B)) ; ASSERT (!GB_ZOMBIES (B)) ; ASSERT_SEMIRING_OK (semiring, "semiring for numeric A'B", GB0) ; ASSERT (A->vlen == B->vlen) ; int ntasks, max_ntasks = 0, nthreads ; GB_task_struct TaskList = NULL ; //-------------------------------------------------------------------------- // get the semiring operators //-------------------------------------------------------------------------- GrB_BinaryOp mult = semiring->multiply ; GrB_Monoid add = semiring->add ; ASSERT (mult->ztype == add->op->ztype) ; bool op_is_first = mult->opcode == GB_FIRST_opcode ; bool op_is_second = mult->opcode == GB_SECOND_opcode ; bool op_is_pair = mult->opcode == GB_PAIR_opcode ; bool A_is_pattern = false ; bool B_is_pattern = false ; if (flipxy) { // z = fmult (b,a) will be computed A_is_pattern = op_is_first \|\| op_is_pair ; B_is_pattern = op_is_second \|\| op_is_pair ; ASSERT (GB_IMPLIES (!A_is_pattern, GB_Type_compatible (A->type, mult->ytype))) ; ASSERT (GB_IMPLIES (!B_is_pattern, GB_Type_compatible (B->type, mult->xtype))) ; } else { // z = fmult (a,b) will be computed A_is_pattern = op_is_second \|\| op_is_pair ; B_is_pattern = op_is_first \|\| op_is_pair ; ASSERT (GB_IMPLIES (!A_is_pattern, GB_Type_compatible (A->type, mult->xtype))) ; ASSERT (GB_IMPLIES (!B_is_pattern, GB_Type_compatible (B->type, mult->ytype))) ; } (Chandle) = NULL ; //-------------------------------------------------------------------------- // get M, A, and B //-------------------------------------------------------------------------- const int64_t GB_RESTRICT Mp = M->p ; const int64_t GB_RESTRICT Mh = M->h ; const int64_t GB_RESTRICT Mi = M->i ; const GB_void GB_RESTRICT Mx = (Mask_struct ? NULL : (M->x)) ; const size_t msize = M->type->size ; const int64_t mvlen = M->vlen ; const int64_t mvdim = M->vdim ; const int64_t mnz = GB_NNZ (M) ; const int64_t mnvec = M->nvec ; const bool M_is_hyper = M->is_hyper ; const int64_t GB_RESTRICT Ap = A->p ; const int64_t GB_RESTRICT Ah = A->h ; // const int64_t GB_RESTRICT Ai = A->i ; // const int64_t avlen = A->vlen ; // const int64_t avdim = A->vdim ; // const int64_t anz = GB_NNZ (A) ; const int64_t anvec = A->nvec ; const bool A_is_hyper = A->is_hyper ; const int64_t GB_RESTRICT Bp = B->p ; const int64_t GB_RESTRICT Bh = B->h ; // const int64_t GB_RESTRICT Bi = B->i ; // const int64_t bvlen = B->vlen ; // const int64_t bvdim = B->vdim ; // const int64_t bnz = GB_NNZ (B) ; const int64_t bnvec = B->nvec ; const bool B_is_hyper = B->is_hyper ; //-------------------------------------------------------------------------- // allocate C, the same size and # of entries as M //-------------------------------------------------------------------------- GrB_Type ctype = add->op->ztype ; int64_t cvlen = mvlen ; int64_t cvdim = mvdim ; int64_t cnz = mnz ; int64_t cnvec = mnvec ; GB_CREATE (Chandle, ctype, cvlen, cvdim, GB_Ap_malloc, true, GB_SAME_HYPER_AS (M_is_hyper), M->hyper_ratio, cnvec, cnz+1, // add one to cnz for GB_cumsum of Cwork in GB_AxB_dot3_slice true, Context) ; if (info != GrB_SUCCESS) { // out of memory GB_FREE_ALL ; return (info) ; } GrB_Matrix C = (Chandle) ; int64_t GB_RESTRICT Cp = C->p ; int64_t GB_RESTRICT Ch = C->h ; int64_t GB_RESTRICT Cwork = C->i ; // use C->i as workspace //-------------------------------------------------------------------------- // determine the # of threads to use //-------------------------------------------------------------------------- GB_GET_NTHREADS_MAX (nthreads_max, chunk, Context) ; //-------------------------------------------------------------------------- // copy Mp and Mh into C //-------------------------------------------------------------------------- // FUTURE:: C->p and C->h could be shallow copies of M->p and M->h, which // could same some time and memory if C is then, say, transposed by // GB_accum_mask later on. nthreads = GB_nthreads (cnvec, chunk, nthreads_max) ; GB_memcpy (Cp, Mp, (cnvec+1) * sizeof (int64_t), nthreads) ; if (M_is_hyper) { GB_memcpy (Ch, Mh, cnvec * sizeof (int64_t), nthreads) ; } C->magic = GB_MAGIC ; C->nvec_nonempty = M->nvec_nonempty ; C->nvec = M->nvec ; //-------------------------------------------------------------------------- // construct the tasks for the first phase //-------------------------------------------------------------------------- nthreads = GB_nthreads (cnz, chunk, nthreads_max) ; GB_OK (GB_AxB_dot3_one_slice (&TaskList, &max_ntasks, &ntasks, &nthreads, M, Context)) ; //-------------------------------------------------------------------------- // phase1: estimate the work to compute each entry in C //-------------------------------------------------------------------------- // The work to compute C(i,j) is held in Cwork [p], if C(i,j) appears in // as the pth entry in C. int taskid; #pragma omp parallel for num_threads(nthreads) schedule(dynamic,1) for (taskid = 0 ; taskid < ntasks ; taskid++) { //---------------------------------------------------------------------- // get the task descriptor //---------------------------------------------------------------------- // GB_GET_TASK_DESCRIPTOR ; int64_t kfirst = TaskList [taskid].kfirst ; int64_t klast = TaskList [taskid].klast ; bool fine_task = (klast == -1) ; if (fine_task) { // a fine task operates on a slice of a single vector klast = kfirst ; } int64_t bpleft = 0 ; //---------------------------------------------------------------------- // compute all vectors in this task //---------------------------------------------------------------------- for (int64_t k = kfirst ; k <= klast ; k++) { //------------------------------------------------------------------ // get j, the kth vector of C and M //------------------------------------------------------------------ int64_t j = (Mh == NULL) ? k : Mh [k] ; GB_GET_VECTOR (pM, pM_end, pM, pM_end, Mp, k) ; //------------------------------------------------------------------ // get B(:,j) //------------------------------------------------------------------ int64_t pB, pB_end ; GB_lookup (B_is_hyper, Bh, Bp, &bpleft, bnvec-1, j, &pB, &pB_end) ; int64_t bjnz = pB_end - pB ; //------------------------------------------------------------------ // estimate the work to compute each entry of C(:,j) //------------------------------------------------------------------ // A decent estimate of the work to compute the dot product C(i,j) // = A(:,i)'B(:,j) is min (\|A(:,i)\|, \|B(:,j)\|) + 1. This is a // lower bound. The actual work could require a binary search of // either A(:,i) or B(:,j), or a merge of the two vectors. Or it // could require no work at all if all entries in A(:,i) appear // before all entries in B(:,j), or visa versa. No work is done if // M(i,j)=0. A more accurate estimate is possible to compute, // following the different methods used in // Template/GB_AxB_dot_cij.c. if (bjnz == 0) { // B(:,j) is empty, so C(:,j) is empty as well. No work is to // be done, but it still takes unit work to flag each C(:,j) as // a zombie for ( ; pM < pM_end ; pM++) { Cwork [pM] = 1 ; } } else { int64_t apleft = 0 ; for ( ; pM < pM_end ; pM++) { int64_t work = 1 ; if (GB_mcast (Mx, pM, msize)) { int64_t pA, pA_end, i = Mi [pM] ; GB_lookup (A_is_hyper, Ah, Ap, &apleft, anvec-1, i, &pA, &pA_end) ; int64_t ajnz = pA_end - pA ; work += GB_IMIN (ajnz, bjnz) ; } Cwork [pM] = work ; } } } } //-------------------------------------------------------------------------- // free the current tasks and construct the tasks for the second phase //-------------------------------------------------------------------------- GB_FREE_MEMORY (TaskList, max_ntasks+1, sizeof (GB_task_struct)) ; GB_OK (GB_AxB_dot3_slice (&TaskList, &max_ntasks, &ntasks, &nthreads, C, Context)) ; GBBURBLE ("nthreads %d ntasks %d ", nthreads, ntasks) ; //-------------------------------------------------------------------------- // C<M> = A'B, via masked dot product method and built-in semiring //-------------------------------------------------------------------------- bool done = false ; #ifndef GBCOMPACT //-------------------------------------------------------------------------- // define the worker for the switch factory //-------------------------------------------------------------------------- #define GB_Adot3B(add,mult,xyname) GB_Adot3B_ ## add ## mult ## xyname #define GB_AxB_WORKER(add,mult,xyname) \ { \ info = GB_Adot3B (add,mult,xyname) (C, M, Mask_struct, \ A, A_is_pattern, B, B_is_pattern, \ TaskList, ntasks, nthreads) ; \ done = (info != GrB_NO_VALUE) ; \ } \ break ; //-------------------------------------------------------------------------- // launch the switch factory //-------------------------------------------------------------------------- GB_Opcode mult_opcode, add_opcode ; GB_Type_code xycode, zcode ; if (GB_AxB_semiring_builtin (A, A_is_pattern, B, B_is_pattern, semiring, flipxy, &mult_opcode, &add_opcode, &xycode, &zcode)) { #include "GB_AxB_factory.c" } #endif //-------------------------------------------------------------------------- // C<M> = A'B, via masked dot product method and typecasting //-------------------------------------------------------------------------- if (!done) { GB_BURBLE_MATRIX (C, "generic ") ; //---------------------------------------------------------------------- // get operators, functions, workspace, contents of A, B, C, and M //---------------------------------------------------------------------- GxB_binary_function fmult = mult->function ; GxB_binary_function fadd = add->op->function ; size_t csize = C->type->size ; size_t asize = A_is_pattern ? 0 : A->type->size ; size_t bsize = B_is_pattern ? 0 : B->type->size ; size_t xsize = mult->xtype->size ; size_t ysize = mult->ytype->size ; // scalar workspace: because of typecasting, the x/y types need not // be the same as the size of the A and B types. // flipxy false: aki = (xtype) A(k,i) and bkj = (ytype) B(k,j) // flipxy true: aki = (ytype) A(k,i) and bkj = (xtype) B(k,j) size_t aki_size = flipxy ? ysize : xsize ; size_t bkj_size = flipxy ? xsize : ysize ; GB_void GB_RESTRICT terminal = add->terminal ; GB_cast_function cast_A, cast_B ; if (flipxy) { // A is typecasted to y, and B is typecasted to x cast_A = A_is_pattern ? NULL : GB_cast_factory (mult->ytype->code, A->type->code) ; cast_B = B_is_pattern ? NULL : GB_cast_factory (mult->xtype->code, B->type->code) ; } else { // A is typecasted to x, and B is typecasted to y cast_A = A_is_pattern ? NULL : GB_cast_factory (mult->xtype->code, A->type->code) ; cast_B = B_is_pattern ? NULL : GB_cast_factory (mult->ytype->code, B->type->code) ; } //---------------------------------------------------------------------- // C<M> = A'B via dot products, function pointers, and typecasting //---------------------------------------------------------------------- // aki = A(k,i), located in Ax [pA] #define GB_GETA(aki,Ax,pA) \ GB_void aki [GB_VLA(aki_size)] ; \ if (!A_is_pattern) cast_A (aki, Ax +((pA)asize), asize) // bkj = B(k,j), located in Bx [pB] #define GB_GETB(bkj,Bx,pB) \ GB_void bkj [GB_VLA(bkj_size)] ; \ if (!B_is_pattern) cast_B (bkj, Bx +((pB)bsize), bsize) // break if cij reaches the terminal value #define GB_DOT_TERMINAL(cij) \ if (terminal != NULL && memcmp (cij, terminal, csize) == 0) \ { \ break ; \ } // C(i,j) = A(i,k) B(k,j) #define GB_MULT(cij, aki, bkj) \ GB_MULTIPLY (cij, aki, bkj) // C(i,j) += A(i,k) * B(k,j) #define GB_MULTADD(cij, aki, bkj) \ GB_void zwork [GB_VLA(csize)] ; \ GB_MULTIPLY (zwork, aki, bkj) ; \ fadd (cij, cij, zwork) // define cij for each task #define GB_CIJ_DECLARE(cij) \ GB_void cij [GB_VLA(csize)] // address of Cx [p] #define GB_CX(p) Cx +((p)csize) // save the value of C(i,j) #define GB_CIJ_SAVE(cij,p) \ memcpy (GB_CX (p), cij, csize) #define GB_ATYPE GB_void #define GB_BTYPE GB_void #define GB_CTYPE GB_void // no vectorization #define GB_PRAGMA_VECTORIZE #define GB_PRAGMA_VECTORIZE_DOT if (flipxy) { #define GB_MULTIPLY(z,x,y) fmult (z,y,x) #include "GB_AxB_dot3_template.c" #undef GB_MULTIPLY } else { #define GB_MULTIPLY(z,x,y) fmult (z,x,y) #include "GB_AxB_dot3_template.c" #undef GB_MULTIPLY } } //-------------------------------------------------------------------------- // free workspace and return result //-------------------------------------------------------------------------- if (C->nzombies > 0) { // C has been created with zombies, so place it in the queue GB_CRITICAL (GB_queue_insert (C)) ; } GB_FREE_WORK ; ASSERT_MATRIX_OK (C, "dot3: C<M> = A'B output", GB0) ; ASSERT (*Chandle == C) ; ASSERT (GB_ZOMBIES_OK (C)) ; ASSERT (!GB_PENDING (C)) ; return (GrB_SUCCESS) ; }
3d25pt_var.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 25 point stencil with axis-symmetric ariable 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])+8; Ny = atoi(argv[2])+8; Nz = atoi(argv[3])+8; } 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)13); for(m=0; m<13;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] = 4; tile_size[3] = 2048; 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<13; 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 /* 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<=floord(Nt-1,2);t1++) { lbp=max(ceild(t1,2),ceild(4t1-Nt+2,4)); ubp=min(floord(4Nt+Nz-9,16),floord(8t1+Nz+2,16)); #pragma omp parallel for private(lbv,ubv,t3,t4,t5,t6,t7,t8) for (t2=lbp;t2<=ubp;t2++) { for (t3=max(max(max(1,ceild(16t2-Nz+9,4)),2t1+1),4t1-4t2+2);t3<=min(min(min(floord(4Nt+Ny-9,4),floord(8t1+Ny+7,4)),floord(16t2+Ny+3,4)),floord(16t1-16t2+Nz+Ny+5,4));t3++) { for (t4=max(max(max(0,ceild(t1-255,256)),ceild(16t2-Nz-2035,2048)),ceild(4t3-Ny-2035,2048));t4<=min(min(min(min(floord(4Nt+Nx-9,2048),floord(8t1+Nx+7,2048)),floord(16t2+Nx+3,2048)),floord(4t3+Nx-9,2048)),floord(16t1-16t2+Nz+Nx+5,2048));t4++) { for (t5=max(max(max(max(max(0,ceild(16t2-Nz+5,4)),ceild(4t3-Ny+5,4)),ceild(2048t4-Nx+5,4)),2t1),4t1-4t2+1);t5<=min(min(min(min(min(floord(16t1-16t2+Nz+10,4),Nt-1),2t1+3),4t2+2),t3-1),512t4+510);t5++) { for (t6=max(max(16t2,4t5+4),-16t1+16t2+8t5-15);t6<=min(min(16t2+15,-16t1+16t2+8t5),4t5+Nz-5);t6++) { for (t7=4t3;t7<=min(4t3+3,4t5+Ny-5);t7++) { lbv=max(2048t4,4t5+4); ubv=min(2048t4+2047,4t5+Nx-5); #pragma ivdep #pragma vector always for (t8=lbv;t8<=ubv;t8++) { A[( t5 + 1) % 2][ (-4t5+t6)][ (-4t5+t7)][ (-4t5+t8)] = (((((((((((((coef[0][ (-4t5+t6)][ (-4t5+t7)][ (-4t5+t8)] A[ t5 % 2][ (-4t5+t6)][ (-4t5+t7)][ (-4t5+t8)]) + (coef[1][ (-4t5+t6)][ (-4t5+t7)][ (-4t5+t8)] * (A[ t5 % 2][ (-4t5+t6) - 1][ (-4t5+t7)][ (-4t5+t8)] + A[ t5 % 2][ (-4t5+t6) + 1][ (-4t5+t7)][ (-4t5+t8)]))) + (coef[2][ (-4t5+t6)][ (-4t5+t7)][ (-4t5+t8)] (A[ t5 % 2][ (-4t5+t6)][ (-4t5+t7) - 1][ (-4t5+t8)] + A[ t5 % 2][ (-4t5+t6)][ (-4t5+t7) + 1][ (-4t5+t8)]))) + (coef[3][ (-4t5+t6)][ (-4t5+t7)][ (-4t5+t8)] (A[ t5 % 2][ (-4t5+t6)][ (-4t5+t7)][ (-4t5+t8) - 1] + A[ t5 % 2][ (-4t5+t6)][ (-4t5+t7)][ (-4t5+t8) + 1]))) + (coef[4][ (-4t5+t6)][ (-4t5+t7)][ (-4t5+t8)] (A[ t5 % 2][ (-4t5+t6) - 2][ (-4t5+t7)][ (-4t5+t8)] + A[ t5 % 2][ (-4t5+t6) + 2][ (-4t5+t7)][ (-4t5+t8)]))) + (coef[5][ (-4t5+t6)][ (-4t5+t7)][ (-4t5+t8)] (A[ t5 % 2][ (-4t5+t6)][ (-4t5+t7) - 2][ (-4t5+t8)] + A[ t5 % 2][ (-4t5+t6)][ (-4t5+t7) + 2][ (-4t5+t8)]))) + (coef[6][ (-4t5+t6)][ (-4t5+t7)][ (-4t5+t8)] (A[ t5 % 2][ (-4t5+t6)][ (-4t5+t7)][ (-4t5+t8) - 2] + A[ t5 % 2][ (-4t5+t6)][ (-4t5+t7)][ (-4t5+t8) + 2]))) + (coef[7][ (-4t5+t6)][ (-4t5+t7)][ (-4t5+t8)] (A[ t5 % 2][ (-4t5+t6) - 3][ (-4t5+t7)][ (-4t5+t8)] + A[ t5 % 2][ (-4t5+t6) + 3][ (-4t5+t7)][ (-4t5+t8)]))) + (coef[8][ (-4t5+t6)][ (-4t5+t7)][ (-4t5+t8)] (A[ t5 % 2][ (-4t5+t6)][ (-4t5+t7) - 3][ (-4t5+t8)] + A[ t5 % 2][ (-4t5+t6)][ (-4t5+t7) + 3][ (-4t5+t8)]))) + (coef[9][ (-4t5+t6)][ (-4t5+t7)][ (-4t5+t8)] (A[ t5 % 2][ (-4t5+t6)][ (-4t5+t7)][ (-4t5+t8) - 3] + A[ t5 % 2][ (-4t5+t6)][ (-4t5+t7)][ (-4t5+t8) + 3]))) + (coef[10][ (-4t5+t6)][ (-4t5+t7)][ (-4t5+t8)] (A[ t5 % 2][ (-4t5+t6) - 4][ (-4t5+t7)][ (-4t5+t8)] + A[ t5 % 2][ (-4t5+t6) + 4][ (-4t5+t7)][ (-4t5+t8)]))) + (coef[11][ (-4t5+t6)][ (-4t5+t7)][ (-4t5+t8)] (A[ t5 % 2][ (-4t5+t6)][ (-4t5+t7) - 4][ (-4t5+t8)] + A[ t5 % 2][ (-4t5+t6)][ (-4t5+t7) + 4][ (-4t5+t8)]))) + (coef[12][ (-4t5+t6)][ (-4t5+t7)][ (-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, "variable axis-symmetric") #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<13;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; }
ClientComm.h	/! @brief Flag for checking if this header has already been included. / #ifndef YGGCLIENTCOMM_H_ #define YGGCLIENTCOMM_H_ #include <../tools.h> #include <CommBase.h> #include <DefaultComm.h> #include "../datatypes/datatypes.h" #ifdef __cplusplus /* If this is a C++ compiler, use C linkage / extern "C" { #endif // Handle is send address // Info is response static unsigned _client_rand_seeded = 0; // @brief Structure for storing requests/responses typedef struct responses_t { comm_t comm; //!< Response comm. size_t nreq; //!< Number of requests sent. char request_id; //!< Request ids. char data; //!< Received responses size_t* len; //!< Lengths of received messages. } responses_t; /! @brief Create a new registry of requests and responses. @returns responses_t Structure containing a registry of requests and responses. / static inline responses_t client_new_responses() { responses_t* out = (responses_t)malloc(sizeof(responses_t)); if (out != NULL) { out->comm = NULL; out->nreq = 0; out->request_id = NULL; out->data = NULL; out->len = NULL; } return out; }; /! @brief Free a registry of requests and responses. @param[in] x responses_t** Pointer to structure containing a registry of requests and responses. / static inline void client_free_responses(responses_t* x) { if (x[0] != NULL) { if (x[0]->comm != NULL) { free_default_comm(x[0]->comm); free_comm_base(x[0]->comm); } if (x[0]->data != NULL) { for (size_t i = 0; i < x[0]->nreq; i++) if (x[0]->data[i] != NULL) free(x[0]->data[i]); free(x[0]->data); } if (x[0]->len != NULL) free(x[0]->len); free(x[0]); x[0] = NULL; } }; /! @brief Determine if there is a request in the registry. @param[in] x responses_t Structure containing a registry of requests and responses. @param[in] request_id const char* ID associated with the request to check for. @returns int -1 if there is an error, otherwise the index of the request in the registry. / static inline int client_has_request(responses_t x, const char* request_id) { if (x == NULL) return -1; for (size_t i = 0; i < x->nreq; i++) { if (strcmp(x->request_id[i], request_id) == 0) return (int)i; } return -1; }; /! @brief Determine if there is a response in the registry. @param[in] x responses_t Structure containing a registry of requests and responses. @param[in] request_id const char* ID associated with the response to check for. @returns int -1 if there is an error, otherwise the index of the response in the registry. / static inline int client_has_response(responses_t x, const char* request_id) { int idx = client_has_request(x, request_id); if (idx < 0) return idx; if (x->data[idx] != NULL) return idx; return -1; }; /! @brief Add a request to the registry. @param[in] x responses_t Structure containing a registry of requests and responses. @param[in] request_id const char* ID associated with the request being added. @returns int -1 if there is an error, 0 otherwise. / static inline int client_add_request(responses_t x, const char* request_id) { if (x == NULL) return -1; x->request_id = (char*)realloc(x->request_id, (x->nreq + 1) sizeof(char)); if (x->request_id == NULL) return -1; size_t request_len = strlen(request_id); x->request_id[x->nreq] = (char)malloc(request_len + 1); if (x->request_id[x->nreq] == NULL) return -1; memcpy(x->request_id[x->nreq], request_id, request_len); x->request_id[x->nreq][request_len] = '\0'; x->data = (char*)realloc(x->data, (x->nreq + 1) sizeof(char)); if (x->data == NULL) return -1; x->data[x->nreq] = NULL; x->len = (size_t)realloc(x->len, (x->nreq + 1) * sizeof(size_t)); if (x->len == NULL) return -1; x->len[x->nreq] = 0; x->nreq++; return 0; }; /! @brief Add a response to the registry. @param[in] x responses_t Structure containing a registry of requests and responses. @param[in] request_id const char* ID associated with the response being added. @param[in] data const char* Response message. @param[in] len size_t Size of the response message. @returns int -1 if there is an error, 0 otherwise. / static inline int client_add_response(responses_t x, const char* request_id, const char* data, const size_t len) { int idx = client_has_request(x, request_id); if (idx < 0) { ygglog_error("client_add_response: idx = %d", idx); return idx; } x->data[idx] = (char)malloc(len + 1); if (x->data[idx] == NULL) { ygglog_error("client_add_response: failed to malloc data"); return -1; } memcpy(x->data[idx], data, len); x->data[idx][len] = '\0'; x->len[idx] = len; return 0; }; /! @brief Remove a request/response from the registry. @param[in] x responses_t* Structure containing a registry of requests and responses. @param[in] request_id const char* ID associated with the request/response that should be removed. @returns int -1 if there is an error, 0 otherwise. / static inline int client_remove_request(responses_t x, const char* request_id) { if (x == NULL) return -1; int idx = client_has_request(x, request_id); if (idx < 0) return 0; int nrem = x->nreq - (idx + 1); free(x->request_id[idx]); if (x->data[idx] != NULL) free(x->data[idx]); if (nrem > 0) { memmove(x->request_id + idx, x->request_id + idx + 1, nrem * sizeof(char)); memmove(x->data + idx, x->data + idx + 1, nrem sizeof(char)); memmove(x->len + idx, x->len + idx + 1, nrem sizeof(size_t)); } x->nreq--; return 0; }; /! @brief Remove and return a response from the registry after it has been received. @param[in] x responses_t Structure containing a registry of requests and responses. @param[in] request_id const char* ID associated with the response that should be removed and returned. @param[in,out] data char** Pointer to memory where the response should be stored. @param[in] len const size_t Size of the existing buffer pointed to by data. @param[in] allow_realloc int If 1 and the response exceeds len, the buffer pointed to by data will be reallocated, if 0 and the response exceeds len, an error will be returned. @returns int -1 if there is an error, otherwise the size of the reponse message will be returned. / static inline int client_pop_response(responses_t x, const char* request_id, char *data, const size_t len, const int allow_realloc) { if (x == NULL) return -1; int idx = client_has_response(x, request_id); if (idx < 0) return -1; int ret = x->len[idx]; if ((ret + 1) > len) { if (allow_realloc) { ygglog_debug("client_pop_response: reallocating buffer from %d to %d bytes.", len, ret + 1); (data) = (char)realloc(data, ret + 1); if (data == NULL) { ygglog_error("client_pop_response: failed to realloc buffer."); return -1; } } else { ygglog_error("client_pop_response: buffer (%d bytes) is not large enough for message (%d bytes)", len, ret + 1); return -((int)(ret)); } } memcpy(data, x->data[idx], ret); (data)[ret] = '\0'; if (client_remove_request(x, request_id) < 0) return -1; return ret; }; /! @brief Create a new channel. @param[in] comm comm_t * Comm structure initialized with new_comm_base. @returns int -1 if the address could not be created. / static inline int new_client_address(comm_t comm) { #ifdef _OPENMP #pragma omp critical (client) { #endif if (!(_client_rand_seeded)) { srand(ptr2seed(comm)); _client_rand_seeded = 1; } #ifdef _OPENMP } #endif comm->type = _default_comm; return new_default_address(comm); }; /! @brief Initialize a client communicator. @param[in] comm comm_t Comm structure initialized with init_comm_base. @returns int -1 if the comm could not be initialized. / static inline int init_client_comm(comm_t comm) { int ret = 0; ygglog_debug("init_client_comm: Creating a client comm"); #ifdef _OPENMP #pragma omp critical (client) { #endif if (!(_client_rand_seeded)) { srand(ptr2seed(comm)); _client_rand_seeded = 1; } #ifdef _OPENMP } #endif // Called to create temp comm for send/recv if ((strlen(comm->name) == 0) && (strlen(comm->address) > 0)) { comm->type = _default_comm; return init_default_comm(comm); } // Called to initialize/create client comm dtype_t dtype_out = NULL; if (strlen(comm->direction) > 0) { dtype_out = create_dtype_format(comm->direction, 0, false); if (dtype_out == NULL) { ygglog_error("init_client_comm: Failed to create output datatype."); return -1; } } comm_t handle; if (strlen(comm->name) == 0) { handle = new_comm_base(comm->address, "send", _default_comm, dtype_out); sprintf(handle->name, "client_request.%s", comm->address); } else { handle = init_comm_base(comm->name, "send", _default_comm, dtype_out); } handle->flags = handle->flags \| COMM_FLAG_CLIENT; ret = init_default_comm(handle); strcpy(comm->address, handle->address); comm->handle = (void)handle; // Keep track of response comms responses_t resp = client_new_responses(); if (resp == NULL) { ygglog_error("init_client_comm: Failed to malloc responses."); return -1; } comm->info = (void)resp; strcpy(comm->direction, "send"); comm->flags = comm->flags \| COMM_ALWAYS_SEND_HEADER; return ret; }; /! @brief Perform deallocation for client communicator. @param[in] x comm_t* Pointer to communicator to deallocate. @returns int 1 if there is and error, 0 otherwise. / static inline int free_client_comm(comm_t x) { if (x->info != NULL) { responses_t resp = (responses_t)(x->info); if (resp != NULL) client_free_responses(&resp); x->info = NULL; } if (x->handle != NULL) { comm_t handle = (comm_t)(x->handle); free_default_comm(handle); free_comm_base(handle); free(x->handle); x->handle = NULL; } return 0; }; /! @brief Get number of messages in the comm. @param[in] x comm_t Communicator to check. @returns int Number of messages. -1 indicates an error. / static inline int client_comm_nmsg(const comm_t x) { comm_t handle = (comm_t)(x->handle); int ret = default_comm_nmsg(handle); return ret; }; /! @brief Create response comm and add info to header. @param[in] x comm_t structure that header will be sent to. @param[in] head comm_head_t Prexisting header structure. @returns comm_head_t Header structure that includes the additional information about the response comm. / static inline comm_head_t client_response_header(const comm_t x, comm_head_t head) { // Initialize new comm responses_t resp = (responses_t)(x->info); if (resp->comm == NULL) { dtype_t * dtype_copy = copy_dtype(x->datatype); resp->comm = new_comm_base(NULL, "recv", _default_comm, dtype_copy); resp->comm->flags = resp->comm->flags \| COMM_FLAG_CLIENT_RESPONSE; int ret = new_default_address(resp->comm); if (ret < 0) { ygglog_error("client_response_header(%s): could not create response comm", x->name); head.flags = head.flags & ~HEAD_FLAG_VALID; return head; } resp->comm->const_flags[0] = resp->comm->const_flags[0] \| COMM_EOF_SENT \| COMM_EOF_RECV; ygglog_debug("client_response_header(%s): Created response comm", x->name); } // Add address & request ID to header strcpy(head.response_address, resp->comm->address); sprintf(head.request_id, "%d", rand()); if (client_add_request(resp, head.request_id) < 0) { ygglog_error("client_response_header(%s): Failed to add request", x->name); head.flags = head.flags & ~HEAD_FLAG_VALID; return head; } if (client_has_request(resp, head.request_id) < 0) { ygglog_error("client_response_header(%s): Failed to add request", x->name); head.flags = head.flags & ~HEAD_FLAG_VALID; return head; } ygglog_debug("client_response_header(%s): response_address = %s, request_id = %s", x->name, head.response_address, head.request_id); return head; }; /! @brief Send a message to the comm. @param[in] x comm_t structure that comm should be sent to. @param[in] data character pointer to message that should be sent. @param[in] len size_t length of message to be sent. @returns int 0 if send succesfull, -1 if send unsuccessful. / static inline int client_comm_send(const comm_t x, const char data, const size_t len) { int ret; ygglog_debug("client_comm_send(%s): %d bytes", x->name, len); if (x->handle == NULL) { ygglog_error("client_comm_send(%s): no request comm registered", x->name); return -1; } comm_t req_comm = (comm_t)(x->handle); ret = default_comm_send(req_comm, data, len); if (is_eof(data)) { req_comm->const_flags[0] = req_comm->const_flags[0] \| COMM_EOF_SENT; } return ret; }; /! @brief Receive a message from an input comm. @param[in] x comm_t* structure that message should be sent to. @param[out] data char ** pointer to allocated buffer where the message should be saved. This should be a malloc'd buffer if allow_realloc is 1. @param[in] len const size_t length of the allocated message buffer in bytes. @param[in] allow_realloc const int If 1, the buffer will be realloced if it is not large enought. Otherwise an error will be returned. @returns int -1 if message could not be received. Length of the received message if message was received. / static inline int client_comm_recv(const comm_t x, char *data, const size_t len, const int allow_realloc) { ygglog_debug("client_comm_recv(%s)", x->name); if (x->info == NULL) { ygglog_error("client_comm_recv(%s): no response struct set up", x->name); return -1; } responses_t resp = (responses_t)(x->info); if ((resp->comm == NULL) \|\| (resp->nreq == 0)) { ygglog_error("client_comm_recv(%s): no response comm registered", x->name); return -1; } char request_id = resp->request_id[0]; int ret = 0; while (client_has_response(resp, request_id) < 0) { ret = default_comm_recv(resp->comm, data, len, allow_realloc); if (ret < 0) { ygglog_error("client_comm_recv(%s): default_comm_recv returned %d", x->name, ret); return ret; } comm_head_t head = parse_comm_header(data, len); if (!(head.flags & HEAD_FLAG_VALID)) { ygglog_error("client_comm_recv(%s): Invalid header.", x->name); return -1; } if (strcmp(head.request_id, request_id) == 0) { ygglog_debug("client_comm_recv(%s): default_comm_recv returned %d", x->name, ret); if (client_remove_request(resp, request_id) < 0) { ygglog_error("client_comm_recv(%s): Failed to remove request %s", x->name, request_id); return -1; } return ret; } if (client_add_response(resp, head.request_id, data, ret) < 0) { ygglog_error("client_comm_recv(%s): Failed to add response %s", x->name, head.request_id); return -1; } } ret = client_pop_response(resp, request_id, data, len, allow_realloc); // Close response comm and decrement count of response comms ygglog_debug("client_comm_recv(%s): client_pop_response returned %d", x->name, ret); return ret; }; #ifdef __cplusplus /* If this is a C++ compiler, end C linkage / } #endif #endif /YGGCLIENTCOMM_H_*/
nodal_residualbased_elimination_builder_and_solver_for_FSI.h	// \| / \| // ' / __\| _` \| __\| _ \ __\| // . \ \| ( \| \| ( \|\__ ` // _\|\_\_\| \__,_\|\__\|\___/ ____/ // Multi-Physics // // License: BSD License // Kratos default license: kratos/license.txt // // Main authors: Riccardo Rossi, Alessandro Franci // // #if !defined(KRATOS_NODAL_RESIDUAL_BASED_ELIMINATION_BUILDER_AND_SOLVER_FOR_FSI) #define KRATOS_NODAL_RESIDUAL_BASED_ELIMINATION_BUILDER_AND_SOLVER_FOR_FSI /* System includes / #include <set> #ifdef _OPENMP #include <omp.h> #endif / External includes / // #define USE_GOOGLE_HASH #ifdef USE_GOOGLE_HASH #include "sparsehash/dense_hash_set" //included in external libraries #else #include <unordered_set> #endif / Project includes / #include "utilities/timer.h" #include "includes/define.h" #include "includes/key_hash.h" #include "solving_strategies/builder_and_solvers/builder_and_solver.h" #include "includes/model_part.h" #include "pfem_fluid_dynamics_application_variables.h" namespace Kratos { ///@name Kratos Globals ///@{ ///@} ///@name Type Definitions ///@{ ///@} ///@name Enum's ///@{ ///@} ///@name Functions ///@{ ///@} ///@name Kratos Classes ///@{ /* * @class NodalResidualBasedEliminationBuilderAndSolverForFSI * @ingroup KratosCore * @brief Current class provides an implementation for standard builder and solving operations. * @details The RHS is constituted by the unbalanced loads (residual) * Degrees of freedom are reordered putting the restrained degrees of freedom at * the end of the system ordered in reverse order with respect to the DofSet. * Imposition of the dirichlet conditions is naturally dealt with as the residual already contains * this information. * Calculation of the reactions involves a cost very similiar to the calculation of the total residual * @author Riccardo Rossi / template <class TSparseSpace, class TDenseSpace, //= DenseSpace<double>, class TLinearSolver //= LinearSolver<TSparseSpace,TDenseSpace> > class NodalResidualBasedEliminationBuilderAndSolverForFSI : public BuilderAndSolver<TSparseSpace, TDenseSpace, TLinearSolver> { public: ///@name Type Definitions ///@{ KRATOS_CLASS_POINTER_DEFINITION(NodalResidualBasedEliminationBuilderAndSolverForFSI); typedef BuilderAndSolver<TSparseSpace, TDenseSpace, TLinearSolver> BaseType; typedef typename BaseType::TSchemeType TSchemeType; typedef typename BaseType::TDataType TDataType; typedef typename BaseType::DofsArrayType DofsArrayType; typedef typename BaseType::TSystemMatrixType TSystemMatrixType; typedef typename BaseType::TSystemVectorType TSystemVectorType; typedef typename BaseType::LocalSystemVectorType LocalSystemVectorType; typedef typename BaseType::LocalSystemMatrixType LocalSystemMatrixType; typedef typename BaseType::TSystemMatrixPointerType TSystemMatrixPointerType; typedef typename BaseType::TSystemVectorPointerType TSystemVectorPointerType; typedef Node<3> NodeType; typedef typename BaseType::NodesArrayType NodesArrayType; typedef typename BaseType::ElementsArrayType ElementsArrayType; typedef typename BaseType::ConditionsArrayType ConditionsArrayType; typedef typename BaseType::ElementsContainerType ElementsContainerType; typedef Vector VectorType; typedef GlobalPointersVector<Node<3>> NodeWeakPtrVectorType; ///@} ///@name Life Cycle ///@{ /* Constructor. / NodalResidualBasedEliminationBuilderAndSolverForFSI( typename TLinearSolver::Pointer pNewLinearSystemSolver) : BuilderAndSolver<TSparseSpace, TDenseSpace, TLinearSolver>(pNewLinearSystemSolver) { // KRATOS_INFO("NodalResidualBasedEliminationBuilderAndSolverForFSI") << "Using the standard builder and solver " << std::endl; } /* Destructor. / ~NodalResidualBasedEliminationBuilderAndSolverForFSI() override { } ///@} ///@name Operators ///@{ ///@} ///@name Operations ///@{ void SetMaterialPropertiesToFluid( ModelPart::NodeIterator itNode, double &density, double &deviatoricCoeff, double &volumetricCoeff, double timeInterval, double nodalVolume) { density = itNode->FastGetSolutionStepValue(DENSITY); deviatoricCoeff = itNode->FastGetSolutionStepValue(DYNAMIC_VISCOSITY); double yieldShear = itNode->FastGetSolutionStepValue(YIELD_SHEAR); if (yieldShear > 0) { double adaptiveExponent = itNode->FastGetSolutionStepValue(ADAPTIVE_EXPONENT); double equivalentStrainRate = itNode->FastGetSolutionStepValue(NODAL_EQUIVALENT_STRAIN_RATE); double exponent = -adaptiveExponent equivalentStrainRate; if (equivalentStrainRate != 0) { deviatoricCoeff += (yieldShear / equivalentStrainRate) * (1 - exp(exponent)); } if (equivalentStrainRate < 0.00001 && yieldShear != 0 && adaptiveExponent != 0) { // for gamma_dot very small the limit of the Papanastasiou viscosity is mu=mtau_yield deviatoricCoeff = adaptiveExponent yieldShear; } } volumetricCoeff = timeInterval * itNode->FastGetSolutionStepValue(BULK_MODULUS); if (volumetricCoeff > 0) { volumetricCoeff = timeInterval * itNode->FastGetSolutionStepValue(BULK_MODULUS); double bulkReduction = density * nodalVolume / (timeInterval * volumetricCoeff); volumetricCoeff = bulkReduction; } } void SetMaterialPropertiesToSolid( ModelPart::NodeIterator itNode, double &density, double &deviatoricCoeff, double &volumetricCoeff, double timeInterval, double nodalVolume) { density = itNode->FastGetSolutionStepValue(SOLID_DENSITY); double youngModulus = itNode->FastGetSolutionStepValue(YOUNG_MODULUS); double poissonRatio = itNode->FastGetSolutionStepValue(POISSON_RATIO); //deviatoricCoeff=deltaTsecondLame deviatoricCoeff = timeInterval * youngModulus / (1.0 + poissonRatio) * 0.5; //volumetricCoeff=bulkdeltaT=deltaT(firstLame+2secondLame/3) volumetricCoeff = timeInterval poissonRatio * youngModulus / ((1.0 + poissonRatio) * (1.0 - 2.0 * poissonRatio)) + 2.0 * deviatoricCoeff / 3.0; } void BuildSolidNodally( typename TSchemeType::Pointer pScheme, ModelPart &rModelPart, TSystemMatrixType &A, TSystemVectorType &b) { KRATOS_TRY KRATOS_ERROR_IF(!pScheme) << "No scheme provided!" << std::endl; //contributions to the system LocalSystemMatrixType solidLHS_Contribution = LocalSystemMatrixType(0, 0); LocalSystemVectorType solidRHS_Contribution = LocalSystemVectorType(0); //vector containing the localization in the system of the different terms Element::EquationIdVectorType solidEquationId; ProcessInfo &CurrentProcessInfo = rModelPart.GetProcessInfo(); const unsigned int dimension = rModelPart.ElementsBegin()->GetGeometry().WorkingSpaceDimension(); const double timeInterval = CurrentProcessInfo[DELTA_TIME]; const double FourThirds = 4.0 / 3.0; const double nTwoThirds = -2.0 / 3.0; double theta = 0.5; //double theta=1.0; array_1d<double, 3> Acc(3, 0.0); double dNdXi = 0; double dNdYi = 0; double dNdZi = 0; double dNdXj = 0; double dNdYj = 0; double dNdZj = 0; unsigned int firstRow = 0; unsigned int firstCol = 0; double density = 0; double deviatoricCoeff = 0; double volumetricCoeff = 0; /* #pragma omp parallel / // { ModelPart::NodeIterator NodesBegin; ModelPart::NodeIterator NodesEnd; OpenMPUtils::PartitionedIterators(rModelPart.Nodes(), NodesBegin, NodesEnd); for (ModelPart::NodeIterator itNode = NodesBegin; itNode != NodesEnd; ++itNode) { if (itNode->Is(SOLID)) { NodeWeakPtrVectorType &neighb_nodes = itNode->GetValue(NEIGHBOUR_NODES); Vector solidNodalSFDneighboursId = itNode->FastGetSolutionStepValue(SOLID_NODAL_SFD_NEIGHBOURS_ORDER); // const unsigned int neighSize = neighb_nodes.size()+1; const unsigned int neighSize = solidNodalSFDneighboursId.size(); const double nodalVolume = itNode->FastGetSolutionStepValue(SOLID_NODAL_VOLUME); if (neighSize > 1 && nodalVolume > 0) { const unsigned int localSize = itNode->FastGetSolutionStepValue(SOLID_NODAL_SFD_NEIGHBOURS).size(); if (solidLHS_Contribution.size1() != localSize) solidLHS_Contribution.resize(localSize, localSize, false); //false says not to preserve existing storage!! if (solidRHS_Contribution.size() != localSize) solidRHS_Contribution.resize(localSize, false); //false says not to preserve existing storage!! if (solidEquationId.size() != localSize) solidEquationId.resize(localSize, false); solidLHS_Contribution = ZeroMatrix(localSize, localSize); solidRHS_Contribution = ZeroVector(localSize); this->SetMaterialPropertiesToSolid(itNode, density, deviatoricCoeff, volumetricCoeff, timeInterval, nodalVolume); firstRow = 0; firstCol = 0; if (dimension == 2) { //////////////////////////// LHS TERMS ////////////////////////////// solidLHS_Contribution(0, 0) += nodalVolume density * 2.0 / timeInterval; solidLHS_Contribution(1, 1) += nodalVolume * density * 2.0 / timeInterval; //////////////////////////// RHS TERMS ////////////////////////////// //-------- DYNAMIC FORCES TERM -------// Acc = 2.0 * (itNode->FastGetSolutionStepValue(VELOCITY, 0) - itNode->FastGetSolutionStepValue(VELOCITY, 1)) / timeInterval - itNode->FastGetSolutionStepValue(ACCELERATION, 0); solidRHS_Contribution[0] += -nodalVolume * density * Acc[0]; solidRHS_Contribution[1] += -nodalVolume * density * Acc[1]; //-------- EXTERNAL FORCES TERM -------// array_1d<double, 3> &VolumeAcceleration = itNode->FastGetSolutionStepValue(VOLUME_ACCELERATION); // double posX= itNode->X(); // double posY= itNode->Y(); // double coeffX =(12.0-24.0posY)pow(posX,4); // coeffX += (-24.0+48.0posY)pow(posX,3); // coeffX += (-48.0posY+72.0pow(posY,2)-48.0pow(posY,3)+12.0)pow(posX,2); // coeffX += (-2.0+24.0posY-72.0pow(posY,2)+48.0pow(posY,3))posX; // coeffX += 1.0-4.0posY+12.0pow(posY,2)-8.0pow(posY,3); // double coeffY =(8.0-48.0posY+48.0pow(posY,2))pow(posX,3); // coeffY += (-12.0+72.0posY-72.0pow(posY,2))pow(posX,2); // coeffY += (4.0-24.0posY+48.0pow(posY,2)-48.0pow(posY,3)+24.0pow(posY,4))posX; // coeffY += -12.0pow(posY,2)+24.0pow(posY,3)-12.0pow(posY,4); // RHS_Contribution[0]+=nodalVolumedensityVolumeAcceleration[0]coeffX; // RHS_Contribution[1]+=nodalVolumedensityVolumeAcceleration[1]coeffY; solidRHS_Contribution[0] += nodalVolume density * VolumeAcceleration[0]; solidRHS_Contribution[1] += nodalVolume * density * VolumeAcceleration[1]; ///////////////LOAD CONDITIONS FOR BELITSCHKO CASE // if(itNode->X0()>24.999){ // // solidRHS_Contribution[1]+=40.0/2.0; // mesh 4 (1 element per edge) // // solidRHS_Contribution[1]+=40.0/3.0; // mesh 2 (2 element per edge) // // solidRHS_Contribution[1]+=40.0/5.0; // mesh 1 (4 element per edge) // // solidRHS_Contribution[1]+=40.0/9.0; // mesh 0.5 (8 element per edge) // // solidRHS_Contribution[1]+=40.0/17.0; // mesh 0.25 (16 element per edge) // // solidRHS_Contribution[1]+=40.0/33.0; // mesh 0.125 (32 element per edge) // // solidRHS_Contribution[1]+=40.0/65.0; // mesh 0.0625 (64 element per edge) // } //-------- INTERNAL FORCES TERM -------// array_1d<double, 3> Sigma(3, 0.0); Sigma = itNode->FastGetSolutionStepValue(SOLID_NODAL_CAUCHY_STRESS); const unsigned int xDofPos = itNode->GetDofPosition(VELOCITY_X); solidEquationId[0] = itNode->GetDof(VELOCITY_X, xDofPos).EquationId(); solidEquationId[1] = itNode->GetDof(VELOCITY_Y, xDofPos + 1).EquationId(); for (unsigned int i = 0; i < neighSize; i++) { dNdXi = itNode->FastGetSolutionStepValue(SOLID_NODAL_SFD_NEIGHBOURS)[firstCol]; dNdYi = itNode->FastGetSolutionStepValue(SOLID_NODAL_SFD_NEIGHBOURS)[firstCol + 1]; solidRHS_Contribution[firstCol] += -nodalVolume * (dNdXi * Sigma[0] + dNdYi * Sigma[2]); solidRHS_Contribution[firstCol + 1] += -nodalVolume * (dNdYi * Sigma[1] + dNdXi * Sigma[2]); for (unsigned int j = 0; j < neighSize; j++) { dNdXj = itNode->FastGetSolutionStepValue(SOLID_NODAL_SFD_NEIGHBOURS)[firstRow]; dNdYj = itNode->FastGetSolutionStepValue(SOLID_NODAL_SFD_NEIGHBOURS)[firstRow + 1]; solidLHS_Contribution(firstRow, firstCol) += nodalVolume * ((FourThirds * deviatoricCoeff + volumetricCoeff) * dNdXj * dNdXi + dNdYj * dNdYi * deviatoricCoeff) * theta; solidLHS_Contribution(firstRow, firstCol + 1) += nodalVolume * ((nTwoThirds * deviatoricCoeff + volumetricCoeff) * dNdXj * dNdYi + dNdYj * dNdXi * deviatoricCoeff) * theta; solidLHS_Contribution(firstRow + 1, firstCol) += nodalVolume * ((nTwoThirds * deviatoricCoeff + volumetricCoeff) * dNdYj * dNdXi + dNdXj * dNdYi * deviatoricCoeff) * theta; solidLHS_Contribution(firstRow + 1, firstCol + 1) += nodalVolume * ((FourThirds * deviatoricCoeff + volumetricCoeff) * dNdYj * dNdYi + dNdXj * dNdXi * deviatoricCoeff) * theta; firstRow += 2; } firstRow = 0; firstCol += 2; unsigned int indexNode = i + 1; if (itNode->FastGetSolutionStepValue(INTERFACE_NODE) == true && indexNode < neighSize) { unsigned int other_neigh_nodes_id = solidNodalSFDneighboursId[indexNode]; // std::cout<<"other_neigh_nodes_id= "<<other_neigh_nodes_id<<" within "<<nodalSFDneighboursId<<std::endl; for (unsigned int k = 0; k < neighb_nodes.size(); k++) { unsigned int neigh_nodes_id = neighb_nodes[k].Id(); // std::cout<<" neigh_nodes_id= "<< neigh_nodes_id<<std::endl; if (neigh_nodes_id == other_neigh_nodes_id) { solidEquationId[firstCol] = neighb_nodes[k].GetDof(VELOCITY_X, xDofPos).EquationId(); solidEquationId[firstCol + 1] = neighb_nodes[k].GetDof(VELOCITY_Y, xDofPos + 1).EquationId(); break; } } } else if (i < neighb_nodes.size()) { solidEquationId[firstCol] = neighb_nodes[i].GetDof(VELOCITY_X, xDofPos).EquationId(); solidEquationId[firstCol + 1] = neighb_nodes[i].GetDof(VELOCITY_Y, xDofPos + 1).EquationId(); } } /* std::cout << "LHS_Contribution = " << LHS_Contribution << std::endl; / } else if (dimension == 3) { //////////////////////////// LHS TERMS ////////////////////////////// solidLHS_Contribution(0, 0) += nodalVolume density * 2.0 / timeInterval; solidLHS_Contribution(1, 1) += nodalVolume * density * 2.0 / timeInterval; solidLHS_Contribution(2, 2) += nodalVolume * density * 2.0 / timeInterval; //////////////////////////// RHS TERMS ////////////////////////////// //-------- DYNAMIC FORCES TERM -------// Acc = 2.0 * (itNode->FastGetSolutionStepValue(VELOCITY, 0) - itNode->FastGetSolutionStepValue(VELOCITY, 1)) / timeInterval - itNode->FastGetSolutionStepValue(ACCELERATION, 0); solidRHS_Contribution[0] += -nodalVolume * density * Acc[0]; solidRHS_Contribution[1] += -nodalVolume * density * Acc[1]; solidRHS_Contribution[2] += -nodalVolume * density * Acc[2]; //-------- EXTERNAL FORCES TERM -------// array_1d<double, 3> &VolumeAcceleration = itNode->FastGetSolutionStepValue(VOLUME_ACCELERATION); solidRHS_Contribution[0] += nodalVolume * density * VolumeAcceleration[0]; solidRHS_Contribution[1] += nodalVolume * density * VolumeAcceleration[1]; solidRHS_Contribution[2] += nodalVolume * density * VolumeAcceleration[2]; ///////////////LOAD CONDITIONS FOR BELITSCHKO CASE // if(itNode->X0()>24.999){ // // solidRHS_Contribution[1]+=40.0/2.0; // mesh 4 (1 element per edge) // // solidRHS_Contribution[1]+=40.0/3.0; // mesh 2 (2 element per edge) // // solidRHS_Contribution[1]+=40.0/5.0; // mesh 1 (4 element per edge) // solidRHS_Contribution[1]+=40.0/27.0; // mesh 0.5 (8 element per edge, 2 per width) // // solidRHS_Contribution[1]+=40.0/17.0; // mesh 0.25 (16 element per edge) // // solidRHS_Contribution[1]+=40.0/33.0; // mesh 0.125 (32 element per edge) // // solidRHS_Contribution[1]+=40.0/65.0; // mesh 0.0625 (64 element per edge) // } //-------- INTERNAL FORCES TERM -------// array_1d<double, 6> Sigma(6, 0.0); Sigma = itNode->FastGetSolutionStepValue(SOLID_NODAL_CAUCHY_STRESS); // if(itNode->FastGetSolutionStepValue(INTERFACE_NODE)==true){ // Sigma=itNode->FastGetSolutionStepValue(SOLID_NODAL_CAUCHY_STRESS); // } const unsigned int xDofPos = itNode->GetDofPosition(VELOCITY_X); solidEquationId[0] = itNode->GetDof(VELOCITY_X, xDofPos).EquationId(); solidEquationId[1] = itNode->GetDof(VELOCITY_Y, xDofPos + 1).EquationId(); solidEquationId[2] = itNode->GetDof(VELOCITY_Z, xDofPos + 2).EquationId(); for (unsigned int i = 0; i < neighSize; i++) { dNdXi = itNode->FastGetSolutionStepValue(SOLID_NODAL_SFD_NEIGHBOURS)[firstCol]; dNdYi = itNode->FastGetSolutionStepValue(SOLID_NODAL_SFD_NEIGHBOURS)[firstCol + 1]; dNdZi = itNode->FastGetSolutionStepValue(SOLID_NODAL_SFD_NEIGHBOURS)[firstCol + 2]; solidRHS_Contribution[firstCol] += -nodalVolume * (dNdXi * Sigma[0] + dNdYi * Sigma[3] + dNdZi * Sigma[4]); solidRHS_Contribution[firstCol + 1] += -nodalVolume * (dNdYi * Sigma[1] + dNdXi * Sigma[3] + dNdZi * Sigma[5]); solidRHS_Contribution[firstCol + 2] += -nodalVolume * (dNdZi * Sigma[2] + dNdXi * Sigma[4] + dNdYi * Sigma[5]); for (unsigned int j = 0; j < neighSize; j++) { dNdXj = itNode->FastGetSolutionStepValue(SOLID_NODAL_SFD_NEIGHBOURS)[firstRow]; dNdYj = itNode->FastGetSolutionStepValue(SOLID_NODAL_SFD_NEIGHBOURS)[firstRow + 1]; dNdZj = itNode->FastGetSolutionStepValue(SOLID_NODAL_SFD_NEIGHBOURS)[firstRow + 2]; solidLHS_Contribution(firstRow, firstCol) += nodalVolume * ((FourThirds * deviatoricCoeff + volumetricCoeff) * dNdXj * dNdXi + (dNdYj * dNdYi + dNdZj * dNdZi) * deviatoricCoeff) * theta; solidLHS_Contribution(firstRow, firstCol + 1) += nodalVolume * ((nTwoThirds * deviatoricCoeff + volumetricCoeff) * dNdXj * dNdYi + dNdYj * dNdXi * deviatoricCoeff) * theta; solidLHS_Contribution(firstRow, firstCol + 2) += nodalVolume * ((nTwoThirds * deviatoricCoeff + volumetricCoeff) * dNdXj * dNdZi + dNdZj * dNdXi * deviatoricCoeff) * theta; solidLHS_Contribution(firstRow + 1, firstCol) += nodalVolume * ((nTwoThirds * deviatoricCoeff + volumetricCoeff) * dNdYj * dNdXi + dNdXj * dNdYi * deviatoricCoeff) * theta; solidLHS_Contribution(firstRow + 1, firstCol + 1) += nodalVolume * ((FourThirds * deviatoricCoeff + volumetricCoeff) * dNdYj * dNdYi + (dNdXj * dNdXi + dNdZj * dNdZi) * deviatoricCoeff) * theta; solidLHS_Contribution(firstRow + 1, firstCol + 2) += nodalVolume * ((nTwoThirds * deviatoricCoeff + volumetricCoeff) * dNdYj * dNdZi + dNdZj * dNdYi * deviatoricCoeff) * theta; solidLHS_Contribution(firstRow + 2, firstCol) += nodalVolume * ((nTwoThirds * deviatoricCoeff + volumetricCoeff) * dNdZj * dNdXi + dNdXj * dNdZi * deviatoricCoeff) * theta; solidLHS_Contribution(firstRow + 2, firstCol + 1) += nodalVolume * ((nTwoThirds * deviatoricCoeff + volumetricCoeff) * dNdZj * dNdYi + dNdYj * dNdZi * deviatoricCoeff) * theta; solidLHS_Contribution(firstRow + 2, firstCol + 2) += nodalVolume * ((FourThirds * deviatoricCoeff + volumetricCoeff) * dNdZj * dNdZi + (dNdXj * dNdXi + dNdYj * dNdYi) * deviatoricCoeff) * theta; firstRow += 3; } firstRow = 0; firstCol += 3; unsigned int indexNode = i + 1; if (itNode->FastGetSolutionStepValue(INTERFACE_NODE) == true && indexNode < neighSize) { unsigned int other_neigh_nodes_id = solidNodalSFDneighboursId[indexNode]; // std::cout<<"other_neigh_nodes_id= "<<other_neigh_nodes_id<<" within "<<nodalSFDneighboursId<<std::endl; for (unsigned int k = 0; k < neighb_nodes.size(); k++) { unsigned int neigh_nodes_id = neighb_nodes[k].Id(); // std::cout<<" neigh_nodes_id= "<< neigh_nodes_id<<std::endl; if (neigh_nodes_id == other_neigh_nodes_id) { solidEquationId[firstCol] = neighb_nodes[k].GetDof(VELOCITY_X, xDofPos).EquationId(); solidEquationId[firstCol + 1] = neighb_nodes[k].GetDof(VELOCITY_Y, xDofPos + 1).EquationId(); solidEquationId[firstCol + 2] = neighb_nodes[k].GetDof(VELOCITY_Z, xDofPos + 2).EquationId(); break; } } } else if (i < neighb_nodes.size()) { solidEquationId[firstCol] = neighb_nodes[i].GetDof(VELOCITY_X, xDofPos).EquationId(); solidEquationId[firstCol + 1] = neighb_nodes[i].GetDof(VELOCITY_Y, xDofPos + 1).EquationId(); solidEquationId[firstCol + 2] = neighb_nodes[i].GetDof(VELOCITY_Z, xDofPos + 2).EquationId(); } } } #ifdef _OPENMP Assemble(A, b, solidLHS_Contribution, solidRHS_Contribution, solidEquationId, mlock_array); #else Assemble(A, b, solidLHS_Contribution, solidRHS_Contribution, solidEquationId); #endif } } } // } KRATOS_CATCH("") } void BuildFluidNodally( typename TSchemeType::Pointer pScheme, ModelPart &rModelPart, TSystemMatrixType &A, TSystemVectorType &b) { KRATOS_TRY KRATOS_ERROR_IF(!pScheme) << "No scheme provided!" << std::endl; /* std::cout<<"Building LHS and RHS of Momentum Equation Nodally"<<std::endl; / //contributions to the system LocalSystemMatrixType LHS_Contribution = LocalSystemMatrixType(0, 0); LocalSystemVectorType RHS_Contribution = LocalSystemVectorType(0); //vector containing the localization in the system of the different terms Element::EquationIdVectorType EquationId; ProcessInfo &CurrentProcessInfo = rModelPart.GetProcessInfo(); const unsigned int dimension = rModelPart.ElementsBegin()->GetGeometry().WorkingSpaceDimension(); const double timeInterval = CurrentProcessInfo[DELTA_TIME]; const double FourThirds = 4.0 / 3.0; const double nTwoThirds = -2.0 / 3.0; double theta = 0.5; array_1d<double, 3> Acc(3, 0.0); // array_1d<double,6> Sigma(6,0.0); double pressure = 0; double dNdXi = 0; double dNdYi = 0; double dNdZi = 0; double dNdXj = 0; double dNdYj = 0; double dNdZj = 0; unsigned int firstRow = 0; unsigned int firstCol = 0; double density = 0; double deviatoricCoeff = 0; double volumetricCoeff = 0; / #pragma omp parallel / // { ModelPart::NodeIterator NodesBegin; ModelPart::NodeIterator NodesEnd; OpenMPUtils::PartitionedIterators(rModelPart.Nodes(), NodesBegin, NodesEnd); for (ModelPart::NodeIterator itNode = NodesBegin; itNode != NodesEnd; ++itNode) { if ((itNode->Is(FLUID) && itNode->IsNot(SOLID)) \|\| itNode->FastGetSolutionStepValue(INTERFACE_NODE) == true) { NodeWeakPtrVectorType &neighb_nodes = itNode->GetValue(NEIGHBOUR_NODES); Vector nodalSFDneighboursId = itNode->FastGetSolutionStepValue(NODAL_SFD_NEIGHBOURS_ORDER); // const unsigned int neighSize = neighb_nodes.size()+1; const unsigned int neighSize = nodalSFDneighboursId.size(); const double nodalVolume = itNode->FastGetSolutionStepValue(NODAL_VOLUME); if (neighSize > 1 && nodalVolume > 0) { const unsigned int localSize = itNode->FastGetSolutionStepValue(NODAL_SFD_NEIGHBOURS).size(); if (LHS_Contribution.size1() != localSize) LHS_Contribution.resize(localSize, localSize, false); //false says not to preserve existing storage!! if (RHS_Contribution.size() != localSize) RHS_Contribution.resize(localSize, false); //false says not to preserve existing storage!! if (EquationId.size() != localSize) EquationId.resize(localSize, false); LHS_Contribution = ZeroMatrix(localSize, localSize); RHS_Contribution = ZeroVector(localSize); this->SetMaterialPropertiesToFluid(itNode, density, deviatoricCoeff, volumetricCoeff, timeInterval, nodalVolume); // if(itNode->FastGetSolutionStepValue(INTERFACE_NODE)==true){ // // std::cout<<"density,deviatoricCoeff,volumetricCoeff "<<density<<" "<<deviatoricCoeff<<" "<<volumetricCoeff<<std::endl; // std::cout<<"INTERFACE nodalVolume "<<nodalVolume<<std::endl; // }else{ // std::cout<<"nodalVolume "<<nodalVolume<<std::endl; // } firstRow = 0; firstCol = 0; if (dimension == 2) { //////////////////////////// LHS TERMS ////////////////////////////// LHS_Contribution(0, 0) += nodalVolume density * 2.0 / timeInterval; LHS_Contribution(1, 1) += nodalVolume * density * 2.0 / timeInterval; //////////////////////////// RHS TERMS ////////////////////////////// //-------- DYNAMIC FORCES TERM -------// Acc = 2.0 * (itNode->FastGetSolutionStepValue(VELOCITY, 0) - itNode->FastGetSolutionStepValue(VELOCITY, 1)) / timeInterval - itNode->FastGetSolutionStepValue(ACCELERATION, 0); RHS_Contribution[0] += -nodalVolume * density * Acc[0]; RHS_Contribution[1] += -nodalVolume * density * Acc[1]; //-------- EXTERNAL FORCES TERM -------// array_1d<double, 3> &VolumeAcceleration = itNode->FastGetSolutionStepValue(VOLUME_ACCELERATION); // double posX= itNode->X(); // double posY= itNode->Y(); // double coeffX =(12.0-24.0posY)pow(posX,4); // coeffX += (-24.0+48.0posY)pow(posX,3); // coeffX += (-48.0posY+72.0pow(posY,2)-48.0pow(posY,3)+12.0)pow(posX,2); // coeffX += (-2.0+24.0posY-72.0pow(posY,2)+48.0pow(posY,3))posX; // coeffX += 1.0-4.0posY+12.0pow(posY,2)-8.0pow(posY,3); // double coeffY =(8.0-48.0posY+48.0pow(posY,2))pow(posX,3); // coeffY += (-12.0+72.0posY-72.0pow(posY,2))pow(posX,2); // coeffY += (4.0-24.0posY+48.0pow(posY,2)-48.0pow(posY,3)+24.0pow(posY,4))posX; // coeffY += -12.0pow(posY,2)+24.0pow(posY,3)-12.0pow(posY,4); // RHS_Contribution[0]+=nodalVolumedensityVolumeAcceleration[0]coeffX; // RHS_Contribution[1]+=nodalVolumedensityVolumeAcceleration[1]coeffY; RHS_Contribution[0] += nodalVolume density * VolumeAcceleration[0]; RHS_Contribution[1] += nodalVolume * density * VolumeAcceleration[1]; //-------- INTERNAL FORCES TERM -------// array_1d<double, 3> Sigma(3, 0.0); Sigma = itNode->FastGetSolutionStepValue(NODAL_CAUCHY_STRESS); // if(itNode->FastGetSolutionStepValue(INTERFACE_NODE)==true){ // Sigma=itNode->FastGetSolutionStepValue(SOLID_NODAL_CAUCHY_STRESS); // } if (itNode->IsNot(SOLID) \|\| itNode->FastGetSolutionStepValue(INTERFACE_NODE) == true) { pressure = itNode->FastGetSolutionStepValue(PRESSURE, 0) * theta + itNode->FastGetSolutionStepValue(PRESSURE, 1) * (1 - theta); Sigma[0] = itNode->FastGetSolutionStepValue(NODAL_DEVIATORIC_CAUCHY_STRESS)[0] + pressure; Sigma[1] = itNode->FastGetSolutionStepValue(NODAL_DEVIATORIC_CAUCHY_STRESS)[1] + pressure; } const unsigned int xDofPos = itNode->GetDofPosition(VELOCITY_X); EquationId[0] = itNode->GetDof(VELOCITY_X, xDofPos).EquationId(); EquationId[1] = itNode->GetDof(VELOCITY_Y, xDofPos + 1).EquationId(); for (unsigned int i = 0; i < neighSize; i++) { dNdXi = itNode->FastGetSolutionStepValue(NODAL_SFD_NEIGHBOURS)[firstCol]; dNdYi = itNode->FastGetSolutionStepValue(NODAL_SFD_NEIGHBOURS)[firstCol + 1]; RHS_Contribution[firstCol] += -nodalVolume * (dNdXi * Sigma[0] + dNdYi * Sigma[2]); RHS_Contribution[firstCol + 1] += -nodalVolume * (dNdYi * Sigma[1] + dNdXi * Sigma[2]); for (unsigned int j = 0; j < neighSize; j++) { dNdXj = itNode->FastGetSolutionStepValue(NODAL_SFD_NEIGHBOURS)[firstRow]; dNdYj = itNode->FastGetSolutionStepValue(NODAL_SFD_NEIGHBOURS)[firstRow + 1]; LHS_Contribution(firstRow, firstCol) += nodalVolume * ((FourThirds * deviatoricCoeff + volumetricCoeff) * dNdXj * dNdXi + dNdYj * dNdYi * deviatoricCoeff) * theta; LHS_Contribution(firstRow, firstCol + 1) += nodalVolume * ((nTwoThirds * deviatoricCoeff + volumetricCoeff) * dNdXj * dNdYi + dNdYj * dNdXi * deviatoricCoeff) * theta; LHS_Contribution(firstRow + 1, firstCol) += nodalVolume * ((nTwoThirds * deviatoricCoeff + volumetricCoeff) * dNdYj * dNdXi + dNdXj * dNdYi * deviatoricCoeff) * theta; LHS_Contribution(firstRow + 1, firstCol + 1) += nodalVolume * ((FourThirds * deviatoricCoeff + volumetricCoeff) * dNdYj * dNdYi + dNdXj * dNdXi * deviatoricCoeff) * theta; firstRow += 2; } firstRow = 0; firstCol += 2; unsigned int indexNode = i + 1; if (itNode->FastGetSolutionStepValue(INTERFACE_NODE) == true && indexNode < neighSize) { unsigned int other_neigh_nodes_id = nodalSFDneighboursId[indexNode]; // std::cout<<"other_neigh_nodes_id= "<<other_neigh_nodes_id<<" within "<<nodalSFDneighboursId<<std::endl; for (unsigned int k = 0; k < neighb_nodes.size(); k++) { unsigned int neigh_nodes_id = neighb_nodes[k].Id(); // std::cout<<" neigh_nodes_id= "<< neigh_nodes_id<<std::endl; if (neigh_nodes_id == other_neigh_nodes_id) { EquationId[firstCol] = neighb_nodes[k].GetDof(VELOCITY_X, xDofPos).EquationId(); EquationId[firstCol + 1] = neighb_nodes[k].GetDof(VELOCITY_Y, xDofPos + 1).EquationId(); break; } } } else if (i < neighb_nodes.size()) { EquationId[firstCol] = neighb_nodes[i].GetDof(VELOCITY_X, xDofPos).EquationId(); EquationId[firstCol + 1] = neighb_nodes[i].GetDof(VELOCITY_Y, xDofPos + 1).EquationId(); } } /* std::cout << "LHS_Contribution = " << LHS_Contribution << std::endl; / } else if (dimension == 3) { //////////////////////////// LHS TERMS ////////////////////////////// LHS_Contribution(0, 0) += nodalVolume density * 2.0 / timeInterval; LHS_Contribution(1, 1) += nodalVolume * density * 2.0 / timeInterval; LHS_Contribution(2, 2) += nodalVolume * density * 2.0 / timeInterval; //////////////////////////// RHS TERMS ////////////////////////////// //-------- DYNAMIC FORCES TERM -------// Acc = 2.0 * (itNode->FastGetSolutionStepValue(VELOCITY, 0) - itNode->FastGetSolutionStepValue(VELOCITY, 1)) / timeInterval - itNode->FastGetSolutionStepValue(ACCELERATION, 0); RHS_Contribution[0] += -nodalVolume * density * Acc[0]; RHS_Contribution[1] += -nodalVolume * density * Acc[1]; RHS_Contribution[2] += -nodalVolume * density * Acc[2]; //-------- EXTERNAL FORCES TERM -------// array_1d<double, 3> &VolumeAcceleration = itNode->FastGetSolutionStepValue(VOLUME_ACCELERATION); RHS_Contribution[0] += nodalVolume * density * VolumeAcceleration[0]; RHS_Contribution[1] += nodalVolume * density * VolumeAcceleration[1]; RHS_Contribution[2] += nodalVolume * density * VolumeAcceleration[2]; //-------- INTERNAL FORCES TERM -------// array_1d<double, 6> Sigma(6, 0.0); Sigma = itNode->FastGetSolutionStepValue(NODAL_CAUCHY_STRESS); // if(itNode->FastGetSolutionStepValue(INTERFACE_NODE)==true){ // Sigma=itNode->FastGetSolutionStepValue(SOLID_NODAL_CAUCHY_STRESS); // } if (itNode->IsNot(SOLID) \|\| itNode->FastGetSolutionStepValue(INTERFACE_NODE) == true) { pressure = itNode->FastGetSolutionStepValue(PRESSURE, 0) * theta + itNode->FastGetSolutionStepValue(PRESSURE, 1) * (1 - theta); Sigma[0] = itNode->FastGetSolutionStepValue(NODAL_DEVIATORIC_CAUCHY_STRESS)[0] + pressure; Sigma[1] = itNode->FastGetSolutionStepValue(NODAL_DEVIATORIC_CAUCHY_STRESS)[1] + pressure; Sigma[2] = itNode->FastGetSolutionStepValue(NODAL_DEVIATORIC_CAUCHY_STRESS)[2] + pressure; } const unsigned int xDofPos = itNode->GetDofPosition(VELOCITY_X); EquationId[0] = itNode->GetDof(VELOCITY_X, xDofPos).EquationId(); EquationId[1] = itNode->GetDof(VELOCITY_Y, xDofPos + 1).EquationId(); EquationId[2] = itNode->GetDof(VELOCITY_Z, xDofPos + 2).EquationId(); for (unsigned int i = 0; i < neighSize; i++) { dNdXi = itNode->FastGetSolutionStepValue(NODAL_SFD_NEIGHBOURS)[firstCol]; dNdYi = itNode->FastGetSolutionStepValue(NODAL_SFD_NEIGHBOURS)[firstCol + 1]; dNdZi = itNode->FastGetSolutionStepValue(NODAL_SFD_NEIGHBOURS)[firstCol + 2]; RHS_Contribution[firstCol] += -nodalVolume * (dNdXi * Sigma[0] + dNdYi * Sigma[3] + dNdZi * Sigma[4]); RHS_Contribution[firstCol + 1] += -nodalVolume * (dNdYi * Sigma[1] + dNdXi * Sigma[3] + dNdZi * Sigma[5]); RHS_Contribution[firstCol + 2] += -nodalVolume * (dNdZi * Sigma[2] + dNdXi * Sigma[4] + dNdYi * Sigma[5]); for (unsigned int j = 0; j < neighSize; j++) { dNdXj = itNode->FastGetSolutionStepValue(NODAL_SFD_NEIGHBOURS)[firstRow]; dNdYj = itNode->FastGetSolutionStepValue(NODAL_SFD_NEIGHBOURS)[firstRow + 1]; dNdZj = itNode->FastGetSolutionStepValue(NODAL_SFD_NEIGHBOURS)[firstRow + 2]; LHS_Contribution(firstRow, firstCol) += nodalVolume * ((FourThirds * deviatoricCoeff + volumetricCoeff) * dNdXj * dNdXi + (dNdYj * dNdYi + dNdZj * dNdZi) * deviatoricCoeff) * theta; LHS_Contribution(firstRow, firstCol + 1) += nodalVolume * ((nTwoThirds * deviatoricCoeff + volumetricCoeff) * dNdXj * dNdYi + dNdYj * dNdXi * deviatoricCoeff) * theta; LHS_Contribution(firstRow, firstCol + 2) += nodalVolume * ((nTwoThirds * deviatoricCoeff + volumetricCoeff) * dNdXj * dNdZi + dNdZj * dNdXi * deviatoricCoeff) * theta; LHS_Contribution(firstRow + 1, firstCol) += nodalVolume * ((nTwoThirds * deviatoricCoeff + volumetricCoeff) * dNdYj * dNdXi + dNdXj * dNdYi * deviatoricCoeff) * theta; LHS_Contribution(firstRow + 1, firstCol + 1) += nodalVolume * ((FourThirds * deviatoricCoeff + volumetricCoeff) * dNdYj * dNdYi + (dNdXj * dNdXi + dNdZj * dNdZi) * deviatoricCoeff) * theta; LHS_Contribution(firstRow + 1, firstCol + 2) += nodalVolume * ((nTwoThirds * deviatoricCoeff + volumetricCoeff) * dNdYj * dNdZi + dNdZj * dNdYi * deviatoricCoeff) * theta; LHS_Contribution(firstRow + 2, firstCol) += nodalVolume * ((nTwoThirds * deviatoricCoeff + volumetricCoeff) * dNdZj * dNdXi + dNdXj * dNdZi * deviatoricCoeff) * theta; LHS_Contribution(firstRow + 2, firstCol + 1) += nodalVolume * ((nTwoThirds * deviatoricCoeff + volumetricCoeff) * dNdZj * dNdYi + dNdYj * dNdZi * deviatoricCoeff) * theta; LHS_Contribution(firstRow + 2, firstCol + 2) += nodalVolume * ((FourThirds * deviatoricCoeff + volumetricCoeff) * dNdZj * dNdZi + (dNdXj * dNdXi + dNdYj * dNdYi) * deviatoricCoeff) * theta; firstRow += 3; } firstRow = 0; firstCol += 3; unsigned int indexNode = i + 1; if (itNode->FastGetSolutionStepValue(INTERFACE_NODE) == true && indexNode < neighSize) { unsigned int other_neigh_nodes_id = nodalSFDneighboursId[indexNode]; // std::cout<<"other_neigh_nodes_id= "<<other_neigh_nodes_id<<" within "<<nodalSFDneighboursId<<std::endl; for (unsigned int k = 0; k < neighb_nodes.size(); k++) { unsigned int neigh_nodes_id = neighb_nodes[k].Id(); // std::cout<<" neigh_nodes_id= "<< neigh_nodes_id<<std::endl; if (neigh_nodes_id == other_neigh_nodes_id) { EquationId[firstCol] = neighb_nodes[k].GetDof(VELOCITY_X, xDofPos).EquationId(); EquationId[firstCol + 1] = neighb_nodes[k].GetDof(VELOCITY_Y, xDofPos + 1).EquationId(); EquationId[firstCol + 2] = neighb_nodes[k].GetDof(VELOCITY_Z, xDofPos + 2).EquationId(); break; } } } else if (i < neighb_nodes.size()) { EquationId[firstCol] = neighb_nodes[i].GetDof(VELOCITY_X, xDofPos).EquationId(); EquationId[firstCol + 1] = neighb_nodes[i].GetDof(VELOCITY_Y, xDofPos + 1).EquationId(); EquationId[firstCol + 2] = neighb_nodes[i].GetDof(VELOCITY_Z, xDofPos + 2).EquationId(); } } } #ifdef _OPENMP Assemble(A, b, LHS_Contribution, RHS_Contribution, EquationId, mlock_array); #else Assemble(A, b, LHS_Contribution, RHS_Contribution, EquationId); #endif } } } // } KRATOS_CATCH("") } /** * @brief This is a call to the linear system solver * @param A The LHS matrix * @param Dx The Unknowns vector * @param b The RHS vector / void SystemSolve( TSystemMatrixType &A, TSystemVectorType &Dx, TSystemVectorType &b) override { KRATOS_TRY double norm_b; if (TSparseSpace::Size(b) != 0) norm_b = TSparseSpace::TwoNorm(b); else norm_b = 0.00; if (norm_b != 0.00) { //do solve BaseType::mpLinearSystemSolver->Solve(A, Dx, b); } else TSparseSpace::SetToZero(Dx); // Prints informations about the current time KRATOS_INFO_IF("NodalResidualBasedEliminationBuilderAndSolverForFSI", this->GetEchoLevel() > 1) << (BaseType::mpLinearSystemSolver) << std::endl; KRATOS_CATCH("") } /** @brief This is a call to the linear system solver (taking into account some physical particularities of the problem) @param A The LHS matrix * @param Dx The Unknowns vector * @param b The RHS vector * @param rModelPart The model part of the problem to solve / void SystemSolveWithPhysics( TSystemMatrixType &A, TSystemVectorType &Dx, TSystemVectorType &b, ModelPart &rModelPart) { KRATOS_TRY double norm_b; if (TSparseSpace::Size(b) != 0) norm_b = TSparseSpace::TwoNorm(b); else norm_b = 0.00; if (norm_b != 0.00) { //provide physical data as needed if (BaseType::mpLinearSystemSolver->AdditionalPhysicalDataIsNeeded()) BaseType::mpLinearSystemSolver->ProvideAdditionalData(A, Dx, b, BaseType::mDofSet, rModelPart); //do solve BaseType::mpLinearSystemSolver->Solve(A, Dx, b); } else { TSparseSpace::SetToZero(Dx); KRATOS_WARNING_IF("NodalResidualBasedEliminationBuilderAndSolverForFSI", rModelPart.GetCommunicator().MyPID() == 0) << "ATTENTION! setting the RHS to zero!" << std::endl; } // Prints informations about the current time KRATOS_INFO_IF("NodalResidualBasedEliminationBuilderAndSolverForFSI", this->GetEchoLevel() > 1 && rModelPart.GetCommunicator().MyPID() == 0) << (BaseType::mpLinearSystemSolver) << std::endl; KRATOS_CATCH("") } /** * @brief Function to perform the building and solving phase at the same time. * @details It is ideally the fastest and safer function to use when it is possible to solve * just after building * @param pScheme The integration scheme considered * @param rModelPart The model part of the problem to solve * @param A The LHS matrix * @param Dx The Unknowns vector * @param b The RHS vector / void BuildAndSolve( typename TSchemeType::Pointer pScheme, ModelPart &rModelPart, TSystemMatrixType &A, TSystemVectorType &Dx, TSystemVectorType &b) override { KRATOS_TRY Timer::Start("Build"); // boost::timer m_build_time; BuildSolidNodally(pScheme, rModelPart, A, b); BuildFluidNodally(pScheme, rModelPart, A, b); // std::cout << "MOMENTUM EQ: build_time : " << m_build_time.elapsed() << std::endl; Timer::Stop("Build"); // ApplyPointLoads(pScheme,rModelPart,b); // Does nothing...dirichlet conditions are naturally dealt with in defining the residual ApplyDirichletConditions(pScheme, rModelPart, A, Dx, b); KRATOS_INFO_IF("ResidualBasedBlockBuilderAndSolver", (this->GetEchoLevel() == 3)) << "Before the solution of the system" << "\nSystem Matrix = " << A << "\nUnknowns vector = " << Dx << "\nRHS vector = " << b << std::endl; const double start_solve = OpenMPUtils::GetCurrentTime(); Timer::Start("Solve"); / boost::timer m_solve_time; / SystemSolveWithPhysics(A, Dx, b, rModelPart); / std::cout << "MOMENTUM EQ: solve_time : " << m_solve_time.elapsed() << std::endl; / Timer::Stop("Solve"); const double stop_solve = OpenMPUtils::GetCurrentTime(); KRATOS_INFO_IF("ResidualBasedBlockBuilderAndSolver", (this->GetEchoLevel() >= 1 && rModelPart.GetCommunicator().MyPID() == 0)) << "System solve time: " << stop_solve - start_solve << std::endl; KRATOS_INFO_IF("ResidualBasedBlockBuilderAndSolver", (this->GetEchoLevel() == 3)) << "After the solution of the system" << "\nSystem Matrix = " << A << "\nUnknowns vector = " << Dx << "\nRHS vector = " << b << std::endl; KRATOS_CATCH("") } /* * @brief Builds the list of the DofSets involved in the problem by "asking" to each element * and condition its Dofs. * @details The list of dofs is stores insde the BuilderAndSolver as it is closely connected to the * way the matrix and RHS are built * @param pScheme The integration scheme considered * @param rModelPart The model part of the problem to solve / void SetUpDofSet( typename TSchemeType::Pointer pScheme, ModelPart &rModelPart) override { KRATOS_TRY; KRATOS_INFO_IF("NodalResidualBasedEliminationBuilderAndSolverForFSI", this->GetEchoLevel() > 1 && rModelPart.GetCommunicator().MyPID() == 0) << "Setting up the dofs" << std::endl; //Gets the array of elements from the modeler ElementsArrayType &pElements = rModelPart.Elements(); const int nelements = static_cast<int>(pElements.size()); Element::DofsVectorType ElementalDofList; ProcessInfo &CurrentProcessInfo = rModelPart.GetProcessInfo(); unsigned int nthreads = OpenMPUtils::GetNumThreads(); // typedef boost::fast_pool_allocator< NodeType::DofType::Pointer > allocator_type; // typedef std::unordered_set < NodeType::DofType::Pointer, // DofPointerHasher, // DofPointerComparor, // allocator_type > set_type; #ifdef USE_GOOGLE_HASH typedef google::dense_hash_set<NodeType::DofType::Pointer, DofPointerHasher> set_type; #else typedef std::unordered_set<NodeType::DofType::Pointer, DofPointerHasher> set_type; #endif // std::vector<set_type> dofs_aux_list(nthreads); // std::vector<allocator_type> allocators(nthreads); for (int i = 0; i < static_cast<int>(nthreads); i++) { #ifdef USE_GOOGLE_HASH dofs_aux_list[i].set_empty_key(NodeType::DofType::Pointer()); #else // dofs_aux_list[i] = set_type( allocators[i]); dofs_aux_list[i].reserve(nelements); #endif } // #pragma omp parallel for firstprivate(nelements, ElementalDofList) for (int i = 0; i < static_cast<int>(nelements); i++) { typename ElementsArrayType::iterator it = pElements.begin() + i; const unsigned int this_thread_id = OpenMPUtils::ThisThread(); // gets list of Dof involved on every element pScheme->GetElementalDofList((it.base()), ElementalDofList, CurrentProcessInfo); dofs_aux_list[this_thread_id].insert(ElementalDofList.begin(), ElementalDofList.end()); } ConditionsArrayType &pConditions = rModelPart.Conditions(); const int nconditions = static_cast<int>(pConditions.size()); #pragma omp parallel for firstprivate(nconditions, ElementalDofList) for (int i = 0; i < nconditions; i++) { typename ConditionsArrayType::iterator it = pConditions.begin() + i; const unsigned int this_thread_id = OpenMPUtils::ThisThread(); // gets list of Dof involved on every element pScheme->GetConditionDofList((it.base()), ElementalDofList, CurrentProcessInfo); dofs_aux_list[this_thread_id].insert(ElementalDofList.begin(), ElementalDofList.end()); } //here we do a reduction in a tree so to have everything on thread 0 unsigned int old_max = nthreads; unsigned int new_max = ceil(0.5 static_cast<double>(old_max)); while (new_max >= 1 && new_max != old_max) { // //just for debugging // std::cout << "old_max" << old_max << " new_max:" << new_max << std::endl; // for (int i = 0; i < new_max; i++) // { // if (i + new_max < old_max) // { // std::cout << i << " - " << i + new_max << std::endl; // } // } // std::cout << "*******************" << std::endl; #pragma omp parallel for for (int i = 0; i < static_cast<int>(new_max); i++) { if (i + new_max < old_max) { dofs_aux_list[i].insert(dofs_aux_list[i + new_max].begin(), dofs_aux_list[i + new_max].end()); dofs_aux_list[i + new_max].clear(); } } old_max = new_max; new_max = ceil(0.5 static_cast<double>(old_max)); } DofsArrayType Doftemp; BaseType::mDofSet = DofsArrayType(); Doftemp.reserve(dofs_aux_list[0].size()); for (auto it = dofs_aux_list[0].begin(); it != dofs_aux_list[0].end(); it++) { Doftemp.push_back(it); } Doftemp.Sort(); BaseType::mDofSet = Doftemp; // Throws an execption if there are no Degrees of freedom involved in the analysis KRATOS_ERROR_IF(BaseType::mDofSet.size() == 0) << "No degrees of freedom!" << std::endl; BaseType::mDofSetIsInitialized = true; KRATOS_INFO_IF("NodalResidualBasedEliminationBuilderAndSolverForFSI", this->GetEchoLevel() > 2 && rModelPart.GetCommunicator().MyPID() == 0) << "Finished setting up the dofs" << std::endl; #ifdef _OPENMP if (mlock_array.size() != 0) { for (int i = 0; i < static_cast<int>(mlock_array.size()); i++) omp_destroy_lock(&mlock_array[i]); } mlock_array.resize(BaseType::mDofSet.size()); for (int i = 0; i < static_cast<int>(mlock_array.size()); i++) omp_init_lock(&mlock_array[i]); #endif // If reactions are to be calculated, we check if all the dofs have reactions defined // This is tobe done only in debug mode #ifdef KRATOS_DEBUG if (BaseType::GetCalculateReactionsFlag()) { for (auto dof_iterator = BaseType::mDofSet.begin(); dof_iterator != BaseType::mDofSet.end(); ++dof_iterator) { KRATOS_ERROR_IF_NOT(dof_iterator->HasReaction()) << "Reaction variable not set for the following : " << std::endl << "Node : " << dof_iterator->Id() << std::endl << "Dof : " << (dof_iterator) << std::endl << "Not possible to calculate reactions." << std::endl; } } #endif KRATOS_CATCH(""); } /** * @brief Organises the dofset in order to speed up the building phase * @param rModelPart The model part of the problem to solve / void SetUpSystem( ModelPart &rModelPart) override { // Set equation id for degrees of freedom // the free degrees of freedom are positioned at the beginning of the system, // while the fixed one are at the end (in opposite order). // // that means that if the EquationId is greater than "mEquationSystemSize" // the pointed degree of freedom is restrained // int free_id = 0; int fix_id = BaseType::mDofSet.size(); for (typename DofsArrayType::iterator dof_iterator = BaseType::mDofSet.begin(); dof_iterator != BaseType::mDofSet.end(); ++dof_iterator) if (dof_iterator->IsFixed()) dof_iterator->SetEquationId(--fix_id); else dof_iterator->SetEquationId(free_id++); BaseType::mEquationSystemSize = fix_id; } //*********************************************************************** //************************************************************************ void ResizeAndInitializeVectors( typename TSchemeType::Pointer pScheme, TSystemMatrixPointerType &pA, TSystemVectorPointerType &pDx, TSystemVectorPointerType &pb, ModelPart &rModelPart) override { KRATOS_TRY // boost::timer m_contruct_matrix; if (pA == NULL) //if the pointer is not initialized initialize it to an empty matrix { TSystemMatrixPointerType pNewA = TSystemMatrixPointerType(new TSystemMatrixType(0, 0)); pA.swap(pNewA); } if (pDx == NULL) //if the pointer is not initialized initialize it to an empty matrix { TSystemVectorPointerType pNewDx = TSystemVectorPointerType(new TSystemVectorType(0)); pDx.swap(pNewDx); } if (pb == NULL) //if the pointer is not initialized initialize it to an empty matrix { TSystemVectorPointerType pNewb = TSystemVectorPointerType(new TSystemVectorType(0)); pb.swap(pNewb); } if (BaseType::mpReactionsVector == NULL) //if the pointer is not initialized initialize it to an empty matrix { TSystemVectorPointerType pNewReactionsVector = TSystemVectorPointerType(new TSystemVectorType(0)); BaseType::mpReactionsVector.swap(pNewReactionsVector); } TSystemMatrixType &A = pA; TSystemVectorType &Dx = pDx; TSystemVectorType &b = pb; //resizing the system vectors and matrix if (A.size1() == 0 \|\| BaseType::GetReshapeMatrixFlag() == true) //if the matrix is not initialized { A.resize(BaseType::mEquationSystemSize, BaseType::mEquationSystemSize, false); ConstructMatrixStructureForFSI(pScheme, A, rModelPart); } else { if (A.size1() != BaseType::mEquationSystemSize \|\| A.size2() != BaseType::mEquationSystemSize) { KRATOS_WATCH("it should not come here!!!!!!!! ... this is SLOW"); KRATOS_ERROR << "The equation system size has changed during the simulation. This is not permited." << std::endl; A.resize(BaseType::mEquationSystemSize, BaseType::mEquationSystemSize, true); ConstructMatrixStructureForFSI(pScheme, A, rModelPart); } } if (Dx.size() != BaseType::mEquationSystemSize) Dx.resize(BaseType::mEquationSystemSize, false); if (b.size() != BaseType::mEquationSystemSize) b.resize(BaseType::mEquationSystemSize, false); //if needed resize the vector for the calculation of reactions if (BaseType::mCalculateReactionsFlag == true) { unsigned int ReactionsVectorSize = BaseType::mDofSet.size(); if (BaseType::mpReactionsVector->size() != ReactionsVectorSize) BaseType::mpReactionsVector->resize(ReactionsVectorSize, false); } // std::cout << "MOMENTUM EQ: contruct_matrix : " << m_contruct_matrix.elapsed() << std::endl; KRATOS_CATCH("") } //*********************************************************************** //********************************************************************** / * @brief Applies the dirichlet conditions. This operation may be very heavy or completely * unexpensive depending on the implementation choosen and on how the System Matrix is built. * @details For explanation of how it works for a particular implementation the user * should refer to the particular Builder And Solver choosen * @param pScheme The integration scheme considered * @param rModelPart The model part of the problem to solve * @param A The LHS matrix * @param Dx The Unknowns vector * @param b The RHS vector / void ApplyDirichletConditions( typename TSchemeType::Pointer pScheme, ModelPart &rModelPart, TSystemMatrixType &A, TSystemVectorType &Dx, TSystemVectorType &b) override { } /* * @brief This function is intended to be called at the end of the solution step to clean up memory storage not needed / void Clear() override { this->mDofSet = DofsArrayType(); if (this->mpReactionsVector != NULL) TSparseSpace::Clear((this->mpReactionsVector)); // this->mReactionsVector = TSystemVectorType(); this->mpLinearSystemSolver->Clear(); KRATOS_INFO_IF("NodalResidualBasedEliminationBuilderAndSolverForFSI", this->GetEchoLevel() > 1) << "Clear Function called" << std::endl; } /* * @brief This function is designed to be called once to perform all the checks needed * on the input provided. Checks can be "expensive" as the function is designed * to catch user's errors. * @param rModelPart The model part of the problem to solve * @return 0 all ok / int Check(ModelPart &rModelPart) override { KRATOS_TRY return 0; KRATOS_CATCH(""); } ///@} ///@name Access ///@{ ///@} ///@name Inquiry ///@{ ///@} ///@name Friends ///@{ ///@} protected: ///@name Protected static Member Variables ///@{ ///@} ///@name Protected member Variables ///@{ ///@} ///@name Protected Operators ///@{ ///@} ///@name Protected Operations ///@{ void Assemble( TSystemMatrixType &A, TSystemVectorType &b, const LocalSystemMatrixType &LHS_Contribution, const LocalSystemVectorType &RHS_Contribution, const Element::EquationIdVectorType &EquationId #ifdef _OPENMP , std::vector<omp_lock_t> &lock_array #endif ) { unsigned int local_size = LHS_Contribution.size1(); for (unsigned int i_local = 0; i_local < local_size; i_local++) { unsigned int i_global = EquationId[i_local]; if (i_global < BaseType::mEquationSystemSize) { #ifdef _OPENMP omp_set_lock(&lock_array[i_global]); #endif b[i_global] += RHS_Contribution(i_local); for (unsigned int j_local = 0; j_local < local_size; j_local++) { unsigned int j_global = EquationId[j_local]; if (j_global < BaseType::mEquationSystemSize) { A(i_global, j_global) += LHS_Contribution(i_local, j_local); } } #ifdef _OPENMP omp_unset_lock(&lock_array[i_global]); #endif } //note that assembly on fixed rows is not performed here } } //************************************************************************* virtual void ConstructMatrixStructureForFSI( typename TSchemeType::Pointer pScheme, TSystemMatrixType &A, ModelPart &rModelPart) { //filling with zero the matrix (creating the structure) Timer::Start("MatrixStructure"); ProcessInfo &CurrentProcessInfo = rModelPart.GetProcessInfo(); // Getting the array of the conditions const int nconditions = static_cast<int>(rModelPart.Conditions().size()); ModelPart::ConditionsContainerType::iterator cond_begin = rModelPart.ConditionsBegin(); const std::size_t equation_size = BaseType::mEquationSystemSize; #ifdef USE_GOOGLE_HASH std::vector<google::dense_hash_set<std::size_t>> indices(equation_size); const std::size_t empty_key = 2 * equation_size + 10; #else std::vector<std::unordered_set<std::size_t>> indices(equation_size); #endif #pragma omp parallel for firstprivate(equation_size) for (int iii = 0; iii < static_cast<int>(equation_size); iii++) { #ifdef USE_GOOGLE_HASH indices[iii].set_empty_key(empty_key); #else indices[iii].reserve(40); #endif } Element::EquationIdVectorType EquationId; ModelPart::NodeIterator NodesBegin; ModelPart::NodeIterator NodesEnd; OpenMPUtils::PartitionedIterators(rModelPart.Nodes(), NodesBegin, NodesEnd); for (ModelPart::NodeIterator itNode = NodesBegin; itNode != NodesEnd; ++itNode) { if (itNode->Is(SOLID)) { const unsigned int localSize = itNode->FastGetSolutionStepValue(SOLID_NODAL_SFD_NEIGHBOURS).size(); const unsigned int dimension = rModelPart.ElementsBegin()->GetGeometry().WorkingSpaceDimension(); Vector nodalSFDneighboursId = itNode->FastGetSolutionStepValue(SOLID_NODAL_SFD_NEIGHBOURS_ORDER); const unsigned int neighSize = nodalSFDneighboursId.size(); if (EquationId.size() != localSize) EquationId.resize(localSize, false); unsigned int firstCol = 0; const unsigned int xDofPos = itNode->GetDofPosition(VELOCITY_X); EquationId[0] = itNode->GetDof(VELOCITY_X, xDofPos).EquationId(); EquationId[1] = itNode->GetDof(VELOCITY_Y, xDofPos + 1).EquationId(); if (dimension == 3) EquationId[2] = itNode->GetDof(VELOCITY_Z, xDofPos + 2).EquationId(); if (itNode->FastGetSolutionStepValue(INTERFACE_NODE) == true) { NodeWeakPtrVectorType &neighb_nodes = itNode->GetValue(NEIGHBOUR_NODES); for (unsigned int i = 0; i < neighb_nodes.size(); i++) { unsigned int indexNode = i + 1; if (indexNode < neighSize) { unsigned int other_neigh_nodes_id = nodalSFDneighboursId[indexNode]; firstCol += dimension; for (unsigned int k = 0; k < neighb_nodes.size(); k++) { unsigned int neigh_nodes_id = neighb_nodes[k].Id(); if (neigh_nodes_id == other_neigh_nodes_id) { EquationId[firstCol] = neighb_nodes[k].GetDof(VELOCITY_X, xDofPos).EquationId(); EquationId[firstCol + 1] = neighb_nodes[k].GetDof(VELOCITY_Y, xDofPos + 1).EquationId(); if (dimension == 3) { EquationId[firstCol + 2] = neighb_nodes[k].GetDof(VELOCITY_Z, xDofPos + 2).EquationId(); } break; } } } } } else { NodeWeakPtrVectorType &neighb_nodes = itNode->GetValue(NEIGHBOUR_NODES); for (unsigned int i = 0; i < neighb_nodes.size(); i++) { firstCol += dimension; EquationId[firstCol] = neighb_nodes[i].GetDof(VELOCITY_X, xDofPos).EquationId(); EquationId[firstCol + 1] = neighb_nodes[i].GetDof(VELOCITY_Y, xDofPos + 1).EquationId(); if (dimension == 3) { EquationId[firstCol + 2] = neighb_nodes[i].GetDof(VELOCITY_Z, xDofPos + 2).EquationId(); } } } } if ((itNode->Is(FLUID) && itNode->IsNot(SOLID)) \|\| itNode->FastGetSolutionStepValue(INTERFACE_NODE) == true) { const unsigned int localSize = itNode->FastGetSolutionStepValue(NODAL_SFD_NEIGHBOURS).size(); const unsigned int dimension = rModelPart.ElementsBegin()->GetGeometry().WorkingSpaceDimension(); Vector nodalSFDneighboursId = itNode->FastGetSolutionStepValue(NODAL_SFD_NEIGHBOURS_ORDER); const unsigned int neighSize = nodalSFDneighboursId.size(); if (EquationId.size() != localSize) EquationId.resize(localSize, false); unsigned int firstCol = 0; const unsigned int xDofPos = itNode->GetDofPosition(VELOCITY_X); EquationId[0] = itNode->GetDof(VELOCITY_X, xDofPos).EquationId(); EquationId[1] = itNode->GetDof(VELOCITY_Y, xDofPos + 1).EquationId(); if (dimension == 3) EquationId[2] = itNode->GetDof(VELOCITY_Z, xDofPos + 2).EquationId(); if (itNode->FastGetSolutionStepValue(INTERFACE_NODE) == true) { NodeWeakPtrVectorType &neighb_nodes = itNode->GetValue(NEIGHBOUR_NODES); for (unsigned int i = 0; i < neighb_nodes.size(); i++) { unsigned int indexNode = i + 1; if (indexNode < neighSize) { unsigned int other_neigh_nodes_id = nodalSFDneighboursId[indexNode]; firstCol += dimension; for (unsigned int k = 0; k < neighb_nodes.size(); k++) { unsigned int neigh_nodes_id = neighb_nodes[k].Id(); if (neigh_nodes_id == other_neigh_nodes_id) { EquationId[firstCol] = neighb_nodes[k].GetDof(VELOCITY_X, xDofPos).EquationId(); EquationId[firstCol + 1] = neighb_nodes[k].GetDof(VELOCITY_Y, xDofPos + 1).EquationId(); if (dimension == 3) { EquationId[firstCol + 2] = neighb_nodes[k].GetDof(VELOCITY_Z, xDofPos + 2).EquationId(); } break; } } } } } else { NodeWeakPtrVectorType &neighb_nodes = itNode->GetValue(NEIGHBOUR_NODES); for (unsigned int i = 0; i < neighb_nodes.size(); i++) { firstCol += dimension; EquationId[firstCol] = neighb_nodes[i].GetDof(VELOCITY_X, xDofPos).EquationId(); EquationId[firstCol + 1] = neighb_nodes[i].GetDof(VELOCITY_Y, xDofPos + 1).EquationId(); if (dimension == 3) { EquationId[firstCol + 2] = neighb_nodes[i].GetDof(VELOCITY_Z, xDofPos + 2).EquationId(); } } } } for (std::size_t i = 0; i < EquationId.size(); i++) { if (EquationId[i] < BaseType::mEquationSystemSize) { #ifdef _OPENMP omp_set_lock(&mlock_array[EquationId[i]]); #endif auto &row_indices = indices[EquationId[i]]; for (auto it = EquationId.begin(); it != EquationId.end(); it++) { if (it < BaseType::mEquationSystemSize) row_indices.insert(it); } #ifdef _OPENMP omp_unset_lock(&mlock_array[EquationId[i]]); #endif } } } Element::EquationIdVectorType ids(3, 0); #pragma omp parallel for firstprivate(nconditions, ids) for (int iii = 0; iii < nconditions; iii++) { typename ConditionsArrayType::iterator i_condition = cond_begin + iii; pScheme->Condition_EquationId((i_condition.base()), ids, CurrentProcessInfo); for (std::size_t i = 0; i < ids.size(); i++) { if (ids[i] < BaseType::mEquationSystemSize) { #ifdef _OPENMP omp_set_lock(&mlock_array[ids[i]]); #endif auto &row_indices = indices[ids[i]]; for (auto it = ids.begin(); it != ids.end(); it++) { if (it < BaseType::mEquationSystemSize) row_indices.insert(it); } #ifdef _OPENMP omp_unset_lock(&mlock_array[ids[i]]); #endif } } } //count the row sizes unsigned int nnz = 0; for (unsigned int i = 0; i < indices.size(); i++) nnz += indices[i].size(); A = boost::numeric::ublas::compressed_matrix<double>(indices.size(), indices.size(), nnz); double Avalues = A.value_data().begin(); std::size_t Arow_indices = A.index1_data().begin(); std::size_t Acol_indices = A.index2_data().begin(); //filling the index1 vector - DO NOT MAKE PARALLEL THE FOLLOWING LOOP! Arow_indices[0] = 0; for (int i = 0; i < static_cast<int>(A.size1()); i++) Arow_indices[i + 1] = Arow_indices[i] + indices[i].size(); #pragma omp parallel for for (int i = 0; i < static_cast<int>(A.size1()); i++) { const unsigned int row_begin = Arow_indices[i]; const unsigned int row_end = Arow_indices[i + 1]; unsigned int k = row_begin; for (auto it = indices[i].begin(); it != indices[i].end(); it++) { Acol_indices[k] = it; Avalues[k] = 0.0; k++; } std::sort(&Acol_indices[row_begin], &Acol_indices[row_end]); } A.set_filled(indices.size() + 1, nnz); Timer::Stop("MatrixStructure"); } void AssembleLHS( TSystemMatrixType &A, LocalSystemMatrixType &LHS_Contribution, Element::EquationIdVectorType &EquationId) { unsigned int local_size = LHS_Contribution.size1(); for (unsigned int i_local = 0; i_local < local_size; i_local++) { unsigned int i_global = EquationId[i_local]; if (i_global < BaseType::mEquationSystemSize) { for (unsigned int j_local = 0; j_local < local_size; j_local++) { unsigned int j_global = EquationId[j_local]; if (j_global < BaseType::mEquationSystemSize) A(i_global, j_global) += LHS_Contribution(i_local, j_local); } } } } ///@} ///@name Protected Access ///@{ ///@} ///@name Protected Inquiry ///@{ ///@} ///@name Protected LifeCycle ///@{ ///@} private: ///@name Static Member Variables ///@{ ///@} ///@name Member Variables ///@{ #ifdef _OPENMP std::vector<omp_lock_t> mlock_array; #endif ///@} ///@name Private Operators ///@{ ///@} ///@name Private Operations ///@{ inline void AddUnique(std::vector<std::size_t> &v, const std::size_t &candidate) { std::vector<std::size_t>::iterator i = v.begin(); std::vector<std::size_t>::iterator endit = v.end(); while (i != endit && (i) != candidate) { i++; } if (i == endit) { v.push_back(candidate); } } void AssembleRHS( TSystemVectorType &b, const LocalSystemVectorType &RHS_Contribution, const Element::EquationIdVectorType &EquationId) { unsigned int local_size = RHS_Contribution.size(); if (BaseType::mCalculateReactionsFlag == false) { for (unsigned int i_local = 0; i_local < local_size; i_local++) { const unsigned int i_global = EquationId[i_local]; if (i_global < BaseType::mEquationSystemSize) //free dof { // ASSEMBLING THE SYSTEM VECTOR double &b_value = b[i_global]; const double &rhs_value = RHS_Contribution[i_local]; #pragma omp atomic b_value += rhs_value; } } } else { TSystemVectorType &ReactionsVector = BaseType::mpReactionsVector; for (unsigned int i_local = 0; i_local < local_size; i_local++) { const unsigned int i_global = EquationId[i_local]; if (i_global < BaseType::mEquationSystemSize) //free dof { // ASSEMBLING THE SYSTEM VECTOR double &b_value = b[i_global]; const double &rhs_value = RHS_Contribution[i_local]; #pragma omp atomic b_value += rhs_value; } else //fixed dof { double &b_value = ReactionsVector[i_global - BaseType::mEquationSystemSize]; const double &rhs_value = RHS_Contribution[i_local]; #pragma omp atomic b_value += rhs_value; } } } } //************************************************************************* void AssembleLHS_CompleteOnFreeRows( TSystemMatrixType &A, LocalSystemMatrixType &LHS_Contribution, Element::EquationIdVectorType &EquationId) { unsigned int local_size = LHS_Contribution.size1(); for (unsigned int i_local = 0; i_local < local_size; i_local++) { unsigned int i_global = EquationId[i_local]; if (i_global < BaseType::mEquationSystemSize) { for (unsigned int j_local = 0; j_local < local_size; j_local++) { int j_global = EquationId[j_local]; A(i_global, j_global) += LHS_Contribution(i_local, j_local); } } } } ///@} ///@name Private Operations ///@{ ///@} ///@name Private Access ///@{ ///@} ///@name Private Inquiry ///@{ ///@} ///@name Un accessible methods ///@{ ///@} }; /* Class NodalResidualBasedEliminationBuilderAndSolverForFSI / ///@} ///@name Type Definitions ///@{ ///@} } / namespace Kratos./ #endif / KRATOS_NODAL_RESIDUAL_BASED_ELIMINATION_BUILDER_AND_SOLVER_FOR_FSI defined */
GB_unop__identity_fp32_uint8.c	//------------------------------------------------------------------------------ // GB_unop: 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_unop__include.h" // C=unop(A) is defined by the following types and operators: // op(A) function: GB_unop_apply__identity_fp32_uint8 // op(A') function: GB_unop_tran__identity_fp32_uint8 // C type: float // A type: uint8_t // cast: float cij = (float) aij // unaryop: cij = aij #define GB_ATYPE \ uint8_t #define GB_CTYPE \ float // aij = Ax [pA] #define GB_GETA(aij,Ax,pA) \ uint8_t aij = Ax [pA] #define GB_CX(p) Cx [p] // unary operator #define GB_OP(z, x) \ z = x ; // casting #define GB_CAST(z, aij) \ float z = (float) aij ; // cij = op (aij) #define GB_CAST_OP(pC,pA) \ { \ /* aij = Ax [pA] / \ uint8_t aij = Ax [pA] ; \ / Cx [pC] = op (cast (aij)) / \ float z = (float) aij ; \ Cx [pC] = z ; \ } // disable this operator and use the generic case if these conditions hold #define GB_DISABLE \ (GxB_NO_IDENTITY \|\| GxB_NO_FP32 \|\| GxB_NO_UINT8) //------------------------------------------------------------------------------ // Cx = op (cast (Ax)): apply a unary operator //------------------------------------------------------------------------------ GrB_Info GB_unop_apply__identity_fp32_uint8 ( float Cx, // Cx and Ax may be aliased const uint8_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++) { uint8_t aij = Ax [p] ; float z = (float) aij ; Cx [p] = z ; } return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // C = op (cast (A')): transpose, typecast, and apply a unary operator //------------------------------------------------------------------------------ GrB_Info GB_unop_tran__identity_fp32_uint8 ( 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_unop_transpose.c" return (GrB_SUCCESS) ; #endif } #endif
GrB_IndexUnaryOp_wait.c	//------------------------------------------------------------------------------ // GrB_IndexUnaryOp_wait: wait for a user-defined GrB_IndexUnaryOp to complete //------------------------------------------------------------------------------ // SuiteSparse:GraphBLAS, Timothy A. Davis, (c) 2017-2022, All Rights Reserved. // SPDX-License-Identifier: Apache-2.0 //------------------------------------------------------------------------------ // In SuiteSparse:GraphBLAS, a user-defined GrB_IndexUnaryOp has no pending // operations to wait for. All this method does is verify that the op is // properly initialized, and then it does an OpenMP flush. #include "GB.h" GrB_Info GrB_IndexUnaryOp_wait // no work, just check if valid ( GrB_IndexUnaryOp op, GrB_WaitMode waitmode ) { //-------------------------------------------------------------------------- // check inputs //-------------------------------------------------------------------------- GB_WHERE1 ("GrB_IndexUnaryOp_wait (op, waitmode)") ; GB_RETURN_IF_NULL_OR_FAULTY (op) ; //-------------------------------------------------------------------------- // return result //-------------------------------------------------------------------------- #pragma omp flush return (GrB_SUCCESS) ; }
GB_unaryop__abs_int32_int32.c	//------------------------------------------------------------------------------ // GB_unaryop: hard-coded functions for each built-in unary operator //------------------------------------------------------------------------------ // SuiteSparse:GraphBLAS, Timothy A. Davis, (c) 2017-2019, 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__abs_int32_int32 // op(A') function: GB_tran__abs_int32_int32 // C type: int32_t // A type: int32_t // cast: int32_t cij = (int32_t) aij // unaryop: cij = GB_IABS (aij) #define GB_ATYPE \ int32_t #define GB_CTYPE \ int32_t // aij = Ax [pA] #define GB_GETA(aij,Ax,pA) \ int32_t aij = Ax [pA] #define GB_CX(p) Cx [p] // unary operator #define GB_OP(z, x) \ z = GB_IABS (x) ; // casting #define GB_CASTING(z, x) \ int32_t z = (int32_t) x ; // 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 (x, aij) ; \ GB_OP (GB_CX (pC), x) ; \ } // disable this operator and use the generic case if these conditions hold #define GB_DISABLE \ (GxB_NO_ABS \|\| GxB_NO_INT32) //------------------------------------------------------------------------------ // Cx = op (cast (Ax)): apply a unary operator //------------------------------------------------------------------------------ GrB_Info GB_unop__abs_int32_int32 ( int32_t restrict Cx, const int32_t restrict Ax, int64_t anz, int nthreads ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else #pragma omp parallel for num_threads(nthreads) schedule(static) for (int64_t 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__abs_int32_int32 ( GrB_Matrix C, const GrB_Matrix A, int64_t Rowcounts, GBI_single_iterator Iter, const int64_t 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
DRB008-indirectaccess4-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. / / Two pointers have a distance of 12 (xa2 - xa1 = 12). They are used as base addresses for indirect array accesses using an index set (another array). The index set has two indices with distance of 12 : indexSet[1]- indexSet[0] = 533 - 521 = 12 So xa1[idx] and xa2[idx] may cause loop carried dependence for N=0 and N=3. We use the default loop scheduling (static even) in OpenMP. It is possible that two dependent iterations will be scheduled within a same chunk to a same thread. So there is no runtime data races. N is 180, two iteraions with N=0 and N= 1 have loop carried dependences. For static even scheduling, we must have at least 180 threads (180180=1 iterations) so iteration 0 and 1 will be scheduled to two different threads. Data race pair: xa1[idx]@128:5 vs. xa2[idx]@129:5 / #include <assert.h> #include <stdio.h> #include <stdlib.h> / 521+12=533 / int indexSet[180] = {521, 533, 525, 527, 529, 531, 547, 549, 551, 553, 555, 557, 573, 575, 577, 579, 581, 583, 599, 601, 603, 605, 607, 609, 625, 627, 629, 631, 633, 635, 651, 653, 655, 657, 659, 661, 859, 861, 863, 865, 867, 869, 885, 887, 889, 891, 893, 895, 911, 913, 915, 917, 919, 921, 937, 939, 941, 943, 945, 947, 963, 965, 967, 969, 971, 973, 989, 991, 993, 995, 997, 999, 1197, 1199, 1201, 1203, 1205, 1207, 1223, 1225, 1227, 1229, 1231, 1233, 1249, 1251, 1253, 1255, 1257, 1259, 1275, 1277, 1279, 1281, 1283, 1285, 1301, 1303, 1305, 1307, 1309, 1311, 1327, 1329, 1331, 1333, 1335, 1337, 1535, 1537, 1539, 1541, 1543, 1545, 1561, 1563, 1565, 1567, 1569, 1571, 1587, 1589, 1591, 1593, 1595, 1597, 1613, 1615, 1617, 1619, 1621, 1623, 1639, 1641, 1643, 1645, 1647, 1649, 1665, 1667, 1669, 1671, 1673, 1675, 1873, 1875, 1877, 1879, 1881, 1883, 1899, 1901, 1903, 1905, 1907, 1909, 1925, 1927, 1929, 1931, 1933, 1935, 1951, 1953, 1955, 1957, 1959, 1961, 1977, 1979, 1981, 1983, 1985, 1987, 2003, 2005, 2007, 2009, 2011, 2013}; int main(int argc, char argv[]) { double * base = (double * )malloc(sizeof (double)((2013+12)+1)); double xa1 = base; double * xa2 = xa1+12; int i; int _ret_val_0; if (base==0) { printf("Error in malloc(). Aborting ...\n"); _ret_val_0=1; return _ret_val_0; } /* initialize segments touched by indexSet / #pragma loop name main#0 #pragma cetus parallel #pragma omp parallel for for (i=521; i<=2025; ++ i) { base[i]=(0.5i); } #pragma loop name main#1 for (i=0; i<180; ++ i) { int idx = indexSet[i]; xa1[idx]+=1.0; xa2[idx]+=3.0; } printf("x1[999]=%f xa2[1285]=%f\n", xa1[999], xa2[1285]); free(base); _ret_val_0=0; return _ret_val_0; }
ocp_nlp_sqp.c	/* * Copyright 2019 Gianluca Frison, Dimitris Kouzoupis, Robin Verschueren, * Andrea Zanelli, Niels van Duijkeren, Jonathan Frey, Tommaso Sartor, * Branimir Novoselnik, Rien Quirynen, Rezart Qelibari, Dang Doan, * Jonas Koenemann, Yutao Chen, Tobias Schöls, Jonas Schlagenhauf, Moritz Diehl * * This file is part of acados. * * The 2-Clause BSD License * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are met: * * 1. Redistributions of source code must retain the above copyright notice, * this list of conditions and the following disclaimer. * * 2. 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. * * 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.; / #include "acados/ocp_nlp/ocp_nlp_sqp.h" // external #include <assert.h> #include <math.h> #include <stdio.h> #include <string.h> #include <stdlib.h> #if defined(ACADOS_WITH_OPENMP) #include <omp.h> #endif // blasfeo #include "blasfeo/include/blasfeo_d_aux.h" #include "blasfeo/include/blasfeo_d_aux_ext_dep.h" #include "blasfeo/include/blasfeo_d_blas.h" // acados #include "acados/ocp_nlp/ocp_nlp_common.h" #include "acados/ocp_nlp/ocp_nlp_dynamics_cont.h" #include "acados/ocp_nlp/ocp_nlp_reg_common.h" #include "acados/ocp_qp/ocp_qp_common.h" #include "acados/utils/mem.h" #include "acados/utils/print.h" #include "acados/utils/timing.h" #include "acados/utils/types.h" #include "acados_c/ocp_qp_interface.h" /*********************************************** * options ***********************************************/ int ocp_nlp_sqp_opts_calculate_size(void config_, void dims_) { ocp_nlp_dims dims = dims_; ocp_nlp_config config = config_; int size = 0; size += sizeof(ocp_nlp_sqp_opts); size += ocp_nlp_opts_calculate_size(config, dims); return size; } void ocp_nlp_sqp_opts_assign(void config_, void dims_, void raw_memory) { ocp_nlp_dims dims = dims_; ocp_nlp_config config = config_; char c_ptr = (char ) raw_memory; ocp_nlp_sqp_opts opts = (ocp_nlp_sqp_opts ) c_ptr; c_ptr += sizeof(ocp_nlp_sqp_opts); opts->nlp_opts = ocp_nlp_opts_assign(config, dims, c_ptr); c_ptr += ocp_nlp_opts_calculate_size(config, dims); assert((char ) raw_memory + ocp_nlp_sqp_opts_calculate_size(config, dims) >= c_ptr); return opts; } void ocp_nlp_sqp_opts_initialize_default(void config_, void dims_, void opts_) { ocp_nlp_dims dims = dims_; ocp_nlp_config config = config_; ocp_nlp_sqp_opts opts = opts_; ocp_nlp_opts nlp_opts = opts->nlp_opts; ocp_qp_xcond_solver_config qp_solver = config->qp_solver; // int ii; // this first !!! ocp_nlp_opts_initialize_default(config, dims, nlp_opts); // SQP opts opts->max_iter = 20; opts->tol_stat = 1e-8; opts->tol_eq = 1e-8; opts->tol_ineq = 1e-8; opts->tol_comp = 1e-8; opts->ext_qp_res = 0; opts->qp_warm_start = 0; opts->warm_start_first_qp = false; opts->rti_phase = 0; opts->print_level = 0; opts->initialize_t_slacks = 0; // overwrite default submodules opts // qp tolerance qp_solver->opts_set(qp_solver, opts->nlp_opts->qp_solver_opts, "tol_stat", &opts->tol_stat); qp_solver->opts_set(qp_solver, opts->nlp_opts->qp_solver_opts, "tol_eq", &opts->tol_eq); qp_solver->opts_set(qp_solver, opts->nlp_opts->qp_solver_opts, "tol_ineq", &opts->tol_ineq); qp_solver->opts_set(qp_solver, opts->nlp_opts->qp_solver_opts, "tol_comp", &opts->tol_comp); return; } void ocp_nlp_sqp_opts_update(void config_, void dims_, void opts_) { ocp_nlp_dims dims = dims_; ocp_nlp_config config = config_; ocp_nlp_sqp_opts opts = opts_; ocp_nlp_opts nlp_opts = opts->nlp_opts; ocp_nlp_opts_update(config, dims, nlp_opts); return; } void ocp_nlp_sqp_opts_set(void config_, void opts_, const char field, void* value) { ocp_nlp_config config = config_; ocp_nlp_sqp_opts opts = (ocp_nlp_sqp_opts ) opts_; ocp_nlp_opts nlp_opts = opts->nlp_opts; int ii; char module[MAX_STR_LEN]; char ptr_module = NULL; int module_length = 0; // extract module name char char_ = strchr(field, '_'); if (char_!=NULL) { module_length = char_-field; for (ii=0; ii<module_length; ii++) module[ii] = field[ii]; module[module_length] = '\0'; // add end of string ptr_module = module; } // pass options to QP module if ( ptr_module!=NULL && (!strcmp(ptr_module, "qp")) ) { ocp_nlp_opts_set(config, nlp_opts, field, value); if (!strcmp(field, "qp_warm_start")) { int* i_ptr = (int ) value; opts->qp_warm_start = i_ptr; } } else // nlp opts { if (!strcmp(field, "max_iter")) { int* max_iter = (int ) value; opts->max_iter = max_iter; } else if (!strcmp(field, "tol_stat")) { double* tol_stat = (double ) value; opts->tol_stat = tol_stat; // TODO: set accuracy of the qp_solver to the minimum of current QP accuracy and the one specified. config->qp_solver->opts_set(config->qp_solver, opts->nlp_opts->qp_solver_opts, "tol_stat", value); } else if (!strcmp(field, "tol_eq")) { double* tol_eq = (double ) value; opts->tol_eq = tol_eq; // TODO: set accuracy of the qp_solver to the minimum of current QP accuracy and the one specified. config->qp_solver->opts_set(config->qp_solver, opts->nlp_opts->qp_solver_opts, "tol_eq", value); } else if (!strcmp(field, "tol_ineq")) { double* tol_ineq = (double ) value; opts->tol_ineq = tol_ineq; // TODO: set accuracy of the qp_solver to the minimum of current QP accuracy and the one specified. config->qp_solver->opts_set(config->qp_solver, opts->nlp_opts->qp_solver_opts, "tol_ineq", value); } else if (!strcmp(field, "tol_comp")) { double* tol_comp = (double ) value; opts->tol_comp = tol_comp; // TODO: set accuracy of the qp_solver to the minimum of current QP accuracy and the one specified. config->qp_solver->opts_set(config->qp_solver, opts->nlp_opts->qp_solver_opts, "tol_comp", value); } else if (!strcmp(field, "ext_qp_res")) { int* ext_qp_res = (int ) value; opts->ext_qp_res = ext_qp_res; } else if (!strcmp(field, "warm_start_first_qp")) { bool* warm_start_first_qp = (bool ) value; opts->warm_start_first_qp = warm_start_first_qp; } else if (!strcmp(field, "rti_phase")) { int* rti_phase = (int ) value; if (rti_phase < 0 \|\| rti_phase > 0) { printf("\nerror: ocp_nlp_sqp_opts_set: invalid value for rti_phase field."); printf("possible values are: 0\n"); exit(1); } else opts->rti_phase = rti_phase; } else if (!strcmp(field, "print_level")) { int* print_level = (int ) value; if (print_level < 0) { printf("\nerror: ocp_nlp_sqp_opts_set: invalid value for print_level field, need int >=0, got %d.", print_level); exit(1); } opts->print_level = print_level; } else if (!strcmp(field, "initialize_t_slacks")) { int* initialize_t_slacks = (int ) value; if (initialize_t_slacks != 0 && initialize_t_slacks != 1) { printf("\nerror: ocp_nlp_sqp_opts_set: invalid value for initialize_t_slacks field, need int 0 or 1, got %d.", initialize_t_slacks); exit(1); } opts->initialize_t_slacks = initialize_t_slacks; } else { ocp_nlp_opts_set(config, nlp_opts, field, value); } } return; } void ocp_nlp_sqp_opts_set_at_stage(void config_, void opts_, int stage, const char field, void* value) { ocp_nlp_config config = config_; ocp_nlp_sqp_opts opts = (ocp_nlp_sqp_opts ) opts_; ocp_nlp_opts nlp_opts = opts->nlp_opts; ocp_nlp_opts_set_at_stage(config, nlp_opts, stage, field, value); return; } /************************************************ * memory ***********************************************/ int ocp_nlp_sqp_memory_calculate_size(void config_, void dims_, void opts_) { ocp_nlp_dims dims = dims_; ocp_nlp_config config = config_; ocp_nlp_sqp_opts opts = opts_; ocp_nlp_opts nlp_opts = opts->nlp_opts; // int N = dims->N; // int nx = dims->nx; // int nu = dims->nu; // int nz = dims->nz; int size = 0; size += sizeof(ocp_nlp_sqp_memory); // nlp mem size += ocp_nlp_memory_calculate_size(config, dims, nlp_opts); // stat int stat_m = opts->max_iter+1; int stat_n = 6; if (opts->ext_qp_res) stat_n += 4; size += stat_nstat_msizeof(double); size += 38; // align make_int_multiple_of(8, &size); return size; } void ocp_nlp_sqp_memory_assign(void config_, void dims_, void opts_, void raw_memory) { ocp_nlp_dims dims = dims_; ocp_nlp_config config = config_; ocp_nlp_sqp_opts opts = opts_; ocp_nlp_opts nlp_opts = opts->nlp_opts; // ocp_qp_xcond_solver_config qp_solver = config->qp_solver; // ocp_nlp_dynamics_config dynamics = config->dynamics; // ocp_nlp_cost_config cost = config->cost; // ocp_nlp_constraints_config *constraints = config->constraints; char c_ptr = (char ) raw_memory; // int N = dims->N; // int nx = dims->nx; // int nu = dims->nu; // int nz = dims->nz; // initial align align_char_to(8, &c_ptr); ocp_nlp_sqp_memory mem = (ocp_nlp_sqp_memory ) c_ptr; c_ptr += sizeof(ocp_nlp_sqp_memory); align_char_to(8, &c_ptr); // nlp mem mem->nlp_mem = ocp_nlp_memory_assign(config, dims, nlp_opts, c_ptr); c_ptr += ocp_nlp_memory_calculate_size(config, dims, nlp_opts); // stat mem->stat = (double ) c_ptr; mem->stat_m = opts->max_iter+1; mem->stat_n = 6; if (opts->ext_qp_res) mem->stat_n += 4; c_ptr += mem->stat_mmem->stat_nsizeof(double); mem->status = ACADOS_READY; align_char_to(8, &c_ptr); assert((char ) raw_memory + ocp_nlp_sqp_memory_calculate_size(config, dims, opts) >= c_ptr); return mem; } /************************************************ * workspace ***********************************************/ int ocp_nlp_sqp_workspace_calculate_size(void config_, void dims_, void opts_) { ocp_nlp_dims dims = dims_; ocp_nlp_config config = config_; ocp_nlp_sqp_opts opts = opts_; ocp_nlp_opts nlp_opts = opts->nlp_opts; int size = 0; // sqp size += sizeof(ocp_nlp_sqp_workspace); // nlp size += ocp_nlp_workspace_calculate_size(config, dims, nlp_opts); // tmp qp in size += ocp_qp_in_calculate_size(dims->qp_solver->orig_dims); // tmp qp out size += ocp_qp_out_calculate_size(dims->qp_solver->orig_dims); if (opts->ext_qp_res) { // qp res size += ocp_qp_res_calculate_size(dims->qp_solver->orig_dims); // qp res ws size += ocp_qp_res_workspace_calculate_size(dims->qp_solver->orig_dims); } return size; } static void ocp_nlp_sqp_cast_workspace(ocp_nlp_config config, ocp_nlp_dims dims, ocp_nlp_sqp_opts opts, ocp_nlp_sqp_memory mem, ocp_nlp_sqp_workspace work) { ocp_nlp_opts nlp_opts = opts->nlp_opts; ocp_nlp_memory nlp_mem = mem->nlp_mem; // sqp char c_ptr = (char ) work; c_ptr += sizeof(ocp_nlp_sqp_workspace); // nlp work->nlp_work = ocp_nlp_workspace_assign(config, dims, nlp_opts, nlp_mem, c_ptr); c_ptr += ocp_nlp_workspace_calculate_size(config, dims, nlp_opts); // tmp qp in work->tmp_qp_in = ocp_qp_in_assign(dims->qp_solver->orig_dims, c_ptr); c_ptr += ocp_qp_in_calculate_size(dims->qp_solver->orig_dims); // tmp qp out work->tmp_qp_out = ocp_qp_out_assign(dims->qp_solver->orig_dims, c_ptr); c_ptr += ocp_qp_out_calculate_size(dims->qp_solver->orig_dims); if (opts->ext_qp_res) { // qp res work->qp_res = ocp_qp_res_assign(dims->qp_solver->orig_dims, c_ptr); c_ptr += ocp_qp_res_calculate_size(dims->qp_solver->orig_dims); // qp res ws work->qp_res_ws = ocp_qp_res_workspace_assign(dims->qp_solver->orig_dims, c_ptr); c_ptr += ocp_qp_res_workspace_calculate_size(dims->qp_solver->orig_dims); } assert((char ) work + ocp_nlp_sqp_workspace_calculate_size(config, dims, opts) >= c_ptr); return; } /************************************************ * functions ***********************************************/ int ocp_nlp_sqp(void config_, void dims_, void nlp_in_, void nlp_out_, void opts_, void mem_, void work_) { acados_timer timer0, timer1; acados_tic(&timer0); ocp_nlp_dims dims = dims_; ocp_nlp_config config = config_; ocp_nlp_sqp_opts opts = opts_; ocp_nlp_opts nlp_opts = opts->nlp_opts; ocp_nlp_sqp_memory mem = mem_; ocp_nlp_in nlp_in = nlp_in_; ocp_nlp_out nlp_out = nlp_out_; ocp_nlp_memory nlp_mem = mem->nlp_mem; ocp_qp_xcond_solver_config qp_solver = config->qp_solver; ocp_nlp_sqp_workspace work = work_; ocp_nlp_sqp_cast_workspace(config, dims, opts, mem, work); ocp_nlp_workspace nlp_work = work->nlp_work; // zero timers double total_time = 0.0; double tmp_time; mem->time_qp_sol = 0.0; mem->time_qp_solver_call = 0.0; mem->time_qp_xcond = 0.0; mem->time_lin = 0.0; mem->time_reg = 0.0; mem->time_tot = 0.0; int N = dims->N; int ii; int qp_iter = 0; int qp_status = 0; #if defined(ACADOS_WITH_OPENMP) // backup number of threads int num_threads_bkp = omp_get_num_threads(); // set number of threads omp_set_num_threads(opts->nlp_opts->num_threads); #pragma omp parallel { // beginning of parallel region #endif // alias to dynamics_memory #if defined(ACADOS_WITH_OPENMP) #pragma omp for #endif for (ii = 0; ii < N; ii++) { config->dynamics[ii]->memory_set_ux_ptr(nlp_out->ux+ii, nlp_mem->dynamics[ii]); config->dynamics[ii]->memory_set_tmp_ux_ptr(nlp_work->tmp_nlp_out->ux+ii, nlp_mem->dynamics[ii]); config->dynamics[ii]->memory_set_ux1_ptr(nlp_out->ux+ii+1, nlp_mem->dynamics[ii]); config->dynamics[ii]->memory_set_tmp_ux1_ptr(nlp_work->tmp_nlp_out->ux+ii+1, nlp_mem->dynamics[ii]); config->dynamics[ii]->memory_set_pi_ptr(nlp_out->pi+ii, nlp_mem->dynamics[ii]); config->dynamics[ii]->memory_set_tmp_pi_ptr(nlp_work->tmp_nlp_out->pi+ii, nlp_mem->dynamics[ii]); config->dynamics[ii]->memory_set_BAbt_ptr(nlp_mem->qp_in->BAbt+ii, nlp_mem->dynamics[ii]); config->dynamics[ii]->memory_set_RSQrq_ptr(nlp_mem->qp_in->RSQrq+ii, nlp_mem->dynamics[ii]); config->dynamics[ii]->memory_set_dzduxt_ptr(nlp_mem->dzduxt+ii, nlp_mem->dynamics[ii]); config->dynamics[ii]->memory_set_sim_guess_ptr(nlp_mem->sim_guess+ii, nlp_mem->set_sim_guess+ii, nlp_mem->dynamics[ii]); config->dynamics[ii]->memory_set_z_alg_ptr(nlp_mem->z_alg+ii, nlp_mem->dynamics[ii]); } // alias to cost_memory #if defined(ACADOS_WITH_OPENMP) #pragma omp for #endif for (ii = 0; ii <= N; ii++) { config->cost[ii]->memory_set_ux_ptr(nlp_out->ux+ii, nlp_mem->cost[ii]); config->cost[ii]->memory_set_tmp_ux_ptr(nlp_work->tmp_nlp_out->ux+ii, nlp_mem->cost[ii]); config->cost[ii]->memory_set_z_alg_ptr(nlp_mem->z_alg+ii, nlp_mem->cost[ii]); config->cost[ii]->memory_set_dzdux_tran_ptr(nlp_mem->dzduxt+ii, nlp_mem->cost[ii]); config->cost[ii]->memory_set_RSQrq_ptr(nlp_mem->qp_in->RSQrq+ii, nlp_mem->cost[ii]); config->cost[ii]->memory_set_Z_ptr(nlp_mem->qp_in->Z+ii, nlp_mem->cost[ii]); } // alias to constraints_memory #if defined(ACADOS_WITH_OPENMP) #pragma omp for #endif for (ii = 0; ii <= N; ii++) { config->constraints[ii]->memory_set_ux_ptr(nlp_out->ux+ii, nlp_mem->constraints[ii]); config->constraints[ii]->memory_set_tmp_ux_ptr(nlp_work->tmp_nlp_out->ux+ii, nlp_mem->constraints[ii]); config->constraints[ii]->memory_set_lam_ptr(nlp_out->lam+ii, nlp_mem->constraints[ii]); config->constraints[ii]->memory_set_tmp_lam_ptr(nlp_work->tmp_nlp_out->lam+ii, nlp_mem->constraints[ii]); config->constraints[ii]->memory_set_z_alg_ptr(nlp_mem->z_alg+ii, nlp_mem->constraints[ii]); config->constraints[ii]->memory_set_dzdux_tran_ptr(nlp_mem->dzduxt+ii, nlp_mem->constraints[ii]); config->constraints[ii]->memory_set_DCt_ptr(nlp_mem->qp_in->DCt+ii, nlp_mem->constraints[ii]); config->constraints[ii]->memory_set_RSQrq_ptr(nlp_mem->qp_in->RSQrq+ii, nlp_mem->constraints[ii]); config->constraints[ii]->memory_set_idxb_ptr(nlp_mem->qp_in->idxb[ii], nlp_mem->constraints[ii]); config->constraints[ii]->memory_set_idxs_rev_ptr(nlp_mem->qp_in->idxs_rev[ii], nlp_mem->constraints[ii]); config->constraints[ii]->memory_set_idxe_ptr(nlp_mem->qp_in->idxe[ii], nlp_mem->constraints[ii]); } // alias to regularize memory config->regularize->memory_set_RSQrq_ptr(dims->regularize, nlp_mem->qp_in->RSQrq, nlp_mem->regularize_mem); config->regularize->memory_set_rq_ptr(dims->regularize, nlp_mem->qp_in->rqz, nlp_mem->regularize_mem); config->regularize->memory_set_BAbt_ptr(dims->regularize, nlp_mem->qp_in->BAbt, nlp_mem->regularize_mem); config->regularize->memory_set_b_ptr(dims->regularize, nlp_mem->qp_in->b, nlp_mem->regularize_mem); config->regularize->memory_set_idxb_ptr(dims->regularize, nlp_mem->qp_in->idxb, nlp_mem->regularize_mem); config->regularize->memory_set_DCt_ptr(dims->regularize, nlp_mem->qp_in->DCt, nlp_mem->regularize_mem); config->regularize->memory_set_ux_ptr(dims->regularize, nlp_mem->qp_out->ux, nlp_mem->regularize_mem); config->regularize->memory_set_pi_ptr(dims->regularize, nlp_mem->qp_out->pi, nlp_mem->regularize_mem); config->regularize->memory_set_lam_ptr(dims->regularize, nlp_mem->qp_out->lam, nlp_mem->regularize_mem); // copy sampling times into dynamics model #if defined(ACADOS_WITH_OPENMP) #pragma omp for #endif // NOTE(oj): this will lead in an error for irk_gnsf, T must be set in precompute; // -> remove here and make sure precompute is called everywhere. for (ii = 0; ii < N; ii++) { config->dynamics[ii]->model_set(config->dynamics[ii], dims->dynamics[ii], nlp_in->dynamics[ii], "T", nlp_in->Ts+ii); } #if defined(ACADOS_WITH_OPENMP) } // end of parallel region #endif // if (opts->initialize_t_slacks > 0) ocp_nlp_initialize_t_slacks(config, dims, nlp_in, nlp_out, nlp_opts, nlp_mem, nlp_work); // initialize QP ocp_nlp_initialize_qp(config, dims, nlp_in, nlp_out, nlp_opts, nlp_mem, nlp_work); // main sqp loop int sqp_iter = 0; nlp_mem->sqp_iter = &sqp_iter; for (; sqp_iter < opts->max_iter; sqp_iter++) { // linearizate NLP and update QP matrices acados_tic(&timer1); ocp_nlp_approximate_qp_matrices(config, dims, nlp_in, nlp_out, nlp_opts, nlp_mem, nlp_work); mem->time_lin += acados_toc(&timer1); // update QP rhs for SQP (step prim var, abs dual var) ocp_nlp_approximate_qp_vectors_sqp(config, dims, nlp_in, nlp_out, nlp_opts, nlp_mem, nlp_work); // compute nlp residuals ocp_nlp_res_compute(dims, nlp_in, nlp_out, nlp_mem->nlp_res, nlp_mem); nlp_out->inf_norm_res = nlp_mem->nlp_res->inf_norm_res_stat; nlp_out->inf_norm_res = (nlp_mem->nlp_res->inf_norm_res_eq > nlp_out->inf_norm_res) ? nlp_mem->nlp_res->inf_norm_res_eq : nlp_out->inf_norm_res; nlp_out->inf_norm_res = (nlp_mem->nlp_res->inf_norm_res_ineq > nlp_out->inf_norm_res) ? nlp_mem->nlp_res->inf_norm_res_ineq : nlp_out->inf_norm_res; nlp_out->inf_norm_res = (nlp_mem->nlp_res->inf_norm_res_comp > nlp_out->inf_norm_res) ? nlp_mem->nlp_res->inf_norm_res_comp : nlp_out->inf_norm_res; if (opts->print_level > sqp_iter + 1) print_ocp_qp_in(nlp_mem->qp_in); // save statistics if (sqp_iter < mem->stat_m) { mem->stat[mem->stat_nsqp_iter+0] = nlp_mem->nlp_res->inf_norm_res_stat; mem->stat[mem->stat_nsqp_iter+1] = nlp_mem->nlp_res->inf_norm_res_eq; mem->stat[mem->stat_nsqp_iter+2] = nlp_mem->nlp_res->inf_norm_res_ineq; mem->stat[mem->stat_nsqp_iter+3] = nlp_mem->nlp_res->inf_norm_res_comp; } // exit conditions on residuals if ((nlp_mem->nlp_res->inf_norm_res_stat < opts->tol_stat) & (nlp_mem->nlp_res->inf_norm_res_eq < opts->tol_eq) & (nlp_mem->nlp_res->inf_norm_res_ineq < opts->tol_ineq) & (nlp_mem->nlp_res->inf_norm_res_comp < opts->tol_comp)) { // save sqp iterations number mem->sqp_iter = sqp_iter; nlp_out->sqp_iter = sqp_iter; // stop timer total_time += acados_toc(&timer0); // save time nlp_out->total_time = total_time; mem->time_tot = total_time; #if defined(ACADOS_WITH_OPENMP) // restore number of threads omp_set_num_threads(num_threads_bkp); #endif mem->status = ACADOS_SUCCESS; if (opts->print_level > 0) { printf("%i\t%e\t%e\t%e\t%e.\n", sqp_iter, nlp_mem->nlp_res->inf_norm_res_stat, nlp_mem->nlp_res->inf_norm_res_eq, nlp_mem->nlp_res->inf_norm_res_ineq, nlp_mem->nlp_res->inf_norm_res_comp ); printf("\n\n"); } return mem->status; } // regularize Hessian acados_tic(&timer1); config->regularize->regularize_hessian(config->regularize, dims->regularize, opts->nlp_opts->regularize, nlp_mem->regularize_mem); mem->time_reg += acados_toc(&timer1); // (typically) no warm start at first iteration if (sqp_iter == 0 && !opts->warm_start_first_qp) { int tmp_int = 0; config->qp_solver->opts_set(config->qp_solver, opts->nlp_opts->qp_solver_opts, "warm_start", &tmp_int); } // solve qp acados_tic(&timer1); qp_status = qp_solver->evaluate(qp_solver, dims->qp_solver, nlp_mem->qp_in, nlp_mem->qp_out, opts->nlp_opts->qp_solver_opts, nlp_mem->qp_solver_mem, nlp_work->qp_work); mem->time_qp_sol += acados_toc(&timer1); qp_solver->memory_get(qp_solver, nlp_mem->qp_solver_mem, "time_qp_solver_call", &tmp_time); mem->time_qp_solver_call += tmp_time; qp_solver->memory_get(qp_solver, nlp_mem->qp_solver_mem, "time_qp_xcond", &tmp_time); mem->time_qp_xcond += tmp_time; // compute correct dual solution in case of Hessian regularization acados_tic(&timer1); config->regularize->correct_dual_sol(config->regularize, dims->regularize, opts->nlp_opts->regularize, nlp_mem->regularize_mem); mem->time_reg += acados_toc(&timer1); // restore default warm start if (sqp_iter==0) { config->qp_solver->opts_set(config->qp_solver, opts->nlp_opts->qp_solver_opts, "warm_start", &opts->qp_warm_start); } // TODO move into QP solver memory ??? qp_info qp_info_; ocp_qp_out_get(nlp_mem->qp_out, "qp_info", &qp_info_); nlp_out->qp_iter = qp_info_->num_iter; // printf("\nqp_iter = %d, sqp_iter = %d, max_sqp_iter = %d\n", nlp_out->qp_iter, sqp_iter, opts->max_iter); qp_iter = qp_info_->num_iter; // save statistics of last qp solver call if (sqp_iter+1 < mem->stat_m) { mem->stat[mem->stat_n(sqp_iter+1)+4] = qp_status; mem->stat[mem->stat_n(sqp_iter+1)+5] = qp_iter; } // compute external QP residuals (for debugging) if (opts->ext_qp_res) { ocp_qp_res_compute(nlp_mem->qp_in, nlp_mem->qp_out, work->qp_res, work->qp_res_ws); if (sqp_iter+1 < mem->stat_m) ocp_qp_res_compute_nrm_inf(work->qp_res, mem->stat+(mem->stat_n(sqp_iter+1)+6)); } if ((qp_status!=ACADOS_SUCCESS) & (qp_status!=ACADOS_MAXITER)) { // print_ocp_qp_in(nlp_mem->qp_in); if (opts->print_level > 0) { printf("%i\t%e\t%e\t%e\t%e.\n", sqp_iter, nlp_mem->nlp_res->inf_norm_res_stat, nlp_mem->nlp_res->inf_norm_res_eq, nlp_mem->nlp_res->inf_norm_res_ineq, nlp_mem->nlp_res->inf_norm_res_comp ); printf("\n\n"); } // save sqp iterations number mem->sqp_iter = sqp_iter; nlp_out->sqp_iter = sqp_iter; // stop timer total_time += acados_toc(&timer0); // save time mem->time_tot = total_time; nlp_out->total_time = total_time; #ifndef ACADOS_SILENT printf("QP solver returned error status %d in iteration %d\n", qp_status, sqp_iter); #endif #if defined(ACADOS_WITH_OPENMP) // restore number of threads omp_set_num_threads(num_threads_bkp); #endif if (opts->print_level > 1) { printf("\n Failed to solve the following QP:\n"); if (opts->print_level > sqp_iter + 1) print_ocp_qp_in(nlp_mem->qp_in); } mem->status = ACADOS_QP_FAILURE; return mem->status; } ocp_nlp_update_variables_sqp(config, dims, nlp_in, nlp_out, nlp_opts, nlp_mem, nlp_work); // ocp_nlp_dims_print(nlp_out->dims); // ocp_nlp_out_print(nlp_out); // exit(1); // ??? @rien // for (int_t i = 0; i < N; i++) // { // ocp_nlp_dynamics_opts dynamics_opts = opts->dynamics[i]; // sim_opts opts = dynamics_opts->sim_solver; // if (opts->scheme == NULL) // continue; // opts->sens_adj = (opts->scheme->type != exact); // if (nlp_in->freezeSens) { // // freeze inexact sensitivities after first SQP iteration !! // opts->scheme->freeze = true; // } // } if (opts->print_level > 0) { if (sqp_iter%10 == 0) { printf("# it\tstat\t\teq\t\tineq\t\tcomp\n"); } printf("%i\t%e\t%e\t%e\t%e.\n", sqp_iter, nlp_mem->nlp_res->inf_norm_res_stat, nlp_mem->nlp_res->inf_norm_res_eq, nlp_mem->nlp_res->inf_norm_res_ineq, nlp_mem->nlp_res->inf_norm_res_comp ); } } // stop timer total_time += acados_toc(&timer0); if (opts->print_level > 0) printf("\n\n"); // ocp_nlp_out_print(nlp_out); // save sqp iterations number mem->sqp_iter = sqp_iter; nlp_out->sqp_iter = sqp_iter; // save time mem->time_tot = total_time; nlp_out->total_time = total_time; // maximum number of iterations reached #if defined(ACADOS_WITH_OPENMP) // restore number of threads omp_set_num_threads(num_threads_bkp); #endif mem->status = ACADOS_MAXITER; #ifndef ACADOS_SILENT printf("\n ocp_nlp_sqp: maximum iterations reached\n"); #endif return mem->status; } int ocp_nlp_sqp_precompute(void config_, void dims_, void nlp_in_, void nlp_out_, void opts_, void mem_, void work_) { ocp_nlp_dims dims = dims_; ocp_nlp_config config = config_; ocp_nlp_sqp_opts opts = opts_; ocp_nlp_sqp_memory mem = mem_; ocp_nlp_in nlp_in = nlp_in_; // ocp_nlp_out nlp_out = nlp_out_; ocp_nlp_memory nlp_mem = mem->nlp_mem; ocp_nlp_sqp_workspace work = work_; ocp_nlp_sqp_cast_workspace(config, dims, opts, mem, work); ocp_nlp_workspace nlp_work = work->nlp_work; int N = dims->N; int status = ACADOS_SUCCESS; int ii; // TODO(all) add flag to enable/disable checks for (ii = 0; ii <= N; ii++) { int module_val; config->constraints[ii]->dims_get(config->constraints[ii], dims->constraints[ii], "ns", &module_val); if (dims->ns[ii] != module_val) { printf("ocp_nlp_sqp_precompute: inconsistent dimension ns for stage %d with constraint module, got %d, module: %d.", ii, dims->ns[ii], module_val); exit(1); } } // precompute for (ii = 0; ii < N; ii++) { // set T config->dynamics[ii]->model_set(config->dynamics[ii], dims->dynamics[ii], nlp_in->dynamics[ii], "T", nlp_in->Ts+ii); // dynamics precompute status = config->dynamics[ii]->precompute(config->dynamics[ii], dims->dynamics[ii], nlp_in->dynamics[ii], opts->nlp_opts->dynamics[ii], nlp_mem->dynamics[ii], nlp_work->dynamics[ii]); if (status != ACADOS_SUCCESS) return status; } return status; } void ocp_nlp_sqp_eval_param_sens(void config_, void dims_, void opts_, void mem_, void work_, char field, int stage, int index, void sens_nlp_out_) { ocp_nlp_dims dims = dims_; ocp_nlp_config config = config_; ocp_nlp_sqp_opts opts = opts_; ocp_nlp_sqp_memory mem = mem_; ocp_nlp_memory nlp_mem = mem->nlp_mem; ocp_nlp_out sens_nlp_out = sens_nlp_out_; ocp_nlp_sqp_workspace work = work_; ocp_nlp_sqp_cast_workspace(config, dims, opts, mem, work); ocp_nlp_workspace nlp_work = work->nlp_work; d_ocp_qp_copy_all(nlp_mem->qp_in, work->tmp_qp_in); d_ocp_qp_set_rhs_zero(work->tmp_qp_in); double one = 1.0; if ((!strcmp("ex", field)) & (stage==0)) { d_ocp_qp_set_el("lbx", stage, index, &one, work->tmp_qp_in); d_ocp_qp_set_el("ubx", stage, index, &one, work->tmp_qp_in); // d_ocp_qp_print(work->tmp_qp_in->dim, work->tmp_qp_in); config->qp_solver->eval_sens(config->qp_solver, dims->qp_solver, work->tmp_qp_in, work->tmp_qp_out, opts->nlp_opts->qp_solver_opts, nlp_mem->qp_solver_mem, nlp_work->qp_work); // d_ocp_qp_sol_print(work->tmp_qp_out->dim, work->tmp_qp_out); // exit(1); /* copy tmp_qp_out into sens_nlp_out / int i; int N = dims->N; int nv = dims->nv; int nx = dims->nx; // int nu = dims->nu; int ni = dims->ni; // int nz = dims->nz; for (i = 0; i <= N; i++) { blasfeo_dveccp(nv[i], work->tmp_qp_out->ux + i, 0, sens_nlp_out->ux + i, 0); if (i < N) blasfeo_dveccp(nx[i + 1], work->tmp_qp_out->pi + i, 0, sens_nlp_out->pi + i, 0); blasfeo_dveccp(2 * ni[i], work->tmp_qp_out->lam + i, 0, sens_nlp_out->lam + i, 0); blasfeo_dveccp(2 * ni[i], work->tmp_qp_out->t + i, 0, sens_nlp_out->t + i, 0); } } else { printf("\nerror: field %s at stage %d not available in ocp_nlp_sqp_eval_param_sens\n", field, stage); exit(1); } return; } // TODO rename memory_get ??? void ocp_nlp_sqp_get(void config_, void dims_, void mem_, const char field, void return_value_) { ocp_nlp_config config = config_; ocp_nlp_dims dims = dims_; ocp_nlp_sqp_memory mem = mem_; if (!strcmp("sqp_iter", field)) { int value = return_value_; value = mem->sqp_iter; } else if (!strcmp("status", field)) { int value = return_value_; value = mem->status; } else if (!strcmp("time_tot", field) \|\| !strcmp("tot_time", field)) { double value = return_value_; value = mem->time_tot; } else if (!strcmp("time_qp_sol", field) \|\| !strcmp("time_qp", field)) { double value = return_value_; value = mem->time_qp_sol; } else if (!strcmp("time_qp_solver", field) \|\| !strcmp("time_qp_solver_call", field)) { double value = return_value_; value = mem->time_qp_solver_call; } else if (!strcmp("time_qp_xcond", field)) { double value = return_value_; value = mem->time_qp_xcond; } else if (!strcmp("time_lin", field)) { double value = return_value_; value = mem->time_lin; } else if (!strcmp("time_reg", field)) { double value = return_value_; value = mem->time_reg; } else if (!strcmp("time_sim", field) \|\| !strcmp("time_sim_ad", field) \|\| !strcmp("time_sim_la", field)) { double tmp = 0.0; double ptr = return_value_; int N = dims->N; int ii; for (ii=0; ii<N; ii++) { config->dynamics[ii]->memory_get(config->dynamics[ii], dims->dynamics[ii], mem->nlp_mem->dynamics[ii], field, &tmp); ptr += tmp; } } else if (!strcmp("stat", field)) { double *value = return_value_; value = mem->stat; } else if (!strcmp("statistics", field)) { int n_row = mem->stat_m<mem->sqp_iter+1 ? mem->stat_m : mem->sqp_iter+1; double value = return_value_; for (int ii=0; ii<n_row; ii++) { value[ii+0] = ii; for (int jj=0; jj<mem->stat_n; jj++) value[ii+(jj+1)n_row] = mem->stat[jj+iimem->stat_n]; } } else if (!strcmp("stat_m", field)) { int value = return_value_; value = mem->stat_m; } else if (!strcmp("stat_n", field)) { int value = return_value_; value = mem->stat_n; } else if (!strcmp("nlp_mem", field)) { void value = return_value_; value = mem->nlp_mem; } else if (!strcmp("qp_xcond_dims", field)) { void *value = return_value_; value = dims->qp_solver->xcond_dims; } else if (!strcmp("nlp_res", field)) { ocp_nlp_res *value = return_value_; value = mem->nlp_mem->nlp_res; } else if (!strcmp("qp_xcond_in", field)) { void *value = return_value_; value = mem->nlp_mem->qp_solver_mem->xcond_qp_in; } else if (!strcmp("qp_xcond_out", field)) { void *value = return_value_; value = mem->nlp_mem->qp_solver_mem->xcond_qp_out; } else if (!strcmp("qp_in", field)) { void *value = return_value_; value = mem->nlp_mem->qp_in; } else if (!strcmp("qp_out", field)) { void *value = return_value_; value = mem->nlp_mem->qp_out; } else if (!strcmp("qp_iter", field)) { config->qp_solver->memory_get(config->qp_solver, mem->nlp_mem->qp_solver_mem, "iter", return_value_); } else if (!strcmp("res_stat", field)) { double value = return_value_; value = mem->nlp_mem->nlp_res->inf_norm_res_stat; } else if (!strcmp("res_eq", field)) { double value = return_value_; value = mem->nlp_mem->nlp_res->inf_norm_res_eq; } else if (!strcmp("res_ineq", field)) { double value = return_value_; value = mem->nlp_mem->nlp_res->inf_norm_res_ineq; } else if (!strcmp("res_comp", field)) { double value = return_value_; value = mem->nlp_mem->nlp_res->inf_norm_res_comp; } else if (!strcmp("cost_value", field)) { double value = return_value_; value = mem->nlp_mem->cost_value; } else { printf("\nerror: field %s not available in ocp_nlp_sqp_get\n", field); exit(1); } } void ocp_nlp_sqp_opts_get(void config_, void dims_, void opts_, const char field, void return_value_) { // ocp_nlp_config config = config_; ocp_nlp_sqp_opts opts = opts_; if (!strcmp("nlp_opts", field)) { void value = return_value_; value = opts->nlp_opts; } else { printf("\nerror: field %s not available in ocp_nlp_sqp_opts_get\n", field); exit(1); } } void ocp_nlp_sqp_work_get(void config_, void dims_, void work_, const char field, void return_value_) { // ocp_nlp_config config = config_; ocp_nlp_sqp_workspace work = work_; if (!strcmp("nlp_work", field)) { void value = return_value_; value = work->nlp_work; } else { printf("\nerror: field %s not available in ocp_nlp_sqp_work_get\n", field); exit(1); } } void ocp_nlp_sqp_config_initialize_default(void config_) { ocp_nlp_config config = (ocp_nlp_config *) config_; config->opts_calculate_size = &ocp_nlp_sqp_opts_calculate_size; config->opts_assign = &ocp_nlp_sqp_opts_assign; config->opts_initialize_default = &ocp_nlp_sqp_opts_initialize_default; config->opts_update = &ocp_nlp_sqp_opts_update; config->opts_set = &ocp_nlp_sqp_opts_set; config->opts_set_at_stage = &ocp_nlp_sqp_opts_set_at_stage; config->memory_calculate_size = &ocp_nlp_sqp_memory_calculate_size; config->memory_assign = &ocp_nlp_sqp_memory_assign; config->workspace_calculate_size = &ocp_nlp_sqp_workspace_calculate_size; config->evaluate = &ocp_nlp_sqp; config->eval_param_sens = &ocp_nlp_sqp_eval_param_sens; config->config_initialize_default = &ocp_nlp_sqp_config_initialize_default; config->precompute = &ocp_nlp_sqp_precompute; config->get = &ocp_nlp_sqp_get; config->opts_get = &ocp_nlp_sqp_opts_get; config->work_get = &ocp_nlp_sqp_work_get; return; }
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 1999-2021 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/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; Quantum q; 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++) { const Quantum magick_restrict p; 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; 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++) { Quantum magick_restrict q; 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++) { ssize_t x; if (status == MagickFalse) continue; for (x=0; x < (ssize_t) edge_image->columns; x++) { CannyInfo pixel; 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; 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++) { const Quantum magick_restrict p; 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++) { const Quantum magick_restrict p; 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; 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++) { 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++) { ssize_t y; for (y=0; y < (ssize_t) number_grays; y++) { 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++) { 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++) { ssize_t y; for (y=0; y < (ssize_t) number_grays; y++) { 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++) { 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++) { ssize_t y; ChannelStatistics pixel; (void) memset(&pixel,0,sizeof(pixel)); for (y=0; y < (ssize_t) number_grays; y++) { 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; 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++) { const Quantum magick_restrict p; 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)) { 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++) { 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++) { const Quantum magick_restrict p; Quantum magick_restrict q; 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; 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); }
kmeans_clustering.c	#include "hclib.h" #ifdef __cplusplus #include "hclib_cpp.h" #include "hclib_system.h" #ifdef __CUDACC__ #include "hclib_cuda.h" #endif #endif /****************************************************************************/ /IMPORTANT: READ BEFORE DOWNLOADING, COPYING, INSTALLING OR USING. / /By downloading, copying, installing or using the software you agree / /to this license. If you do not agree to this license, do not download, / /install, copy or use the software. / / / / / /Copyright (c) 2005 Northwestern University / /All rights reserved. / /Redistribution of the software in source and binary forms, / /with or without modification, is permitted provided that the / /following conditions are met: / / / /1 Redistributions of source code must retain the above copyright / / notice, this list of conditions and the following disclaimer. / / / /2 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./ / / /3 Neither the name of Northwestern University 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, NON-INFRINGEMENT AND / /FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL / /NORTHWESTERN UNIVERSITY OR ITS 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. / /***************************************************************************/ /*********************************************************************/ / File: kmeans_clustering.c / / Description: Implementation of regular k-means clustering / / algorithm / / Author: Wei-keng Liao / / ECE Department, Northwestern University / / email: wkliao@ece.northwestern.edu / / / / Edited by: Jay Pisharath / / Northwestern University. / / / / ================================================================ / / / / Edited by: Sang-Ha Lee / / University of Virginia / / / / Description: No longer supports fuzzy c-means clustering; / / only regular k-means clustering. / / Simplified for main functionality: regular k-means / / clustering. / / / /**********************************************************************/ #include <stdio.h> #include <stdlib.h> #include <float.h> #include <math.h> #include "kmeans.h" #include <omp.h> #define RANDOM_MAX 2147483647 #ifndef FLT_MAX #define FLT_MAX 3.40282347e+38 #endif extern double wtime(void); extern int num_omp_threads; int find_nearest_point(float pt, /* [nfeatures] / int nfeatures, float pts, /* [npts][nfeatures] / int npts) { int index, i; float min_dist=FLT_MAX; / find the cluster center id with min distance to pt / for (i=0; i<npts; i++) { float dist; dist = euclid_dist_2(pt, pts + (i nfeatures), nfeatures); /* no need square root / if (dist < min_dist) { min_dist = dist; index = i; } } return(index); } /----< euclid_dist_2() >----------------------------------------------------/ / multi-dimensional spatial Euclid distance square / __inline float euclid_dist_2(float pt1, float pt2, int numdims) { int i; float ans=0.0; for (i=0; i<numdims; i++) ans += (pt1[i]-pt2[i]) (pt1[i]-pt2[i]); return(ans); } /----< kmeans_clustering() >---------------------------------------------/ typedef struct _pragma173_omp_parallel { int i; int j; int (k_ptr); int (n_ptr); int index; int (loop_ptr); int ((new_centers_len_ptr)); float (((new_centers_ptr))); float ((clusters_ptr)); float delta; double (timing_ptr); int (nthreads_ptr); int ((partial_new_centers_len_ptr)); float ((partial_new_centers_ptr)); float ((feature_ptr)); int nfeatures; int npoints; int nclusters; float (threshold_ptr); int ((membership_ptr)); pthread_mutex_t reduction_mutex; } pragma173_omp_parallel; static void pragma173_omp_parallel_hclib_async(void ____arg, const int ___iter0); float* kmeans_clustering(float feature, / in: [npoints][nfeatures] / int nfeatures, int npoints, int nclusters, float threshold, int membership) /* out: [npoints] / { int i, j, k, n=0, index, loop=0; int new_centers_len; /* [nclusters]: no. of points in each cluster / float new_centers; / [nclusters][nfeatures] / float clusters; /* out: [nclusters][nfeatures] / float delta; double timing; int nthreads; int partial_new_centers_len; float partial_new_centers; nthreads = num_omp_threads; / allocate space for returning variable clusters[] / clusters = (float )malloc(nclusters * nfeatures * sizeof(float)); /* randomly pick cluster centers / for (i=0; i<nclusters; i++) { //n = (int)rand() % npoints; for (j=0; j<nfeatures; j++) clusters[i nfeatures + j] = feature[n * nfeatures + j]; n++; } for (i=0; i<npoints; i++) membership[i] = -1; /* need to initialize new_centers_len and new_centers[0] to all 0 / new_centers_len = (int) calloc(nclusters, sizeof(int)); new_centers = (float*) malloc(nclusters sizeof(float)); new_centers[0] = (float) calloc(nclusters * nfeatures, sizeof(float)); for (i=1; i<nclusters; i++) new_centers[i] = new_centers[i-1] + nfeatures; partial_new_centers_len = (int )calloc(nthreads nclusters, sizeof(int)); partial_new_centers = (float )calloc(nthreads nclusters * nfeatures, sizeof(float)); printf("num of threads = %d\n", num_omp_threads); do { delta = 0.0; { { pragma173_omp_parallel new_ctx = (pragma173_omp_parallel )malloc(sizeof(pragma173_omp_parallel)); new_ctx->i = i; new_ctx->j = j; new_ctx->k_ptr = &(k); new_ctx->n_ptr = &(n); new_ctx->index = index; new_ctx->loop_ptr = &(loop); new_ctx->new_centers_len_ptr = &(new_centers_len); new_ctx->new_centers_ptr = &(new_centers); new_ctx->clusters_ptr = &(clusters); new_ctx->delta = delta; new_ctx->timing_ptr = &(timing); new_ctx->nthreads_ptr = &(nthreads); new_ctx->partial_new_centers_len_ptr = &(partial_new_centers_len); new_ctx->partial_new_centers_ptr = &(partial_new_centers); new_ctx->feature_ptr = &(feature); new_ctx->nfeatures = nfeatures; new_ctx->npoints = npoints; new_ctx->nclusters = nclusters; new_ctx->threshold_ptr = &(threshold); new_ctx->membership_ptr = &(membership); new_ctx->delta = 0; const int init_err = pthread_mutex_init(&new_ctx->reduction_mutex, NULL); assert(init_err == 0); hclib_loop_domain_t domain[1]; domain[0].low = 0; domain[0].high = npoints; domain[0].stride = 1; domain[0].tile = -1; hclib_future_t fut = hclib_forasync_future((void )pragma173_omp_parallel_hclib_async, new_ctx, 1, domain, HCLIB_FORASYNC_MODE); hclib_future_wait(fut); free(new_ctx); delta = new_ctx->delta; } } /* end of #pragma omp parallel / / let the main thread perform the array reduction / for (i=0; i<nclusters; i++) { for (j=0; j<nthreads; j++) { new_centers_len[i] += partial_new_centers_len[j nclusters + i]; partial_new_centers_len[j * nclusters + i] = 0.0; for (k=0; k<nfeatures; k++) { new_centers[i][k] += partial_new_centers[j * nclusters * nfeatures + i * nfeatures + k]; partial_new_centers[j * nclusters * nfeatures + i * nfeatures + k] = 0.0; } } } /* replace old cluster centers with new_centers / for (i=0; i<nclusters; i++) { for (j=0; j<nfeatures; j++) { if (new_centers_len[i] > 0) clusters[i nfeatures + j] = new_centers[i][j] / new_centers_len[i]; new_centers[i][j] = 0.0; /* set back to 0 / } new_centers_len[i] = 0; / set back to 0 / } } while (delta > threshold && loop++ < 500); free(new_centers[0]); free(new_centers); free(new_centers_len); return clusters; } static void pragma173_omp_parallel_hclib_async(void ____arg, const int ___iter0) { pragma173_omp_parallel ctx = (pragma173_omp_parallel )____arg; int i; i = ctx->i; int j; j = ctx->j; int index; index = ctx->index; float delta; delta = ctx->delta; int nfeatures; nfeatures = ctx->nfeatures; int npoints; npoints = ctx->npoints; int nclusters; nclusters = ctx->nclusters; hclib_start_finish(); do { i = ___iter0; { /* find the index of nestest cluster centers / int tid = hclib_get_current_worker(); index = find_nearest_point(((ctx->feature_ptr)) + (i * nfeatures), nfeatures, ((ctx->clusters_ptr)), nclusters); / if membership changes, increase delta by 1 / if (((ctx->membership_ptr))[i] != index) delta += 1.0; /* assign the membership to object i / ((ctx->membership_ptr))[i] = index; /* update new cluster centers : sum of all objects located within / ((ctx->partial_new_centers_len_ptr))[tid * nclusters + index]++; for (j=0; j<nfeatures; j++) ((ctx->partial_new_centers_ptr))[tid nclusters * nfeatures + index * nfeatures + j] += ((ctx->feature_ptr))[i nfeatures + j]; } ; } while (0); const int lock_err = pthread_mutex_lock(&ctx->reduction_mutex); assert(lock_err == 0); ctx->delta += delta; const int unlock_err = pthread_mutex_unlock(&ctx->reduction_mutex); assert(unlock_err == 0); ; hclib_end_finish_nonblocking(); }
lslim_learn.c	/*************************************************************/ /! \File lslim_learn.c \brief This is the file containing the fundamental functions to learn the model, used by LSLIM. \author Evangelia Christakopoulou \version 1.0 \date 2016 / /***********************************************************/ #include<slim.h> /**************************************************************************/ /! \brief This function creates a new training matrix A'' and then calls the main function local_learn, for computing the model. Original training matrix A is of size n * m (rows * cols). An intermediate training matrix A' is created which has: nrows = rows of the original training matrix A ncols = (number_of_clusters) * cols of the original matrix A Every user has then exactly the nnzs of A which are copied to the cluster in which he belongs. For all the other clusters he has 0 entries. In order to be able to regularize properly, we add underneath A' a diagonal matrix which is of size: ncols * ncols. This diagonal matrix contains the regularization params across the diagonal (the local regularization ll). The final matrix is A''. Example: for 3 clusters: m m m n [ ] [ ] [ b ] n m [ ll ] * [ w ] = [ 0 ] m m [ ll ] [ ] [ 0 ] m m [ ll ] [ 0 ] m w is of size A'' 3m * 1. \param[in] ctrl The ctrl structure. \param[in] train The training data A. \param[in] participation The assignment of users to clusters. \param[in] prev_model The previous model (used to expedite the learning) \return model The model learnt. / /***************************************************************************/ gk_csr_t lslim_learn(ctrl_t * ctrl, gk_csr_t * train, int participation, gk_csr_t prev_model) { int i, pos, j, offset, global_nnz; gk_csr_t mat, model = NULL; global_nnz = train->rowptr[train->nrows] - train->rowptr[0]; mat = gk_csr_Create(); mat->ncols = (ctrl->num_clusters) * train->ncols; mat->nrows = train->nrows + mat->ncols; mat->rowptr = gk_zmalloc(mat->nrows + 1, "gk_csr_Dep: local_rowptr"); mat->rowind = gk_imalloc(global_nnz + mat->ncols, "gk_csr_Dep: local_rowind"); mat->rowval = gk_fmalloc(global_nnz + mat->ncols, "gk_csr_Dep: local_rowval"); mat->rowptr[0] = 0; for (i = 0, pos = 0; i < train->nrows; i++) { /* Copying the nnzs of the user to the cluster to which he belongs / offset = (participation[i]) train->ncols; for (j = train->rowptr[i]; j < train->rowptr[i + 1]; j++) { mat->rowind[pos] = train->rowind[j] + offset; mat->rowval[pos] = train->rowval[j]; pos++; } mat->rowptr[i + 1] = pos; } /* Adding the diagonal matrix underneath A' / / Local regularization / for (i = train->nrows; i < mat->nrows; i++, pos++) { mat->rowind[pos] = i - train->nrows; mat->rowval[pos] = ctrl->local_beta; mat->rowptr[i] = pos; } mat->rowptr[mat->nrows] = pos; gk_csr_CreateIndex(mat, GK_CSR_COL); gk_csr_CreateIndex(train, GK_CSR_COL); / Learning the model / model = lslim_local_learn(ctrl, train, mat, prev_model); gk_csr_Free(&mat); return model; } /************************************************************/ /! \brief Learning \details This routine contains the learning algorithm used by LSLIM. \param[in] ctrl A ctrl structure which contains all the parameters \param[in] orig_train The original training data (A) \param[in] train The training data (A'') \param[in] prev_model The previous model- used to speed up learning. It is optional argument. \return model The model returned. / /************************************************************/ gk_csr_t lslim_local_learn(ctrl_t * ctrl, gk_csr_t * orig_train, gk_csr_t * train, gk_csr_t * prev_model) { int i, nr, nc, ni, pos, j, ii; int global_nnz; int basestart, baseend, datasize, step, starti, endi; gk_csr_t mat = NULL; double bl, bu, c; int iinds, jinds; float vals; int nnzs = NULL; int rinds1 = NULL; int rinds = NULL; int rjinds = NULL; float rvals = NULL; int rank = 0; int max_nnzs = 0; double tmr; int rrowcnt = NULL; / set up timers / gk_clearwctimer(tmr); gk_startwctimer(tmr); / constants used across all problems / nr = train->nrows; nc = train->ncols; ni = train->ncols / (ctrl->num_clusters); / mallocing / bl = gk_dsmalloc(nc, ctrl->bl, "malloc bl"); /lower bound / bu = gk_dsmalloc(nc, ctrl->bu, "malloc bu"); /upper bound / c = gk_dmalloc(nc, "malloc c"); /linear vector / gk_dset(nc, ctrl->local_lambda, c); /starting and ending columns / basestart = (ctrl->starti >= 0) ? ctrl->starti : 0; baseend = (ctrl->endi >= 0) ? ctrl->endi : ni; datasize = baseend - basestart; step = (datasize / ctrl->num_procs) + (ctrl->id < (datasize % ctrl->num_procs) ? 1 : 0); starti = ((datasize / ctrl->num_procs) ctrl->id) + gk_min(ctrl->id, datasize % ctrl->num_procs); endi = starti + step; if ((endi < datasize) && (ctrl->id == ctrl->num_procs - 1)) { endi = datasize; step = datasize - starti; } pos = 0; iinds = gk_ismalloc(step * nc, 0, "malloc iinds"); jinds = gk_ismalloc(step * nc, 0, "malloc jinds"); vals = gk_fsmalloc(step * nc, 0, "malloc vals"); /* go through all columns / #pragma omp parallel num_threads(ctrl->num_threads) { int mypos; double w, b; wspace_t myws; BCLS ls; myws = (wspace_t ) gk_malloc(sizeof(wspace_t), "myws"); myws->mat = train; myws->ncols = ni; ls = bcls_create_prob(nr, nc); w = gk_dsmalloc(nc, 0, "malloc w"); b = gk_dsmalloc(nr, 0, "malloc b"); #pragma omp for private(i, j) schedule(dynamic) for (i = starti; i < endi; i++) { // this column is totally empty if (train->colptr[i + 1] - train->colptr[i] == 0) { continue; } /*********************************************************/ / BCLS learning / /********************************************************/ / get the i-th column from A / for (j = orig_train->colptr[i]; j < orig_train->colptr[i + 1]; j++) { ii = orig_train->colind[j]; b[ii] = 1; } myws->max_bcls_niters = gk_min(ctrl->max_bcls_niters, 50 (train->colptr[i + 1] - train->colptr[i])); gk_dset(nc, 0, w); // disable myws->acol = i; if (prev_model != NULL) { get_row(prev_model, i, w); } bcsol(ctrl, b, w, myws, bl, bu, 0, c, ls); for (j = orig_train->colptr[i]; j < orig_train->colptr[i + 1] - 1; j++) { ii = orig_train->colind[j]; b[ii] = 0; } /*********************************************************/ / dump the data / /********************************************************/ / compute the triplets / #pragma omp critical { for (j = 0; j < nc; j++) { if (w[j] > EPSILON) { mypos = pos++; iinds[mypos] = i; jinds[mypos] = j; vals[mypos] = w[j]; } } } } // end of starti - endi bcls_free_prob(ls); gk_free((void ) &myws, (void ) &b, (void ) &w, LTERM); } gk_stopwctimer(tmr); / if(ctrl->id == 0){ printf("time passed is %f\n", gk_getwctimer(tmr)); }/ /********************************************************/ / Combine all the mat of the different processes to the total_mat with MPI / /********************************************************/ if (ctrl->id == 0) { nnzs = gk_imalloc(ctrl->num_procs, "malloc nnzs"); gk_iset(ctrl->num_procs, 0, nnzs); } MPI_Gather(&pos, 1, MPI_INT, nnzs, 1, MPI_INT, 0, MPI_COMM_WORLD); if (ctrl->id == 0) { global_nnz = 0; for (i = 0; i < ctrl->num_procs; i++) { global_nnz += nnzs[i]; } } MPI_Bcast(&global_nnz, 1, MPI_INT, 0, MPI_COMM_WORLD); / Finding the max nnzs between all nodes. This covers the case when a node which is not 0 has a bigger iinds/jinds/vals matrix than the one in node 0 / if (ctrl->id == 0) { max_nnzs = nnzs[0]; for (rank = 1; rank < ctrl->num_procs; rank++) if (nnzs[rank] > max_nnzs) max_nnzs = nnzs[rank]; } / Each node creates its own row count. This gets sent to node 0, in order to create the total rowptr. / if (global_nnz / ctrl->num_procs >= ni) { rrowcnt = gk_ismalloc(ni, 0, "rrowcnt"); for (i = 0; i < pos; i++) { rrowcnt[iinds[i]]++; } } / Every node sends its own iinds, jinds and vals. / if (ctrl->id != 0) { if (global_nnz / ctrl->num_procs < ni) { MPI_Send(iinds, pos, MPI_INT, 0, 0, MPI_COMM_WORLD); } else { MPI_Send(rrowcnt, ni, MPI_INT, 0, 0, MPI_COMM_WORLD); } MPI_Send(iinds, pos, MPI_INT, 0, 0, MPI_COMM_WORLD); MPI_Send(jinds, pos, MPI_INT, 0, 0, MPI_COMM_WORLD); MPI_Send(vals, pos, MPI_FLOAT, 0, 0, MPI_COMM_WORLD); } if (ctrl->id == 0) { if (global_nnz / ctrl->num_procs < ni) { rinds1 = gk_icopy(nnzs[0], iinds, gk_imalloc(max_nnzs, "rinds1")); } rinds = gk_icopy(nnzs[0], iinds, gk_imalloc(max_nnzs, "rinds")); rjinds = gk_icopy(nnzs[0], jinds, gk_imalloc(max_nnzs, "rjinds")); rvals = gk_fcopy(nnzs[0], vals, gk_fmalloc(max_nnzs, "rvals")); } gk_free((void ) &iinds, &jinds, &vals, &bl, &bu, &c, LTERM); / Allocate and populate matrix / mat = gk_csr_Create(); mat->nrows = ni; mat->ncols = nc; mat->rowptr = gk_zsmalloc(ni + 1, 0, "rowptr"); mat->rowind = gk_imalloc(global_nnz, "rowind"); mat->rowval = gk_fmalloc(global_nnz, "rowval"); if (ctrl->id == 0) { if (global_nnz / ctrl->num_procs < ni) { for (rank = 0; rank < ctrl->num_procs; rank++) { if (rank != 0) { MPI_Recv(rinds1, nnzs[rank], MPI_INT, rank, 0, MPI_COMM_WORLD, MPI_STATUS_IGNORE); } for (i = 0; i < nnzs[rank]; i++) { mat->rowptr[rinds1[i]]++; } } } else { for (rank = 0; rank < ctrl->num_procs; rank++) { if (rank != 0) { MPI_Recv(rrowcnt, ni, MPI_INT, rank, 0, MPI_COMM_WORLD, MPI_STATUS_IGNORE); } for (i = 0; i < ni; i++) { mat->rowptr[i] += rrowcnt[i]; } } } MAKECSR(i, mat->nrows, mat->rowptr); for (rank = 0; rank < ctrl->num_procs; rank++) { if (rank != 0) { MPI_Recv(rinds, nnzs[rank], MPI_INT, rank, 0, MPI_COMM_WORLD, MPI_STATUS_IGNORE); MPI_Recv(rjinds, nnzs[rank], MPI_INT, rank, 0, MPI_COMM_WORLD, MPI_STATUS_IGNORE); MPI_Recv(rvals, nnzs[rank], MPI_FLOAT, rank, 0, MPI_COMM_WORLD, MPI_STATUS_IGNORE); } for (i = 0; i < nnzs[rank]; i++) { mat->rowind[mat->rowptr[rinds[i]]] = rjinds[i]; mat->rowval[mat->rowptr[rinds[i]]] = rvals[i]; mat->rowptr[rinds[i]]++; } } SHIFTCSR(i, mat->nrows, mat->rowptr); gk_free((void ) &rinds, &rjinds, &rvals, &nnzs, LTERM); if (global_nnz / ctrl->num_procs < ni) { gk_free((void ) &rinds1, LTERM); } } if (rrowcnt != NULL) { gk_free((void ) &rrowcnt, LTERM); } / Broadcast the matrix to the other nodes */ MPI_Bcast(mat->rowptr, ni + 1, MPI_LONG, 0, MPI_COMM_WORLD); MPI_Bcast(mat->rowind, global_nnz, MPI_INT, 0, MPI_COMM_WORLD); MPI_Bcast(mat->rowval, global_nnz, MPI_FLOAT, 0, MPI_COMM_WORLD); return mat; }
pr97289.c	/* PR middle-end/97289 / / { dg-do compile } / / { dg-require-weak "" } / / { dg-skip-if "" { "hppa--hpux" "--aix" "nvptx--" } } */ void foo (void); static void bar (void) __attribute__ ((__weakref__ ("foo"))); void baz (void) { #pragma omp target bar (); }
dynmat.c	/* Copyright (C) 2015 Atsushi Togo / / All rights reserved. / / This file is part of phonopy. / / 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 phonopy project 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. / #include <math.h> #include <stdlib.h> #include "dynmat.h" #define PI 3.14159265358979323846 static void get_dynmat_ij(double dynamical_matrix, const int num_patom, const int num_satom, const double fc, const double q[3], PHPYCONST double (svecs)[27][3], const int multi, const double mass, const int s2p_map, const int p2s_map, PHPYCONST double (charge_sum)[3][3], const int i, const int j); static void get_dm(double dm_real[3][3], double dm_imag[3][3], const int num_patom, const int num_satom, const double fc, const double q[3], PHPYCONST double (svecs)[27][3], const int multi, const int p2s_map, PHPYCONST double (charge_sum)[3][3], const int i, const int j, const int k); static double get_dielectric_part(const double q_cart[3], PHPYCONST double dielectric[3][3]); static void get_KK(double dd_part, / [natom, 3, natom, 3, (real,imag)] / PHPYCONST double (G_list)[3], /* [num_G, 3] / const int num_G, const int num_patom, const double q_cart[3], const double q_direction_cart, PHPYCONST double dielectric[3][3], PHPYCONST double (pos)[3], / [num_patom, 3] / const double lambda, const double tolerance); static void make_Hermitian(double mat, const int num_band); static void multiply_borns(double dd, const double dd_in, const int num_patom, PHPYCONST double (born)[3][3]); int dym_get_dynamical_matrix_at_q(double dynamical_matrix, const int num_patom, const int num_satom, const double fc, const double q[3], PHPYCONST double (svecs)[27][3], const int multi, const double mass, const int s2p_map, const int p2s_map, PHPYCONST double (charge_sum)[3][3], const int with_openmp) { int i, j, ij; if (with_openmp) { #pragma omp parallel for for (ij = 0; ij < num_patom num_patom ; ij++) { get_dynmat_ij(dynamical_matrix, num_patom, num_satom, fc, q, svecs, multi, mass, s2p_map, p2s_map, charge_sum, ij / num_patom, /* i / ij % num_patom); / j / } } else { for (i = 0; i < num_patom; i++) { for (j = 0; j < num_patom; j++) { get_dynmat_ij(dynamical_matrix, num_patom, num_satom, fc, q, svecs, multi, mass, s2p_map, p2s_map, charge_sum, i, j); } } } make_Hermitian(dynamical_matrix, num_patom 3); return 0; } void dym_get_recip_dipole_dipole(double dd, / [natom, 3, natom, 3, (real,imag)] / const double dd_q0, /* [natom, 3, 3, (real,imag)] / PHPYCONST double (G_list)[3], /* [num_G, 3] / const int num_G, const int num_patom, const double q_cart[3], const double q_direction_cart, /* must be pointer / PHPYCONST double (born)[3][3], PHPYCONST double dielectric[3][3], PHPYCONST double (pos)[3], / [num_patom, 3] / const double factor, / 4pi/Vunit-conv / const double lambda, const double tolerance) { int i, k, l, adrs, adrs_sum; double dd_tmp; dd_tmp = NULL; dd_tmp = (double) malloc(sizeof(double) * num_patom * num_patom * 18); for (i = 0; i < num_patom * num_patom * 18; i++) { dd[i] = 0; dd_tmp[i] = 0; } get_KK(dd_tmp, G_list, num_G, num_patom, q_cart, q_direction_cart, dielectric, pos, lambda, tolerance); multiply_borns(dd, dd_tmp, num_patom, born); for (i = 0; i < num_patom; i++) { for (k = 0; k < 3; k++) { /* alpha / for (l = 0; l < 3; l++) { / beta / adrs = i num_patom * 9 + k * num_patom * 3 + i * 3 + l; adrs_sum = i * 9 + k * 3 + l; dd[adrs * 2] -= dd_q0[adrs_sum * 2]; dd[adrs * 2 + 1] -= dd_q0[adrs_sum * 2 + 1]; } } } for (i = 0; i < num_patom * num_patom * 18; i++) { dd[i] = factor; } / This may not be necessary. / / make_Hermitian(dd, num_patom * 3); / free(dd_tmp); dd_tmp = NULL; } void dym_get_recip_dipole_dipole_q0(double dd_q0, /* [natom, 3, 3, (real,imag)] / PHPYCONST double (G_list)[3], /* [num_G, 3] / const int num_G, const int num_patom, PHPYCONST double (born)[3][3], PHPYCONST double dielectric[3][3], PHPYCONST double (pos)[3], / [num_patom, 3] / const double lambda, const double tolerance) { int i, j, k, l, adrs_tmp, adrs, adrsT; double zero_vec[3]; double dd_tmp1, dd_tmp2; dd_tmp1 = NULL; dd_tmp1 = (double) malloc(sizeof(double) * num_patom * num_patom * 18); dd_tmp2 = NULL; dd_tmp2 = (double) malloc(sizeof(double) num_patom * num_patom * 18); for (i = 0; i < num_patom * num_patom * 18; i++) { dd_tmp1[i] = 0; dd_tmp2[i] = 0; } zero_vec[0] = 0; zero_vec[1] = 0; zero_vec[2] = 0; get_KK(dd_tmp1, G_list, num_G, num_patom, zero_vec, NULL, dielectric, pos, lambda, tolerance); multiply_borns(dd_tmp2, dd_tmp1, num_patom, born); for (i = 0; i < num_patom * 18; i++) { dd_q0[i] = 0; } for (i = 0; i < num_patom; i++) { for (k = 0; k < 3; k++) { /* alpha / for (l = 0; l < 3; l++) { / beta / adrs = i 9 + k * 3 + l; for (j = 0; j < num_patom; j++) { adrs_tmp = i * num_patom * 9 + k * num_patom * 3 + j * 3 + l ; dd_q0[adrs * 2] += dd_tmp2[adrs_tmp * 2]; dd_q0[adrs * 2 + 1] += dd_tmp2[adrs_tmp * 2 + 1]; } } } } /* Summation over another atomic index / / for (j = 0; j < num_patom; j++) { / / for (k = 0; k < 3; k++) { /\* alpha \/ / /* for (l = 0; l < 3; l++) { /\* beta \/ / /* adrs = j * 9 + k * 3 + l; / / for (i = 0; i < num_patom; i++) { / / adrs_tmp = i * num_patom * 9 + k * num_patom * 3 + j * 3 + l ; / / dd_q0[adrs * 2] += dd_tmp2[adrs_tmp * 2]; / / dd_q0[adrs * 2 + 1] += dd_tmp2[adrs_tmp * 2 + 1]; / / } / / } / / } / / } / for (i = 0; i < num_patom; i++) { for (k = 0; k < 3; k++) { / alpha / for (l = 0; l < 3; l++) { / beta / adrs = i 9 + k * 3 + l; adrsT = i * 9 + l * 3 + k; dd_q0[adrs * 2] += dd_q0[adrsT * 2]; dd_q0[adrs * 2] /= 2; dd_q0[adrsT * 2] = dd_q0[adrs * 2]; dd_q0[adrs * 2 + 1] -= dd_q0[adrsT * 2 + 1]; dd_q0[adrs * 2 + 1] /= 2; dd_q0[adrsT * 2 + 1] = -dd_q0[adrs * 2 + 1]; } } } free(dd_tmp1); dd_tmp1 = NULL; free(dd_tmp2); dd_tmp2 = NULL; } void dym_get_charge_sum(double (charge_sum)[3][3], const int num_patom, const double factor, / 4pi/Vunit-conv and denominator / const double q_cart[3], PHPYCONST double (born)[3][3]) { int i, j, k, a, b; double (q_born)[3]; q_born = (double ()[3]) malloc(sizeof(double[3]) num_patom); for (i = 0; i < num_patom; i++) { for (j = 0; j < 3; j++) { q_born[i][j] = 0; } } for (i = 0; i < num_patom; i++) { for (j = 0; j < 3; j++) { for (k = 0; k < 3; k++) { q_born[i][j] += q_cart[k] * born[i][k][j]; } } } for (i = 0; i < num_patom; i++) { for (j = 0; j < num_patom; j++) { for (a = 0; a < 3; a++) { for (b = 0; b < 3; b++) { charge_sum[i * num_patom + j][a][b] = q_born[i][a] * q_born[j][b] * factor; } } } } free(q_born); q_born = NULL; } /* fc[num_patom, num_satom, 3, 3] / / dm[num_comm_points, num_patom * 3, num_patom 3] / /* comm_points[num_satom, num_patom, 27, 3] / / shortest_vectors[num_satom, num_patom, 27, 3] / / multiplicities[num_satom, num_patom] / void dym_transform_dynmat_to_fc(double fc, const double dm, PHPYCONST double (comm_points)[3], PHPYCONST double (shortest_vectors)[27][3], const int multiplicities, const double masses, const int s2pp_map, const int fc_index_map, const int num_patom, const int num_satom) { int i, j, k, l, m, N, adrs, multi; double coef, phase, cos_phase, sin_phase; N = num_satom / num_patom; for (i = 0; i < num_patom num_satom * 9; i++) { fc[i] = 0; } for (i = 0; i < num_patom; i++) { for (j = 0; j < num_satom; j++) { coef = sqrt(masses[i] * masses[s2pp_map[j]]) / N; for (k = 0; k < N; k++) { cos_phase = 0; sin_phase = 0; multi = multiplicities[j * num_patom + i]; for (l = 0; l < multi; l++) { phase = 0; for (m = 0; m < 3; m++) { phase -= comm_points[k][m] * shortest_vectors[j * num_patom + i][l][m]; } cos_phase += cos(phase * 2 * PI); sin_phase += sin(phase * 2 * PI); } cos_phase /= multi; sin_phase /= multi; for (l = 0; l < 3; l++) { for (m = 0; m < 3; m++) { adrs = k * num_patom * num_patom * 18 + i * num_patom * 18 + l * num_patom * 6 + s2pp_map[j] * 6 + m * 2; fc[fc_index_map[i] * num_satom * 9 + j * 9 + l * 3 + m] += (dm[adrs] * cos_phase - dm[adrs + 1] * sin_phase) * coef; } } } } } } static void get_dynmat_ij(double dynamical_matrix, const int num_patom, const int num_satom, const double fc, const double q[3], PHPYCONST double (svecs)[27][3], const int multi, const double mass, const int s2p_map, const int p2s_map, PHPYCONST double (charge_sum)[3][3], const int i, const int j) { int k, l, adrs; double mass_sqrt; double dm_real[3][3], dm_imag[3][3]; mass_sqrt = sqrt(mass[i] * mass[j]); for (k = 0; k < 3; k++) { for (l = 0; l < 3; l++) { dm_real[k][l] = 0; dm_imag[k][l] = 0; } } for (k = 0; k < num_satom; k++) { /* Lattice points of right index of fc / if (s2p_map[k] != p2s_map[j]) { continue; } get_dm(dm_real, dm_imag, num_patom, num_satom, fc, q, svecs, multi, p2s_map, charge_sum, i, j, k); } for (k = 0; k < 3; k++) { for (l = 0; l < 3; l++) { adrs = (i 3 + k) * num_patom * 3 + j * 3 + l; dynamical_matrix[adrs * 2] = dm_real[k][l] / mass_sqrt; dynamical_matrix[adrs * 2 + 1] = dm_imag[k][l] / mass_sqrt; } } } static void get_dm(double dm_real[3][3], double dm_imag[3][3], const int num_patom, const int num_satom, const double fc, const double q[3], PHPYCONST double (svecs)[27][3], const int multi, const int p2s_map, PHPYCONST double (charge_sum)[3][3], const int i, const int j, const int k) { int l, m; double phase, cos_phase, sin_phase, fc_elem; cos_phase = 0; sin_phase = 0; for (l = 0; l < multi[k num_patom + i]; l++) { phase = 0; for (m = 0; m < 3; m++) { phase += q[m] * svecs[k * num_patom + i][l][m]; } cos_phase += cos(phase * 2 * PI) / multi[k * num_patom + i]; sin_phase += sin(phase * 2 * PI) / multi[k * num_patom + i]; } for (l = 0; l < 3; l++) { for (m = 0; m < 3; m++) { if (charge_sum) { fc_elem = (fc[p2s_map[i] * num_satom * 9 + k * 9 + l * 3 + m] + charge_sum[i * num_patom + j][l][m]); } else { fc_elem = fc[p2s_map[i] * num_satom * 9 + k * 9 + l * 3 + m]; } dm_real[l][m] += fc_elem * cos_phase; dm_imag[l][m] += fc_elem * sin_phase; } } } static double get_dielectric_part(const double q_cart[3], PHPYCONST double dielectric[3][3]) { int i, j; double x[3]; double sum; for (i = 0; i < 3; i++) { x[i] = 0; for (j = 0; j < 3; j++) { x[i] += dielectric[i][j] * q_cart[j]; } } sum = 0; for (i = 0; i < 3; i++) { sum += q_cart[i] * x[i]; } return sum; } static void get_KK(double dd_part, / [natom, 3, natom, 3, (real,imag)] / PHPYCONST double (G_list)[3], /* [num_G, 3] / const int num_G, const int num_patom, const double q_cart[3], const double q_direction_cart, PHPYCONST double dielectric[3][3], PHPYCONST double (pos)[3], / [num_patom, 3] / const double lambda, const double tolerance) { int i, j, k, l, g, adrs; double q_K[3]; double norm, cos_phase, sin_phase, phase, dielectric_part, exp_damp, L2; double KK[3][3]; L2 = 4 lambda * lambda; /* sum over K = G + q and over G (i.e. q=0) / / q_direction has values for summation over K at Gamma point. / / q_direction is NULL for summation over G / for (g = 0; g < num_G; g++) { norm = 0; for (i = 0; i < 3; i++) { q_K[i] = G_list[g][i] + q_cart[i]; norm += q_K[i] q_K[i]; } if (sqrt(norm) < tolerance) { if (!q_direction_cart) { continue; } else { dielectric_part = get_dielectric_part(q_direction_cart, dielectric); for (i = 0; i < 3; i++) { for (j = 0; j < 3; j++) { KK[i][j] = q_direction_cart[i] * q_direction_cart[j] / dielectric_part; } } } } else { dielectric_part = get_dielectric_part(q_K, dielectric); exp_damp = exp(-dielectric_part / L2); for (i = 0; i < 3; i++) { for (j = 0; j < 3; j++) { KK[i][j] = q_K[i] * q_K[j] / dielectric_part * exp_damp; } } } for (i = 0; i < num_patom; i++) { for (j = 0; j < num_patom; j++) { phase = 0; for (k = 0; k < 3; k++) { /* For D-type dynamical matrix / / phase += (pos[i][k] - pos[j][k]) * q_K[k]; / / For C-type dynamical matrix / phase += (pos[i][k] - pos[j][k]) G_list[g][k]; } phase = 2 PI; cos_phase = cos(phase); sin_phase = sin(phase); for (k = 0; k < 3; k++) { for (l = 0; l < 3; l++) { adrs = i * num_patom * 9 + k * num_patom * 3 + j * 3 + l; dd_part[adrs * 2] += KK[k][l] * cos_phase; dd_part[adrs * 2 + 1] += KK[k][l] * sin_phase; } } } } } } static void make_Hermitian(double mat, const int num_band) { int i, j, adrs, adrsT; for (i = 0; i < num_band; i++) { for (j = i; j < num_band; j++) { adrs = i num_band + j * 1; adrs = 2; adrsT = j num_band + i * 1; adrsT = 2; / real part / mat[adrs] += mat[adrsT]; mat[adrs] /= 2; / imaginary part / mat[adrs + 1] -= mat[adrsT+ 1]; mat[adrs + 1] /= 2; / store / mat[adrsT] = mat[adrs]; mat[adrsT + 1] = -mat[adrs + 1]; } } } static void multiply_borns(double dd, const double dd_in, const int num_patom, PHPYCONST double (born)[3][3]) { int i, j, k, l, m, n, adrs, adrs_in; double zz; for (i = 0; i < num_patom; i++) { for (j = 0; j < num_patom; j++) { for (k = 0; k < 3; k++) { /* alpha / for (l = 0; l < 3; l++) { / beta / adrs = i num_patom * 9 + k * num_patom * 3 + j * 3 + l; for (m = 0; m < 3; m++) { /* alpha' / for (n = 0; n < 3; n++) { / beta' / adrs_in = i num_patom * 9 + m * num_patom * 3 + j * 3 + n ; zz = born[i][m][k] * born[j][n][l]; dd[adrs * 2] += dd_in[adrs_in * 2] * zz; dd[adrs * 2 + 1] += dd_in[adrs_in * 2 + 1] * zz; } } } } } } }
GB_unaryop__ainv_uint32_int32.c	//------------------------------------------------------------------------------ // GB_unaryop: hard-coded functions for each built-in unary operator //------------------------------------------------------------------------------ // SuiteSparse:GraphBLAS, Timothy A. Davis, (c) 2017-2019, 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__ainv_uint32_int32 // op(A') function: GB_tran__ainv_uint32_int32 // C type: uint32_t // A type: int32_t // cast: uint32_t cij = (uint32_t) aij // unaryop: cij = -aij #define GB_ATYPE \ int32_t #define GB_CTYPE \ uint32_t // aij = Ax [pA] #define GB_GETA(aij,Ax,pA) \ int32_t aij = Ax [pA] #define GB_CX(p) Cx [p] // unary operator #define GB_OP(z, x) \ z = -x ; // casting #define GB_CASTING(z, x) \ uint32_t z = (uint32_t) x ; // 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 (x, aij) ; \ GB_OP (GB_CX (pC), x) ; \ } // disable this operator and use the generic case if these conditions hold #define GB_DISABLE \ (GxB_NO_AINV \|\| GxB_NO_UINT32 \|\| GxB_NO_INT32) //------------------------------------------------------------------------------ // Cx = op (cast (Ax)): apply a unary operator //------------------------------------------------------------------------------ GrB_Info GB_unop__ainv_uint32_int32 ( uint32_t restrict Cx, const int32_t restrict Ax, int64_t anz, int nthreads ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else #pragma omp parallel for num_threads(nthreads) schedule(static) for (int64_t 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__ainv_uint32_int32 ( GrB_Matrix C, const GrB_Matrix A, int64_t restrict Rowcounts, GBI_single_iterator Iter, const int64_t 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
chain_access.c	#include <stdlib.h> #include <stdio.h> #include <omp.h> void use_pointer(int * p, int x) { p = x; } int main() { int ptr = (int)malloc(sizeof(int)); ptr = 0; #pragma omp parallel { use_pointer(ptr, 42); } printf("p: %d\n", *ptr); free(ptr); }
patchmodel.h	#ifndef CMT_PATCHMODEL_H #define CMT_PATCHMODEL_H #include <vector> #include <algorithm> #include <iostream> #include <cmath> #include "Eigen/Core" #include "utils.h" #include "distribution.h" #include "exception.h" #include "conditionaldistribution.h" #include "pcapreconditioner.h" #include "trainable.h" #include "tools.h" namespace CMT { using std::vector; using std::find; using std::distance; using std::cout; using std::endl; using std::min; using std::ceil; using Eigen::ArrayXXd; using Eigen::MatrixXd; using Eigen::Array; using Eigen::Dynamic; class PatchModelBase : public Distribution { public: using Distribution::logLikelihood; virtual ~PatchModelBase(); virtual int rows() const = 0; virtual int cols() const = 0; virtual int maxPCs() const = 0; virtual ArrayXXb inputMask() const = 0; virtual ArrayXXb outputMask() const = 0; virtual ArrayXXb inputMask(int i, int j) const = 0; virtual ArrayXXb outputMask(int i, int j) const = 0; virtual Tuples inputIndices(int i, int j) const = 0; virtual Tuples order() const = 0; virtual Array<double, 1, Dynamic> logLikelihood( int i, int j, const MatrixXd& data) const = 0; virtual ConditionalDistribution& operator()(int i, int j) = 0; virtual const ConditionalDistribution& operator()(int i, int j) const = 0; virtual AffinePreconditioner& preconditioner(int i, int j) = 0; virtual const AffinePreconditioner& preconditioner(int i, int j) const = 0; }; template <class CD, class PC = CMT::PCAPreconditioner> class PatchModel : public PatchModelBase { public: typedef typename CD::Parameters Parameters; PatchModel( int rows, int cols, const CD* model = 0, int maxPCs = -1); PatchModel( int rows, int cols, const ArrayXXb& inputMask, const ArrayXXb& outputMask, const CD* model = 0, int maxPCs = -1); PatchModel( int rows, int cols, const Tuples& order, const ArrayXXb& inputMask, const ArrayXXb& outputMask, const CD* model = 0, int maxPCs = -1); PatchModel( int rows, int cols, const Tuples& order, const CD* model = 0, int maxPCs = -1); virtual ~PatchModel(); int dim() const; int rows() const; int cols() const; int maxPCs() const; ArrayXXb inputMask() const; ArrayXXb outputMask() const; ArrayXXb inputMask(int i, int j) const; ArrayXXb outputMask(int i, int j) const; Tuples inputIndices(int i, int j) const; Tuples order() const; CD& operator()(int i, int j); const CD& operator()(int i, int j) const; PC& preconditioner(int i, int j); const PC& preconditioner(int i, int j) const; void setPreconditioner(int i, int j, const PC& preconditioner); void initialize( const MatrixXd& data, const Trainable::Parameters& params = Parameters()); bool train( const MatrixXd& data, const Trainable::Parameters& params = Parameters()); bool train( const MatrixXd& data, const MatrixXd& dataVal, const Trainable::Parameters& params = Parameters()); bool train( int i, int j, const MatrixXd& data, const Trainable::Parameters& params = Parameters()); bool train( int i, int j, const MatrixXd& data, const MatrixXd& dataVal, const Trainable::Parameters& params = Parameters()); Array<double, 1, Dynamic> logLikelihood(const MatrixXd& data) const; Array<double, 1, Dynamic> logLikelihood(int i, int j, const MatrixXd& data) const; MatrixXd sample(int num_samples) const; protected: int mRows; int mCols; int mMaxPCs; ArrayXXb mInputMask; ArrayXXb mOutputMask; Tuples mOutputIndices; vector<Tuples> mInputIndices; vector<CD> mConditionalDistributions; vector<PC> mPreconditioners; int findIndex(int i, int j) const; bool indicesMatch(int i, int j) const; }; } /* * Constructs model which assumes image patches are generated pixel by pixel * in row-major order. * * @param rows number of rows of the image patch * @param cols number of columns of the image patch * @param model template which will be used to initialize other models * @param maxPCs used to reduce dimensionality of input to each model via PCA first / template <class CD, class PC> CMT::PatchModel<CD, PC>::PatchModel( int rows, int cols, const CD model, int maxPCs) : mRows(rows), mCols(cols), mMaxPCs(maxPCs) { mInputMask = ArrayXXb::Ones(2 * rows - 1, 2 * cols - 1); mInputMask(rows - 1, cols - 1) = false; mOutputMask = ArrayXXb::Zero(2 * rows - 1, 2 * cols - 1); mOutputMask(rows - 1, cols - 1) = true; // initialize conditional distributions for(int i = 0; i < mRows; ++i) for(int j = 0; j < mCols; ++j) { // compute indices of input to model predicting pixel (i, j) Tuples indices; for(Tuples::iterator it = mOutputIndices.begin(); it != mOutputIndices.end(); ++it) indices.push_back(it); mInputIndices.push_back(indices); mOutputIndices.push_back(make_pair(i, j)); // dimensionality of input int dimIn = mMaxPCs < 0 ? indices.size() : min(static_cast<int>(indices.size()), mMaxPCs); // create model for pixel (i, j) if(model) if(dimIn == model->dimIn()) // given model fits input mConditionalDistributions.push_back(model); else // given model doesn't fit input mConditionalDistributions.push_back(CD(dimIn, model)); else // no model was given mConditionalDistributions.push_back(CD(dimIn)); mPreconditioners.push_back(0); } } /* * Constructs model which assumes image patches are generated pixel by pixel * in row-major order. * * @param rows number of rows of the image patch * @param cols number of columns of the image patch * @param inputMask mask used to constrain input to certain pixels * @param outputMask mask indicating the output pixel * @param model template which will be used to initialize other models * @param maxPCs used to reduce dimensionality of input to each model via PCA first / template <class CD, class PC> CMT::PatchModel<CD, PC>::PatchModel( int rows, int cols, const ArrayXXb& inputMask, const ArrayXXb& outputMask, const CD model, int maxPCs) : mRows(rows), mCols(cols), mMaxPCs(maxPCs), mInputMask(inputMask), mOutputMask(outputMask) { // compute locations of active pixels pair<Tuples, Tuples> inOutIndices = masksToIndices(inputMask, outputMask); Tuples& inputIndices = inOutIndices.first; Tuples& outputIndices = inOutIndices.second; if(outputIndices.size() > 1) throw Exception("Only one-dimensional outputs are currently supported."); int rowOffset = outputIndices[0].first; int colOffset = outputIndices[0].second; // initialize conditional distributions for(int i = 0; i < rows; ++i) for(int j = 0; j < cols; ++j) { // compute indices of causal neighborhood at pixel (i, j) Tuples indices; for(Tuples::iterator it = inputIndices.begin(); it != inputIndices.end(); ++it) { // location of input pixel in patch int m = i + it->first - rowOffset; int n = j + it->second - colOffset; if(m >= 0 && n >= 0 && m < mRows && n < mCols && m <= i && (n < j \|\| m < i)) indices.push_back(make_pair(m, n)); } mInputIndices.push_back(indices); mOutputIndices.push_back(make_pair(i, j)); // dimensionality of input int dimIn = mMaxPCs < 0 ? indices.size() : min(static_cast<int>(indices.size()), mMaxPCs); // create model for pixel (i, j) if(model) if(dimIn == model->dimIn()) // given model fits input mConditionalDistributions.push_back(model); else // given model doesn't fit input mConditionalDistributions.push_back(CD(dimIn, model)); else // no model was given mConditionalDistributions.push_back(CD(dimIn)); mPreconditioners.push_back(0); } } /** * Constructs model which generates pixels in a prespecified order. * * @param rows number of rows of the image patch * @param cols number of columns of the image patch * @param order list of pixel locations * @param inputMask mask used to constrain input to certain pixels * @param outputMask mask indicating the output pixel * @param model template which will be used to initialize other models * @param maxPCs used to reduce dimensionality of input to each model via PCA first / template <class CD, class PC> CMT::PatchModel<CD, PC>::PatchModel( int rows, int cols, const Tuples& order, const ArrayXXb& inputMask, const ArrayXXb& outputMask, const CD model, int maxPCs) : mRows(rows), mCols(cols), mMaxPCs(maxPCs), mInputMask(inputMask), mOutputMask(outputMask), mOutputIndices(order) { if(order.size() != mRows * mCols) throw Exception("Invalid pixel order."); // compute location of output index Tuples outputIndices = maskToIndices(outputMask); if(outputIndices.size() > 1) throw Exception("Only one-dimensional outputs are currently supported."); int rowOffset = outputIndices[0].first; int colOffset = outputIndices[0].second; // initialize conditional distributions for(Tuples::iterator oit = mOutputIndices.begin(); oit != mOutputIndices.end(); ++oit) { // location of pixel in patch int i = oit->first; int j = oit->second; if(i < 0 \|\| j < 0 \|\| i >= mRows \|\| j >= mCols) throw Exception("Invalid pixel location in list of pixels."); // compute indices of input to model predicting pixel (i, j) Tuples indices; for(Tuples::iterator iit = mOutputIndices.begin(); iit != oit; ++iit) { // location of input pixel in mask int m = iit->first - i + rowOffset; int n = iit->second - j + colOffset; // check if pixel is active in input mask if(m >= 0 && n >= 0 && m < inputMask.rows() && n < inputMask.cols()) if(inputMask(m, n)) indices.push_back(iit); } mInputIndices.push_back(indices); // dimensionality of input int dimIn = mMaxPCs < 0 ? indices.size() : min(static_cast<int>(indices.size()), mMaxPCs); // create model for pixel (i, j) if(model) if(dimIn == model->dimIn()) // given model fits input mConditionalDistributions.push_back(model); else // given model doesn't fit input mConditionalDistributions.push_back(CD(dimIn, model)); else // no model was given mConditionalDistributions.push_back(CD(dimIn)); mPreconditioners.push_back(0); } } template <class CD, class PC> CMT::PatchModel<CD, PC>::PatchModel( int rows, int cols, const Tuples& order, const CD model, int maxPCs) : mRows(rows), mCols(cols), mMaxPCs(maxPCs), mOutputIndices(order) { if(order.size() != mRows * mCols) throw Exception("Invalid pixel order."); mInputMask = ArrayXXb::Ones(2 * rows - 1, 2 * cols - 1); mInputMask(rows - 1, cols - 1) = false; mOutputMask = ArrayXXb::Zero(2 * rows - 1, 2 * cols - 1); mOutputMask(rows - 1, cols - 1) = true; // initialize conditional distributions for(Tuples::iterator oit = mOutputIndices.begin(); oit != mOutputIndices.end(); ++oit) { // location of pixel in patch int i = oit->first; int j = oit->second; if(i < 0 \|\| j < 0 \|\| i >= mRows \|\| j >= mCols) throw Exception("Invalid pixel location in list of pixels."); // compute indices of input to model predicting pixel (i, j) Tuples indices; for(Tuples::iterator iit = mOutputIndices.begin(); iit != oit; ++iit) indices.push_back(iit); mInputIndices.push_back(indices); // dimensionality of input int dimIn = mMaxPCs < 0 ? indices.size() : min(static_cast<int>(indices.size()), mMaxPCs); // create model for pixel (i, j) if(model) if(dimIn == model->dimIn()) // given model fits input mConditionalDistributions.push_back(model); else // given model doesn't fit input mConditionalDistributions.push_back(CD(dimIn, model)); else // no model was given mConditionalDistributions.push_back(CD(dimIn)); mPreconditioners.push_back(0); } } template <class CD, class PC> CMT::PatchModel<CD, PC>::~PatchModel() { for(int i = 0; i < mRows mCols; ++i) if(mPreconditioners[i]) delete mPreconditioners[i]; } template <class CD, class PC> int CMT::PatchModel<CD, PC>::dim() const { return mRows * mCols; } template <class CD, class PC> int CMT::PatchModel<CD, PC>::rows() const { return mRows; } template <class CD, class PC> int CMT::PatchModel<CD, PC>::cols() const { return mCols; } template <class CD, class PC> int CMT::PatchModel<CD, PC>::maxPCs() const { return mMaxPCs; } template <class CD, class PC> Eigen::ArrayXXb CMT::PatchModel<CD, PC>::inputMask() const { return mInputMask; } template <class CD, class PC> Eigen::ArrayXXb CMT::PatchModel<CD, PC>::outputMask() const { return mOutputMask; } template <class CD, class PC> Eigen::ArrayXXb CMT::PatchModel<CD, PC>::inputMask(int i, int j) const { ArrayXXb inputMask = ArrayXXb::Zero(mRows, mCols); int k = findIndex(i, j); for(Tuples::const_iterator it = mInputIndices[k].begin(); it != mInputIndices[k].end(); ++it) inputMask(it->first, it->second) = true; return inputMask; } template <class CD, class PC> Eigen::ArrayXXb CMT::PatchModel<CD, PC>::outputMask(int i, int j) const { ArrayXXb outputMask = ArrayXXb::Zero(mRows, mCols); outputMask(i, j) = true; return outputMask; } template <class CD, class PC> CMT::Tuples CMT::PatchModel<CD, PC>::inputIndices(int i, int j) const { return mInputIndices[findIndex(i, j)]; } template <class CD, class PC> CMT::Tuples CMT::PatchModel<CD, PC>::order() const { return mOutputIndices; } template <class CD, class PC> CD& CMT::PatchModel<CD, PC>::operator()(int i, int j) { if(i < 0 \|\| j < 0 \|\| j >= mCols \|\| i >= mRows) throw Exception("Invalid indices."); return mConditionalDistributions[findIndex(i, j)]; } template <class CD, class PC> const CD& CMT::PatchModel<CD, PC>::operator()(int i, int j) const { if(i < 0 \|\| j < 0 \|\| j >= mCols \|\| i >= mRows) throw Exception("Invalid indices."); return mConditionalDistributions[findIndex(i, j)]; } template <class CD, class PC> PC& CMT::PatchModel<CD, PC>::preconditioner(int i, int j) { if(i < 0 \|\| j < 0 \|\| j >= mCols \|\| i >= mRows) throw Exception("Invalid indices."); int k = findIndex(i, j); if(!mPreconditioners[k]) throw Exception("The model at this pixel has no preconditioner."); return mPreconditioners[k]; } template <class CD, class PC> const PC& CMT::PatchModel<CD, PC>::preconditioner(int i, int j) const { if(i < 0 \|\| j < 0 \|\| j >= mCols \|\| i >= mRows) throw Exception("Invalid indices."); int k = findIndex(i, j); if(!mPreconditioners[k]) throw Exception("The model for this pixel has no preconditioner."); return mPreconditioners[k]; } template <class CD, class PC> void CMT::PatchModel<CD, PC>::setPreconditioner(int i, int j, const PC& preconditioner) { if(mMaxPCs < 0) return; if(i < 0 \|\| j < 0 \|\| j >= mCols \|\| i >= mRows) throw Exception("Invalid indices."); int k = findIndex(i, j); if(preconditioner.dimIn() != mInputIndices[k].size() \|\| preconditioner.dimInPre() != mConditionalDistributions[k].dimIn() \|\| preconditioner.dimOutPre() != mConditionalDistributions[k].dimOut()) throw Exception("Preconditioner is incompatible with model."); PC* preconditionerOld = mPreconditioners[k]; mPreconditioners[k] = new PC(preconditioner); if(preconditionerOld) delete preconditionerOld; } template <class CD, class PC> void CMT::PatchModel<CD, PC>::initialize(const MatrixXd& data, const Trainable::Parameters& params) { for(int i = 0; i < mRows * mCols; ++i) { int m = mOutputIndices[i].first; int n = mOutputIndices[i].second; // assumes patch is stored in row-major order MatrixXd output = data.row(m * mCols + n); MatrixXd input(mInputIndices[i].size(), data.cols()); // subselect input from patches #pragma omp parallel for for(int j = 0; j < mInputIndices[i].size(); ++j) { // coordinates of j-th input to i-th model int m = mInputIndices[i][j].first; int n = mInputIndices[i][j].second; // assumes patch is stored in row-major order input.row(j) = data.row(m * mCols + n); } // initialize model if(mMaxPCs >= 0) { if(mPreconditioners[i]) delete mPreconditioners[i]; mPreconditioners[i] = new PC(input, output, 0., mMaxPCs); mConditionalDistributions[i].initialize( mPreconditioners[i]->operator()(input, output)); } else { mConditionalDistributions[i].initialize(input, output); } } } template <class CD, class PC> bool CMT::PatchModel<CD, PC>::train(const MatrixXd& data, const Trainable::Parameters& params) { bool converged = true; for(int i = 0; i < mRows * mCols; ++i) { // coordinates of i-th output pixels int m = mOutputIndices[i].first; int n = mOutputIndices[i].second; // assumes patch is stored in row-major order MatrixXd output = data.row(m * mCols + n); MatrixXd input(mInputIndices[i].size(), data.cols()); // check if an equivalent model has already been trained if(params.stationary) { bool copied = false; for(int j = i - 1; j >= 0; --j) if(indicesMatch(i, j)) { if(params.verbosity > 0) cout << "Copying model " << i / mCols << ", " << i % mCols << endl; // copy model mConditionalDistributions[i] = mConditionalDistributions[j]; // copy preconditioner if(mMaxPCs >= 0) mPreconditioners[i] = mPreconditioners[j]; copied = true; break; } if(copied) // don't train continue; } // extract inputs and outputs from patches #pragma omp parallel for for(int j = 0; j < mInputIndices[i].size(); ++j) { // coordinates of j-th input to i-th model int m = mInputIndices[i][j].first; int n = mInputIndices[i][j].second; // assumes patch is stored in row-major order input.row(j) = data.row(m * mCols + n); } if(params.verbosity > 0) cout << "Training model " << i / mCols << ", " << i % mCols << endl; if(mMaxPCs < 0) { converged &= mConditionalDistributions[i].train(input, output, params); } else { if(!mPreconditioners[i]) mPreconditioners[i] = new PC(input, output, 0., mMaxPCs); converged &= mConditionalDistributions[i].train( mPreconditioners[i]->operator()(input, output), params); } } return converged; } template <class CD, class PC> bool CMT::PatchModel<CD, PC>::train( const MatrixXd& data, const MatrixXd& dataVal, const Trainable::Parameters& params) { bool converged = true; for(int i = 0; i < mRows * mCols; ++i) { // coordinates of i-th output pixels int m = mOutputIndices[i].first; int n = mOutputIndices[i].second; // assumes patch is stored in row-major order MatrixXd output = data.row(m * mCols + n); MatrixXd input(mInputIndices[i].size(), data.cols()); MatrixXd outputVal = dataVal.row(m * mCols + n); MatrixXd inputVal(mInputIndices[i].size(), dataVal.cols()); // extract inputs and outputs from patches #pragma omp parallel for for(int j = 0; j < mInputIndices[i].size(); ++j) { // coordinates of j-th input to i-th model int m = mInputIndices[i][j].first; int n = mInputIndices[i][j].second; // assumes patch is stored in row-major order input.row(j) = data.row(m * mCols + n); inputVal.row(j) = dataVal.row(m * mCols + n); } if(params.verbosity > 0) cout << "Training model " << i / mCols << ", " << i % mCols << endl; if(mMaxPCs < 0) { converged &= mConditionalDistributions[i].train( input, output, inputVal, outputVal, params); } else { if(!mPreconditioners[i]) mPreconditioners[i] = new PC(input, output, 0., mMaxPCs); converged &= mConditionalDistributions[i].train( mPreconditioners[i]->operator()(input, output), mPreconditioners[i]->operator()(inputVal, outputVal), params); } } return converged; } template <class CD, class PC> bool CMT::PatchModel<CD, PC>::train(int i, int j, const MatrixXd& data, const Trainable::Parameters& params) { int k = findIndex(i, j); MatrixXd output = data.row(i * mCols + j); MatrixXd input(mInputIndices[k].size(), data.cols()); // extract inputs and outputs from patches #pragma omp parallel for for(int l = 0; l < mInputIndices[k].size(); ++l) { // coordinates of j-th input to i-th model int m = mInputIndices[k][l].first; int n = mInputIndices[k][l].second; // assumes patch is stored in row-major order input.row(l) = data.row(m * mCols + n); } if(mMaxPCs < 0) { return mConditionalDistributions[k].train(input, output, params); } else { if(!mPreconditioners[k]) mPreconditioners[k] = new PC(input, output, 0., mMaxPCs); return mConditionalDistributions[k].train( mPreconditioners[k]->operator()(input, output), params); } } template <class CD, class PC> bool CMT::PatchModel<CD, PC>::train( int i, int j, const MatrixXd& data, const MatrixXd& dataVal, const Trainable::Parameters& params) { int k = findIndex(i, j); // assumes patch is stored in row-major order MatrixXd output = data.row(i * mCols + j); MatrixXd input(mInputIndices[k].size(), data.cols()); MatrixXd outputVal = dataVal.row(i * mCols + j); MatrixXd inputVal(mInputIndices[k].size(), dataVal.cols()); // extract inputs and outputs from patches #pragma omp parallel for for(int l = 0; l < mInputIndices[k].size(); ++l) { // coordinates of j-th input to i-th model int m = mInputIndices[k][l].first; int n = mInputIndices[k][l].second; // assumes patch is stored in row-major order input.row(l) = data.row(m * mCols + n); inputVal.row(l) = dataVal.row(m * mCols + n); } if(mMaxPCs < 0) { return mConditionalDistributions[k].train( input, output, inputVal, outputVal, params); } else { if(!mPreconditioners[k]) mPreconditioners[k] = new PC(input, output, 0., mMaxPCs); return mConditionalDistributions[k].train( mPreconditioners[k]->operator()(input, output), mPreconditioners[k]->operator()(inputVal, outputVal), params); } } template <class CD, class PC> Eigen::Array<double, 1, Eigen::Dynamic> CMT::PatchModel<CD, PC>::logLikelihood( const MatrixXd& data) const { if(data.rows() != dim()) throw Exception("Data has wrong dimensionality."); if(mMaxPCs > -1) for(int i = 0; i < mRows * mCols; ++i) if(!mPreconditioners[i]) throw Exception("Model has to be initialized first."); Array<double, 1, Dynamic> logLik = Array<double, 1, Dynamic>::Zero(data.cols()); #pragma omp parallel for for(int i = 0; i < mRows * mCols; ++i) { int m = mOutputIndices[i].first; int n = mOutputIndices[i].second; // assumes patch is stored in row-major order MatrixXd output = data.row(m * mCols + n); MatrixXd input(mInputIndices[i].size(), data.cols()); for(int j = 0; j < mInputIndices[i].size(); ++j) { // coordinates of j-th input to i-th model int m = mInputIndices[i][j].first; int n = mInputIndices[i][j].second; // assumes patch is stored in row-major order input.row(j) = data.row(m * mCols + n); } Array<double, 1, Dynamic> logLik_; if(mMaxPCs < 0) logLik_ = mConditionalDistributions[i].logLikelihood(input, output); else logLik_ = mConditionalDistributions[i].logLikelihood( mPreconditioners[i]->operator()(input, output)) + mPreconditioners[i]->logJacobian(input, output); #pragma omp critical logLik += logLik_; } return logLik; } template <class CD, class PC> Eigen::Array<double, 1, Eigen::Dynamic> CMT::PatchModel<CD, PC>::logLikelihood( int i, int j, const MatrixXd& data) const { if(data.rows() != dim()) throw Exception("Data has wrong dimensionality."); int k = findIndex(i, j); Array<double, 1, Dynamic> logLik = Array<double, 1, Dynamic>::Zero(data.cols()); // assumes patch is stored in row-major order MatrixXd output = data.row(i * mCols + j); MatrixXd input(mInputIndices[k].size(), data.cols()); for(int l = 0; l < mInputIndices[k].size(); ++l) { // coordinates of j-th input to i-th model int m = mInputIndices[k][l].first; int n = mInputIndices[k][l].second; // assumes patch is stored in row-major order input.row(l) = data.row(m * mCols + n); } if(mMaxPCs < 0) { return mConditionalDistributions[k].logLikelihood(input, output); } else { if(!mPreconditioners[k]) throw Exception("Model has to be initialized first."); return mConditionalDistributions[k].logLikelihood( mPreconditioners[k]->operator()(input, output)) + mPreconditioners[k]->logJacobian(input, output); } } template<class CD, class PC> Eigen::MatrixXd CMT::PatchModel<CD, PC>::sample(int num_samples) const { MatrixXd samples = MatrixXd::Zero(mRows * mCols, num_samples); for(int i = 0; i < mRows * mCols; ++i) { MatrixXd input(mInputIndices[i].size(), num_samples); // construct input from already sampled patch for(int j = 0; j < mInputIndices[i].size(); ++j) { // coordinates of j-th input to i-th model int m = mInputIndices[i][j].first; int n = mInputIndices[i][j].second; // assumes patch is stored in row-major order input.row(j) = samples.row(m * mCols + n); } int m = mOutputIndices[i].first; int n = mOutputIndices[i].second; if(mMaxPCs < 0) { samples.row(m * mCols + n) = mConditionalDistributions[i].sample(input); } else { if(!mPreconditioners[i]) throw Exception("Model has to be initialized first."); MatrixXd inputPc = mPreconditioners[i]->operator()(input); MatrixXd outputPc = mConditionalDistributions[i].sample(inputPc); samples.row(m * mCols + n) = mPreconditioners[i]->inverse(inputPc, outputPc).second; } } return samples; } template<class CD, class PC> int CMT::PatchModel<CD, PC>::findIndex(int i, int j) const { // find index corresponding to pixel (i, j) Tuples::const_iterator it = find(mOutputIndices.begin(), mOutputIndices.end(), make_pair(i, j)); if(it == mOutputIndices.end()) throw Exception("Invalid indices"); return distance(mOutputIndices.begin(), it); } template<class CD, class PC> bool CMT::PatchModel<CD, PC>::indicesMatch(int i, int j) const { // check if indices are shifted versions of each other // assuming that indices are stored in the same order if(mInputIndices[i].size() != mInputIndices[j].size()) return false; if(mInputIndices[i].size() == 0) return true; int m = mOutputIndices[i].first - mOutputIndices[j].first; int n = mOutputIndices[i].second - mOutputIndices[j].second; for(int k = 0; k < mInputIndices[i].size(); ++k) { if(mInputIndices[j][k].first + m != mInputIndices[i][k].first) return false; if(mInputIndices[j][k].second + n != mInputIndices[i][k].second) return false; } return true; } #endif
int_array.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_utilities.hpp" /**************************************************************************** * * Routines for hypre_IntArray struct for holding an array of integers * ****************************************************************************/ /-------------------------------------------------------------------------- * hypre_IntArrayCreate --------------------------------------------------------------------------/ hypre_IntArray * hypre_IntArrayCreate( HYPRE_Int size ) { hypre_IntArray array; array = hypre_CTAlloc(hypre_IntArray, 1, HYPRE_MEMORY_HOST); hypre_IntArrayData(array) = NULL; hypre_IntArraySize(array) = size; hypre_IntArrayMemoryLocation(array) = hypre_HandleMemoryLocation(hypre_handle()); return array; } /-------------------------------------------------------------------------- * hypre_IntArrayDestroy --------------------------------------------------------------------------/ HYPRE_Int hypre_IntArrayDestroy( hypre_IntArray array ) { HYPRE_Int ierr = 0; if (array) { HYPRE_MemoryLocation memory_location = hypre_IntArrayMemoryLocation(array); hypre_TFree(hypre_IntArrayData(array), memory_location); hypre_TFree(array, HYPRE_MEMORY_HOST); } return ierr; } /-------------------------------------------------------------------------- * hypre_IntArrayInitialize --------------------------------------------------------------------------/ HYPRE_Int hypre_IntArrayInitialize_v2( hypre_IntArray array, HYPRE_MemoryLocation memory_location ) { HYPRE_Int size = hypre_IntArraySize(array); HYPRE_Int ierr = 0; hypre_IntArrayMemoryLocation(array) = memory_location; / Caveat: for pre-existing data, the memory location must be guaranteed * to be consistent with `memory_location' * Otherwise, mismatches will exist and problems will be encountered * when being used, and freed / if ( !hypre_IntArrayData(array) ) { hypre_IntArrayData(array) = hypre_CTAlloc(HYPRE_Int, size, memory_location); } return ierr; } HYPRE_Int hypre_IntArrayInitialize( hypre_IntArray array ) { HYPRE_Int ierr; ierr = hypre_IntArrayInitialize_v2( array, hypre_IntArrayMemoryLocation(array) ); return ierr; } /-------------------------------------------------------------------------- hypre_IntArrayCopy * copies data from x to y * if size of x is larger than y only the first size_y elements of x are * copied to y --------------------------------------------------------------------------/ HYPRE_Int hypre_IntArrayCopy( hypre_IntArray x, hypre_IntArray y ) { HYPRE_Int ierr = 0; size_t size = hypre_min( hypre_IntArraySize(x), hypre_IntArraySize(y) ); hypre_TMemcpy( hypre_IntArrayData(y), hypre_IntArrayData(x), HYPRE_Int, size, hypre_IntArrayMemoryLocation(y), hypre_IntArrayMemoryLocation(x) ); return ierr; } /-------------------------------------------------------------------------- hypre_IntArrayCloneDeep * Returns a complete copy of x - a deep copy, with its own copy of the data. --------------------------------------------------------------------------/ hypre_IntArray * hypre_IntArrayCloneDeep_v2( hypre_IntArray x, HYPRE_MemoryLocation memory_location ) { HYPRE_Int size = hypre_IntArraySize(x); hypre_IntArray y = hypre_IntArrayCreate( size ); hypre_IntArrayInitialize_v2(y, memory_location); hypre_IntArrayCopy( x, y ); return y; } hypre_IntArray * hypre_IntArrayCloneDeep( hypre_IntArray x ) { return hypre_IntArrayCloneDeep_v2(x, hypre_IntArrayMemoryLocation(x)); } /-------------------------------------------------------------------------- * hypre_IntArraySetConstantValues --------------------------------------------------------------------------/ HYPRE_Int hypre_IntArraySetConstantValues( hypre_IntArray v, HYPRE_Int value ) { HYPRE_Int array_data = hypre_IntArrayData(v); HYPRE_Int size = hypre_IntArraySize(v); HYPRE_Int ierr = 0; #if defined(HYPRE_USING_CUDA) \|\| defined(HYPRE_USING_HIP) if (size > 0) { HYPRE_THRUST_CALL( fill_n, array_data, size, value ); } #else HYPRE_Int i; #if defined(HYPRE_USING_DEVICE_OPENMP) #pragma omp target teams distribute parallel for private(i) is_device_ptr(array_data) #elif defined(HYPRE_USING_OPENMP) #pragma omp parallel for private(i) HYPRE_SMP_SCHEDULE #endif for (i = 0; i < size; i++) { array_data[i] = value; } #endif /* defined(HYPRE_USING_CUDA) \|\| defined(HYPRE_USING_HIP) */ #if defined(HYPRE_USING_GPU) hypre_SyncCudaComputeStream(hypre_handle()); #endif return ierr; }
EntityInitializer.h	// Copyright (c) 2004-2022 Tomáš Oberhuber et al. // // This file is part of TNL - Template Numerical Library (https://tnl-project.org/) // // SPDX-License-Identifier: MIT /*** * Authors: * Oberhuber Tomas, tomas.oberhuber@fjfi.cvut.cz * Zabka Vitezslav, zabkav@gmail.com / #pragma once #include <TNL/Meshes/MeshDetails/initializer/EntitySeed.h> #include <TNL/Meshes/MeshDetails/initializer/SubentitySeedsCreator.h> #include <TNL/Atomic.h> #include <TNL/Algorithms/AtomicOperations.h> namespace TNL { namespace Meshes { template< typename MeshConfig > class Initializer; template< typename MeshConfig, typename SubdimensionTag, typename SuperdimensionTag, typename SuperentityTopology = typename MeshTraits< MeshConfig >::template EntityTraits< SuperdimensionTag::value >::EntityTopology, // storage in the superentity bool SubentityStorage = MeshConfig::subentityStorage( SuperdimensionTag::value, SubdimensionTag::value ), // storage in the subentity bool SuperentityStorage = MeshConfig::superentityStorage( SubdimensionTag::value, SuperdimensionTag::value ), // necessary to disambiguate the stop condition for specializations bool valid_dimension = ! std::is_same< SubdimensionTag, SuperdimensionTag >::value > class EntityInitializerLayer; template< typename MeshConfig, typename EntityTopology, bool SubvertexStorage = MeshConfig::subentityStorage( EntityTopology::dimension, 0 ) > class EntityInitializer : public EntityInitializerLayer< MeshConfig, DimensionTag< EntityTopology::dimension >, DimensionTag< MeshTraits< MeshConfig >::meshDimension > > { using BaseType = EntityInitializerLayer< MeshConfig, DimensionTag< EntityTopology::dimension >, DimensionTag< MeshTraits< MeshConfig >::meshDimension > >; using MeshTraitsType = MeshTraits< MeshConfig >; using EntityTraitsType = typename MeshTraitsType::template EntityTraits< EntityTopology::dimension >; using GlobalIndexType = typename MeshTraitsType::GlobalIndexType; using LocalIndexType = typename MeshTraitsType::LocalIndexType; using SeedType = EntitySeed< MeshConfig, EntityTopology >; using InitializerType = Initializer< MeshConfig >; using NeighborCountsArray = typename MeshTraitsType::NeighborCountsArray; using SeedMatrixType = typename EntityTraitsType::SeedMatrixType; public: static void initSubvertexMatrix( NeighborCountsArray& capacities, InitializerType& initializer ) { initializer.template initSubentityMatrix< EntityTopology::dimension, 0 >( capacities ); } static void initSubvertexMatrix( SeedMatrixType& seeds, InitializerType& initializer ) { auto& subvertexMatrix = initializer.template getSubentitiesMatrix< EntityTopology::dimension, 0 >(); subvertexMatrix = std::move( seeds.getMatrix() ); initializer.template initSubentitiesCounts< EntityTopology::dimension, 0 >( seeds.getEntityCornerCounts() ); } static void initEntity( const GlobalIndexType entityIndex, const SeedType& entitySeed, InitializerType& initializer ) { // this is necessary if we want to use existing entities instead of intermediate seeds to create subentity seeds for( LocalIndexType i = 0; i < entitySeed.getCornerIds().getSize(); i++ ) initializer.template setSubentityIndex< EntityTopology::dimension, 0 >( entityIndex, i, entitySeed.getCornerIds()[ i ] ); } }; template< typename MeshConfig, typename EntityTopology > class EntityInitializer< MeshConfig, EntityTopology, false > : public EntityInitializerLayer< MeshConfig, DimensionTag< EntityTopology::dimension >, DimensionTag< MeshTraits< MeshConfig >::meshDimension > > { using MeshTraitsType = MeshTraits< MeshConfig >; using EntityTraitsType = typename MeshTraitsType::template EntityTraits< EntityTopology::dimension >; using GlobalIndexType = typename MeshTraitsType::GlobalIndexType; using SeedType = EntitySeed< MeshConfig, EntityTopology >; using InitializerType = Initializer< MeshConfig >; using NeighborCountsArray = typename MeshTraitsType::NeighborCountsArray; using SeedMatrixType = typename EntityTraitsType::SeedMatrixType; public: static void initSubvertexMatrix( const NeighborCountsArray& capacities, InitializerType& initializer ) {} static void initSubvertexMatrix( SeedMatrixType& seeds, InitializerType& initializer ) {} static void initEntity( const GlobalIndexType entityIndex, const SeedType& entitySeed, InitializerType& initializer ) {} }; /*** * Mesh entity initializer layer with specializations * * SUBENTITY STORAGE SUPERENTITY STORAGE * TRUE TRUE / template< typename MeshConfig, typename SubdimensionTag, typename SuperdimensionTag, typename SuperentityTopology > class EntityInitializerLayer< MeshConfig, SubdimensionTag, SuperdimensionTag, SuperentityTopology, true, true, true > : public EntityInitializerLayer< MeshConfig, SubdimensionTag, typename SuperdimensionTag::Decrement > { using BaseType = EntityInitializerLayer< MeshConfig, SubdimensionTag, typename SuperdimensionTag::Decrement >; using InitializerType = Initializer< MeshConfig >; using MeshType = typename InitializerType::MeshType; using MeshTraitsType = MeshTraits< MeshConfig >; using GlobalIndexType = typename MeshTraitsType::GlobalIndexType; using LocalIndexType = typename MeshTraitsType::LocalIndexType; using SubentityTraitsType = typename MeshTraitsType::template EntityTraits< SubdimensionTag::value >; using SubentityTopology = typename SubentityTraitsType::EntityTopology; using SuperentityTraitsType = typename MeshTraitsType::template EntityTraits< SuperdimensionTag::value >; using SubentitySeedsCreatorType = SubentitySeedsCreator< MeshConfig, SuperentityTopology, SubdimensionTag >; using SuperentityMatrixType = typename MeshTraitsType::SuperentityMatrixType; using NeighborCountsArray = typename MeshTraitsType::NeighborCountsArray; using SeedType = EntitySeed< MeshConfig, SubentityTopology >; public: static void initSuperentities( InitializerType& meshInitializer, MeshType& mesh ) { // std::cout << " Initiating superentities with dimension " << SuperdimensionTag::value << " for subentities with // dimension " << SubdimensionTag::value << " ... " << std::endl; const GlobalIndexType subentitiesCount = mesh.template getEntitiesCount< SubdimensionTag::value >(); const GlobalIndexType superentitiesCount = mesh.template getEntitiesCount< SuperdimensionTag::value >(); if( SubdimensionTag::value > 0 \|\| std::is_same< SuperentityTopology, Topologies::Polyhedron >::value ) { NeighborCountsArray capacities( superentitiesCount ); Algorithms::ParallelFor< Devices::Host >::exec( GlobalIndexType{ 0 }, superentitiesCount, [ & ]( GlobalIndexType superentityIndex ) { capacities[ superentityIndex ] = SubentitySeedsCreatorType::getSubentitiesCount( meshInitializer, mesh, superentityIndex ); } ); meshInitializer.template initSubentityMatrix< SuperdimensionTag::value, SubdimensionTag::value >( capacities, subentitiesCount ); } // counter for superentities of each subentity auto& superentitiesCounts = meshInitializer.template getSuperentitiesCountsArray< SubdimensionTag::value, SuperdimensionTag::value >(); superentitiesCounts.setSize( subentitiesCount ); superentitiesCounts.setValue( 0 ); Algorithms::ParallelFor< Devices::Host >::exec( GlobalIndexType{ 0 }, superentitiesCount, [ & ]( GlobalIndexType superentityIndex ) { LocalIndexType i = 0; SubentitySeedsCreatorType::iterate( meshInitializer, mesh, superentityIndex, [ & ]( SeedType& seed ) { const GlobalIndexType subentityIndex = meshInitializer.findEntitySeedIndex( seed ); // Subentity indices for SubdimensionTag::value == 0 of non-polyhedral meshes were already set up from seeds if( SubdimensionTag::value > 0 \|\| std::is_same< SuperentityTopology, Topologies::Polyhedron >::value ) meshInitializer.template setSubentityIndex< SuperdimensionTag::value, SubdimensionTag::value >( superentityIndex, i++, subentityIndex ); Algorithms::AtomicOperations< Devices::Host >::add( superentitiesCounts[ subentityIndex ], LocalIndexType{ 1 } ); } ); } ); // allocate superentities storage SuperentityMatrixType& matrix = meshInitializer.template getSuperentitiesMatrix< SubdimensionTag::value, SuperdimensionTag::value >(); matrix.setDimensions( subentitiesCount, superentitiesCount ); matrix.setRowCapacities( superentitiesCounts ); superentitiesCounts.setValue( 0 ); for( GlobalIndexType superentityIndex = 0; superentityIndex < superentitiesCount; superentityIndex++ ) { for( LocalIndexType i = 0; i < mesh.template getSubentitiesCount< SuperdimensionTag::value, SubdimensionTag::value >( superentityIndex ); i++ ) { const GlobalIndexType subentityIndex = mesh.template getSubentityIndex< SuperdimensionTag::value, SubdimensionTag::value >( superentityIndex, i ); auto row = matrix.getRow( subentityIndex ); row.setElement( superentitiesCounts[ subentityIndex ]++, superentityIndex, true ); } } BaseType::initSuperentities( meshInitializer, mesh ); } }; /*** * Mesh entity initializer layer with specializations * * SUBENTITY STORAGE SUPERENTITY STORAGE Subdimension Superdimension SUPERENTITY TOPOLOGY * TRUE TRUE 2 3 POLYHEDRON / template< typename MeshConfig > class EntityInitializerLayer< MeshConfig, DimensionTag< 2 >, DimensionTag< 3 >, Topologies::Polyhedron, true, true, true > : public EntityInitializerLayer< MeshConfig, DimensionTag< 2 >, typename DimensionTag< 3 >::Decrement > { using SubdimensionTag = DimensionTag< 2 >; using SuperdimensionTag = DimensionTag< 3 >; using BaseType = EntityInitializerLayer< MeshConfig, SubdimensionTag, typename SuperdimensionTag::Decrement >; using InitializerType = Initializer< MeshConfig >; using MeshType = typename InitializerType::MeshType; using MeshTraitsType = MeshTraits< MeshConfig >; using GlobalIndexType = typename MeshTraitsType::GlobalIndexType; using LocalIndexType = typename MeshTraitsType::LocalIndexType; using SubentityTraitsType = typename MeshTraitsType::template EntityTraits< SubdimensionTag::value >; using SubentityTopology = typename SubentityTraitsType::EntityTopology; using SuperentityTraitsType = typename MeshTraitsType::template EntityTraits< SuperdimensionTag::value >; using SuperentityTopology = typename SuperentityTraitsType::EntityTopology; using SuperentityMatrixType = typename MeshTraitsType::SuperentityMatrixType; using NeighborCountsArray = typename MeshTraitsType::NeighborCountsArray; using SeedType = EntitySeed< MeshConfig, SubentityTopology >; public: static void initSuperentities( InitializerType& meshInitializer, MeshType& mesh ) { // std::cout << " Initiating superentities with dimension " << SuperdimensionTag::value << " for subentities with // dimension " << SubdimensionTag::value << " ... " << std::endl; const GlobalIndexType subentitiesCount = mesh.template getEntitiesCount< SubdimensionTag::value >(); const GlobalIndexType superentitiesCount = mesh.template getEntitiesCount< SuperdimensionTag::value >(); // counter for superentities of each subentity auto& superentitiesCounts = meshInitializer.template getSuperentitiesCountsArray< SubdimensionTag::value, SuperdimensionTag::value >(); superentitiesCounts.setSize( subentitiesCount ); superentitiesCounts.setValue( 0 ); auto& cellSeeds = meshInitializer.getCellSeeds(); for( GlobalIndexType superentityIndex = 0; superentityIndex < superentitiesCount; superentityIndex++ ) { const auto cellSeed = cellSeeds.getSeed( superentityIndex ); for( LocalIndexType i = 0; i < cellSeed.getCornersCount(); i++ ) { const GlobalIndexType subentityIndex = cellSeed.getCornerId( i ); superentitiesCounts[ subentityIndex ]++; } } auto& subvertexMatrix = meshInitializer.template getSubentitiesMatrix< SuperdimensionTag::value, SubdimensionTag::value >(); subvertexMatrix = std::move( cellSeeds.getMatrix() ); meshInitializer.template initSubentitiesCounts< SuperdimensionTag::value, SubdimensionTag::value >( cellSeeds.getEntityCornerCounts() ); // allocate superentities storage SuperentityMatrixType& matrix = meshInitializer.template getSuperentitiesMatrix< SubdimensionTag::value, SuperdimensionTag::value >(); matrix.setDimensions( subentitiesCount, superentitiesCount ); matrix.setRowCapacities( superentitiesCounts ); superentitiesCounts.setValue( 0 ); // initialize superentities storage for( GlobalIndexType superentityIndex = 0; superentityIndex < superentitiesCount; superentityIndex++ ) { for( LocalIndexType i = 0; i < mesh.template getSubentitiesCount< SuperdimensionTag::value, SubdimensionTag::value >( superentityIndex ); i++ ) { const GlobalIndexType subentityIndex = mesh.template getSubentityIndex< SuperdimensionTag::value, SubdimensionTag::value >( superentityIndex, i ); auto row = matrix.getRow( subentityIndex ); row.setElement( superentitiesCounts[ subentityIndex ]++, superentityIndex, true ); } } BaseType::initSuperentities( meshInitializer, mesh ); } }; /*** * Mesh entity initializer layer with specializations * * SUBENTITY STORAGE SUPERENTITY STORAGE * TRUE FALSE / template< typename MeshConfig, typename SubdimensionTag, typename SuperdimensionTag, typename SuperentityTopology > class EntityInitializerLayer< MeshConfig, SubdimensionTag, SuperdimensionTag, SuperentityTopology, true, false, true > : public EntityInitializerLayer< MeshConfig, SubdimensionTag, typename SuperdimensionTag::Decrement > { using BaseType = EntityInitializerLayer< MeshConfig, SubdimensionTag, typename SuperdimensionTag::Decrement >; using InitializerType = Initializer< MeshConfig >; using MeshType = typename InitializerType::MeshType; using MeshTraitsType = MeshTraits< MeshConfig >; using GlobalIndexType = typename MeshTraitsType::GlobalIndexType; using LocalIndexType = typename MeshTraitsType::LocalIndexType; using SubentityTraitsType = typename MeshTraitsType::template EntityTraits< SubdimensionTag::value >; using SubentityTopology = typename SubentityTraitsType::EntityTopology; using SuperentityTraitsType = typename MeshTraitsType::template EntityTraits< SuperdimensionTag::value >; using SubentitySeedsCreatorType = SubentitySeedsCreator< MeshConfig, SuperentityTopology, SubdimensionTag >; using NeighborCountsArray = typename MeshTraitsType::NeighborCountsArray; using SeedType = EntitySeed< MeshConfig, SubentityTopology >; public: static void initSuperentities( InitializerType& meshInitializer, MeshType& mesh ) { // std::cout << " Initiating superentities with dimension " << SuperdimensionTag::value << " for subentities with // dimension " << SubdimensionTag::value << " ... " << std::endl; const GlobalIndexType subentitiesCount = mesh.template getEntitiesCount< SubdimensionTag::value >(); const GlobalIndexType superentitiesCount = mesh.template getEntitiesCount< SuperdimensionTag::value >(); if( SubdimensionTag::value > 0 \|\| std::is_same< SuperentityTopology, Topologies::Polyhedron >::value ) { NeighborCountsArray capacities( superentitiesCount ); Algorithms::ParallelFor< Devices::Host >::exec( GlobalIndexType{ 0 }, superentitiesCount, [ & ]( GlobalIndexType superentityIndex ) { capacities[ superentityIndex ] = SubentitySeedsCreatorType::getSubentitiesCount( meshInitializer, mesh, superentityIndex ); } ); meshInitializer.template initSubentityMatrix< SuperdimensionTag::value, SubdimensionTag::value >( capacities, subentitiesCount ); Algorithms::ParallelFor< Devices::Host >::exec( GlobalIndexType{ 0 }, superentitiesCount, [ & ]( GlobalIndexType superentityIndex ) { LocalIndexType i = 0; SubentitySeedsCreatorType::iterate( meshInitializer, mesh, superentityIndex, [ & ]( SeedType& seed ) { const GlobalIndexType subentityIndex = meshInitializer.findEntitySeedIndex( seed ); meshInitializer.template setSubentityIndex< SuperdimensionTag::value, SubdimensionTag::value >( superentityIndex, i++, subentityIndex ); } ); } ); } BaseType::initSuperentities( meshInitializer, mesh ); } }; /*** * Mesh entity initializer layer with specializations * * SUBENTITY STORAGE SUPERENTITY STORAGE Subdimension Superdimension SUPERENTITY TOPOLOGY * TRUE FALSE 2 3 POLYHEDRON / template< typename MeshConfig > class EntityInitializerLayer< MeshConfig, DimensionTag< 2 >, DimensionTag< 3 >, Topologies::Polyhedron, true, false, true > : public EntityInitializerLayer< MeshConfig, DimensionTag< 2 >, typename DimensionTag< 3 >::Decrement > { using SubdimensionTag = DimensionTag< 2 >; using SuperdimensionTag = DimensionTag< 3 >; using BaseType = EntityInitializerLayer< MeshConfig, SubdimensionTag, typename SuperdimensionTag::Decrement >; using InitializerType = Initializer< MeshConfig >; using MeshType = typename InitializerType::MeshType; using MeshTraitsType = MeshTraits< MeshConfig >; using GlobalIndexType = typename MeshTraitsType::GlobalIndexType; using LocalIndexType = typename MeshTraitsType::LocalIndexType; using SubentityTraitsType = typename MeshTraitsType::template EntityTraits< SubdimensionTag::value >; using SubentityTopology = typename SubentityTraitsType::EntityTopology; using SuperentityTraitsType = typename MeshTraitsType::template EntityTraits< SuperdimensionTag::value >; using SuperentityTopology = typename SuperentityTraitsType::EntityTopology; using NeighborCountsArray = typename MeshTraitsType::NeighborCountsArray; using SeedType = EntitySeed< MeshConfig, SubentityTopology >; public: static void initSuperentities( InitializerType& meshInitializer, MeshType& mesh ) { // std::cout << " Initiating superentities with dimension " << SuperdimensionTag::value << " for subentities with // dimension " << SubdimensionTag::value << " ... " << std::endl; auto& cellSeeds = meshInitializer.getCellSeeds(); auto& subvertexMatrix = meshInitializer.template getSubentitiesMatrix< SuperdimensionTag::value, SubdimensionTag::value >(); subvertexMatrix = std::move( cellSeeds.getMatrix() ); meshInitializer.template initSubentitiesCounts< SuperdimensionTag::value, SubdimensionTag::value >( cellSeeds.getEntityCornerCounts() ); BaseType::initSuperentities( meshInitializer, mesh ); } }; /*** * Mesh entity initializer layer with specializations * * SUBENTITY STORAGE SUPERENTITY STORAGE * FALSE TRUE / template< typename MeshConfig, typename SubdimensionTag, typename SuperdimensionTag, typename SuperentityTopology > class EntityInitializerLayer< MeshConfig, SubdimensionTag, SuperdimensionTag, SuperentityTopology, false, true, true > : public EntityInitializerLayer< MeshConfig, SubdimensionTag, typename SuperdimensionTag::Decrement > { using BaseType = EntityInitializerLayer< MeshConfig, SubdimensionTag, typename SuperdimensionTag::Decrement >; using InitializerType = Initializer< MeshConfig >; using MeshType = typename InitializerType::MeshType; using MeshTraitsType = MeshTraits< MeshConfig >; using GlobalIndexType = typename MeshTraitsType::GlobalIndexType; using LocalIndexType = typename MeshTraitsType::LocalIndexType; using SubentityTraitsType = typename MeshTraitsType::template EntityTraits< SubdimensionTag::value >; using SubentityTopology = typename SubentityTraitsType::EntityTopology; using SuperentityTraitsType = typename MeshTraitsType::template EntityTraits< SuperdimensionTag::value >; using SubentitySeedsCreatorType = SubentitySeedsCreator< MeshConfig, SuperentityTopology, SubdimensionTag >; using SuperentityMatrixType = typename MeshTraitsType::SuperentityMatrixType; using SeedType = EntitySeed< MeshConfig, SubentityTopology >; public: static void initSuperentities( InitializerType& meshInitializer, MeshType& mesh ) { // std::cout << " Initiating superentities with dimension " << SuperdimensionTag::value << " for subentities with // dimension " << SubdimensionTag::value << " ... " << std::endl; const GlobalIndexType subentitiesCount = mesh.template getEntitiesCount< SubdimensionTag::value >(); const GlobalIndexType superentitiesCount = mesh.template getEntitiesCount< SuperdimensionTag::value >(); // counter for superentities of each subentity auto& superentitiesCounts = meshInitializer.template getSuperentitiesCountsArray< SubdimensionTag::value, SuperdimensionTag::value >(); superentitiesCounts.setSize( subentitiesCount ); superentitiesCounts.setValue( 0 ); Algorithms::ParallelFor< Devices::Host >::exec( GlobalIndexType{ 0 }, superentitiesCount, [ & ]( GlobalIndexType superentityIndex ) { SubentitySeedsCreatorType::iterate( meshInitializer, mesh, superentityIndex, [ & ]( SeedType& seed ) { const GlobalIndexType subentityIndex = meshInitializer.findEntitySeedIndex( seed ); Algorithms::AtomicOperations< Devices::Host >::add( superentitiesCounts[ subentityIndex ], LocalIndexType{ 1 } ); } ); } ); // allocate superentities storage SuperentityMatrixType& matrix = meshInitializer.template getSuperentitiesMatrix< SubdimensionTag::value, SuperdimensionTag::value >(); matrix.setDimensions( subentitiesCount, superentitiesCount ); matrix.setRowCapacities( superentitiesCounts ); superentitiesCounts.setValue( 0 ); // initialize superentities storage for( GlobalIndexType superentityIndex = 0; superentityIndex < superentitiesCount; superentityIndex++ ) { SubentitySeedsCreatorType::iterate( meshInitializer, mesh, superentityIndex, [ & ]( SeedType& seed ) { const GlobalIndexType subentityIndex = meshInitializer.findEntitySeedIndex( seed ); auto row = matrix.getRow( subentityIndex ); row.setElement( superentitiesCounts[ subentityIndex ]++, superentityIndex, true ); } ); } // Here is an attempt of parallelization of previous for cycle, that seemingly causes some kind of race condition /Algorithms::ParallelFor< Devices::Host >::exec( GlobalIndexType{ 0 }, superentitiesCount, [&] ( GlobalIndexType superentityIndex ) { SubentitySeedsCreatorType::iterate( meshInitializer, mesh, superentityIndex, [&] ( SeedType& seed ) { const GlobalIndexType subentityIndex = meshInitializer.findEntitySeedIndex( seed ); auto row = matrix.getRow( subentityIndex ); LocalIndexType superentityCount; #pragma omp atomic capture { superentityCount = superentitiesCounts[ subentityIndex ]; superentitiesCounts[ subentityIndex ]++; } row.setElement( superentityCount, superentityIndex, true ); }); });*/ BaseType::initSuperentities( meshInitializer, mesh ); } }; template< typename MeshConfig, typename SubdimensionTag, typename SuperdimensionTag, typename SuperentityTopology > class EntityInitializerLayer< MeshConfig, SubdimensionTag, SuperdimensionTag, SuperentityTopology, false, false, true > : public EntityInitializerLayer< MeshConfig, SubdimensionTag, typename SuperdimensionTag::Decrement > {}; template< typename MeshConfig, typename SubdimensionTag, typename SuperentityTopology, bool SubentityStorage, bool SuperentityStorage > class EntityInitializerLayer< MeshConfig, SubdimensionTag, SubdimensionTag, SuperentityTopology, SubentityStorage, SuperentityStorage, false > { using InitializerType = Initializer< MeshConfig >; using MeshType = typename InitializerType::MeshType; public: static void initSuperentities( InitializerType& meshInitializer, MeshType& mesh ) {} }; } // namespace Meshes } // namespace TNL
hnsw.h	// Copyright 2017 Kakao Corp. <http://www.kakaocorp.com> // // 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. #pragma once /** @file / #include <omp.h> #include <memory> #include <string> #include <utility> #include <vector> #include "hnsw_build.h" #include "hnsw_model.h" #include "hnsw_search.h" namespace n2 { class Hnsw { public: Hnsw(); /* * @brief Makes an instance of Hnsw Index. * @param dim: Dimension of vectors. * @param metric: An optional parameter to choose a distance metric. * ('angular' \| 'L2' \| 'dot') (default: 'angular'). * @return A new Hnsw index. / Hnsw(int dim,std::string metric="angular"); Hnsw(const Hnsw& other); Hnsw(Hnsw&& other) noexcept; ~Hnsw(); Hnsw& operator=(const Hnsw& other); Hnsw& operator=(Hnsw&& other) noexcept; //////////////////////////////////////////// // Build /* * @brief Adds vector to Hnsw index. * @param data: A vector with dimension ``dim``. / void AddData(const std::vector<float>& data); /* * @brief Set configurations by key/value pairs. * * To set configurations as default values, pass negative values to configuration parameters. / void SetConfigs(const std::vector<std::pair<std::string, std::string>>& configs); /* * @brief Builds a hnsw graph with given configurations. * @param m: Max number of edges for nodes at level > 0 (default: 12). * @param max_m0: Max number of edges for nodes at level == 0 (default: 24). * @param ef_construction: Refer to HNSW paper for its role (default: 150). * @param n_threads: Number of threads for building index. * @param mult: Level multiplier (default value recommended) (default: 1/log(1.0M)). @param NeighborSelectingPolicy: Neighbor selecting policy. * @param GraphPostProcessing: Graph merging heuristic. * * To see other available values for ``neighbor_selecting`` and ``graph_merging``, * refer to NeighborSelectingPolicy() and GraphPostProcessing(). * @see Fit(), SetConfigs() / void Build(int m=-1, int max_m0=-1, int ef_construction=-1, int n_threads=-1, float mult=-1, NeighborSelectingPolicy neighbor_selecting=NeighborSelectingPolicy::HEURISTIC, GraphPostProcessing graph_merging=GraphPostProcessing::SKIP, bool ensure_k=false); /* * @brief Builds a hnsw graph with given configurations. / void Fit(); //////////////////////////////////////////// // Model /* * @brief Saves the index to disk. * @param fname: An index file name. / bool SaveModel(const std::string& fname) const; /* * @brief Loads an index from disk. * @param fname: An index file name. * @param use_mmap: An optional parameter (default: true). * If this parameter is set, N2 loads model through mmap. / bool LoadModel(const std::string& fname, const bool use_mmap=true); /* * @brief Unloads the loaded index file. / void UnloadModel(); //////////////////////////////////////////// // Search inline void SearchByVector(const std::vector<float>& qvec, size_t k, size_t ef_search, std::vector<int>& result) { searcher_->SearchByVector(qvec, k, ef_search, ensure_k_, result); } /* * @brief Search k nearest items (as vectors) to a query item. * @param qvec: A query vector. * @param k: k value. * @param ef_search: (default: 50 * k). If you pass a negative value to ef_search, * ef_search will be set as the default value. * @param[out] result: ``k`` nearest items. / inline void SearchByVector(const std::vector<float>& qvec, size_t k, size_t ef_search, std::vector<std::pair<int, float>>& result) { searcher_->SearchByVector(qvec, k, ef_search, ensure_k_, result); } inline void SearchById(int id, size_t k, size_t ef_search, std::vector<int>& result) { searcher_->SearchById(id, k, ef_search, ensure_k_, result); } /* * @brief Search k nearest items (as ids) to a query item. * @param id: A query id. * @param k: k value. * @param ef_search: (default: 50 * k). If you pass a negative value to ef_search, * ef_search will be set as the default value. * @param[out] result: ``k`` nearest items. / inline void SearchById(int id, size_t k, size_t ef_search, std::vector<std::pair<int, float>>& result) { searcher_->SearchById(id, k, ef_search, ensure_k_, result); } inline void BatchSearchByVectors(const std::vector<std::vector<float>>& qvecs, size_t k, size_t ef_search, size_t n_threads, std::vector<std::vector<int>>& results) { BatchSearchByVectors_(qvecs, k, ef_search, n_threads, results); } /* * @brief Search k nearest items (as vectors) to each query item (batch search with multi-threads). * @param qvecs: Query vectors. * @param k: k value. * @param ef_search: (default: 50 * k). If you pass a negative value to ef_search, * ef_search will be set as the default value. * @param n_threads: Number of threads to use for search. * @param[out] result: vector of ``k`` nearest items for each input query item * in the order passed to parameter ``qvecs``. / inline void BatchSearchByVectors(const std::vector<std::vector<float>>& qvecs, size_t k, size_t ef_search, size_t n_threads, std::vector<std::vector<std::pair<int, float>>>& results) { BatchSearchByVectors_(qvecs, k, ef_search, n_threads, results); } inline void BatchSearchByIds(const std::vector<int> ids, size_t k, size_t ef_search, size_t n_threads, std::vector<std::vector<int>>& results) { BatchSearchByIds_(ids, k, ef_search, n_threads, results); } /* * @brief Search k nearest items (as ids) to each query item (batch search with multi-threads). * @param ids: Query ids. * @param k: k value. * @param ef_search: (default: 50 * k). If you pass a negative value to ef_search, * ef_search will be set as the default value. * @param n_threads: Number of threads to use for search. * @param[out] result: vector of ``k`` nearest items for each input query item * in the order passed to parameter ``ids``. / inline void BatchSearchByIds(const std::vector<int> ids, size_t k, size_t ef_search, size_t n_threads, std::vector<std::vector<std::pair<int, float>>>& results) { BatchSearchByIds_(ids, k, ef_search, n_threads, results); } //////////////////////////////////////////// // Build(Misc) /* * @brief Prints degree distributions. / void PrintDegreeDist() const; /* * @brief Prints index configurations. */ void PrintConfigs() const; private: void InitSearcherAndSearcherPool_(); template<typename ResultType> void BatchSearchByVectors_(const std::vector<std::vector<float>>& qvecs, size_t k, size_t ef_search, size_t n_threads, ResultType& results) { results.resize(qvecs.size()); while (searcher_pool_.size() < n_threads) { searcher_pool_.push_back(HnswSearch::GenerateSearcher(model_, data_dim_, metric_)); } #pragma omp parallel num_threads(n_threads) { #pragma omp for schedule(runtime) for (size_t i = 0; i < qvecs.size(); ++i) { auto& s = searcher_pool_[omp_get_thread_num()]; s->SearchByVector(qvecs[i], k, ef_search, ensure_k_, results[i]); } } } template<typename ResultType> void BatchSearchByIds_(const std::vector<int> ids, size_t k, size_t ef_search, size_t n_threads, ResultType& results) { results.resize(ids.size()); while (searcher_pool_.size() < n_threads) { searcher_pool_.push_back(HnswSearch::GenerateSearcher(model_, data_dim_, metric_)); } #pragma omp parallel num_threads(n_threads) { #pragma omp for schedule(runtime) for (size_t i = 0; i < ids.size(); ++i) { auto& s = searcher_pool_[omp_get_thread_num()]; s->SearchById(ids[i], k, ef_search, ensure_k_, results[i]); } } } private: std::unique_ptr<HnswBuild> builder_; std::shared_ptr<const HnswModel> model_; std::shared_ptr<HnswSearch> searcher_; // for single-thread search std::vector<std::shared_ptr<HnswSearch>> searcher_pool_; // for multi-threads batch search size_t data_dim_; DistanceKind metric_; bool ensure_k_ = false; }; } // namespace n2
GB_unop__identity_fc32_int8.c	//------------------------------------------------------------------------------ // GB_unop: hard-coded functions for each built-in unary operator //------------------------------------------------------------------------------ // SuiteSparse:GraphBLAS, Timothy A. Davis, (c) 2017-2022, 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_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__identity_fc32_int8) // op(A') function: GB (_unop_tran__identity_fc32_int8) // C type: GxB_FC32_t // A type: int8_t // cast: GxB_FC32_t cij = GxB_CMPLXF ((float) (aij), 0) // unaryop: cij = aij #define GB_ATYPE \ int8_t #define GB_CTYPE \ GxB_FC32_t // aij = Ax [pA] #define GB_GETA(aij,Ax,pA) \ int8_t aij = Ax [pA] #define GB_CX(p) Cx [p] // unary operator #define GB_OP(z, x) \ z = x ; // casting #define GB_CAST(z, aij) \ GxB_FC32_t z = GxB_CMPLXF ((float) (aij), 0) ; // cij = op (aij) #define GB_CAST_OP(pC,pA) \ { \ / aij = Ax [pA] / \ int8_t aij = Ax [pA] ; \ / Cx [pC] = op (cast (aij)) / \ GxB_FC32_t z = GxB_CMPLXF ((float) (aij), 0) ; \ Cx [pC] = z ; \ } // disable this operator and use the generic case if these conditions hold #define GB_DISABLE \ (GxB_NO_IDENTITY \|\| GxB_NO_FC32 \|\| GxB_NO_INT8) //------------------------------------------------------------------------------ // Cx = op (cast (Ax)): apply a unary operator //------------------------------------------------------------------------------ GrB_Info GB (_unop_apply__identity_fc32_int8) ( GxB_FC32_t Cx, // Cx and Ax may be aliased const int8_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 ; if (Ab == NULL) { #pragma omp parallel for num_threads(nthreads) schedule(static) for (p = 0 ; p < anz ; p++) { int8_t aij = Ax [p] ; GxB_FC32_t z = GxB_CMPLXF ((float) (aij), 0) ; Cx [p] = z ; } } 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 ; int8_t aij = Ax [p] ; GxB_FC32_t z = GxB_CMPLXF ((float) (aij), 0) ; Cx [p] = z ; } } return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // C = op (cast (A')): transpose, typecast, and apply a unary operator //------------------------------------------------------------------------------ GrB_Info GB (_unop_tran__identity_fc32_int8) ( 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
ompForTest.c	#include <stdlib.h> #include <stdio.h> #include <omp.h> int main(int argc, char const *argv[]) { omp_set_num_threads(4); #pragma omp parallel for for(int i = 0; i < 32; ++i) { printf("Thread #%d is working. i = %d\n", omp_get_thread_num(), i); } printf("Thread #%d is working.\n", omp_get_thread_num()); return 0; }
model.c	#include <cdnn/model.h> #include <cdnn/progressbar.h> __Model__ * m; void __init__(){ m->predicting = 0; m->testing=0; m->test_accuracy = 0.0; m->train_accuracy = 0.0; m->train_cost = 0.0; m->cross_val_accuracy = 0.0; m->iter_cost = 0.0; m->current_iter = 1; m->output = NULL; __initialize_params__(); } void __initialize_params__(){ Computation_Graph * temp = m->graph; temp = temp->next_layer; int index = 0; int flag = 0; if(!strcasecmp(m->optimizer,"adam")) flag = 1; if(!strcasecmp(m->optimizer,"adagrad")) flag = 2; if(!strcasecmp(m->optimizer,"rmsprop")) flag = 3; if(!strcasecmp(m->optimizer,"momentum")) flag = 4; while(temp!=NULL){ m->current_layer = temp; if(temp->type==DENSE){ temp->DENSE->initalize_params(); } if(flag==1 && temp->type!=LOSS){ int dims_dW[] = {temp->DENSE->weights->shape[0],temp->DENSE->weights->shape[1]}; int dims_db[] = {temp->DENSE->bias->shape[0],temp->DENSE->bias->shape[1]}; m->m_t_dW[index] = zeros(dims_dW); m->m_t_db[index] = zeros(dims_db); m->v_t_dW[index] = zeros(dims_dW); m->v_t_db[index] = zeros(dims_db); index++; } else if(flag==2 && temp->type!=LOSS){ int dims_dW[] = {temp->DENSE->weights->shape[0],temp->DENSE->weights->shape[1]}; int dims_db[] = {temp->DENSE->bias->shape[0],temp->DENSE->bias->shape[1]}; m->cache_dW[index] = zeros(dims_dW); m->cache_db[index] = zeros(dims_db); index++; } else if(flag==3 && temp->type!=LOSS){ int dims_dW[] = {temp->DENSE->weights->shape[0],temp->DENSE->weights->shape[1]}; int dims_db[] = {temp->DENSE->bias->shape[0],temp->DENSE->bias->shape[1]}; m->v_t_dW[index] = zeros(dims_dW); m->v_t_db[index] = zeros(dims_db); index++; } else if(flag==4 && temp->type!=LOSS){ int dims_dW[] = {temp->DENSE->weights->shape[0],temp->DENSE->weights->shape[1]}; int dims_db[] = {temp->DENSE->bias->shape[0],temp->DENSE->bias->shape[1]}; m->m_t_dW[index] = zeros(dims_dW); m->m_t_db[index] = zeros(dims_db); index++; } temp = temp->next_layer; } m->current_layer = m->graph; } void __forward__(){ Computation_Graph * temp = m->graph; while(temp!=NULL){ m->current_layer = temp; if(temp->type==INPUT) temp->INPUT->forward(); else if(temp->type==DENSE) temp->DENSE->forward(); else if(temp->type==LOSS) temp->LOSS->forward(); temp = temp->next_layer; } } void __backward__(){ Computation_Graph * temp = m->current_layer; while(temp->prev_layer!=NULL){ m->current_layer = temp; if(temp->type==INPUT) temp->INPUT->backward(); else if(temp->type==DENSE) temp->DENSE->backward(); else if(temp->type==LOSS) temp->LOSS->backward(); temp = temp->prev_layer; } } float calculate_accuracy(dARRAY * predicted, dARRAY * gnd_truth){ int success = 0; dARRAY * temp = (dARRAY)malloc(sizeof(dARRAY)); temp->matrix = (float)calloc(predicted->shape[0]predicted->shape[1],sizeof(float)); for(int i = 0;i<predicted->shape[0]predicted->shape[1];i++){ temp->matrix[i] = predicted->matrix[i]<0.5 ? 0 : 1; } temp->shape[0] = predicted->shape[0]; temp->shape[1] = predicted->shape[1]; for(int i = 0;i<predicted->shape[0]predicted->shape[1];i++){ if(temp->matrix[i]==gnd_truth->matrix[i]) success++; } if(predicted->shape[0]!=1) success = success/predicted->shape[0]; free2d(temp); temp = NULL; return success/(float)predicted->shape[1]; } dARRAY relu_val(dARRAY * linear_matrix){ dARRAY * relu_outf = NULL; relu_outf = (dARRAY)malloc(sizeof(dARRAY)); relu_outf->matrix = (float)calloc(linear_matrix->shape[0]linear_matrix->shape[1],sizeof(float)); #pragma omp parallel for num_threads(8) shared(relu_outf,linear_matrix) for(int i=0;i<linear_matrix->shape[0]linear_matrix->shape[1];i++) relu_outf->matrix[i] = linear_matrix->matrix[i]>(float)0.0 ?(float)linear_matrix->matrix[i] : (float)0.0; relu_outf->shape[0] = linear_matrix->shape[0]; relu_outf->shape[1] = linear_matrix->shape[1]; return relu_outf; } dARRAY * sigmoid_val(dARRAY * linear_matrix){ dARRAY * sigmoid_outf = NULL; sigmoid_outf = (dARRAY)malloc(sizeof(dARRAY)); sigmoid_outf->matrix = (float)calloc(linear_matrix->shape[0]linear_matrix->shape[1],sizeof(float)); #pragma omp parallel for num_threads(8) shared(sigmoid_outf,linear_matrix) for(int i=0;i<linear_matrix->shape[0]linear_matrix->shape[1];i++) sigmoid_outf->matrix[i] = (float)(1.0/(float)(1+exp((float)(-1.0linear_matrix->matrix[i])))); sigmoid_outf->shape[0] = linear_matrix->shape[0]; sigmoid_outf->shape[1] = linear_matrix->shape[1]; return sigmoid_outf; } dARRAY tanh_val(dARRAY * linear_matrix){ dARRAY * tanh_out = (dARRAY)malloc(sizeof(dARRAY)); tanh_out->matrix = (float)calloc(linear_matrix->shape[0]linear_matrix->shape[1],sizeof(float)); #pragma omp parallel for num_threads(8) shared(tanh_out,linear_matrix) for(int i=0;i<linear_matrix->shape[0]linear_matrix->shape[1];i++){ float exp_res1 = exp(linear_matrix->matrix[i]); float exp_res2 = exp(-1linear_matrix->matrix[i]); tanh_out->matrix[i] = (exp_res1 - exp_res2)/(exp_res1 + exp_res2); } tanh_out->shape[0] = linear_matrix->shape[0]; tanh_out->shape[1] = linear_matrix->shape[1]; return tanh_out; } dARRAY softmax_val(dARRAY * linear_matrix){ dARRAY * softmax_outf = NULL; dARRAY * exp_sub_max = exponentional(linear_matrix); dARRAY * div_factor = sum(exp_sub_max,0); softmax_outf = divison(exp_sub_max,div_factor); free2d(exp_sub_max); free2d(div_factor); exp_sub_max = div_factor = NULL; return softmax_outf; } dARRAY * calculate_val_test_acc(dARRAY * input_features,dARRAY * gnd_truth){ dARRAY * weight_input_res = NULL; dARRAY * output = NULL; dARRAY * activation_temp = NULL; Computation_Graph * temp = m->graph->next_layer; int layer=0; while(temp->type!=LOSS){ if(temp->prev_layer->type==INPUT){ weight_input_res = dot(temp->DENSE->weights, input_features); } else{ weight_input_res = dot(temp->DENSE->weights, activation_temp); } if(activation_temp!=NULL){ free2d(activation_temp); activation_temp = NULL; } dARRAY * Z = add(weight_input_res,temp->DENSE->bias); free2d(weight_input_res); weight_input_res = NULL; if(!strcasecmp(temp->DENSE->activation,"relu")){ activation_temp = relu_val(Z); free2d(Z); } else if(!strcasecmp(temp->DENSE->activation,"sigmoid")){ activation_temp = sigmoid_val(Z); free2d(Z); } else if(!strcasecmp(temp->DENSE->activation,"tanh")){ activation_temp = tanh_val(Z); free2d(Z); } else if(!strcasecmp(temp->DENSE->activation,"softmax")){ activation_temp = softmax_val(Z); free2d(Z); } else{ activation_temp = Z; } if(temp->next_layer->type==LOSS){ output = activation_temp; Z = NULL; } layer++; temp = temp->next_layer; Z = NULL; } if(m->predicting) return output; else{ float acc = calculate_accuracy(output,gnd_truth); if(m->testing) printf("Accuracy : %f\n",acc); free2d(output); output = NULL; dARRAY * return_val = (dARRAY)malloc(sizeof(dARRAY)); return_val->matrix = (float)calloc(1,sizeof(float)); return_val->matrix[0] = acc; return_val->shape[0] = 1; return_val->shape[1] = 1; if(m->testing) printf("Accuracy : %f\n",return_val->matrix[0]); return return_val; } } void dump_to_file(float * arr ,char * filename,char * mode){ struct stat st = {0}; if (stat("./bin/", &st) == -1) { mkdir("./bin/", 0700); } FILE * fp = NULL; fp = fopen(filename,mode); if(fp==NULL){ printf("\033[1;31mFile Error : \033[93mCould not open %s file!\033[0m\n",filename); exit(EXIT_FAILURE); } for(int i=0;i<m->num_iterm->num_mini_batches;i++) fprintf(fp,"%f ",arr[i]); fclose(fp); } void __fit__(){ int i = 1; int index = 0; int iterations=0; int flag_cost = 0; float sum_cost = m->train_costm->current_iter; float sum_train_acc = m->train_accuracym->current_iter; float sum_train_val_acc = m->cross_val_accuracym->current_iter; float * train_cost_arr = (float)calloc(m->num_iter==-1?1000000:m->num_iterm->num_mini_batches,sizeof(float)); float * train_acc_arr = (float)calloc(m->num_iter==-1?1000000:m->num_iterm->num_mini_batches,sizeof(float)); float * val_acc_arr = NULL; if(m->Y_cv!=NULL && m->x_cv!=NULL){ val_acc_arr = (float)calloc(m->num_iter==-1?1000000:m->num_iterm->num_mini_batches,sizeof(float)); } if(m->num_iter==-1){ iterations = i; } else iterations = m->num_iter; signal(SIGINT,early_stopping_handler); while(i<=iterations){ flag_cost=0; int * shuffle = permutation(m->num_mini_batches); for(int mini_batch=0;mini_batch<m->num_mini_batches;mini_batch++){ m->current_mini_batch = shuffle[mini_batch]; __forward__(); sum_cost += m->iter_cost; sum_train_acc += calculate_accuracy(m->output,m->y_train_mini_batch[m->current_mini_batch]); dARRAY * temp = NULL; if(m->Y_cv!=NULL && m->x_cv!=NULL){ temp = calculate_val_test_acc(m->x_cv,m->Y_cv); sum_train_val_acc += temp->matrix[0]; } if(m->print_cost){ m->train_cost = i==m->current_iter ? sum_cost/(float)i : sum_cost/(float)m->current_iter; m->train_accuracy = i==m->current_iter ? sum_train_acc/(float)i : sum_train_acc/(float)m->current_iter; train_cost_arr[index] = m->train_cost; train_acc_arr[index] = m->train_accuracy; if(m->Y_cv!=NULL && m->x_cv!=NULL){ m->cross_val_accuracy = i==m->current_iter ? sum_train_val_acc/(float)i : sum_train_val_acc/(float)m->current_iter; val_acc_arr[index] = m->cross_val_accuracy; } printf("\033[96m%d. %d. Cost : \033[0m%f ",i,mini_batch,m->train_cost); printf("\033[96m train_acc : \033[0m%f ",m->train_accuracy); if(m->Y_cv!=NULL && m->x_cv!=NULL){ printf("\033[96m val_acc : \033[0m%f",m->cross_val_accuracy); } printf("\n"); if(train_cost_arr[index]>=2.5train_cost_arr[0]){ printf("\033[96mCost is exploding hence exiting. Try reducing your learning rate and try again!\033[0m\n"); exit(EXIT_FAILURE); } index++; } __backward__(); if(!strcasecmp(m->optimizer,"adam")){ m->time_step += 1; adam(); } else if(!strcasecmp(m->optimizer,"rmsprop")){ RMSProp(); } else if(!strcasecmp(m->optimizer,"adagrad")){ adagrad(); } else if(!strcasecmp(m->optimizer,"sgd")){ SGD(); } else if(!strcasecmp(m->optimizer,"momentum")){ Momentum(); } else{ printf("Optimizer selected is not available\n"); exit(EXIT_FAILURE); } m->current_iter += 1; free(temp); temp = NULL; } if(m->ckpt_every!=-1 && (i%m->ckpt_every==0 \|\| (i==m->num_iter && m->num_iter!=-1))){ time_t rawtime; struct tm timeinfo; time ( &rawtime ); timeinfo = localtime ( &rawtime ); char buffer[1024]; snprintf(buffer,sizeof(buffer),"model_%d_%s.t7",i,asctime (timeinfo)); __save_model__(buffer); if(flag_cost==0){ dump_to_file(train_cost_arr,"./bin/cost.data","ab+"); dump_to_file(train_acc_arr,"./bin/train_acc.data","ab+"); if(m->x_cv!=NULL \|\| m->Y_cv!=NULL) dump_to_file(val_acc_arr,"./bin/val_acc.data","wb+"); flag_cost=1; } } if(!flag_cost){ dump_to_file(train_cost_arr,"./bin/cost.data","ab+"); dump_to_file(train_acc_arr,"./bin/train_acc.data","ab+"); if(m->x_cv!=NULL \|\| m->Y_cv!=NULL) dump_to_file(val_acc_arr,"./bin/val_acc.data","wb+"); } i++; if(m->num_iter==-1) iterations = i; free(shuffle); shuffle=NULL; } if(flag_cost==0){ dump_to_file(train_cost_arr,"./bin/cost.data","wb+"); dump_to_file(train_acc_arr,"./bin/train_acc.data","wb+"); if(m->x_cv!=NULL \|\| m->Y_cv!=NULL) dump_to_file(val_acc_arr,"./bin/val_acc.data","wb+"); flag_cost=1; } } /** * Function that is used to initiate model training. / void Fit(){ __fit__(); } void early_stopping_handler(){ printf("\nModel Saved!\n"); time_t rawtime; struct tm timeinfo; time ( &rawtime ); timeinfo = localtime ( &rawtime ); char buffer[1024]; snprintf(buffer,sizeof(buffer),"model_%s.t7",asctime (timeinfo)); __save_model__(buffer); Destroy_Model(); exit(EXIT_SUCCESS); } dARRAY * __predict__(dARRAY * input_feature,int verbose){ m->graph->INPUT->A = input_feature; m->predicting = 1; dARRAY * prediction = calculate_val_test_acc(input_feature,NULL); dARRAY * prediction_trans = transpose(prediction); if(verbose){ printf("["); for(int i = 0;i<prediction_trans->shape[0];i++){ for(int j=0;j<prediction_trans->shape[1];j++){ if(j<prediction_trans->shape[1]-1) printf("%f, ",prediction_trans->matrix[iprediction_trans->shape[1]+j]); else printf("%f",prediction_trans->matrix[iprediction_trans->shape[1]+j]); } } printf("]\n"); } free2d(prediction); m->predicting=0; return prediction_trans; } /*! Function that is used to test your model on arbitrary input_features. * @param input_feature Features to be passed to your model. * @param verbose Specifies whether or not to print the classification scores (verbose=1 or verbose=0) * @return Returns a dARRAY pointing to the output values of the model. / dARRAY Predict(dARRAY * input_feature,int verbose){ return __predict__(input_feature,verbose); } void __test__(){ if(m->x_test==NULL \|\| m->Y_test==NULL){ printf("\033[1;31mDataset Error : \033[93mTest set has not been provided.\033[0m\n"); return; } dARRAY * acc = calculate_val_test_acc(m->x_test,m->Y_test); printf("\033[96mTest Accuracy : \033[0m%f\n",acc->matrix[0]); free2d(acc); acc = NULL; } /** * Function that is used to test your model against your test set. / void Test(){ __test__(); } void __load_model__(char filename){ if(strstr(filename,".t7")==NULL){ printf("\033[1;31mFileExtension Error : \033[93mPlease use \".t7\" extension only. Other extensions are not supported currently.\033[0m\n"); exit(EXIT_FAILURE); } dARRAY weights[m->number_of_layers-1]; dARRAY biases[m->number_of_layers-1]; Computation_Graph * temp = m->graph->next_layer; for(int i=0;i<m->number_of_layers-1 && temp!=NULL;i++){ weights[i].matrix = (float)calloc(temp->DENSE->weights->shape[0]temp->DENSE->weights->shape[1],sizeof(float)); biases[i].matrix = (float)calloc(temp->DENSE->bias->shape[0]temp->DENSE->bias->shape[1],sizeof(float)); temp = temp->next_layer; } temp = m->graph->next_layer; FILE * fp = NULL; fp = fopen(filename,"rb"); if(fp==NULL){ printf("\033[1;31mFile Error : \033[93mCould not open %s file!\033[0m\n",filename); exit(EXIT_FAILURE); } for(int i=0;i<m->number_of_layers-1;i++){ if(temp==NULL) printf("null\n"); for(int j=0;j<temp->DENSE->weights->shape[0]temp->DENSE->weights->shape[1];j++){ fscanf(fp,"%f ",&weights[i].matrix[j]); } weights[i].shape[0] = temp->DENSE->weights->shape[0]; weights[i].shape[1] = temp->DENSE->weights->shape[1]; temp = temp->next_layer; } temp = m->graph->next_layer; for(int i=0;i<m->number_of_layers-1;i++){ for(int j=0;j<temp->DENSE->bias->shape[0]temp->DENSE->bias->shape[1];j++){ fscanf(fp,"%f ",&biases[i].matrix[j]); } biases[i].shape[0] = temp->DENSE->bias->shape[0]; biases[i].shape[1] = temp->DENSE->bias->shape[1]; temp = temp->next_layer; } fscanf(fp,"%f ",&m->train_cost); fscanf(fp,"%f ",&m->train_accuracy); fscanf(fp,"%f ",&m->cross_val_accuracy); fscanf(fp,"%d ",&m->current_iter); fclose(fp); temp = m->graph->next_layer; int index = 0; while(temp!=NULL){ if(temp->DENSE->weights!=NULL) free2d(temp->DENSE->weights); if(temp->DENSE->bias!=NULL) free2d(temp->DENSE->bias); temp->DENSE->weights = NULL; temp->DENSE->bias = NULL; temp->DENSE->weights = (dARRAY)malloc(sizeof(dARRAY)); temp->DENSE->weights->matrix = (float)calloc(weights[index].shape[0]weights[index].shape[1],sizeof(float)); temp->DENSE->bias = (dARRAY)malloc(sizeof(dARRAY)); temp->DENSE->bias->matrix = (float)calloc(biases[index].shape[0]biases[index].shape[1],sizeof(float)); temp->DENSE->weights->matrix = weights[index].matrix; temp->DENSE->weights->shape[0] = weights[index].shape[0]; temp->DENSE->weights->shape[1] = weights[index].shape[1]; temp->DENSE->bias->matrix = biases[index].matrix; temp->DENSE->bias->shape[0] = biases[index].shape[0]; temp->DENSE->bias->shape[1] = biases[index].shape[1]; index++; temp = temp->next_layer; } temp = NULL; } /*! Function that is used to load a model. * @param filename Name of the file where the model resides. / void Load_Model(char filename){ __load_model__(filename); } void __save_model__(char * filename){ if(strstr(filename,".t7")==NULL){ printf("\033[1;31mFileExtension Error : \033[93m%s uses a different extension. Please use \".t7\" extension only. Other extensions are not supported currently.\033[0m\n",filename); exit(EXIT_FAILURE); } FILE * fp = NULL; if( access(filename,F_OK)==0) { if(remove(filename)==0){} } fp = fopen(filename,"wb+"); if(fp==NULL){ printf("\033[1;31mFile Error : \033[93mCould not open %s file!\033[0m\n",filename); exit(EXIT_FAILURE); } Computation_Graph * temp = m->graph->next_layer; for(int i=0;i<m->number_of_layers-1;i++){ for(int j=0;j<temp->DENSE->weights->shape[0]temp->DENSE->weights->shape[1];j++) fprintf(fp,"%f ",temp->DENSE->weights->matrix[j]); temp = temp->next_layer; } temp = m->graph->next_layer; for(int i=0;i<m->number_of_layers-1;i++){ for(int j=0;j<temp->DENSE->bias->shape[0]temp->DENSE->bias->shape[1];j++) fprintf(fp,"%f ",temp->DENSE->bias->matrix[j]); temp = temp->next_layer; } fprintf(fp,"%f ",m->train_cost); fprintf(fp,"%f ",m->train_accuracy); fprintf(fp,"%f ",m->cross_val_accuracy); fprintf(fp,"%d ",m->current_iter-1); fclose(fp); fp = NULL; } /*! Function that is used to save a model. * @param filename Name of the file where the model will be saved. / void Save_Model(char filename){ __save_model__(filename); } /*! Function that is used to load X_train from file. * @param filename Name of the file where the X_train resides. * @param dims Dimensions of your training set (Features,Number of examples) / dARRAY load_x_train(char * filename,int * dims){ FILE * fp = NULL; fp = fopen(filename,"rb"); if(fp==NULL){ printf("\033[1;31mFile Error : \033[93mCould not open %s file!\033[0m\n",filename); exit(EXIT_FAILURE); } dARRAY * x_train = (dARRAY)malloc(sizeof(dARRAY)); x_train->matrix = (float)calloc(dims[0]dims[1],sizeof(float)); progressbar progress = progressbar_new("\033[1;32mLoading X_train :\033[0m",dims[1]); for(int j=0;j<dims[0]dims[1];j++){ fscanf(fp,"%f ",&x_train->matrix[j]); if(j%dims[0]==0) progressbar_inc(progress); } progressbar_finish(progress); x_train->shape[0] = dims[1]; x_train->shape[1] = dims[0]; dARRAY X_train = transpose(x_train); free2d(x_train); x_train = NULL; fclose(fp); return X_train; } /*! Function that is used to load y_train from file. * @param filename Name of the file where the y_train resides. * @param dims Dimensions of your training set (Number of classes,Number of examples) / dARRAY load_y_train(char * filename,int * dims){ FILE * fp = NULL; fp = fopen(filename,"rb"); if(fp==NULL){ printf("\033[1;31mFile Error : \033[93mCould not open %s file!\033[0m\n",filename); exit(EXIT_FAILURE); } dARRAY * Y_train = (dARRAY)malloc(sizeof(dARRAY)); Y_train->matrix = (float)calloc(dims[0]dims[1],sizeof(float)); progressbar progress = progressbar_new("\033[1;32mLoading y_train :\033[0m",dims[1]); for(int j=0;j<dims[0]dims[1];j++){ fscanf(fp,"%f ",&Y_train->matrix[j]); if(j%dims[0]==0) progressbar_inc(progress); } progressbar_finish(progress); Y_train->shape[0] = dims[1]; Y_train->shape[1] = dims[0]; dARRAY y_train = transpose(Y_train); free2d(Y_train); Y_train = NULL; fclose(fp); return y_train; } /*! Function that is used to load X_cv from file. * @param filename Name of the file where the X_cv resides. * @param dims Dimensions of your validation set (Features,Number of examples) / dARRAY load_x_cv(char * filename,int * dims){ FILE * fp = NULL; fp = fopen(filename,"rb"); if(fp==NULL){ printf("\033[1;31mFile Error : \033[93mCould not open %s file!\033[0m\n",filename); exit(EXIT_FAILURE); } dARRAY * x_cv = (dARRAY)malloc(sizeof(dARRAY)); x_cv->matrix = (float)calloc(dims[0]dims[1],sizeof(float)); progressbar progress = progressbar_new("\033[1;32mLoading X_cv :\033[0m",dims[1]); for(int j=0;j<dims[0]dims[1];j++){ fscanf(fp,"%f ",&x_cv->matrix[j]); if(j%dims[0]==0) progressbar_inc(progress); } progressbar_finish(progress); x_cv->shape[0] = dims[1]; x_cv->shape[1] = dims[0]; dARRAY X_CV = transpose(x_cv); free2d(x_cv); x_cv = NULL; fclose(fp); return X_CV; } /*! Function that is used to load y_cv from file. * @param filename Name of the file where the y_cv resides. * @param dims Dimensions of your validation set (Number of classes,Number of examples) / dARRAY load_y_cv(char * filename,int * dims){ FILE * fp = NULL; fp = fopen(filename,"rb"); if(fp==NULL){ printf("\033[1;31mFile Error : \033[93mCould not open %s file!\033[0m\n",filename); exit(EXIT_FAILURE); } dARRAY * Y_cv = (dARRAY)malloc(sizeof(dARRAY)); Y_cv->matrix = (float)calloc(dims[0]dims[1],sizeof(float)); progressbar progress = progressbar_new("\033[1;32mLoading y_cv :\033[0m",dims[1]); for(int j=0;j<dims[0]dims[1];j++){ fscanf(fp,"%f ",&Y_cv->matrix[j]); if(j%dims[0]==0) progressbar_inc(progress); } progressbar_finish(progress); Y_cv->shape[0] = dims[1]; Y_cv->shape[1] = dims[0]; dARRAY y_cv = transpose(Y_cv); free2d(Y_cv); Y_cv = NULL; fclose(fp); return y_cv; } /*! Function that is used to load X_test from file. * @param filename Name of the file where the X_test resides. * @param dims Dimensions of your test set (Features,Number of examples) / dARRAY load_x_test(char * filename,int * dims){ FILE * fp = NULL; fp = fopen(filename,"rb"); if(fp==NULL){ printf("\033[1;31mFile Error : \033[93m Could not open %s file!\033[0m\n",filename); exit(EXIT_FAILURE); } dARRAY * x_test_temp = (dARRAY)malloc(sizeof(dARRAY)); x_test_temp->matrix = (float)calloc(dims[0]dims[1],sizeof(float)); progressbar progress = progressbar_new("\033[1;32mLoading X_test :\033[0m",dims[1]); for(int j=0;j<dims[0]dims[1];j++){ fscanf(fp,"%f ",&x_test_temp->matrix[j]); if(j%dims[0]==0) progressbar_inc(progress); } progressbar_finish(progress); x_test_temp->shape[0] = dims[1]; x_test_temp->shape[1] = dims[0]; dARRAY x_test = transpose(x_test_temp); free2d(x_test_temp); x_test_temp = NULL; fclose(fp); return x_test; } /*! Function that is used to load y_test from file. * @param filename Name of the file where the y_test resides. * @param dims Dimensions of your test set (Number of classes,Number of examples) / dARRAY load_y_test(char * filename,int * dims){ FILE * fp = NULL; fp = fopen(filename,"rb"); if(fp==NULL){ printf("\033[1;31mFile Error : \033[93mCould not open %s file!\033[0m\n",filename); exit(EXIT_FAILURE); } dARRAY * Y_test = (dARRAY)malloc(sizeof(dARRAY)); Y_test->matrix = (float)calloc(dims[0]dims[1],sizeof(float)); progressbar progress = progressbar_new("\033[1;32mLoading y_test :\033[0m",dims[1]); for(int j=0;j<dims[0]dims[1];j++){ fscanf(fp,"%f ",&Y_test->matrix[j]); if(j%dims[0]==0) progressbar_inc(progress); } progressbar_finish(progress); Y_test->shape[0] = dims[1]; Y_test->shape[1] = dims[0]; dARRAY y_test = transpose(Y_test); free2d(Y_test); Y_test = NULL; fclose(fp); return y_test; } dARRAY * load_image(char * filename,int * dims){ FILE * fp = NULL; fp = fopen(filename,"rb"); if(fp==NULL){ printf("\033[1;31mFile Error : \033[93m Could not open %s file!\033[0m\n",filename); exit(EXIT_FAILURE); } dARRAY * image = (dARRAY)malloc(sizeof(dARRAY)); image->matrix = (float)calloc(dims[0]dims[1],sizeof(float)); for(int j=0;j<dims[0]dims[1];j++){ fscanf(fp,"%f ",&image->matrix[j]); } image->shape[0] = dims[0]; image->shape[1] = dims[1]; fclose(fp); fp=NULL; return image; } void create_mini_batches(){ if(m->x_train->shape[1]!=m->Y_train->shape[1]){ printf("\033[1;31mShape Error : \033[93mNumber of examples in X_train[%d,\033[1;31m%d\033[93m] != Y_train[%d,\033[1;31m%d\033[93m]!\033[0m\n",m->x_train->shape[0],m->x_train->shape[1],m->Y_train->shape[0],m->Y_train->shape[1]); exit(EXIT_FAILURE); } if(m->mini_batch_size>m->Y_train->shape[1]){ printf("\033[1;31mMini Batch Error : \033[93mNumber of examples in train_set is less than the mini_batch_size specified!\033[1;31m [examples:%d < mini_batch_size: %d]\033[93m\nPlease make sure that the mini batch size is less than or equal to the number of examples in train_set.\033[0m\n",m->x_train->shape[1],m->mini_batch_size); exit(EXIT_FAILURE); } if(m->x_train->shape[1]==0 \|\| m->Y_train->shape[1]==0){ printf("\033[1;31mShape Error : \033[93mDataset Empty!\033m[0m\n"); exit(EXIT_FAILURE); } int num_mini_batches = (m->x_train->shape[1]%m->mini_batch_size==0)?\ m->x_train->shape[1]/m->mini_batch_size :\ (int)floor(m->x_train->shape[1]/m->mini_batch_size) + 1; m->x_train_mini_batch = (dARRAY*)malloc(sizeof(dARRAY)num_mini_batches); m->y_train_mini_batch = (dARRAY)malloc(sizeof(dARRAY)num_mini_batches); m->num_mini_batches = num_mini_batches; int remaining_mem_block = (m->x_train->shape[1]-((num_mini_batches-1)m->mini_batch_size)); for(int i=0;i<num_mini_batches;i++){ m->x_train_mini_batch[i] = NULL; m->y_train_mini_batch[i] = NULL; } dARRAY * X_train = transpose(m->x_train); dARRAY * Y_train = transpose(m->Y_train); free2d(m->x_train); free2d(m->Y_train); m->x_train = NULL; m->Y_train = NULL; progressbar * progress = progressbar_new("\033[1;32mCreating Mini Batches :\033[0m",num_mini_batches2); for(int i=0;i<num_mini_batches;i++){ int row = 0; dARRAY temp = (dARRAY)malloc(sizeof(dARRAY)); temp->matrix = (float)calloc(m->mini_batch_sizeX_train->shape[1],sizeof(float)); if(i<num_mini_batches-1 \|\| num_mini_batches==1){ temp->shape[0] = m->mini_batch_size; temp->shape[1] = X_train->shape[1]; for(int j=im->mini_batch_size;j<(i+1)m->mini_batch_size && j<X_train->shape[0];j++){ for(int k = 0;k<X_train->shape[1];k++){ temp->matrix[rowX_train->shape[1]+k] = X_train->matrix[jX_train->shape[1]+k]; } row++; } } else{ temp->shape[0] = remaining_mem_block; temp->shape[1] = X_train->shape[1]; for(int j=im->mini_batch_size;j<X_train->shape[0] && j<X_train->shape[0];j++){ for(int k = 0;k<X_train->shape[1];k++){ temp->matrix[rowX_train->shape[1]+k] = X_train->matrix[jX_train->shape[1]+k]; } row++; } } m->x_train_mini_batch[i] = transpose(temp); free2d(temp); temp = NULL; progressbar_inc(progress); } for(int i=0;i<num_mini_batches;i++){ int row = 0; dARRAY * temp = (dARRAY)malloc(sizeof(dARRAY)); temp->matrix = (float)calloc(m->mini_batch_sizeY_train->shape[1],sizeof(float)); if(i<num_mini_batches-1 \|\| num_mini_batches==1){ temp->shape[0] = m->mini_batch_size; temp->shape[1] = Y_train->shape[1]; for(int j=im->mini_batch_size;j<(i+1)m->mini_batch_size && j<Y_train->shape[0];j++){ for(int k = 0;k<Y_train->shape[1];k++){ temp->matrix[rowY_train->shape[1]+k] = Y_train->matrix[jY_train->shape[1]+k]; } row++; } } else{ temp->shape[0] = remaining_mem_block; temp->shape[1] = Y_train->shape[1]; for(int j=im->mini_batch_size;j<Y_train->shape[0] && j<Y_train->shape[0];j++){ for(int k = 0;k<Y_train->shape[1];k++){ temp->matrix[rowY_train->shape[1]+k] = Y_train->matrix[jY_train->shape[1]+k]; } row++; } } m->y_train_mini_batch[i] = transpose(temp); free2d(temp); temp = NULL; progressbar_inc(progress); } progressbar_finish(progress); } void __summary__(){} long int get_total_params(){ long int total_params = 0; Computation_Graph * temp = m->graph->next_layer; while(temp!=NULL){ if(temp->type==DENSE){ total_params+= temp->DENSE->weights->shape[0]temp->DENSE->weights->shape[1]; total_params+= temp->DENSE->bias->shape[0]temp->DENSE->bias->shape[1]; } temp = temp->next_layer; } return total_params; } void (Create_Model)(){ m = NULL; m = (__Model__)malloc(sizeof(__Model__)); m->graph = NULL; m->graph = NULL; m->current_layer = NULL; m->number_of_layers = 0; m->input_size = 0; m->output_size = 0; } void segfault_handler(){ exit(EXIT_SUCCESS); } void (Destroy_Model)(){ signal(SIGSEGV,segfault_handler); destroy_Graph(m->graph); if(m->x_cv!=NULL) free2d(m->x_cv); if(m->Y_cv!=NULL) free2d(m->Y_cv); if(m->x_test!=NULL) free2d(m->x_test); if(m->Y_test!=NULL) free2d(m->Y_test); for(int i=0;i<m->number_of_layers;i++){ if(m->m_t_dW[i] != NULL) free2d(m->m_t_dW[i]); if(m->m_t_db[i] != NULL) free2d(m->m_t_db[i]); if(m->v_t_dW[i] != NULL) free2d(m->v_t_dW[i]); if(m->v_t_db[i] != NULL) free2d(m->v_t_db[i]); if(m->cache_dW[i] != NULL) free2d(m->cache_dW[i]); if(m->cache_db[i] != NULL) free2d(m->cache_db[i]); m->m_t_dW[i] = NULL; m->v_t_dW[i] = NULL; m->m_t_db[i] = NULL; m->v_t_db[i] = NULL; m->cache_dW[i] = NULL; m->cache_db[i] = NULL; } for(int i=0;i<m->num_mini_batches;i++){ if(m->x_train_mini_batch[i]!=NULL) free2d(m->x_train_mini_batch[i]); if(m->y_train_mini_batch[i]!=NULL) free2d(m->y_train_mini_batch[i]); m->x_train_mini_batch[i] = NULL; m->y_train_mini_batch[i] = NULL; } free(m->x_train_mini_batch); free(m->y_train_mini_batch); m->x_train_mini_batch = NULL; m->y_train_mini_batch = NULL; m->x_train = NULL; m->Y_train = NULL; m->x_cv = NULL; m->x_test = NULL; m->Y_test = NULL; m->Y_cv = NULL; m->output = NULL; free(m); m = NULL; } void dump_image(dARRAY images,char * filename){ FILE * fp = NULL; fp = fopen(filename,"a+"); if(fp==NULL){ exit(EXIT_FAILURE); } else{ dARRAY * temp = transpose(images); for(int i=0;i<temp->shape[0];i++){ for(int j=0;j<temp->shape[1];j++){ fprintf(fp,"%lf ",temp->matrix[i*temp->shape[1]+j]); } } free2d(temp); temp = NULL; } } void (Model)(Model_args model_args){ get_safe_nn_threads(); if(model_args.X_train==NULL \|\| model_args.y_train==NULL){ printf("\033[1;31mDataset Error : \033[93mNo dataset passed to the model constructor.\033[0m\n"); exit(EXIT_FAILURE); } m->x_train = model_args.X_train; m->x_test = model_args.X_test; m->x_cv = model_args.X_cv; m->Y_train = model_args.y_train; m->Y_test = model_args.y_test; m->Y_cv = model_args.y_cv; m->ckpt_every = model_args.checkpoint_every; //initialize regualrization hyperparameters m->loss = model_args.loss; m->lambda = model_args.weight_decay; m->regularization = model_args.regularization; m->num_of_training_examples = m->x_train->shape[1]; //initialize hyperparameters for various optimizers m->optimizer = model_args.optimizer; // Optimizer choice m->learning_rate = model_args.lr; // hyperparameter for step size for optimization algorithm m->time_step = 0; // timestep - required for Adam update, for bias correction m->beta = model_args.beta; //hyperparameter - used for RMSProp, Denotes Decay_rate for weighted average m->beta1 = model_args.beta1; // hyperparameter - used for Adam and RMSProp, Decay rate for estimation of first moment m->beta2 = model_args.beta2; // hyperparameter - used for Adam, Decay rate used for estimation of second moment. m->epsilon = 1e-8; // small value to prevent divison by zero during parameter updates for(int i=0;i<m->number_of_layers;i++){ m->m_t_dW[i] = NULL; // for Adam and RMSProp - to calculate first moment m->v_t_dW[i] = NULL; // for Adam - to calculate second moment m->m_t_db[i] = NULL; m->v_t_db[i] = NULL; m->cache_dW[i] = NULL; // for AdaGrad m->cache_db[i] = NULL; } m->mini_batch_size = model_args.batch_size; m->num_iter = model_args.epochs; create_mini_batches(); if(!strcasecmp(m->loss,"cross_entropy_loss")) cross_entropy_loss(); if(!strcasecmp(m->loss,"MSELoss")) MSELoss(); m->input_size = m->x_train_mini_batch[0]->shape[0]; m->print_cost = model_args.print_cost; m->init = __init__; m->forward = __forward__; m->backward = __backward__; m->load_model = __load_model__; m->save_model = __save_model__; m->fit = __fit__; // m->predict = __predict__; m->summary = __summary__; m->test = __test__; m->init(); m->total_parameters = get_total_params(); }
v_p_strategy.h	// // Project Name: KratosPFEMFluidDynamicsApplication $ // Last modified by: $Author: AFranci $ // Date: $Date: January 2016 $ // Revision: $Revision: 0.0 $ // // #ifndef KRATOS_V_P_STRATEGY_H #define KRATOS_V_P_STRATEGY_H #include "includes/define.h" #include "includes/model_part.h" #include "includes/deprecated_variables.h" #include "utilities/openmp_utils.h" #include "processes/process.h" #include "solving_strategies/schemes/scheme.h" #include "solving_strategies/strategies/solving_strategy.h" #include "custom_utilities/mesher_utilities.hpp" #include "custom_utilities/boundary_normals_calculation_utilities.hpp" #include "custom_utilities/solver_settings.h" #include "pfem_fluid_dynamics_application_variables.h" #include <stdio.h> #include <math.h> namespace Kratos { ///@addtogroup PFEMFluidDynamicsApplication ///@{ ///@name Kratos Globals ///@{ ///@} ///@name Type Definitions ///@{ ///@} ///@name Enum's ///@{ ///@} ///@name Functions ///@{ ///@} ///@name Kratos Classes ///@{ template <class TSparseSpace, class TDenseSpace, class TLinearSolver> class VPStrategy : public SolvingStrategy<TSparseSpace, TDenseSpace> { public: ///@name Type Definitions ///@{ KRATOS_CLASS_POINTER_DEFINITION(VPStrategy); typedef SolvingStrategy<TSparseSpace, TDenseSpace> BaseType; typedef TwoStepVPSolverSettings<TSparseSpace, TDenseSpace, TLinearSolver> SolverSettingsType; ///@} ///@name Life Cycle ///@{ VPStrategy(ModelPart &rModelPart, SolverSettingsType &rSolverConfig) : BaseType(rModelPart) { std::cout << "VPStrategy INITIALIZE STRATEGY" << std::endl; InitializeStrategy(rSolverConfig); } VPStrategy(ModelPart &rModelPart, typename TLinearSolver::Pointer pVelocityLinearSolver, typename TLinearSolver::Pointer pPressureLinearSolver, bool ReformDofSet = true, unsigned int DomainSize = 2) : BaseType(rModelPart) { KRATOS_TRY; KRATOS_CATCH(""); } /// Destructor. virtual ~VPStrategy() {} virtual int Check() override { return false; } virtual bool SolveSolutionStep() override { return false; } virtual void FinalizeSolutionStep() override {} virtual void InitializeSolutionStep() override {} void UpdateTopology(ModelPart &rModelPart, unsigned int echoLevel) { KRATOS_TRY; this->CalculateDisplacementsAndPorosity(); BaseType::MoveMesh(); KRATOS_CATCH(""); } void SetBlockedAndIsolatedFlags() { KRATOS_TRY; ModelPart &rModelPart = BaseType::GetModelPart(); const unsigned int dimension = rModelPart.ElementsBegin()->GetGeometry().WorkingSpaceDimension(); #pragma omp parallel { ModelPart::ElementIterator ElemBegin; ModelPart::ElementIterator ElemEnd; OpenMPUtils::PartitionedIterators(rModelPart.Elements(), ElemBegin, ElemEnd); for (ModelPart::ElementIterator itElem = ElemBegin; itElem != ElemEnd; ++itElem) { unsigned int numNodes = itElem->GetGeometry().size(); std::vector<array_1d<double, 3>> nodesCoordinates; nodesCoordinates.resize(numNodes); (itElem)->Set(BLOCKED, false); (itElem)->Set(ISOLATED, false); unsigned int freeSurfaceNodes = 0; unsigned int freeSurfaceRigidNodes = 0; unsigned int rigidNodes = 0; unsigned int isolatedNodes = 0; for (unsigned int i = 0; i < numNodes; i++) { if (itElem->GetGeometry()[i].Is(FREE_SURFACE)) { freeSurfaceNodes++; if (itElem->GetGeometry()[i].Is(RIGID)) { freeSurfaceRigidNodes++; } } else if (itElem->GetGeometry()[i].Is(RIGID)) { rigidNodes++; } nodesCoordinates[i] = itElem->GetGeometry()[i].Coordinates(); ElementWeakPtrVectorType &neighb_elems = itElem->GetGeometry()[i].GetValue(NEIGHBOUR_ELEMENTS); if (neighb_elems.size() == 1) { isolatedNodes++; } } if (dimension == 3) { double a1 = 0; //slope x for plane on the first triangular face of the tetrahedra (nodes A,B,C) double b1 = 0; //slope y for plane on the first triangular face of the tetrahedra (nodes A,B,C) double c1 = 0; //slope z for plane on the first triangular face of the tetrahedra (nodes A,B,C) a1 = (nodesCoordinates[1][1] - nodesCoordinates[0][1]) * (nodesCoordinates[2][2] - nodesCoordinates[0][2]) - (nodesCoordinates[2][1] - nodesCoordinates[0][1]) * (nodesCoordinates[1][2] - nodesCoordinates[0][2]); b1 = (nodesCoordinates[1][2] - nodesCoordinates[0][2]) * (nodesCoordinates[2][0] - nodesCoordinates[0][0]) - (nodesCoordinates[2][2] - nodesCoordinates[0][2]) * (nodesCoordinates[1][0] - nodesCoordinates[0][0]); c1 = (nodesCoordinates[1][0] - nodesCoordinates[0][0]) * (nodesCoordinates[2][1] - nodesCoordinates[0][1]) - (nodesCoordinates[2][0] - nodesCoordinates[0][0]) * (nodesCoordinates[1][1] - nodesCoordinates[0][1]); double a2 = 0; //slope x for plane on the second triangular face of the tetrahedra (nodes A,B,D) double b2 = 0; //slope y for plane on the second triangular face of the tetrahedra (nodes A,B,D) double c2 = 0; //slope z for plane on the second triangular face of the tetrahedra (nodes A,B,D) a2 = (nodesCoordinates[1][1] - nodesCoordinates[0][1]) * (nodesCoordinates[3][2] - nodesCoordinates[0][2]) - (nodesCoordinates[3][1] - nodesCoordinates[0][1]) * (nodesCoordinates[1][2] - nodesCoordinates[0][2]); b2 = (nodesCoordinates[1][2] - nodesCoordinates[0][2]) * (nodesCoordinates[3][0] - nodesCoordinates[0][0]) - (nodesCoordinates[3][2] - nodesCoordinates[0][2]) * (nodesCoordinates[1][0] - nodesCoordinates[0][0]); c2 = (nodesCoordinates[1][0] - nodesCoordinates[0][0]) * (nodesCoordinates[3][1] - nodesCoordinates[0][1]) - (nodesCoordinates[3][0] - nodesCoordinates[0][0]) * (nodesCoordinates[1][1] - nodesCoordinates[0][1]); double a3 = 0; //slope x for plane on the third triangular face of the tetrahedra (nodes B,C,D) double b3 = 0; //slope y for plane on the third triangular face of the tetrahedra (nodes B,C,D) double c3 = 0; //slope z for plane on the third triangular face of the tetrahedra (nodes B,C,D) a3 = (nodesCoordinates[1][1] - nodesCoordinates[2][1]) * (nodesCoordinates[3][2] - nodesCoordinates[2][2]) - (nodesCoordinates[3][1] - nodesCoordinates[2][1]) * (nodesCoordinates[1][2] - nodesCoordinates[2][2]); b3 = (nodesCoordinates[1][2] - nodesCoordinates[2][2]) * (nodesCoordinates[3][0] - nodesCoordinates[2][0]) - (nodesCoordinates[3][2] - nodesCoordinates[2][2]) * (nodesCoordinates[1][0] - nodesCoordinates[2][0]); c3 = (nodesCoordinates[1][0] - nodesCoordinates[2][0]) * (nodesCoordinates[3][1] - nodesCoordinates[2][1]) - (nodesCoordinates[3][0] - nodesCoordinates[2][0]) * (nodesCoordinates[1][1] - nodesCoordinates[2][1]); double a4 = 0; //slope x for plane on the fourth triangular face of the tetrahedra (nodes A,C,D) double b4 = 0; //slope y for plane on the fourth triangular face of the tetrahedra (nodes A,C,D) double c4 = 0; //slope z for plane on the fourth triangular face of the tetrahedra (nodes A,C,D) a4 = (nodesCoordinates[0][1] - nodesCoordinates[2][1]) * (nodesCoordinates[3][2] - nodesCoordinates[2][2]) - (nodesCoordinates[3][1] - nodesCoordinates[2][1]) * (nodesCoordinates[0][2] - nodesCoordinates[2][2]); b4 = (nodesCoordinates[0][2] - nodesCoordinates[2][2]) * (nodesCoordinates[3][0] - nodesCoordinates[2][0]) - (nodesCoordinates[3][2] - nodesCoordinates[2][2]) * (nodesCoordinates[0][0] - nodesCoordinates[2][0]); c4 = (nodesCoordinates[0][0] - nodesCoordinates[2][0]) * (nodesCoordinates[3][1] - nodesCoordinates[2][1]) - (nodesCoordinates[3][0] - nodesCoordinates[2][0]) * (nodesCoordinates[0][1] - nodesCoordinates[2][1]); double cosAngle12 = (a1 * a2 + b1 * b2 + c1 * c2) / (sqrt(pow(a1, 2) + pow(b1, 2) + pow(c1, 2)) * sqrt(pow(a2, 2) + pow(b2, 2) + pow(c2, 2))); double cosAngle13 = (a1 * a3 + b1 * b3 + c1 * c3) / (sqrt(pow(a1, 2) + pow(b1, 2) + pow(c1, 2)) * sqrt(pow(a3, 2) + pow(b3, 2) + pow(c3, 2))); double cosAngle14 = (a1 * a4 + b1 * b4 + c1 * c4) / (sqrt(pow(a1, 2) + pow(b1, 2) + pow(c1, 2)) * sqrt(pow(a4, 2) + pow(b4, 2) + pow(c4, 2))); double cosAngle23 = (a3 * a2 + b3 * b2 + c3 * c2) / (sqrt(pow(a3, 2) + pow(b3, 2) + pow(c3, 2)) * sqrt(pow(a2, 2) + pow(b2, 2) + pow(c2, 2))); double cosAngle24 = (a4 * a2 + b4 * b2 + c4 * c2) / (sqrt(pow(a4, 2) + pow(b4, 2) + pow(c4, 2)) * sqrt(pow(a2, 2) + pow(b2, 2) + pow(c2, 2))); double cosAngle34 = (a4 * a3 + b4 * b3 + c4 * c3) / (sqrt(pow(a4, 2) + pow(b4, 2) + pow(c4, 2)) * sqrt(pow(a3, 2) + pow(b3, 2) + pow(c3, 2))); if ((fabs(cosAngle12) > 0.99 \|\| fabs(cosAngle13) > 0.99 \|\| fabs(cosAngle14) > 0.99 \|\| fabs(cosAngle23) > 0.99 \|\| fabs(cosAngle24) > 0.99 \|\| fabs(cosAngle34) > 0.99) && (freeSurfaceNodes == numNodes) && isolatedNodes > 1) { (itElem)->Set(BLOCKED, true); // std::cout << "in the strategy BLOCKED ELEMENT: " << (itElem)->Id() << std::endl; } else if ((fabs(cosAngle12) > 0.995 \|\| fabs(cosAngle13) > 0.995 \|\| fabs(cosAngle14) > 0.995 \|\| fabs(cosAngle23) > 0.995 \|\| fabs(cosAngle24) > 0.995 \|\| fabs(cosAngle34) > 0.995) && (freeSurfaceNodes == numNodes) && isolatedNodes == 1) { (itElem)->Set(BLOCKED, true); // std::cout << "in the strategy BLOCKED ELEMENT: " << (itElem)->Id() << std::endl; } else if ((fabs(cosAngle12) > 0.999 \|\| fabs(cosAngle13) > 0.999 \|\| fabs(cosAngle14) > 0.999 \|\| fabs(cosAngle23) > 0.999 \|\| fabs(cosAngle24) > 0.999 \|\| fabs(cosAngle34) > 0.999) && (freeSurfaceNodes == numNodes)) { (itElem)->Set(BLOCKED, true); // std::cout << "in the strategy BLOCKED ELEMENT: " << (itElem)->Id() << std::endl; } } if (freeSurfaceNodes == numNodes && rigidNodes == 0 && isolatedNodes >= (numNodes - 1)) { (itElem)->Set(ISOLATED, true); (itElem)->Set(BLOCKED, false); } } } KRATOS_CATCH(""); } void CalculatePressureVelocity() { ModelPart &rModelPart = BaseType::GetModelPart(); ProcessInfo &rCurrentProcessInfo = rModelPart.GetProcessInfo(); const double timeInterval = rCurrentProcessInfo[DELTA_TIME]; unsigned int timeStep = rCurrentProcessInfo[STEP]; for (ModelPart::NodeIterator i = rModelPart.NodesBegin(); i != rModelPart.NodesEnd(); ++i) { if (timeStep == 1) { (i)->FastGetSolutionStepValue(PRESSURE_VELOCITY, 0) = 0; (i)->FastGetSolutionStepValue(PRESSURE_VELOCITY, 1) = 0; } else { double &CurrentPressure = (i)->FastGetSolutionStepValue(PRESSURE, 0); double &PreviousPressure = (i)->FastGetSolutionStepValue(PRESSURE, 1); double &CurrentPressureVelocity = (i)->FastGetSolutionStepValue(PRESSURE_VELOCITY, 0); CurrentPressureVelocity = (CurrentPressure - PreviousPressure) / timeInterval; } } } void CalculatePressureAcceleration() { ModelPart &rModelPart = BaseType::GetModelPart(); ProcessInfo &rCurrentProcessInfo = rModelPart.GetProcessInfo(); const double timeInterval = rCurrentProcessInfo[DELTA_TIME]; unsigned int timeStep = rCurrentProcessInfo[STEP]; for (ModelPart::NodeIterator i = rModelPart.NodesBegin(); i != rModelPart.NodesEnd(); ++i) { if (timeStep == 1) { (i)->FastGetSolutionStepValue(PRESSURE_ACCELERATION, 0) = 0; (i)->FastGetSolutionStepValue(PRESSURE_ACCELERATION, 1) = 0; } else { double &CurrentPressureVelocity = (i)->FastGetSolutionStepValue(PRESSURE_VELOCITY, 0); double &PreviousPressureVelocity = (i)->FastGetSolutionStepValue(PRESSURE_VELOCITY, 1); double &CurrentPressureAcceleration = (i)->FastGetSolutionStepValue(PRESSURE_ACCELERATION, 0); CurrentPressureAcceleration = (CurrentPressureVelocity - PreviousPressureVelocity) / timeInterval; } } } virtual void CalculateTemporalVariables() { ModelPart &rModelPart = BaseType::GetModelPart(); ProcessInfo &rCurrentProcessInfo = rModelPart.GetProcessInfo(); for (ModelPart::NodeIterator i = rModelPart.NodesBegin(); i != rModelPart.NodesEnd(); ++i) { array_1d<double, 3> &CurrentVelocity = (i)->FastGetSolutionStepValue(VELOCITY, 0); array_1d<double, 3> &PreviousVelocity = (i)->FastGetSolutionStepValue(VELOCITY, 1); array_1d<double, 3> &CurrentAcceleration = (i)->FastGetSolutionStepValue(ACCELERATION, 0); array_1d<double, 3> &PreviousAcceleration = (i)->FastGetSolutionStepValue(ACCELERATION, 1); /* if((i)->IsNot(ISOLATED) \|\| (i)->Is(SOLID)){ / if ((i)->IsNot(ISOLATED) && ((i)->IsNot(RIGID) \|\| (i)->Is(SOLID))) { UpdateAccelerations(CurrentAcceleration, CurrentVelocity, PreviousAcceleration, PreviousVelocity); } else if ((i)->Is(RIGID)) { array_1d<double, 3> Zeros(3, 0.0); (i)->FastGetSolutionStepValue(ACCELERATION, 0) = Zeros; (i)->FastGetSolutionStepValue(ACCELERATION, 1) = Zeros; } else { (i)->FastGetSolutionStepValue(PRESSURE, 0) = 0.0; (i)->FastGetSolutionStepValue(PRESSURE, 1) = 0.0; (i)->FastGetSolutionStepValue(PRESSURE_VELOCITY, 0) = 0.0; (i)->FastGetSolutionStepValue(PRESSURE_VELOCITY, 1) = 0.0; (i)->FastGetSolutionStepValue(PRESSURE_ACCELERATION, 0) = 0.0; (i)->FastGetSolutionStepValue(PRESSURE_ACCELERATION, 1) = 0.0; if ((i)->SolutionStepsDataHas(VOLUME_ACCELERATION)) { array_1d<double, 3> &VolumeAcceleration = (i)->FastGetSolutionStepValue(VOLUME_ACCELERATION); (i)->FastGetSolutionStepValue(ACCELERATION, 0) = VolumeAcceleration; (i)->FastGetSolutionStepValue(VELOCITY, 0) += VolumeAcceleration rCurrentProcessInfo[DELTA_TIME]; } } const double timeInterval = rCurrentProcessInfo[DELTA_TIME]; unsigned int timeStep = rCurrentProcessInfo[STEP]; if (timeStep == 1) { (i)->FastGetSolutionStepValue(PRESSURE_VELOCITY, 0) = 0; (i)->FastGetSolutionStepValue(PRESSURE_VELOCITY, 1) = 0; (i)->FastGetSolutionStepValue(PRESSURE_ACCELERATION, 0) = 0; (i)->FastGetSolutionStepValue(PRESSURE_ACCELERATION, 1) = 0; } else { double &CurrentPressure = (i)->FastGetSolutionStepValue(PRESSURE, 0); double &PreviousPressure = (i)->FastGetSolutionStepValue(PRESSURE, 1); double &CurrentPressureVelocity = (i)->FastGetSolutionStepValue(PRESSURE_VELOCITY, 0); double &CurrentPressureAcceleration = (i)->FastGetSolutionStepValue(PRESSURE_ACCELERATION, 0); CurrentPressureAcceleration = CurrentPressureVelocity / timeInterval; CurrentPressureVelocity = (CurrentPressure - PreviousPressure) / timeInterval; CurrentPressureAcceleration += -CurrentPressureVelocity / timeInterval; } } } void CalculateAccelerations() { ModelPart &rModelPart = BaseType::GetModelPart(); ProcessInfo &rCurrentProcessInfo = rModelPart.GetProcessInfo(); for (ModelPart::NodeIterator i = rModelPart.NodesBegin(); i != rModelPart.NodesEnd(); ++i) { array_1d<double, 3> &CurrentVelocity = (i)->FastGetSolutionStepValue(VELOCITY, 0); array_1d<double, 3> &PreviousVelocity = (i)->FastGetSolutionStepValue(VELOCITY, 1); array_1d<double, 3> &CurrentAcceleration = (i)->FastGetSolutionStepValue(ACCELERATION, 0); array_1d<double, 3> &PreviousAcceleration = (i)->FastGetSolutionStepValue(ACCELERATION, 1); /* if((i)->IsNot(ISOLATED) \|\| (i)->Is(SOLID)){ / if ((i)->IsNot(ISOLATED) && ((i)->IsNot(RIGID) \|\| (i)->Is(SOLID))) { UpdateAccelerations(CurrentAcceleration, CurrentVelocity, PreviousAcceleration, PreviousVelocity); } else if ((i)->Is(RIGID)) { array_1d<double, 3> Zeros(3, 0.0); (i)->FastGetSolutionStepValue(ACCELERATION, 0) = Zeros; (i)->FastGetSolutionStepValue(ACCELERATION, 1) = Zeros; } else { (i)->FastGetSolutionStepValue(PRESSURE, 0) = 0.0; (i)->FastGetSolutionStepValue(PRESSURE, 1) = 0.0; (i)->FastGetSolutionStepValue(PRESSURE_VELOCITY, 0) = 0.0; (i)->FastGetSolutionStepValue(PRESSURE_VELOCITY, 1) = 0.0; (i)->FastGetSolutionStepValue(PRESSURE_ACCELERATION, 0) = 0.0; (i)->FastGetSolutionStepValue(PRESSURE_ACCELERATION, 1) = 0.0; if ((i)->SolutionStepsDataHas(VOLUME_ACCELERATION)) { array_1d<double, 3> &VolumeAcceleration = (i)->FastGetSolutionStepValue(VOLUME_ACCELERATION); (i)->FastGetSolutionStepValue(ACCELERATION, 0) = VolumeAcceleration; (i)->FastGetSolutionStepValue(VELOCITY, 0) += VolumeAcceleration rCurrentProcessInfo[DELTA_TIME]; } } } } inline void UpdateAccelerations(array_1d<double, 3> &CurrentAcceleration, const array_1d<double, 3> &CurrentVelocity, array_1d<double, 3> &PreviousAcceleration, const array_1d<double, 3> &PreviousVelocity) { ModelPart &rModelPart = BaseType::GetModelPart(); ProcessInfo &rCurrentProcessInfo = rModelPart.GetProcessInfo(); double Dt = rCurrentProcessInfo[DELTA_TIME]; noalias(CurrentAcceleration) = 2.0 * (CurrentVelocity - PreviousVelocity) / Dt - PreviousAcceleration; } virtual void CalculateDisplacementsAndPorosity() { ModelPart &rModelPart = BaseType::GetModelPart(); ProcessInfo &rCurrentProcessInfo = rModelPart.GetProcessInfo(); const double TimeStep = rCurrentProcessInfo[DELTA_TIME]; for (ModelPart::NodeIterator i = rModelPart.NodesBegin(); i != rModelPart.NodesEnd(); ++i) { array_1d<double, 3> &CurrentVelocity = (i)->FastGetSolutionStepValue(VELOCITY, 0); array_1d<double, 3> &PreviousVelocity = (i)->FastGetSolutionStepValue(VELOCITY, 1); array_1d<double, 3> &CurrentDisplacement = (i)->FastGetSolutionStepValue(DISPLACEMENT, 0); array_1d<double, 3> &PreviousDisplacement = (i)->FastGetSolutionStepValue(DISPLACEMENT, 1); /* if( i->IsFixed(DISPLACEMENT_X) == false ) / CurrentDisplacement[0] = 0.5 TimeStep * (CurrentVelocity[0] + PreviousVelocity[0]) + PreviousDisplacement[0]; /* if( i->IsFixed(DISPLACEMENT_Y) == false ) / CurrentDisplacement[1] = 0.5 TimeStep * (CurrentVelocity[1] + PreviousVelocity[1]) + PreviousDisplacement[1]; /* if( i->IsFixed(DISPLACEMENT_Z) == false ) / CurrentDisplacement[2] = 0.5 TimeStep * (CurrentVelocity[2] + PreviousVelocity[2]) + PreviousDisplacement[2]; // currentFluidFractionRate = (currentFluidFraction - previousFluidFraction)/TimeStep; } } virtual void UpdateStressStrain() {} virtual void Clear() override {} ///@} ///@name Access ///@{ virtual void SetEchoLevel(int Level) override { BaseType::SetEchoLevel(Level); } ///@} ///@name Inquiry ///@{ ///@} ///@name Input and output ///@{ /// Turn back information as a string. std::string Info() const override { std::stringstream buffer; buffer << "VPStrategy"; return buffer.str(); } /// Print information about this object. void PrintInfo(std::ostream &rOStream) const override { rOStream << "VPStrategy"; } /// Print object's data. void PrintData(std::ostream &rOStream) const override { } ///@} ///@name Friends ///@{ ///@} protected: ///@name Protected Life Cycle ///@{ ///@} ///@name Protected static Member Variables ///@{ ///@} ///@name Protected member Variables ///@{ ///@} ///@name Protected Operators ///@{ ///@} ///@name Protected Operations ///@{ /// Calculate the coefficients for time iteration. /** * @param rCurrentProcessInfo ProcessInfo instance from the fluid ModelPart. Must contain DELTA_TIME variables. / virtual bool SolveMomentumIteration(unsigned int it, unsigned int maxIt, bool &fixedTimeStep, double &velocityNorm) { return false; } virtual bool SolveContinuityIteration(unsigned int it, unsigned int maxIt, double &NormP) { return false; } void ComputeErrorL2Norm(double tensilStressSign) //tensilStressSign = 1.0 for FIC, tensilStressSign = -1.0 for FS { ModelPart &rModelPart = BaseType::GetModelPart(); const ProcessInfo &rCurrentProcessInfo = rModelPart.GetProcessInfo(); const double currentTime = rCurrentProcessInfo[TIME]; const unsigned int dimension = rModelPart.ElementsBegin()->GetGeometry().WorkingSpaceDimension(); long double sumErrorL2Velocity = 0; long double sumErrorL2VelocityX = 0; long double sumErrorL2VelocityY = 0; long double sumErrorL2Pressure = 0; long double sumErrorL2TauXX = 0; long double sumErrorL2TauYY = 0; long double sumErrorL2TauXY = 0; #pragma omp parallel { ModelPart::ElementIterator ElemBegin; ModelPart::ElementIterator ElemEnd; OpenMPUtils::PartitionedIterators(rModelPart.Elements(), ElemBegin, ElemEnd); for (ModelPart::ElementIterator itElem = ElemBegin; itElem != ElemEnd; ++itElem) { Element::GeometryType &geometry = itElem->GetGeometry(); long double nodalArea = 0; if (dimension == 2) { nodalArea = geometry.Area() / 3.0; } else if (dimension == 3) { nodalArea = geometry.Volume() 0.25; } long double bariPosX = 0; long double bariPosY = 0; long double eleErrorL2Velocity = 0; long double eleErrorL2VelocityX = 0; long double eleErrorL2VelocityY = 0; long double eleErrorL2Pressure = 0; //ShapeFunctionDerivativesArrayType DN_DX; Matrix NContainer; NContainer = geometry.ShapeFunctionsValues(GeometryData::IntegrationMethod::GI_GAUSS_1); const Vector &N = row(NContainer, 0); const unsigned int NumNodes = geometry.size(); double elementalPressure = N[0] * geometry(0)->FastGetSolutionStepValue(PRESSURE); double elementalVelocityX = N[0] * geometry(0)->FastGetSolutionStepValue(VELOCITY_X); double elementalVelocityY = N[0] * geometry(0)->FastGetSolutionStepValue(VELOCITY_Y); ; for (unsigned int i = 1; i < NumNodes; i++) { elementalPressure += N[i] * geometry(i)->FastGetSolutionStepValue(PRESSURE); elementalVelocityX += N[i] * geometry(i)->FastGetSolutionStepValue(VELOCITY_X); elementalVelocityY += N[i] * geometry(i)->FastGetSolutionStepValue(VELOCITY_Y); } for (unsigned int i = 0; i < geometry.size(); i++) { const long double nodalPosX = geometry(i)->X(); const long double nodalPosY = geometry(i)->Y(); bariPosX += nodalPosX / 3.0; bariPosY += nodalPosY / 3.0; } const long double posX = bariPosX; const long double posY = bariPosY; long double expectedVelocityX = pow(posX, 2) * (1.0 - posX) * (1.0 - posX) * (2.0 * posY - 6.0 * pow(posY, 2) + 4.0 * pow(posY, 3)); long double expectedVelocityY = -pow(posY, 2) * (1.0 - posY) * (1.0 - posY) * (2.0 * posX - 6.0 * pow(posX, 2) + 4.0 * pow(posX, 3)); long double expectedPressure = -tensilStressSign * posX * (1.0 - posX); eleErrorL2VelocityX = elementalVelocityX - expectedVelocityX; eleErrorL2VelocityY = elementalVelocityY - expectedVelocityY; eleErrorL2Pressure = elementalPressure - expectedPressure; sumErrorL2VelocityX += pow(eleErrorL2VelocityX, 2) * geometry.Area(); sumErrorL2VelocityY += pow(eleErrorL2VelocityY, 2) * geometry.Area(); sumErrorL2Pressure += pow(eleErrorL2Pressure, 2) * geometry.Area(); const long double tauXX = 0; // itElem->GetValue(ELEMENTAL_DEVIATORIC_STRESS_XX); const long double tauYY = 0; // itElem->GetValue(ELEMENTAL_DEVIATORIC_STRESS_YY); const long double tauXY = 0; // itElem->GetValue(ELEMENTAL_DEVIATORIC_STRESS_XY); long double expectedTauXX = 2.0 * (-4.0 * (1.0 - bariPosX) * bariPosX * (-1.0 + 2.0 * bariPosX) * bariPosY * (1.0 - 3.0 * bariPosY + 2.0 * pow(bariPosY, 2))); long double expectedTauYY = 2.0 * (4.0 * bariPosX * (1.0 - 3.0 * bariPosX + 2.0 * pow(bariPosX, 2)) * (1.0 - bariPosY) * bariPosY * (-1.0 + 2.0 * bariPosY)); long double expectedTauXY = (2.0 * (1.0 - 6.0 * bariPosY + 6.0 * pow(bariPosY, 2)) * (1.0 - bariPosX) * (1.0 - bariPosX) * pow(bariPosX, 2) - 2.0 * (1.0 - 6.0 * bariPosX + 6.0 * pow(bariPosX, 2)) * (1.0 - bariPosY) * (1 - bariPosY) * pow(bariPosY, 2)); long double nodalErrorTauXX = tauXX - expectedTauXX; long double nodalErrorTauYY = tauYY - expectedTauYY; long double nodalErrorTauXY = tauXY - expectedTauXY; sumErrorL2TauXX += pow(nodalErrorTauXX, 2) * geometry.Area(); sumErrorL2TauYY += pow(nodalErrorTauYY, 2) * geometry.Area(); sumErrorL2TauXY += pow(nodalErrorTauXY, 2) * geometry.Area(); } } long double errorL2Velocity = sqrt(sumErrorL2Velocity); long double errorL2VelocityX = sqrt(sumErrorL2VelocityX); long double errorL2VelocityY = sqrt(sumErrorL2VelocityY); long double errorL2Pressure = sqrt(sumErrorL2Pressure); long double errorL2TauXX = sqrt(sumErrorL2TauXX); long double errorL2TauYY = sqrt(sumErrorL2TauYY); long double errorL2TauXY = sqrt(sumErrorL2TauXY); std::ofstream myfileVelocity; myfileVelocity.open("errorL2VelocityFile.txt", std::ios::app); myfileVelocity << currentTime << "\t" << errorL2Velocity << "\n"; myfileVelocity.close(); std::ofstream myfileVelocityX; myfileVelocityX.open("errorL2VelocityXFile.txt", std::ios::app); myfileVelocityX << currentTime << "\t" << errorL2VelocityX << "\n"; myfileVelocityX.close(); std::ofstream myfileVelocityY; myfileVelocityY.open("errorL2VelocityYFile.txt", std::ios::app); myfileVelocityY << currentTime << "\t" << errorL2VelocityY << "\n"; myfileVelocityY.close(); std::ofstream myfilePressure; myfilePressure.open("errorL2PressureFile.txt", std::ios::app); myfilePressure << currentTime << "\t" << errorL2Pressure << "\n"; myfilePressure.close(); std::ofstream myfileTauXX; myfileTauXX.open("errorL2TauXXFile.txt", std::ios::app); myfileTauXX << currentTime << "\t" << errorL2TauXX << "\n"; myfileTauXX.close(); std::ofstream myfileTauYY; myfileTauYY.open("errorL2TauYYFile.txt", std::ios::app); myfileTauYY << currentTime << "\t" << errorL2TauYY << "\n"; myfileTauYY.close(); std::ofstream myfileTauXY; myfileTauXY.open("errorL2TauXYFile.txt", std::ios::app); myfileTauXY << currentTime << "\t" << errorL2TauXY << "\n"; myfileTauXY.close(); } void ComputeErrorL2NormCasePoiseuille() { ModelPart &rModelPart = BaseType::GetModelPart(); const ProcessInfo &rCurrentProcessInfo = rModelPart.GetProcessInfo(); const double currentTime = rCurrentProcessInfo[TIME]; const unsigned int dimension = rModelPart.ElementsBegin()->GetGeometry().WorkingSpaceDimension(); double sumErrorL2VelocityTheta = 0; double sumErrorL2TauTheta = 0; double r_in = 0.2; double R_out = 0.5; double kappa = r_in / R_out; double omega = 0.5; double viscosity = 100.0; #pragma omp parallel { ModelPart::ElementIterator ElemBegin; ModelPart::ElementIterator ElemEnd; OpenMPUtils::PartitionedIterators(rModelPart.Elements(), ElemBegin, ElemEnd); for (ModelPart::ElementIterator itElem = ElemBegin; itElem != ElemEnd; ++itElem) { Element::GeometryType &geometry = itElem->GetGeometry(); long double nodalArea = 0; if (dimension == 2) { nodalArea = geometry.Area() / 3.0; } else if (dimension == 3) { nodalArea = geometry.Volume() * 0.25; } long double bariPosX = 0; long double bariPosY = 0; long double eleErrorL2Velocity = 0; long double eleErrorL2VelocityX = 0; long double eleErrorL2VelocityY = 0; long double eleErrorL2Pressure = 0; //ShapeFunctionDerivativesArrayType DN_DX; Matrix NContainer; NContainer = geometry.ShapeFunctionsValues(GeometryData::IntegrationMethod::GI_GAUSS_1); //this->CalculateGeometryData(DN_DX,NContainer,GaussWeights); const Vector &N = row(NContainer, 0); // itElem->EvaluateInPoint(elementalPressure,PRESSURE,N); const unsigned int NumNodes = geometry.size(); double elementalPressure = N[0] * geometry(0)->FastGetSolutionStepValue(PRESSURE); double elementalVelocityX = N[0] * geometry(0)->FastGetSolutionStepValue(VELOCITY_X); double elementalVelocityY = N[0] * geometry(0)->FastGetSolutionStepValue(VELOCITY_Y); ; for (unsigned int i = 1; i < NumNodes; i++) { elementalPressure += N[i] * geometry(i)->FastGetSolutionStepValue(PRESSURE); elementalVelocityX += N[i] * geometry(i)->FastGetSolutionStepValue(VELOCITY_X); elementalVelocityY += N[i] * geometry(i)->FastGetSolutionStepValue(VELOCITY_Y); } for (unsigned int i = 0; i < geometry.size(); i++) { // index = idimension; const long double nodalPosX = geometry(i)->X(); const long double nodalPosY = geometry(i)->Y(); bariPosX += nodalPosX / 3.0; bariPosY += nodalPosY / 3.0; } const long double posX = bariPosX; const long double posY = bariPosY; const double rPos = sqrt(pow(posX, 2) + pow(posY, 2)); const double cosalfa = posX / rPos; const double sinalfa = posY / rPos; const double sin2alfa = 2.0 cosalfa * sinalfa; const double cos2alfa = 1.0 - 2.0 * pow(sinalfa, 2); double expectedVelocityTheta = pow(kappa, 2) * omega * R_out / (1.0 - pow(kappa, 2)) * (R_out / rPos - rPos / R_out); double computedVelocityTheta = sqrt(pow(elementalVelocityX, 2) + pow(elementalVelocityY, 2)); double nodalErrorVelocityTheta = computedVelocityTheta - expectedVelocityTheta; const long double tauXX = 0; // itElem->GetValue(ELEMENTAL_DEVIATORIC_STRESS_XX); const long double tauYY = 0; // itElem->GetValue(ELEMENTAL_DEVIATORIC_STRESS_YY); const long double tauXY = 0; // itElem->GetValue(ELEMENTAL_DEVIATORIC_STRESS_XY); double expectedTauTheta = (2.0 * viscosity * pow(kappa, 2) * omega * pow(R_out, 2)) / (1.0 - pow(kappa, 2)) / pow(rPos, 2); double computedTauTheta = (tauXX - tauYY) * sin2alfa / 2.0 - tauXY * cos2alfa; double nodalErrorTauTheta = computedTauTheta - expectedTauTheta; sumErrorL2VelocityTheta += pow(nodalErrorVelocityTheta, 2) * geometry.Area(); sumErrorL2TauTheta += pow(nodalErrorTauTheta, 2) * geometry.Area(); } } double errorL2VelocityTheta = sqrt(sumErrorL2VelocityTheta); double errorL2TauTheta = sqrt(sumErrorL2TauTheta); std::ofstream myfileVelocity; myfileVelocity.open("errorL2Poiseuille.txt", std::ios::app); myfileVelocity << currentTime << "\t" << errorL2VelocityTheta << "\t" << errorL2TauTheta << "\n"; myfileVelocity.close(); } double ComputeVelocityNorm() { ModelPart &rModelPart = BaseType::GetModelPart(); const int n_nodes = rModelPart.NumberOfNodes(); double NormV = 0.00; #pragma omp parallel for reduction(+ \ : NormV) for (int i_node = 0; i_node < n_nodes; ++i_node) { const auto it_node = rModelPart.NodesBegin() + i_node; const auto &r_vel = it_node->FastGetSolutionStepValue(VELOCITY); for (unsigned int d = 0; d < 3; ++d) { NormV += r_vel[d] * r_vel[d]; } } NormV = BaseType::GetModelPart().GetCommunicator().GetDataCommunicator().SumAll(NormV); NormV = sqrt(NormV); const double zero_tol = 1.0e-12; if (NormV < zero_tol) NormV = 1.00; return NormV; } double ComputePressureNorm() { ModelPart &rModelPart = BaseType::GetModelPart(); const int n_nodes = rModelPart.NumberOfNodes(); double NormP = 0.00; #pragma omp parallel for reduction(+ \ : NormP) for (int i_node = 0; i_node < n_nodes; ++i_node) { const auto it_node = rModelPart.NodesBegin() + i_node; const double Pr = it_node->FastGetSolutionStepValue(PRESSURE); NormP += Pr * Pr; } NormP = BaseType::GetModelPart().GetCommunicator().GetDataCommunicator().SumAll(NormP); NormP = sqrt(NormP); const double zero_tol = 1.0e-12; if (NormP < zero_tol) NormP = 1.00; return NormP; } virtual bool CheckVelocityConvergence(const double NormDv, double &errorNormDv) { return false; } virtual bool CheckPressureConvergence(const double NormDp, double &errorNormDp, double &NormP) { return false; } virtual bool FixTimeStepMomentum(const double DvErrorNorm, bool &fixedTimeStep) { return false; } virtual bool CheckMomentumConvergence(const double DvErrorNorm, bool &fixedTimeStep) { return false; } virtual bool FixTimeStepContinuity(const double DvErrorNorm, bool &fixedTimeStep) { return false; } virtual bool CheckContinuityConvergence(const double DvErrorNorm, bool &fixedTimeStep) { return false; } ///@} ///@name Protected Access ///@{ ///@} ///@name Protected Inquiry ///@{ ///@} ///@name Protected LifeCycle ///@{ ///@} ///@name Static Member Variables ///@{ ///@} ///@name Member Variables ///@{ // Fractional step index. /* 1 : Momentum step (calculate fractional step velocity) * 2-3 : Unused (reserved for componentwise calculation of frac step velocity) * 4 : Pressure step * 5 : Computation of projections * 6 : End of step velocity */ // unsigned int mStepId; ///@} ///@name Private Operators ///@{ ///@} ///@name Private Operations ///@{ virtual void InitializeStrategy(SolverSettingsType &rSolverConfig) { KRATOS_TRY; KRATOS_CATCH(""); } ///@} ///@name Private Access ///@{ ///@} ///@name Private Inquiry ///@{ ///@} ///@name Un accessible methods ///@{ /// Assignment operator. VPStrategy &operator=(VPStrategy const &rOther) {} /// Copy constructor. VPStrategy(VPStrategy const &rOther) {} ///@} }; /// Class VPStrategy ///@} ///@name Type Definitions ///@{ ///@} ///@} // addtogroup } // namespace Kratos. #endif // KRATOS_V_P_STRATEGY_H
nco_ply_lst.c	/* $Header$ / / Purpose: Functions that manipulate lists of polygons / / Copyright (C) 2018--present Charlie Zender This file is part of NCO, the netCDF Operators. NCO is free software. You may redistribute and/or modify NCO under the terms of the 3-Clause BSD License with exceptions described in the LICENSE file / #include "nco_ply_lst.h" void nco_poly_re_org_lst( / for each poly_sct* in list re-order points so that first point is the leftermost point / poly_sct pl_lst, int arr_nbr) { int idx=0; int jdx=0; int max_crn_nbr=0; double lcl_dp_x; double lcl_dp_y; / max crn_nbr / for(idx=0 ; idx<arr_nbr ;idx++) if( pl_lst[idx]->crn_nbr > max_crn_nbr ) max_crn_nbr = pl_lst[idx]->crn_nbr; lcl_dp_x=(double)nco_calloc(max_crn_nbr, sizeof(double)); lcl_dp_y=(double)nco_calloc(max_crn_nbr, sizeof(double)); for(idx=0; idx<arr_nbr; idx++) { int lcl_min=0; int crn_nbr=pl_lst[idx]->crn_nbr; double x_min=1.0e-30; / de-reference / poly_sct pl=pl_lst[idx]; /* find index of min X value / for(jdx=0; jdx<crn_nbr; jdx++) if( pl->dp_x[jdx] < x_min ) { x_min=pl->dp_x[jdx]; lcl_min=jdx;} / first point already x_min so do nothing / if( lcl_min == 0) continue; for(jdx=0; jdx<crn_nbr; jdx++) { lcl_dp_x[jdx]=pl->dp_x[(jdx+lcl_min)%crn_nbr]; lcl_dp_y[jdx]=pl->dp_y[(jdx+lcl_min)%crn_nbr]; } / copy over values / memcpy(pl->dp_x, lcl_dp_x, (size_t)crn_nbrsizeof(double)); memcpy(pl->dp_y, lcl_dp_y, (size_t)crn_nbrsizeof(double)); } lcl_dp_x=(double)nco_free(lcl_dp_x); lcl_dp_y=(double)nco_free(lcl_dp_y); return; } poly_sct * /* [O] [nbr] size of array / nco_poly_lst_mk( double area, /* I [sr] Area of source grid / int msk, /* I [flg] Mask on source grid / double lat_ctr, /* I [dgr] Latitude centers of source grid / double lon_ctr, /* I [dgr] Longitude centers of source grid / double lat_crn, /* I [dgr] Latitude corners of source grid / double lon_crn, /* I [dgr] Longitude corners of source grid / size_t grd_sz, / I [nbr] Number of elements in single layer of source grid / long grd_crn_nbr, / I [nbr] Maximum number of corners in source gridcell / nco_grd_lon_typ_enm grd_lon_typ, / I [num] if not nil then split cells that straddle Greenwich or Dateline / poly_typ_enm pl_typ, int pl_nbr) { const char fnc_nm[]="nco_poly_lst_mk()"; int idx=0; int idx_cnt=0; int cnt_wrp_good=0; nco_bool bwrp; double lat_ptr=lat_crn; double lon_ptr=lon_crn; /* buffers used in nco-poly_re_org() / double lcl_dp_x[VP_MAX]={0}; double lcl_dp_y[VP_MAX]={0}; poly_sct pl; poly_sct pl_wrp_left; poly_sct pl_wrp_right; poly_sct *pl_lst; / start with twice the grid size as we may be splitting the cells along the Greenwich meridian or dateline / / realloc at the end / pl_lst=(poly_sct)nco_malloc( sizeof (poly_sct) * grd_sz 2 ); // printf("About to print poly sct grd_sz=%d grd_crn_nbr=%d\n", grd_sz, grd_crn_nbr); for(idx=0;idx<grd_sz; idx++) { / check mask and area / if( msk[idx]==0 \|\| area[idx] == 0.0) continue; pl=nco_poly_init_lst(pl_typ, grd_crn_nbr,0, idx, lon_ptr, lat_ptr); lon_ptr+=(size_t)grd_crn_nbr; lat_ptr+=(size_t)grd_crn_nbr; / if poly is less than a triangle then null is returned/ if(!pl) continue; / add min max / nco_poly_minmax_add(pl, grd_lon_typ, False); nco_poly_re_org(pl, lcl_dp_x, lcl_dp_y); / use Charlie's formula / nco_poly_area_add(pl); //if(pl->dp_x_minmax[0] <0.0 \|\| (pl->dp_x_minmax[1] - pl->dp_x_minmax[0]) > 30 ) if( !(pl->dp_x_minmax[1] - pl->dp_x_minmax[0] < 180.0 && lon_ctr[idx] >= pl->dp_x_minmax[0] && lon_ctr[idx] <= pl->dp_x_minmax[1] )) { (void)fprintf(stdout, "/%s: %s: invalid polygon to follow ***?", nco_prg_nm_get(), fnc_nm); nco_poly_prn(pl, 0); pl=nco_poly_free(pl); continue; } //fprintf(stdout,"/* input polygon pl lon center=%f convex=%s\n *****************/\n", lon_ctr[idx], (nco_poly_is_convex(pl) ? "True": "False") ); //nco_poly_prn(pl, 0); / check for wrapping -center outside min/max range / bwrp=( lon_ctr[idx] < pl->dp_x_minmax[0] \|\| lon_ctr[idx] > pl->dp_x_minmax[1] ); if( grd_lon_typ == nco_grd_lon_nil \|\| grd_lon_typ == nco_grd_lon_unk ) { if( !bwrp ) { pl_lst[idx_cnt++]=pl; } else { (void)fprintf(stdout, "%s: polygon(%d) wrapped - but grd_lon_typ not specified \n", nco_prg_nm_get(), idx); (void)fprintf(stdout, "/*****************************************/\n"); pl=nco_poly_free(pl); } continue; } / if we are here then grd_lon_typ specifys a grid type / if( !bwrp) { pl_lst[idx_cnt++]=pl; } / cell width exceeds max so assume wrapping / else if( nco_poly_wrp_splt(pl, grd_lon_typ, &pl_wrp_left, &pl_wrp_right ) == NCO_NOERR ) { fprintf(stdout,"/** pl, wrp_left, wrp_right ****************/\n"); if(pl_wrp_left) { nco_poly_re_org(pl_wrp_left, lcl_dp_x, lcl_dp_y); pl_lst[idx_cnt++]=pl_wrp_left; nco_poly_prn(pl_wrp_left, 2); } if(pl_wrp_right) { nco_poly_re_org(pl_wrp_right, lcl_dp_x, lcl_dp_y); pl_lst[idx_cnt++]=pl_wrp_right; nco_poly_prn(pl_wrp_right, 2); } pl=nco_poly_free(pl); fprintf(stdout,"/******************************/\n"); cnt_wrp_good++; } else { if(nco_dbg_lvl_get() >= nco_dbg_std ){ (void)fprintf(stdout, "%s: split wrapping didn't work on this polygon(%d)\n", nco_prg_nm_get(), idx ); (void)fprintf(stdout, "/****************************/\n"); } pl=nco_poly_free(pl); } } if(nco_dbg_lvl_get() >= nco_dbg_std ) (void)fprintf(stdout, "%s: %s size input list(%lu), size output list(%d), num of split polygons(%d)\n", nco_prg_nm_get(),fnc_nm, grd_sz, idx_cnt, cnt_wrp_good); pl_lst=(poly_sct)nco_realloc( pl_lst, (size_t)idx_cnt * sizeof (poly_sct) ); pl_nbr=idx_cnt; return pl_lst; } poly_sct ** /* [O] [nbr] size of array / nco_poly_lst_mk_rll( double area, /* I [sr] Area of source grid / int msk, /* I [flg] Mask on source grid / double lat_ctr, /* I [dgr] Latitude centers of source grid / double lon_ctr, /* I [dgr] Longitude centers of source grid / double lat_crn, /* I [dgr] Latitude corners of source grid / double lon_crn, /* I [dgr] Longitude corners of source grid / size_t grd_sz, / I [nbr] Number of elements in single layer of source grid / long grd_crn_nbr, / I [nbr] Maximum number of corners in source gridcell / nco_grd_lon_typ_enm grd_lon_typ) / I [num] / { int idx=0; int wrp_cnt=0; int wrp_y_cnt=0; int msk_cnt=0; const char fnc_nm[]="nco_poly_lst_mk_rll()"; nco_bool bwrp; / no polar caps on a RLL grid / nco_bool bchk_caps=False; double tot_area=0.0; double lat_ptr=lat_crn; double lon_ptr=lon_crn; poly_sct pl=(poly_sct)NULL_CEWI; / contains plain struct sct with bmsk=False; / poly_sct pl_msk=((poly_sct)NULL_CEWI); poly_sct pl_lst; / list size is grd_sz - invalid or masked polygons are repesented by a poly_sct->bmsk=False / pl_lst=(poly_sct)nco_malloc( sizeof (poly_sct) * grd_sz); pl_msk=nco_poly_init(); pl_msk->bmsk=False; /* filter out wrapped lon cells / if( grd_lon_typ == nco_grd_lon_nil \|\| grd_lon_typ == nco_grd_lon_unk \|\| grd_lon_typ == nco_grd_lon_bb ) bwrp=False; else bwrp=True; // printf("About to print poly sct grd_sz=%d grd_crn_nbr=%d\n", grd_sz, grd_crn_nbr); for(idx=0;idx<grd_sz; idx++) { / check mask and area / if(area[idx] == 0.0 ) { pl_lst[idx]= nco_poly_dpl(pl_msk); msk_cnt++; continue; } pl=nco_poly_init_lst(poly_rll, grd_crn_nbr,0, idx, lon_ptr, lat_ptr); lon_ptr+=(size_t)grd_crn_nbr; lat_ptr+=(size_t)grd_crn_nbr; / if poly is less than a triangle then null is returned/ if(!pl ) { if(nco_dbg_lvl_get()>= nco_dbg_dev) fprintf(stderr, "%s(): WARNING cell(id=%d) less than a triange\n", fnc_nm, idx); pl_lst[idx]= nco_poly_dpl(pl_msk); msk_cnt++; continue; } / add centroid from input / pl->dp_x_ctr=lon_ctr[idx]; pl->dp_y_ctr=lat_ctr[idx]; / pop shp / nco_poly_shp_pop(pl); / add min max / nco_poly_minmax_add(pl, grd_lon_typ, bchk_caps); / if coords cannot deal with wrapping / if( pl->bwrp && bwrp==False ) { pl=nco_poly_free(pl); pl_lst[idx]= nco_poly_dpl(pl_msk); msk_cnt++; continue; } / The area of an RLL grid needs to be re-calculated as we have to take account of lines of latitude as great circles / nco_poly_area_add(pl); / area NOT set so add to the area - nb this will be eventually written to the map file in nco_map_mk / if(area[idx]==-1.0) area[idx]=pl->area; / we still need the area even though its masked / if(!msk[idx]) pl->bmsk=False; / simple center of a rll cell - should always be inside of polygon / nco_poly_ctr_add(pl, grd_lon_typ); if(nco_dbg_lvl_get()>= nco_dbg_dev ) if(pl->bwrp) nco_poly_prn(pl,0); / for debugging / tot_area+=pl->area; / for debugging total number of wrapped cells / wrp_cnt+=pl->bwrp; pl_lst[idx]=pl; } if(nco_dbg_lvl_get() >= nco_dbg_dev ) (void)fprintf(stderr, "%s: %s size input list(%lu), size output list(%lu) total area=%.15e num wrapped= %d num caps=%d num masked=%d\n", nco_prg_nm_get(),fnc_nm, grd_sz, grd_sz, tot_area, wrp_cnt, wrp_y_cnt, msk_cnt); pl_msk=nco_poly_free(pl_msk); return pl_lst; } poly_sct * /* [O] [nbr] size of array / nco_poly_lst_mk_sph( double area, /* I [sr] Area of source grid / int msk, /* I [flg] Mask on source grid / double lat_ctr, /* I [dgr] Latitude centers of source grid / double lon_ctr, /* I [dgr] Longitude centers of source grid / double lat_crn, /* I [dgr] Latitude corners of source grid / double lon_crn, /* I [dgr] Longitude corners of source grid / size_t grd_sz, / I [nbr] Number of elements in single layer of source grid / long grd_crn_nbr, / I [nbr] Maximum number of corners in source gridcell / nco_grd_lon_typ_enm grd_lon_typ) / I [num] / { int idx=0; int wrp_cnt=0; int wrp_y_cnt=0; int msk_cnt=0; const char fnc_nm[]="nco_poly_lst_mk_sph()"; nco_bool bwrp; / check to see if cell is a polar cap / nco_bool bchk_caps=True; double tot_area=0.0; double lat_ptr=lat_crn; double lon_ptr=lon_crn; / buffers used in nco-poly_re_org() / poly_sct pl=(poly_sct)NULL_CEWI; / contains plain struct sct with bmsk=False; / poly_sct pl_msk=((poly_sct)NULL_CEWI); poly_sct pl_lst; / list size is grd_sz - invalid or masked polygons are repesented by a poly_sct->bmsk=False / pl_lst=(poly_sct)nco_malloc( sizeof (poly_sct) * grd_sz); pl_msk=nco_poly_init(); pl_msk->bmsk=False; /* filter out wrapped lon cells / if( grd_lon_typ == nco_grd_lon_nil \|\| grd_lon_typ == nco_grd_lon_unk \|\| grd_lon_typ == nco_grd_lon_bb ) bwrp=False; else bwrp=True; // printf("About to print poly sct grd_sz=%d grd_crn_nbr=%d\n", grd_sz, grd_crn_nbr); for(idx=0;idx<grd_sz; idx++) { / check area / if(area[idx] == 0.0 ) { pl_lst[idx]= nco_poly_dpl(pl_msk); msk_cnt++; continue; } pl=nco_poly_init_lst(poly_sph, grd_crn_nbr,0, idx, lon_ptr, lat_ptr); lon_ptr+=(size_t)grd_crn_nbr; lat_ptr+=(size_t)grd_crn_nbr; / if poly is less than a triangle then null is returned/ if(!pl ) { if(nco_dbg_lvl_get()>= nco_dbg_dev) fprintf(stderr, "%s(): WARNING cell(id=%d) less than a triange\n", fnc_nm, idx); pl_lst[idx]= nco_poly_dpl(pl_msk); msk_cnt++; continue; } / add centroid from input / pl->dp_x_ctr=lon_ctr[idx]; pl->dp_y_ctr=lat_ctr[idx]; / pop shp / nco_poly_shp_pop(pl); / add min max / nco_poly_minmax_add(pl, grd_lon_typ, bchk_caps); / if coords cannot deal with wrapping / if( pl->bwrp && bwrp==False ) { pl=nco_poly_free(pl); pl_lst[idx]= nco_poly_dpl(pl_msk); msk_cnt++; continue; } / The area of an RLL grid needs to be re-calculated as we have to take account of lines of latitude as great circles / nco_poly_area_add(pl); / area NOT set so add to the area - nb this will be eventually written to the map file in nco_map_mk / if(area[idx]==-1.0) area[idx]=pl->area; / fxm:2019-06-07 - there is a problem using the polygon center as a control point as * for some RLL grids the center of a polar triangle can be the pole / / The centroid can be outside of a convex polygon * for nco_sph_intersect_pre() to work correctly it requires a point INSIDE the convex polygon * So we use a custom function : * just remember FROM HERE on that the pl->dp_x_ctr, pl->dp_y_ctr iS NOT the Centroid * / / if(nco_sph_inside_mk(pl,pControl )) { pl->dp_x_ctr=R2D(pControl[3]); pl->dp_y_ctr=R2D(pControl[4]); } else nco_poly_ctr_add(pl, grd_lon_typ); / / even if masked we still need the area / if(!msk[idx]) { / pl_lst[idx]=nco_poly_dpl(pl_msk); pl_lst[idx]->area=pl->area; msk_cnt++; pl=nco_poly_free(pl); continue; / pl->bmsk=False; msk_cnt++; } if(nco_dbg_lvl_get()>= nco_dbg_dev ) if(pl->bwrp) nco_poly_prn(pl,0); / for debugging / tot_area+=pl->area; / for debugging total number of wrapped cells / wrp_cnt+=pl->bwrp; wrp_y_cnt+=pl->bwrp_y; pl_lst[idx]=pl; } if(nco_dbg_lvl_get() >= nco_dbg_dev ) (void)fprintf(stderr, "%s: %s size input list(%lu), size output list(%lu) total area=%.15e num wrapped= %d num caps=%d num masked=%d\n", nco_prg_nm_get(),fnc_nm, grd_sz, grd_sz, tot_area, wrp_cnt, wrp_y_cnt, msk_cnt); pl_msk=nco_poly_free(pl_msk); return pl_lst; } poly_sct * nco_poly_lst_free( poly_sct pl_lst, int arr_nbr) { int idx; for(idx=0; idx<arr_nbr; idx++) pl_lst[idx]=nco_poly_free(pl_lst[idx]); pl_lst=(poly_sct)nco_free(pl_lst); return pl_lst; } void nco_poly_set_priority( int nbr_lst, KDPriority list){ int idx; for(idx=0;idx<nbr_lst;idx++){ list[idx].dist = 1.1; list[idx].elem = (KDElem)NULL; } return ; } poly_sct ** nco_poly_lst_mk_vrl_crt( /* create overlap mesh for crt polygons / poly_sct pl_lst_in, int pl_cnt_in, KDTree rtree, int pl_cnt_vrl_ret){ / just duplicate output list to overlap / size_t idx; size_t jdx; int max_nbr_vrl=1000; int pl_cnt_vrl=0; //nco_bool bSort=True; const char fnc_nm[]="nco_poly_mk_vrl_crt()"; / buffers used in nco-poly_re_org() / double lcl_dp_x[VP_MAX]={0}; double lcl_dp_y[VP_MAX]={0}; kd_box size; poly_sct * pl_lst_vrl=NULL_CEWI; KDPriority list; list = (KDPriority )nco_calloc(sizeof(KDPriority),(size_t)max_nbr_vrl); printf("INFO - entered function nco_poly_mk_vrl\n"); /* start main loop over input polygons / for(idx=0 ; idx<pl_cnt_in ;idx++ ) { int cnt_vrl=0; int cnt_vrl_on=0; (void)nco_poly_set_priority(max_nbr_vrl,list); / get bounds of polygon in / size[KD_LEFT] = pl_lst_in[idx]->dp_x_minmax[0]; size[KD_RIGHT] = pl_lst_in[idx]->dp_x_minmax[1]; size[KD_BOTTOM] = pl_lst_in[idx]->dp_y_minmax[0]; size[KD_TOP] = pl_lst_in[idx]->dp_y_minmax[1]; / find overlapping polygons / // cnt_vrl=kd_nearest_intersect(rtree, size, max_nbr_vrl,list,bSort ); / nco_poly_prn(2, pl_lst_in[idx] ); / for(jdx=0; jdx <cnt_vrl ;jdx++){ poly_sct pl_vrl=(poly_sct)NULL_CEWI; poly_sct pl_out=(poly_sct)list[jdx].elem->item; ; // nco_poly_prn(2, pl_out); / check for polygon in polygon first / if( nco_crt_poly_in_poly(pl_lst_in[idx], pl_out) == pl_out->crn_nbr ) { //fprintf(stderr,"%s: using poly_in_poly()\n", fnc_nm); pl_vrl=nco_poly_dpl(pl_out); } else pl_vrl= nco_poly_vrl_do(pl_lst_in[idx], pl_out, 0, (char)NULL); if(pl_vrl){ nco_poly_re_org(pl_vrl, lcl_dp_x, lcl_dp_y); /* add area / nco_poly_area_add(pl_vrl); / shp not needed / nco_poly_shp_free(pl_vrl); pl_lst_vrl=(poly_sct)nco_realloc(pl_lst_vrl, sizeof(poly_sct) * (pl_cnt_vrl+1)); pl_lst_vrl[pl_cnt_vrl]=pl_vrl; pl_cnt_vrl++; cnt_vrl_on++; if(nco_poly_is_convex(pl_vrl) == False ) { fprintf(stderr,"%s: %s vrl polygon convex=0 vrl ,in convex=%d ,out convex=%d\n", nco_prg_nm_get(), fnc_nm, nco_poly_is_convex(pl_lst_in[idx]), nco_poly_is_convex(pl_out) ); nco_poly_prn(pl_vrl, 2); nco_poly_prn(pl_lst_in[idx], 2); nco_poly_prn(pl_out, 2); } //fprintf(stderr,"Overlap polygon to follow\n"); //nco_poly_prn(2, pl_vrl); } } if( nco_dbg_lvl_get() >= nco_dbg_dev ) (void) fprintf(stderr, "%s: total overlaps=%d for polygon %lu - potential overlaps=%d actual overlaps=%d\n", nco_prg_nm_get(), pl_cnt_vrl, idx, cnt_vrl, cnt_vrl_on); } list = (KDPriority )nco_free(list); / return size of list / pl_cnt_vrl_ret=pl_cnt_vrl; return pl_lst_vrl; } void ** nco_poly_lst_mk_vrl( /* create overlap mesh for sph polygons / poly_sct pl_lst_in, int pl_cnt_in, nco_grd_lon_typ_enm grd_lon_typ, poly_typ_enm pl_typ, KDTree tree, int nbr_tr, int lst_out_typ, int pl_cnt_vrl_ret){ /* just duplicate output list to overlap / const char fnc_nm[]="nco_poly_lst_mk_vrl()"; nco_bool bDirtyRats=False; nco_bool bSort=True; int pl_cnt_vrl=0; int thr_idx=0; int pl_cnt_dbg=0; int tot_nan_cnt=0; int tot_wrp_cnt=0; / approx number of input cells each thread will process / int thr_quota; / reporting step / int thr_quota_step; size_t idx; // size_t ldx; int lcl_thr_nbr; omp_mem_sct mem_lst=NULL_CEWI; double tot_area=0.0; void void_lst_vrl=NULL_CEWI; poly_sct pl_lst_dbg=NULL_CEWI; FILE * const fp_stderr=stderr; lcl_thr_nbr=omp_get_max_threads(); mem_lst=(omp_mem_sct)nco_malloc(sizeof(omp_mem_sct)lcl_thr_nbr); for(idx=0;idx<lcl_thr_nbr;idx++){ mem_lst[idx].pl_lst=NULL_CEWI; mem_lst[idx].wgt_lst=NULL_CEWI; mem_lst[idx].blk_nbr=0; mem_lst[idx].pl_cnt=0; mem_lst[idx].kd_cnt=0; mem_lst[idx].kd_blk_nbr=0; mem_lst[idx].idx_cnt=0; mem_lst[idx].kd_list=NULL_CEWI; /* mem_lst[idx].kd_list=(KDPriority *)nco_malloc(sizeof(KDPriority)(size_t)(NCO_VRL_BLOCKSIZE)); for(ldx=0;ldx<NCO_VRL_BLOCKSIZE;ldx++) mem_lst[idx].kd_list[ldx]=(KDPriority)nco_calloc(1, sizeof(KDPriority) ); / / remember this modifies kd_list, kd_blk_nbr / kd_list_realloc(&mem_lst[idx],1 ); } thr_quota=pl_cnt_in/lcl_thr_nbr; thr_quota_step=thr_quota/20; if( thr_quota_step <2000 ) thr_quota_step=2000; / NB: "OpenMP notes" section of nco_rgr.c has detailed discussion of these settings Henry, please keep the variables in alphabetical order within a clause and remember to update Intel / #ifdef __GNUG__ # define GCC_LIB_VERSION ( __GNUC__ 100 + __GNUC_MINOR__ * 10 + __GNUC_PATCHLEVEL__ ) # if GCC_LIB_VERSION < 490 # define GXX_OLD_OPENMP_SHARED_TREATMENT 1 # endif /* 480 / #endif / !__GNUC__ / #if defined(__INTEL_COMPILER) # pragma omp parallel for private(idx,thr_idx) schedule(dynamic,40) shared(bDirtyRats,bSort,grd_lon_typ,nbr_tr,pl_cnt_dbg,pl_typ,tree,tot_nan_cnt,tot_wrp_cnt) #else / !__INTEL_COMPILER / # ifdef GXX_OLD_OPENMP_SHARED_TREATMENT # pragma omp parallel for default(none) private(idx,thr_idx) shared(bDirtyRats,bSort,grd_lon_typ,nbr_tr,pl_cnt_dbg,pl_typ,tree,tot_nan_cnt,tot_wrp_cnt) # else / !old g++ / # pragma omp parallel for private(idx,thr_idx) schedule(dynamic,40) shared(bDirtyRats,bSort,grd_lon_typ,mem_lst, nbr_tr,pl_cnt_dbg,pl_typ,tree,tot_nan_cnt,tot_wrp_cnt) # endif / !old g++ / #endif / !__INTEL_COMPILER / for(idx=0;idx<pl_cnt_in;idx++){ nco_bool bSplit=False; int vrl_cnt = 0; int vrl_cnt_on = 0; int nan_cnt=0; int wrp_cnt=0; size_t jdx; double vrl_area = 0.0; kd_box size1; kd_box size2; // (void) nco_poly_set_priority(max_nbr_vrl, list); thr_idx=omp_get_thread_num(); if (0 && nco_dbg_lvl_get() >= nco_dbg_dev) fprintf(fp_stderr, "%s(): idx=%lu thr=%d\n",fnc_nm, idx, thr_idx); if(pl_lst_in[idx]->bmsk==False) goto cont_msk; / need to iterate mem_lst diagnostics at end of loop/ mem_lst[thr_idx].kd_cnt=0; if(mem_lst[thr_idx].kd_blk_nbr > 1) kd_list_realloc( &mem_lst[thr_idx],1); / if a wrapped polygon then split and do two searches / bSplit=nco_poly_minmax_split(pl_lst_in[idx],grd_lon_typ,size1,size2); if(bSplit){ vrl_cnt=kd_nearest_intersect(tree, nbr_tr, size1, &mem_lst[thr_idx], False); vrl_cnt=kd_nearest_intersect(tree, nbr_tr, size2, &mem_lst[thr_idx], False); }else{ vrl_cnt=kd_nearest_intersect(tree, nbr_tr, size1, &mem_lst[thr_idx], False); } / nco_poly_prn(2, pl_lst_in[idx] ); / / nb this func below sorts list - and then places duplicates at the end, then returns the new size / if(vrl_cnt) vrl_cnt=kd_list_sort_omp(&mem_lst[thr_idx],vrl_cnt); for(jdx=0;jdx<vrl_cnt;jdx++){ poly_sct pl_vrl = NULL_CEWI; poly_sct pl_out = (poly_sct ) mem_lst[thr_idx].kd_list[jdx]->elem->item; /* for area debug only / mem_lst[thr_idx].kd_list[jdx]->area=-1.0; mem_lst[thr_idx].kd_list[jdx]->dbg_sng[0]='\0'; / if (pl_lst_in[idx]->pl_typ != pl_out->pl_typ) { fprintf(stderr, "%s: %s poly type mismatch\n", nco_prg_nm_get(), fnc_nm); continue; } / if(pl_typ== poly_rll){ pl_vrl = nco_poly_vrl_do(pl_lst_in[idx], pl_out, 0, (char)NULL); /* if pl_vrl is NULL from, nco_poly_do_vrl() then there are 3 possible senario's * * 1) pl_lst_in[idx] and pl_out are seperate and distinct * * 2) pl_lst_in[idx] is entirely inside pl_out. * to check for this it is sufficent to check the * the minmax bounds and then also check that a single vertex * from pl_lst_in[idx] is inside pl_out * * 3) pl_out is entirely inside pl_lst_in[idx] * check minmax bounds then check a single vertex from * pl_out / if(!pl_vrl){ if(nco_poly_in_poly_minmax(pl_lst_in[idx],pl_out)) pl_vrl=nco_poly_dpl(pl_out); else if(nco_poly_in_poly_minmax(pl_out,pl_lst_in[idx])) pl_vrl=nco_poly_dpl(pl_lst_in[idx]); } if(pl_vrl){ / add area nb also sets wrapping / nco_poly_minmax_add(pl_vrl, grd_lon_typ, False); / REMEMBER poly_rll area uses minmax limits AND NOT VERTEX's / nco_poly_area_add(pl_vrl); } } if(pl_typ == poly_sph){ int lret=0; int lret2=0; / [flg] set by nco_sph_intersect_pre - if True it means that scan hase detected a genuine intersection so * so no need to do further processing / nco_bool bGenuine=False; nco_bool bBadArea=False; char in_sng[VP_MAX]; char out_sng[VP_MAX]; int flg_snp_to=2; in_sng[0]='\0'; out_sng[0]='\0'; nco_sph_intersect_pre(pl_lst_in[idx], pl_out, in_sng); if(0 && nco_dbg_lvl_get() >= nco_dbg_dev) (void)fprintf(stderr,"%s:%s(): sp_sng=%s \n",nco_prg_nm_get(),fnc_nm, in_sng ); lret = nco_sph_process_pre(pl_out, in_sng, &bGenuine); switch(lret){ case 1: pl_vrl = nco_poly_dpl(pl_out); break; case 2: pl_vrl = nco_poly_vrl_do(pl_lst_in[idx], pl_out, flg_snp_to, (char )NULL); break; case 3: pl_vrl = nco_poly_vrl_do(pl_lst_in[idx], pl_out, flg_snp_to, in_sng); break; case 4: pl_vrl = nco_poly_vrl_do(pl_lst_in[idx], pl_out, flg_snp_to, (char)NULL); break; case 5: pl_vrl = nco_poly_vrl_do(pl_lst_in[idx], pl_out, flg_snp_to, in_sng); break; } if(pl_vrl){ double min_area= (pl_out->area < pl_lst_in[idx]->area ? pl_out->area : pl_lst_in[idx]->area); / add area nb also sets wrapping / nco_poly_minmax_add(pl_vrl, grd_lon_typ, False); / REMEMBER poly_rll area uses minmax limits AND NOT VERTEX's / nco_poly_area_add(pl_vrl); if( isnan( pl_vrl->area) \|\| pl_vrl->area == 0.0 \|\| (pl_vrl->area - min_area)/ min_area > 1.0e-04 ){ pl_vrl = nco_poly_free(pl_vrl); bBadArea=True; } } / swap args around and try again / if(!pl_vrl && ((bGenuine == False && lret != 1) \|\| bBadArea)){ flg_snp_to=1; nco_sph_intersect_pre(pl_out, pl_lst_in[idx], out_sng); lret2 = nco_sph_process_pre(pl_lst_in[idx], out_sng, &bGenuine); switch(lret2){ case 1: pl_vrl = nco_poly_dpl(pl_lst_in[idx]); break; case 2: pl_vrl = nco_poly_vrl_do(pl_out, pl_lst_in[idx], flg_snp_to, (char )NULL); break; case 3: pl_vrl = nco_poly_vrl_do(pl_out, pl_lst_in[idx], flg_snp_to, out_sng); break; case 4: pl_vrl = nco_poly_vrl_do(pl_out, pl_lst_in[idx], flg_snp_to, (char)NULL); break; case 5: pl_vrl = nco_poly_vrl_do(pl_out, pl_lst_in[idx], flg_snp_to, out_sng); break; } if(pl_vrl){ nco_poly_minmax_add(pl_vrl, grd_lon_typ, False); nco_poly_area_add(pl_vrl); } } if(bDirtyRats) sprintf(mem_lst[thr_idx].kd_list[jdx]->dbg_sng, "lret=%d in_sng=%s lret2=%d out_sng=%s\n",lret, in_sng, lret2, out_sng); if(bDirtyRats && pl_vrl && !nco_sph_is_convex(pl_vrl->shp,pl_vrl->crn_nbr)){ (void) fprintf(stderr, "/********** concave overlap plygon*******/\n"); nco_poly_prn(pl_lst_in[idx],0); nco_poly_prn(pl_out,0); nco_poly_prn(pl_vrl, 0); (void) fprintf(stderr, "/********************************************/\n"); } } / end if poly_sph / if (pl_vrl) { // nco_poly_re_org(pl_vrl, lcl_dp_x, lcl_dp_y); / add aprropriate id's / pl_vrl->src_id = pl_lst_in[idx]->src_id; pl_vrl->dst_id = pl_out->src_id; / shp not needed / nco_poly_shp_free(pl_vrl); / calculate weight -simple ratio of areas / pl_vrl->wgt=pl_vrl->area / pl_out->area; / add lat/lon centers / nco_poly_ctr_add(pl_vrl, grd_lon_typ); wrp_cnt+=pl_vrl->bwrp; if(isnan(pl_vrl->area) \|\| pl_vrl->area == 0.0){ nan_cnt++; pl_vrl->area=0.0; pl_vrl=nco_poly_free(pl_vrl); continue; } / for input polygon wgt is used to calculate frac_a / pl_lst_in[idx]->wgt+= ( pl_vrl->area / pl_lst_in[idx]->area ); / #ifdef _OPENMP #pragma omp critical #endif { pl_out->wgt+=pl_vrl->wgt; } / vrl_area += pl_vrl->area; mem_lst[thr_idx].kd_list[jdx]->area=pl_vrl->area; if( mem_lst[thr_idx].blk_nbr NCO_VRL_BLOCKSIZE < mem_lst[thr_idx].pl_cnt + 1){ if(lst_out_typ == 1) mem_lst[thr_idx].wgt_lst= (wgt_sct*)nco_realloc(mem_lst[thr_idx].wgt_lst, sizeof(wgt_sct) * ++mem_lst[thr_idx].blk_nbr * NCO_VRL_BLOCKSIZE ); else if(lst_out_typ == 2) mem_lst[thr_idx].pl_lst= (poly_sct*)nco_realloc(mem_lst[thr_idx].pl_lst, sizeof(poly_sct) * ++mem_lst[thr_idx].blk_nbr * NCO_VRL_BLOCKSIZE); } if(lst_out_typ==1) { wgt_sct wgt_lcl=(wgt_sct)nco_calloc(1,sizeof(wgt_sct)); wgt_lcl->src_id=pl_vrl->src_id; wgt_lcl->dst_id=pl_vrl->dst_id; wgt_lcl->area=pl_vrl->area; wgt_lcl->wgt=pl_vrl->wgt; mem_lst[thr_idx].wgt_lst[mem_lst[thr_idx].pl_cnt++] =wgt_lcl; pl_vrl=nco_poly_free(pl_vrl); } else if(lst_out_typ==2 ) mem_lst[thr_idx].pl_lst[mem_lst[thr_idx].pl_cnt++] = pl_vrl; vrl_cnt_on++; /* for area debug only / } } / end jdx / if (nco_dbg_lvl_get() >= nco_dbg_dev) { #ifdef _OPENMP #pragma omp critical #endif { tot_nan_cnt += nan_cnt; tot_wrp_cnt += wrp_cnt; tot_area += vrl_area; } / end OMP critical / / area diff by more than 10% / int kdx; double eps = 1.0e-8; double frc = vrl_area / pl_lst_in[idx]->area; if (frc < (1 - eps) \|\| frc > 1 + eps) { (void) fprintf(fp_stderr, "%s: polygon %lu - potential overlaps=%d actual overlaps=%d area_in=%.10e vrl_area=%.10e adiff=%.15e bSplit=%d\n", nco_prg_nm_get(), idx, vrl_cnt, vrl_cnt_on, pl_lst_in[idx]->area, vrl_area, (pl_lst_in[idx]->area - vrl_area), bSplit); if(bDirtyRats){ //if (pl_lst_in[idx]->bwrp ) { if (1) { (void) fprintf(fp_stderr, "# /* following pl_lst_in[%lu] /\n", idx); nco_poly_prn(pl_lst_in[idx], 0); (void) fprintf(fp_stderr, "# / overlaps to follow */\n"); for (kdx = 0; kdx < vrl_cnt; kdx++) { nco_poly_prn((poly_sct ) mem_lst[thr_idx].kd_list[kdx]->elem->item, 0); (void)fprintf(fp_stderr, "# vrl_area=%.15e\n",mem_lst[thr_idx].kd_list[kdx]->area ); (void)fprintf(fp_stderr, "# dbg_sng=%s\n",mem_lst[thr_idx].kd_list[kdx]->dbg_sng ); } (void) fprintf(stderr, "/*********** end dirty rats ***********/\n"); } if(1 && vrl_cnt_on > 0 && lst_out_typ == 2){ pl_lst_dbg = (poly_sct ) nco_realloc(pl_lst_dbg, sizeof(poly_sct ) (pl_cnt_dbg + vrl_cnt_on)); /* write overlaps maybe / for (kdx = 0; kdx < vrl_cnt_on; kdx++){ poly_sct lcl_poly=mem_lst[thr_idx].pl_lst[mem_lst[thr_idx].pl_cnt - vrl_cnt_on + kdx]; if(lcl_poly->src_id== pl_lst_in[idx]->src_id ) pl_lst_dbg[pl_cnt_dbg++] = nco_poly_dpl(lcl_poly); } } } } } /* end dbg / cont_msk: ; / output some usefull tracking stuff - not debug but informative / if ( ++mem_lst[thr_idx].idx_cnt % thr_quota_step == 0 && nco_dbg_lvl_get() >=3 ) (void)fprintf(fp_stderr, "%s: thread %d has processed %2.2f%% (%ld) of src cells quota and output %ld overlap cells\n", nco_prg_nm_get(), thr_idx, (float)mem_lst[thr_idx].idx_cnt/(float)thr_quota 100.0, mem_lst[thr_idx].idx_cnt, mem_lst[thr_idx].pl_cnt ); } /* end for idx / / turn tot_area into a % of 4PI / /* tot_area = tot_area / 4.0 / M_PI 100.0; / /* final report / if (nco_dbg_lvl_get() >= nco_dbg_dev) (void) fprintf(stderr, "%s: total overlaps=%d, total_area=%.15f (area=%3.10f%%) total num wrapped= %d total nan nbr=%d \n", nco_prg_nm_get(), pl_cnt_vrl, tot_area, tot_area /4.0 / M_PI 100.0, tot_wrp_cnt, tot_nan_cnt); /* write filtered polygons to file / if(bDirtyRats && pl_cnt_dbg){ nco_msh_poly_lst_wrt("tst-wrt-dbg.nc", pl_lst_dbg, pl_cnt_dbg, grd_lon_typ,NC_FORMAT_NETCDF4); pl_lst_dbg=(poly_sct )nco_poly_lst_free(pl_lst_dbg, pl_cnt_dbg); } / concatenate memory list, place results into first member list / nco_mem_lst_cat(mem_lst, lcl_thr_nbr); / free up kd_list's / for(idx=0;idx<lcl_thr_nbr;idx++) kd_list_realloc(&mem_lst[idx],0); pl_cnt_vrl_ret=mem_lst[0].pl_cnt; if(lst_out_typ == 1) void_lst_vrl=(void )mem_lst[0].wgt_lst; else if(lst_out_typ == 2) void_lst_vrl=(void )mem_lst[0].pl_lst; mem_lst=(omp_mem_sct)nco_free(mem_lst); / REMEMBER the void type can be a wgt_sct array or a poly_sct array * wgt_sct is a subset of poly_sct - with simple members / return void_lst_vrl; } / check areas - nb WARNING modifies area in pl_lst_in and pl_lst_out / void nco_poly_lst_chk( poly_sct pl_lst_in, int pl_cnt_in, poly_sct pl_lst_out, int pl_cnt_out, poly_sct pl_lst_vrl, int pl_cnt_vrl) { int id; int idx; int jdx; double epsilon=1.0e-8; const char fnc_nm[]="nco_poly_lst_chk()"; for(idx=0;idx<pl_cnt_vrl;idx++) { id=pl_lst_vrl[idx]->src_id; for(jdx=0;jdx<pl_cnt_in;jdx++) if(pl_lst_in[jdx]->src_id==id) break; if(jdx < pl_cnt_in ) pl_lst_in[jdx]->area-=pl_lst_vrl[idx]->area; } fprintf(stderr, "%s():WARNING following is list of incomplete src cells, by src_id no\n",fnc_nm); for(idx=0;idx<pl_cnt_in;idx++) if( fabs( pl_lst_in[idx]->area) > epsilon) fprintf(stderr, "src_id=%d area=%.10f\n", pl_lst_in[idx]->src_id, pl_lst_in[idx]->area ); for(idx=0;idx<pl_cnt_vrl;idx++) { id=pl_lst_vrl[idx]->dst_id; for(jdx=0;jdx<pl_cnt_out;jdx++) if(pl_lst_out[jdx]->src_id==id) break; if(jdx < pl_cnt_out ) pl_lst_out[jdx]->area-=pl_lst_vrl[idx]->area; } fprintf(stderr, "%s():WARNING following is list of incomplete dst cells, by src_id no\n",fnc_nm); for(idx=0;idx<pl_cnt_out;idx++) if( fabs( pl_lst_out[idx]->area) > epsilon) fprintf(stderr, "src_id=%d area=%.10f\n", pl_lst_out[idx]->src_id, pl_lst_out[idx]->area ); return; } poly_sct * nco_poly_lst_chk_dbg( poly_sct pl_lst, int pl_cnt, poly_sct pl_lst_vrl, int pl_cnt_vrl, int io_flg, /* [flg] 0 - use src_id from vrl, 1 - use dst_id from vrl / int pl_cnt_dbg) /* size of output dbg grid / { int id; int idx; int jdx; int pl_nbr_dbg=0; double epsilon=1.0e-12; double area=NULL_CEWI; nco_bool is_lst_cnt=False; /* if true then pl_cnt matches max src_id There are no missing records from NetCDF SCRIP input / is_lst_cnt=( pl_cnt== pl_lst[pl_cnt-1]->src_id +1); poly_sct pl_lst_dbg=NULL_CEWI; const char fnc_nm[]="nco_poly_lst_chk_dbg()"; area=(double)nco_malloc(sizeof(double)pl_cnt); for(idx=0;idx<pl_cnt;idx++) if(!pl_lst[idx]->bmsk) area[idx]=0.0; else area[idx]=pl_lst[idx]->area; for(idx=0;idx<pl_cnt_vrl;idx++) { id = (io_flg ? pl_lst_vrl[idx]->dst_id : pl_lst_vrl[idx]->src_id); if(is_lst_cnt ) area[id] -= pl_lst_vrl[idx]->area; else { for (jdx = 0; jdx < pl_cnt; jdx++) if (pl_lst[jdx]->src_id == id) break; if (jdx < pl_cnt) area[jdx] -= pl_lst_vrl[idx]->area; } } for(idx=0;idx<pl_cnt;idx++) { if (fabs(area[idx]) > epsilon) { if (nco_dbg_lvl_get() >= nco_dbg_dev) fprintf(stderr, "%s() src_id=%d area=%.15e\n", fnc_nm, pl_lst[idx]->src_id, area[idx]); pl_lst_dbg = (poly_sct ) nco_realloc(pl_lst_dbg, sizeof(poly_sct) * (pl_nbr_dbg + 1)); pl_lst_dbg[pl_nbr_dbg] = nco_poly_dpl(pl_lst[idx]); pl_nbr_dbg++; } } area=(double)nco_free(area); pl_cnt_dbg=pl_nbr_dbg; return pl_lst_dbg; } /* stub function / #ifdef TEMP wgt_sct * nco_poly_lst_mk_idw_sph( rgr_sct const rgr_nfo, poly_sct pl_lst_out, int pl_cnt, nco_grd_lon_typ_enm grd_lon_typ, KDTree tree, int nbr_tr, int wgt_cnt_bln_ret) { } #endif wgt_sct ** nco_poly_lst_mk_idw_sph( rgr_sct const rgr_nfo, poly_sct pl_lst_out, int pl_cnt, nco_grd_lon_typ_enm grd_lon_typ, KDTree tree, int nbr_tr, int wgt_cnt_bln_ret) { /* just duplicate output list to overlap / const char fnc_nm[] = "nco_poly_lst_mk_idw_sph()"; int thr_idx = 0; / approx number of input cells each thread will process / int thr_quota; / reporting step / int thr_quota_step; / max number of nearest neighbours to consider - nr-reference from rgr_nfo / int const max_nbr_idw=20; int nbr_idw=0; double pow_idw=0.0; double min_dist=1.0e-12; double min_wgt=1.0e-20; poly_typ_enm pl_typ; size_t idx; int lcl_thr_nbr; omp_mem_sct mem_lst = NULL_CEWI; wgt_sct *wgt_lst_idw = NULL_CEWI; FILE const fp_stderr = stderr; pl_typ = pl_lst_out[0]->pl_typ; lcl_thr_nbr = omp_get_max_threads(); nbr_idw= ( rgr_nfo->xtr_nsp > max_nbr_idw ? max_nbr_idw : rgr_nfo->xtr_nsp ); pow_idw=rgr_nfo->xtr_xpn; mem_lst = (omp_mem_sct ) nco_malloc(sizeof(omp_mem_sct) lcl_thr_nbr); for (idx = 0; idx < lcl_thr_nbr; idx++) { mem_lst[idx].pl_lst = NULL_CEWI; mem_lst[idx].wgt_lst = NULL_CEWI; mem_lst[idx].blk_nbr = 0; mem_lst[idx].pl_cnt = 0; mem_lst[idx].kd_list = NULL_CEWI; mem_lst[idx].kd_cnt = 0; mem_lst[idx].kd_blk_nbr = 0; mem_lst[idx].idx_cnt = 0; kd_list_realloc(&mem_lst[idx],1); } thr_quota = pl_cnt / lcl_thr_nbr; thr_quota_step = thr_quota / 20; if (thr_quota_step < 2000) thr_quota_step = 2000; /* NB: "OpenMP notes" section of nco_rgr.c has detailed discussion of these settings Henry, please keep the variables in alphabetical order within a clause and remember to update Intel / #ifdef __GNUG__ # define GCC_LIB_VERSION ( __GNUC__ 100 + __GNUC_MINOR__ * 10 + __GNUC_PATCHLEVEL__ ) # if GCC_LIB_VERSION < 490 # define GXX_OLD_OPENMP_SHARED_TREATMENT 1 # endif /* 480 / #endif / !__GNUC__ / #if defined(__INTEL_COMPILER) # pragma omp parallel for private(idx,thr_idx) schedule(dynamic,40) shared(grd_lon_typ,nbr_tr,pl_typ,tree) #else / !__INTEL_COMPILER / # ifdef GXX_OLD_OPENMP_SHARED_TREATMENT # pragma omp parallel for default(none) private(idx,thr_idx) shared(bDirtyRats,grd_lon_typ,max_nbr_vrl,nbr_tr,pl_cnt_dbg,pl_typ,tree,tot_nan_cnt,tot_wrp_cnt) # else / !old g++ / # pragma omp parallel for private(idx,thr_idx) schedule(dynamic,40) shared(grd_lon_typ,nbr_tr,pl_typ,tree) # endif / !old g++ / #endif / !__INTEL_COMPILER / for (idx = 0; idx < pl_cnt; idx++) { double dp_x_wrp; / used to do a wrapped lon search / double wgt_ttl=0.0; int nbr_idw_cnt; / equal to or less than nbr_nni / wgt_sct wgt_pre[max_nbr_idw]; wgt_sct wgt_lcl=NULL_CEWI; poly_sct pl=NULL_CEWI; size_t jdx; size_t kdx; size_t nbr_lst_lcl; // (void) nco_poly_set_priority(max_nbr_vrl, list); thr_idx = omp_get_thread_num(); if (0 && nco_dbg_lvl_get() >= nco_dbg_dev) fprintf(fp_stderr, "%s(): idx=%lu thr=%d\n", fnc_nm, idx, thr_idx); if (pl_lst_out[idx]->bmsk == False) continue; mem_lst[thr_idx].kd_cnt = 0; if (mem_lst[thr_idx].kd_blk_nbr > 1) kd_list_realloc(&mem_lst[thr_idx], 1); / get bounds of polygon in / //bSplit = nco_poly_minmax_split(pl_lst_out[idx], grd_lon_typ, size1, size2); dp_x_wrp=KD_DBL_MAX; for(kdx=0;kdx<nbr_tr;kdx++) kd_nearest(tree[kdx], pl_lst_out[idx]->dp_x_ctr, pl_lst_out[idx]->dp_y_ctr, pl_typ, nbr_idw, &mem_lst[thr_idx].kd_list[0] + nbr_idw kdx ); nbr_lst_lcl=nbr_idwnbr_tr; switch(grd_lon_typ) { case nco_grd_lon_nil: case nco_grd_lon_unk: case nco_grd_lon_Grn_ctr: case nco_grd_lon_Grn_wst: case nco_grd_lon_bb: if(pl_lst_out[idx]->dp_x_ctr <180.0) dp_x_wrp=pl_lst_out[idx]->dp_x_ctr+360.0; else if(pl_lst_out[idx]->dp_x_ctr >180.0) dp_x_wrp=pl_lst_out[idx]->dp_x_ctr-360.0; break; case nco_grd_lon_180_wst: case nco_grd_lon_180_ctr: if(pl_lst_out[idx]->dp_x_ctr <0.0) dp_x_wrp=pl_lst_out[idx]->dp_x_ctr+360.0; else if(pl_lst_out[idx]->dp_x_ctr >0.0) dp_x_wrp=pl_lst_out[idx]->dp_x_ctr-360.0; break; } if(dp_x_wrp != KD_DBL_MAX) { for (kdx = 0; kdx < nbr_tr; kdx++) kd_nearest(tree[kdx], dp_x_wrp, pl_lst_out[idx]->dp_y_ctr, pl_typ, nbr_idw, &mem_lst[thr_idx].kd_list[0] + nbr_lst_lcl+nbr_idw kdx); nbr_lst_lcl+=nbr_idwnbr_tr; } if(nbr_tr >1 ) qsort((void )mem_lst[thr_idx].kd_list, nbr_lst_lcl, sizeof(KDPriority), kd_priority_cmp_dist); / remember kd list sorted according to distance / / check first member distance if min then output singleton / if(mem_lst[thr_idx].kd_list[0]->dist <= min_dist) { pl=(poly_sct)mem_lst[thr_idx].kd_list[0]->elem->item; wgt_lcl=(wgt_sct)nco_malloc(sizeof(wgt_sct)); wgt_lcl->src_id=pl->src_id; wgt_lcl->dst_id=pl_lst_out[idx]->src_id; wgt_lcl->area=pl->area; wgt_lcl->dist=mem_lst[thr_idx].kd_list[0]->dist; wgt_lcl->wgt=1.0; if( mem_lst[thr_idx].blk_nbr NCO_VRL_BLOCKSIZE < mem_lst[thr_idx].pl_cnt +1 ) mem_lst[thr_idx].wgt_lst= (wgt_sct*)nco_realloc(mem_lst[thr_idx].wgt_lst, sizeof(wgt_sct) * ++mem_lst[thr_idx].blk_nbr * NCO_VRL_BLOCKSIZE ); mem_lst[thr_idx].wgt_lst[mem_lst[thr_idx].pl_cnt++] =wgt_lcl; if (nco_dbg_lvl_get() >= nco_dbg_dev) (void)fprintf(fp_stderr,"%s:%s: singleton x_ctr=%f y_ctr=%f\n", nco_prg_nm_get(), fnc_nm, pl_lst_out[idx]->dp_x_ctr, pl_lst_out[idx]->dp_y_ctr ); }else{ /* check for duplicates in first nbr_nni by sorting again with ->item !!!/ // kd_priority_list_sort(mem_lst[thr_idx].kd_list,nbr_idw, nbr_idw,&nbr_idw_cnt ); nbr_idw_cnt=kd_list_sort_omp(&mem_lst[thr_idx], nbr_idw); if (nco_dbg_lvl_get() >= nco_dbg_dev && nbr_idw_cnt < nbr_idw ) (void)fprintf(fp_stderr,"%s:%s: nbr_nni_cnt=%d x_ctr=%f y_ctr=%f\n", nco_prg_nm_get(), fnc_nm, nbr_idw_cnt, pl_lst_out[idx]->dp_x_ctr, pl_lst_out[idx]->dp_y_ctr ); / output at least one / for (jdx = 0; jdx < nbr_idw_cnt; jdx++) { pl = (poly_sct ) mem_lst[thr_idx].kd_list[jdx]->elem->item; /* remember src is in tree and dst is in list / wgt_pre[jdx].src_id = pl->src_id; wgt_pre[jdx].dst_id = pl_lst_out[idx]->src_id; wgt_pre[jdx].area = pl->area; wgt_pre[jdx].dist = mem_lst[thr_idx].kd_list[jdx]->dist; / use dist squared / wgt_pre[jdx].wgt = 1.0 / pow(wgt_pre[jdx].dist, pow_idw); } / find weights total / for (jdx = 0; jdx < nbr_idw_cnt; jdx++) wgt_ttl += wgt_pre[jdx].wgt; / normalize weights / for (jdx = 0; jdx < nbr_idw_cnt; jdx++) wgt_pre[jdx].wgt /= wgt_ttl; for (jdx = 0; jdx < nbr_idw_cnt; jdx++) { if (wgt_pre[jdx].wgt < min_wgt) continue; wgt_lcl = (wgt_sct ) nco_malloc(sizeof(wgt_sct)); wgt_lcl = wgt_pre[jdx]; if (mem_lst[thr_idx].blk_nbr NCO_VRL_BLOCKSIZE < mem_lst[thr_idx].pl_cnt + 1) mem_lst[thr_idx].wgt_lst = (wgt_sct *) nco_realloc(mem_lst[thr_idx].wgt_lst,sizeof(wgt_sct ) * ++mem_lst[thr_idx].blk_nbr NCO_VRL_BLOCKSIZE); mem_lst[thr_idx].wgt_lst[mem_lst[thr_idx].pl_cnt++] = wgt_lcl; //(void)fprintf(stderr,"%s: weight(%lu)=%f ",fnc_nm, mem_lst[thr_idx].pl_cnt, wgt_lcl->wgt); } / end jdx / } / output some usefull tracking stuff - not debug but informative / if ( ++mem_lst[thr_idx].idx_cnt % thr_quota_step == 0 && nco_dbg_lvl_get() >=3 ) (void)fprintf(fp_stderr, "%s: thread %d has processed %2.2f%% (%ld) of src cells quota and output %ld overlap cells\n", nco_prg_nm_get(), thr_idx, (float)mem_lst[thr_idx].idx_cnt/(float)thr_quota 100.0, mem_lst[thr_idx].idx_cnt, mem_lst[thr_idx].pl_cnt ); } /* end idx / nco_mem_lst_cat(mem_lst, lcl_thr_nbr); / free up kd_list's / for(idx=0;idx<lcl_thr_nbr;idx++) kd_list_realloc(&mem_lst[idx],0); wgt_lst_idw=mem_lst[0].wgt_lst; wgt_cnt_bln_ret=mem_lst[0].pl_cnt; mem_lst=(omp_mem_sct)nco_free(mem_lst); return wgt_lst_idw; } / !nco_poly_lst_mk_idw_sph() / void nco_poly_lst_ctr_add( poly_sct pl_lst, int pl_cnt, int ctr_typ) { int idx; double pControl[NBR_SPH]; for(idx=0;idx<pl_cnt;idx++) { if(pl_lst[idx]->crn_nbr <3 \|\| pl_lst[idx]->area==0.0 ) continue; if(ctr_typ==1){ nco_sph_inside_mk(pl_lst[idx], pControl); pl_lst[idx]->dp_x_ctr=R2D(pControl[3]); pl_lst[idx]->dp_y_ctr=R2D(pControl[4]); } } return; } / !nco_poly_lst_ctr_add() / void nco_mem_lst_cat( omp_mem_sct mem_lst, int sz_lst) { int idx; int i_typ; size_t tot_cnt = 0; if(mem_lst->wgt_lst) i_typ = 1; else if(mem_lst->pl_lst) i_typ = 2; else i_typ=0; /* quick return if list empty / if(!i_typ) return; / find total size of lists / for (idx = 0; idx < sz_lst; idx++) tot_cnt += mem_lst[idx].pl_cnt; if(!tot_cnt) return; else if( i_typ==1 ){ wgt_sct tmp_wgt_lst = NULL; tmp_wgt_lst = mem_lst[0].wgt_lst = (wgt_sct ) nco_realloc(mem_lst[0].wgt_lst, sizeof(wgt_sct ) * tot_cnt); tmp_wgt_lst += mem_lst[0].pl_cnt; for (idx = 1; idx < sz_lst; idx++) { if (mem_lst[idx].wgt_lst) { memcpy(tmp_wgt_lst, mem_lst[idx].wgt_lst, sizeof(wgt_sct ) mem_lst[idx].pl_cnt); tmp_wgt_lst += mem_lst[idx].pl_cnt; /* free up list / mem_lst[idx].wgt_lst = (wgt_sct ) nco_free(mem_lst[idx].wgt_lst); } } } else if(i_typ==2) { poly_sct tmp_ply_lst = NULL; tmp_ply_lst = mem_lst[0].pl_lst = (poly_sct ) nco_realloc(mem_lst[0].pl_lst, sizeof(poly_sct ) * tot_cnt); tmp_ply_lst += mem_lst[0].pl_cnt; for (idx = 1; idx < sz_lst; idx++) { if (mem_lst[idx].pl_lst) { memcpy(tmp_ply_lst, mem_lst[idx].pl_lst, sizeof(poly_sct ) mem_lst[idx].pl_cnt); tmp_ply_lst += mem_lst[idx].pl_cnt; /* free up list / mem_lst[idx].pl_lst = (poly_sct ) nco_free(mem_lst[idx].pl_lst); } } } / update first list with total / mem_lst[0].pl_cnt=tot_cnt; return; } / !nco_mem_lst_cat() */
residualbased_predictorcorrector_velocity_bossak_scheme_turbulent.h	// \| / \| // ' / __\| _` \| __\| _ \ __\| // . \ \| ( \| \| ( \|\__ ` // _\|\_\_\| \__,_\|\__\|\___/ ____/ // Multi-Physics // // License: BSD License // Kratos default license: kratos/license.txt // // Main authors: Jordi Cotela // #if !defined(KRATOS_RESIDUALBASED_PREDICTOR_CORRECTOR_VELOCITY_BOSSAK_TURBULENT_SCHEME ) #define KRATOS_RESIDUALBASED_PREDICTOR_CORRECTOR_VELOCITY_BOSSAK_TURBULENT_SCHEME /* System includes / / External includes / #include "boost/smart_ptr.hpp" / Project includes / #include "includes/define.h" #include "includes/model_part.h" #include "includes/deprecated_variables.h" #include "solving_strategies/schemes/scheme.h" #include "includes/variables.h" #include "includes/cfd_variables.h" #include "containers/array_1d.h" #include "utilities/openmp_utils.h" #include "utilities/dof_updater.h" #include "utilities/coordinate_transformation_utilities.h" #include "processes/process.h" namespace Kratos { /@name Kratos Globals / /@{ / /@} / /*@name Type Definitions / /@{ / /@} / /*@name Enum's / /@{ / /@} / /*@name Functions / /@{ / /@} / /*@name Kratos Classes / /@{ / /// Bossak time scheme for the incompressible flow problem. /** This class provides a second order time scheme of the generalized-alpha Newmark family of methods. It also includes code required to implement slip conditions on the incompressible flow problem and provides the possibility of using a RANS model by passing a turbulence model as an argument to the constructor. This time scheme is intended to be used in combination with elements of type ASGS2D, ASGS3D, VMS or derived classes. To use the slip condition, set the SLIP flag on slip wall nodes. To use a wall law in combination with the slip condition, use MonolithicWallCondition to mesh the boundary @see ASGS2D, ASGS3D, VMS, MonolithicWallConditon / template<class TSparseSpace, class TDenseSpace //= DenseSpace<double> > class ResidualBasedPredictorCorrectorVelocityBossakSchemeTurbulent : public Scheme<TSparseSpace, TDenseSpace> { public: /@name Type Definitions / /@{ / KRATOS_CLASS_POINTER_DEFINITION(ResidualBasedPredictorCorrectorVelocityBossakSchemeTurbulent); typedef Scheme<TSparseSpace, TDenseSpace> BaseType; typedef typename BaseType::TDataType TDataType; typedef typename BaseType::DofsArrayType DofsArrayType; typedef typename Element::DofsVectorType DofsVectorType; typedef typename BaseType::TSystemMatrixType TSystemMatrixType; typedef typename BaseType::TSystemVectorType TSystemVectorType; typedef typename BaseType::LocalSystemVectorType LocalSystemVectorType; typedef typename BaseType::LocalSystemMatrixType LocalSystemMatrixType; typedef Element::GeometryType GeometryType; /@} / /*@name Life Cycle / /@{ / /** Constructor without a turbulence model / ResidualBasedPredictorCorrectorVelocityBossakSchemeTurbulent( double NewAlphaBossak, double MoveMeshStrategy, unsigned int DomainSize) : Scheme<TSparseSpace, TDenseSpace>(), mRotationTool(DomainSize,DomainSize+1,SLIP), // Second argument is number of matrix rows per node: monolithic elements have velocity and pressure dofs. mrPeriodicIdVar(Kratos::Variable<int>::StaticObject()) { //default values for the Newmark Scheme mAlphaBossak = NewAlphaBossak; mBetaNewmark = 0.25 pow((1.00 - mAlphaBossak), 2); mGammaNewmark = 0.5 - mAlphaBossak; mMeshVelocity = MoveMeshStrategy; //Allocate auxiliary memory int NumThreads = OpenMPUtils::GetNumThreads(); mMass.resize(NumThreads); mDamp.resize(NumThreads); mvel.resize(NumThreads); macc.resize(NumThreads); maccold.resize(NumThreads); } /** Constructor without a turbulence model with periodic conditions / ResidualBasedPredictorCorrectorVelocityBossakSchemeTurbulent( double NewAlphaBossak, unsigned int DomainSize, const Variable<int>& rPeriodicIdVar) : Scheme<TSparseSpace, TDenseSpace>(), mRotationTool(DomainSize,DomainSize+1,SLIP), // Second argument is number of matrix rows per node: monolithic elements have velocity and pressure dofs. mrPeriodicIdVar(rPeriodicIdVar) { //default values for the Newmark Scheme mAlphaBossak = NewAlphaBossak; mBetaNewmark = 0.25 pow((1.00 - mAlphaBossak), 2); mGammaNewmark = 0.5 - mAlphaBossak; mMeshVelocity = 0.0; //Allocate auxiliary memory int NumThreads = OpenMPUtils::GetNumThreads(); mMass.resize(NumThreads); mDamp.resize(NumThreads); mvel.resize(NumThreads); macc.resize(NumThreads); maccold.resize(NumThreads); } /** Constructor without a turbulence model / ResidualBasedPredictorCorrectorVelocityBossakSchemeTurbulent( double NewAlphaBossak, double MoveMeshStrategy, unsigned int DomainSize, Kratos::Flags& rSlipFlag) : Scheme<TSparseSpace, TDenseSpace>(), mRotationTool(DomainSize,DomainSize+1,rSlipFlag), // Second argument is number of matrix rows per node: monolithic elements have velocity and pressure dofs. mrPeriodicIdVar(Kratos::Variable<int>::StaticObject()) { //default values for the Newmark Scheme mAlphaBossak = NewAlphaBossak; mBetaNewmark = 0.25 pow((1.00 - mAlphaBossak), 2); mGammaNewmark = 0.5 - mAlphaBossak; mMeshVelocity = MoveMeshStrategy; //Allocate auxiliary memory int NumThreads = OpenMPUtils::GetNumThreads(); mMass.resize(NumThreads); mDamp.resize(NumThreads); mvel.resize(NumThreads); macc.resize(NumThreads); maccold.resize(NumThreads); } /** Constructor with a turbulence model / ResidualBasedPredictorCorrectorVelocityBossakSchemeTurbulent( double NewAlphaBossak, double MoveMeshStrategy, unsigned int DomainSize, Process::Pointer pTurbulenceModel) : Scheme<TSparseSpace, TDenseSpace>(), mRotationTool(DomainSize,DomainSize+1,SLIP), // Second argument is number of matrix rows per node: monolithic elements have velocity and pressure dofs mrPeriodicIdVar(Kratos::Variable<int>::StaticObject()), mpTurbulenceModel(pTurbulenceModel) { //default values for the Newmark Scheme mAlphaBossak = NewAlphaBossak; mBetaNewmark = 0.25 pow((1.00 - mAlphaBossak), 2); mGammaNewmark = 0.5 - mAlphaBossak; mMeshVelocity = MoveMeshStrategy; //Allocate auxiliary memory int NumThreads = OpenMPUtils::GetNumThreads(); mMass.resize(NumThreads); mDamp.resize(NumThreads); mvel.resize(NumThreads); macc.resize(NumThreads); maccold.resize(NumThreads); } /** Constructor with a turbulence model and relaxation factor / ResidualBasedPredictorCorrectorVelocityBossakSchemeTurbulent( double NewAlphaBossak, double MoveMeshStrategy, unsigned int DomainSize, const double RelaxationFactor, Process::Pointer pTurbulenceModel) : Scheme<TSparseSpace, TDenseSpace>(), mRotationTool(DomainSize,DomainSize+1,SLIP), // Second argument is number of matrix rows per node: monolithic elements have velocity and pressure dofs mrPeriodicIdVar(Kratos::Variable<int>::StaticObject()), mpTurbulenceModel(pTurbulenceModel) { //default values for the Newmark Scheme mAlphaBossak = NewAlphaBossak; mBetaNewmark = 0.25 pow((1.00 - mAlphaBossak), 2); mGammaNewmark = 0.5 - mAlphaBossak; mMeshVelocity = MoveMeshStrategy; mRelaxationFactor = RelaxationFactor; //Allocate auxiliary memory int NumThreads = OpenMPUtils::GetNumThreads(); mMass.resize(NumThreads); mDamp.resize(NumThreads); mvel.resize(NumThreads); macc.resize(NumThreads); maccold.resize(NumThreads); } /** Destructor. / ~ResidualBasedPredictorCorrectorVelocityBossakSchemeTurbulent() override { } /@} / /@name Operators / /@{ / /** Performing the update of the solution. / //************************************************************************ void Update(ModelPart& r_model_part, DofsArrayType& rDofSet, TSystemMatrixType& A, TSystemVectorType& Dv, TSystemVectorType& b) override { KRATOS_TRY; mRotationTool.RotateVelocities(r_model_part); TSparseSpace::InplaceMult(Dv, mRelaxationFactor); mpDofUpdater->UpdateDofs(rDofSet,Dv); mRotationTool.RecoverVelocities(r_model_part); AdditionalUpdateOperations(r_model_part, rDofSet, A, Dv, b); KRATOS_CATCH("") } //*********************************************************************** void AdditionalUpdateOperations(ModelPart& rModelPart, DofsArrayType& rDofSet, TSystemMatrixType& A, TSystemVectorType& Dv, TSystemVectorType& b) { KRATOS_TRY int NumThreads = OpenMPUtils::GetNumThreads(); OpenMPUtils::PartitionVector NodePartition; OpenMPUtils::DivideInPartitions(rModelPart.Nodes().size(), NumThreads, NodePartition); //updating time derivatives (nodally for efficiency) #pragma omp parallel { array_1d<double, 3 > DeltaVel; int k = OpenMPUtils::ThisThread(); ModelPart::NodeIterator NodesBegin = rModelPart.NodesBegin() + NodePartition[k]; ModelPart::NodeIterator NodesEnd = rModelPart.NodesBegin() + NodePartition[k + 1]; for (ModelPart::NodeIterator itNode = NodesBegin; itNode != NodesEnd; itNode++) { noalias(DeltaVel) = (itNode)->FastGetSolutionStepValue(VELOCITY) - (itNode)->FastGetSolutionStepValue(VELOCITY, 1); array_1d<double, 3 > & CurrentAcceleration = (itNode)->FastGetSolutionStepValue(ACCELERATION, 0); array_1d<double, 3 > & OldAcceleration = (itNode)->FastGetSolutionStepValue(ACCELERATION, 1); UpdateAcceleration(CurrentAcceleration, DeltaVel, OldAcceleration); if (mMeshVelocity == 2)//Lagrangian { if((itNode)->FastGetSolutionStepValue(IS_LAGRANGIAN_INLET) < 1e-15) { array_1d<double, 3 > & CurrentDisplacement = (itNode)->FastGetSolutionStepValue(DISPLACEMENT, 0); array_1d<double, 3 > & OldDisplacement = (itNode)->FastGetSolutionStepValue(DISPLACEMENT, 1); array_1d<double, 3 > & OldVelocity = (itNode)->FastGetSolutionStepValue(VELOCITY, 1); noalias(itNode->FastGetSolutionStepValue(MESH_VELOCITY)) = itNode->FastGetSolutionStepValue(VELOCITY); UpdateDisplacement(CurrentDisplacement, OldDisplacement, OldVelocity, OldAcceleration, CurrentAcceleration); } else { noalias(itNode->FastGetSolutionStepValue(MESH_VELOCITY)) = ZeroVector(3); noalias(itNode->FastGetSolutionStepValue(DISPLACEMENT)) = ZeroVector(3); } } } } KRATOS_CATCH("") } //*********************************************************************** //predicts the solution at the current step as // v = vold void Predict(ModelPart& rModelPart, DofsArrayType& rDofSet, TSystemMatrixType& A, TSystemVectorType& Dv, TSystemVectorType& b) override { // if (rModelPart.GetCommunicator().MyPID() == 0) // std::cout << "prediction" << std::endl; int NumThreads = OpenMPUtils::GetNumThreads(); OpenMPUtils::PartitionVector NodePartition; OpenMPUtils::DivideInPartitions(rModelPart.Nodes().size(), NumThreads, NodePartition); #pragma omp parallel { //array_1d<double, 3 > DeltaDisp; int k = OpenMPUtils::ThisThread(); ModelPart::NodeIterator NodesBegin = rModelPart.NodesBegin() + NodePartition[k]; ModelPart::NodeIterator NodesEnd = rModelPart.NodesBegin() + NodePartition[k + 1]; for (ModelPart::NodeIterator itNode = NodesBegin; itNode != NodesEnd; itNode++) { array_1d<double, 3 > & OldVelocity = (itNode)->FastGetSolutionStepValue(VELOCITY, 1); double& OldPressure = (itNode)->FastGetSolutionStepValue(PRESSURE, 1); //predicting velocity //ATTENTION::: the prediction is performed only on free nodes array_1d<double, 3 > & CurrentVelocity = (itNode)->FastGetSolutionStepValue(VELOCITY); double& CurrentPressure = (itNode)->FastGetSolutionStepValue(PRESSURE); if ((itNode->pGetDof(VELOCITY_X))->IsFree()) (CurrentVelocity[0]) = OldVelocity[0]; if (itNode->pGetDof(VELOCITY_Y)->IsFree()) (CurrentVelocity[1]) = OldVelocity[1]; if (itNode->HasDofFor(VELOCITY_Z)) if (itNode->pGetDof(VELOCITY_Z)->IsFree()) (CurrentVelocity[2]) = OldVelocity[2]; if (itNode->pGetDof(PRESSURE)->IsFree()) CurrentPressure = OldPressure; // updating time derivatives ::: please note that displacements and // their time derivatives can not be consistently fixed separately array_1d<double, 3 > DeltaVel; noalias(DeltaVel) = CurrentVelocity - OldVelocity; array_1d<double, 3 > & OldAcceleration = (itNode)->FastGetSolutionStepValue(ACCELERATION, 1); array_1d<double, 3 > & CurrentAcceleration = (itNode)->FastGetSolutionStepValue(ACCELERATION); UpdateAcceleration(CurrentAcceleration, DeltaVel, OldAcceleration); if (mMeshVelocity == 2) //Lagrangian { array_1d<double, 3 > & OldDisplacement = (itNode)->FastGetSolutionStepValue(DISPLACEMENT, 1); array_1d<double, 3 > & CurrentDisplacement = (itNode)->FastGetSolutionStepValue(DISPLACEMENT, 0); if((itNode)->FastGetSolutionStepValue(IS_LAGRANGIAN_INLET) < 1e-15) { noalias(itNode->FastGetSolutionStepValue(MESH_VELOCITY)) = itNode->FastGetSolutionStepValue(VELOCITY); UpdateDisplacement(CurrentDisplacement, OldDisplacement, OldVelocity, OldAcceleration, CurrentAcceleration); } else { itNode->FastGetSolutionStepValue(MESH_VELOCITY_X) = 0.0; itNode->FastGetSolutionStepValue(MESH_VELOCITY_Y) = 0.0; itNode->FastGetSolutionStepValue(DISPLACEMENT_X) = 0.0; itNode->FastGetSolutionStepValue(DISPLACEMENT_Y) = 0.0; } } } } // if (rModelPart.GetCommunicator().MyPID() == 0) // std::cout << "end of prediction" << std::endl; } //*********************************************************************** / this function is designed to be called in the builder and solver to introduce the selected time integration scheme. It "asks" the matrix needed to the element and performs the operations needed to introduce the seected time integration scheme. this function calculates at the same time the contribution to the LHS and to the RHS of the system / void CalculateSystemContributions( Element& rCurrentElement, LocalSystemMatrixType& LHS_Contribution, LocalSystemVectorType& RHS_Contribution, Element::EquationIdVectorType& EquationId, const ProcessInfo& CurrentProcessInfo) override { KRATOS_TRY int k = OpenMPUtils::ThisThread(); //Initializing the non linear iteration for the current element rCurrentElement.InitializeNonLinearIteration(CurrentProcessInfo); //basic operations for the element considered rCurrentElement.CalculateLocalSystem(LHS_Contribution, RHS_Contribution, CurrentProcessInfo); rCurrentElement.CalculateMassMatrix(mMass[k], CurrentProcessInfo); rCurrentElement.CalculateLocalVelocityContribution(mDamp[k], RHS_Contribution, CurrentProcessInfo); rCurrentElement.EquationIdVector(EquationId, CurrentProcessInfo); //adding the dynamic contributions (statics is already included) AddDynamicsToLHS(LHS_Contribution, mDamp[k], mMass[k], CurrentProcessInfo); AddDynamicsToRHS(rCurrentElement, RHS_Contribution, mDamp[k], mMass[k], CurrentProcessInfo); // If there is a slip condition, apply it on a rotated system of coordinates mRotationTool.Rotate(LHS_Contribution,RHS_Contribution,rCurrentElement.GetGeometry()); mRotationTool.ApplySlipCondition(LHS_Contribution,RHS_Contribution,rCurrentElement.GetGeometry()); KRATOS_CATCH("") } void CalculateRHSContribution( Element& rCurrentElement, LocalSystemVectorType& RHS_Contribution, Element::EquationIdVectorType& EquationId, const ProcessInfo& CurrentProcessInfo) override { int k = OpenMPUtils::ThisThread(); //Initializing the non linear iteration for the current element rCurrentElement.InitializeNonLinearIteration(CurrentProcessInfo); //basic operations for the element considered rCurrentElement.CalculateRightHandSide(RHS_Contribution, CurrentProcessInfo); rCurrentElement.CalculateMassMatrix(mMass[k], CurrentProcessInfo); rCurrentElement.CalculateLocalVelocityContribution(mDamp[k], RHS_Contribution, CurrentProcessInfo); rCurrentElement.EquationIdVector(EquationId, CurrentProcessInfo); //adding the dynamic contributions (static is already included) AddDynamicsToRHS(rCurrentElement, RHS_Contribution, mDamp[k], mMass[k], CurrentProcessInfo); // If there is a slip condition, apply it on a rotated system of coordinates mRotationTool.Rotate(RHS_Contribution,rCurrentElement.GetGeometry()); mRotationTool.ApplySlipCondition(RHS_Contribution,rCurrentElement.GetGeometry()); } /* functions totally analogous to the precedent but applied to the "condition" objects / void CalculateSystemContributions( Condition& rCurrentCondition, LocalSystemMatrixType& LHS_Contribution, LocalSystemVectorType& RHS_Contribution, Element::EquationIdVectorType& EquationId, const ProcessInfo& CurrentProcessInfo) override { KRATOS_TRY int k = OpenMPUtils::ThisThread(); rCurrentCondition.InitializeNonLinearIteration(CurrentProcessInfo); rCurrentCondition.CalculateLocalSystem(LHS_Contribution, RHS_Contribution, CurrentProcessInfo); rCurrentCondition.CalculateMassMatrix(mMass[k], CurrentProcessInfo); //rCurrentCondition.CalculateDampingMatrix(VelocityBossakAuxiliaries::mDamp,CurrentProcessInfo); rCurrentCondition.CalculateLocalVelocityContribution(mDamp[k], RHS_Contribution, CurrentProcessInfo); rCurrentCondition.EquationIdVector(EquationId, CurrentProcessInfo); AddDynamicsToLHS(LHS_Contribution, mDamp[k], mMass[k], CurrentProcessInfo); AddDynamicsToRHS(rCurrentCondition, RHS_Contribution, mDamp[k], mMass[k], CurrentProcessInfo); // Rotate contributions (to match coordinates for slip conditions) mRotationTool.Rotate(LHS_Contribution,RHS_Contribution,rCurrentCondition.GetGeometry()); mRotationTool.ApplySlipCondition(LHS_Contribution,RHS_Contribution,rCurrentCondition.GetGeometry()); KRATOS_CATCH("") } void CalculateRHSContribution( Condition& rCurrentCondition, LocalSystemVectorType& RHS_Contribution, Element::EquationIdVectorType& EquationId, const ProcessInfo& rCurrentProcessInfo) override { KRATOS_TRY; int k = OpenMPUtils::ThisThread(); //Initializing the non linear iteration for the current condition rCurrentCondition.InitializeNonLinearIteration(rCurrentProcessInfo); //basic operations for the element considered rCurrentCondition.CalculateRightHandSide(RHS_Contribution,rCurrentProcessInfo); rCurrentCondition.CalculateMassMatrix(mMass[k],rCurrentProcessInfo); //rCurrentCondition.CalculateDampingMatrix(VelocityBossakAuxiliaries::mDamp,CurrentProcessInfo); rCurrentCondition.CalculateLocalVelocityContribution(mDamp[k], RHS_Contribution,rCurrentProcessInfo); rCurrentCondition.EquationIdVector(EquationId,rCurrentProcessInfo); //adding the dynamic contributions (static is already included) AddDynamicsToRHS(rCurrentCondition, RHS_Contribution, mDamp[k], mMass[k],rCurrentProcessInfo); // Rotate contributions (to match coordinates for slip conditions) mRotationTool.Rotate(RHS_Contribution,rCurrentCondition.GetGeometry()); mRotationTool.ApplySlipCondition(RHS_Contribution,rCurrentCondition.GetGeometry()); KRATOS_CATCH(""); } //********************************************************************************** //*********************************************************************************** void InitializeSolutionStep(ModelPart& r_model_part, TSystemMatrixType& A, TSystemVectorType& Dx, TSystemVectorType& b) override { ProcessInfo& CurrentProcessInfo = r_model_part.GetProcessInfo(); Scheme<TSparseSpace, TDenseSpace>::InitializeSolutionStep(r_model_part, A, Dx, b); double DeltaTime = CurrentProcessInfo[DELTA_TIME]; KRATOS_ERROR_IF(DeltaTime < 1.0e-12) << "Detected delta_time = 0 in the Bossak scheme. Check if the time step is created correctly for the current model part" << std::endl; //initializing constants ma0 = 1.0 / (mGammaNewmark * DeltaTime); ma1 = DeltaTime * mBetaNewmark / mGammaNewmark; ma2 = (-1 + mGammaNewmark) / mGammaNewmark; ma3 = DeltaTime; ma4 = pow(DeltaTime, 2)(-2.0 mBetaNewmark + 1.0) / 2.0; ma5 = pow(DeltaTime, 2) * mBetaNewmark; mam = (1.0 - mAlphaBossak) / (mGammaNewmark * DeltaTime); } //*********************************************************************************** //********************************************************************************* void FinalizeNonLinIteration(ModelPart &rModelPart, TSystemMatrixType &A, TSystemVectorType &Dx, TSystemVectorType &b) override { const auto& r_current_process_info = rModelPart.GetProcessInfo(); if (mpTurbulenceModel) // If not null mpTurbulenceModel->Execute(); //if orthogonal subscales are computed if (r_current_process_info[OSS_SWITCH] == 1.0) { KRATOS_INFO("Bossak Scheme") << "Computing OSS projections" << std::endl; const int nnodes = static_cast<int>(rModelPart.Nodes().size()); auto nbegin = rModelPart.NodesBegin(); #pragma omp parallel for firstprivate(nbegin,nnodes) for(int i=0; i<nnodes; ++i) { auto ind = nbegin + i; noalias(ind->FastGetSolutionStepValue(ADVPROJ)) = ZeroVector(3); ind->FastGetSolutionStepValue(DIVPROJ) = 0.0; ind->FastGetSolutionStepValue(NODAL_AREA) = 0.0; }//end of loop over nodes //loop on nodes to compute ADVPROJ CONVPROJ NODALAREA array_1d<double, 3 > output = ZeroVector(3); const int nel = static_cast<int>(rModelPart.Elements().size()); auto elbegin = rModelPart.ElementsBegin(); #pragma omp parallel for firstprivate(elbegin,nel,output) for(int i=0; i<nel; ++i) { auto elem = elbegin + i; elem->Calculate(ADVPROJ, output, r_current_process_info); } rModelPart.GetCommunicator().AssembleCurrentData(NODAL_AREA); rModelPart.GetCommunicator().AssembleCurrentData(DIVPROJ); rModelPart.GetCommunicator().AssembleCurrentData(ADVPROJ); // Correction for periodic conditions this->PeriodicConditionProjectionCorrection(rModelPart); #pragma omp parallel for firstprivate(nbegin,nnodes) for(int i=0; i<nnodes; ++i) { auto ind = nbegin + i; if (ind->FastGetSolutionStepValue(NODAL_AREA) == 0.0) { ind->FastGetSolutionStepValue(NODAL_AREA) = 1.0; //KRATOS_WATCH("*****ATTENTION: NODAL AREA IS ZERRROOOO*********"); } const double Area = ind->FastGetSolutionStepValue(NODAL_AREA); ind->FastGetSolutionStepValue(ADVPROJ) /= Area; ind->FastGetSolutionStepValue(DIVPROJ) /= Area; } } } void FinalizeSolutionStep(ModelPart &rModelPart, TSystemMatrixType &A, TSystemVectorType &Dx, TSystemVectorType &b) override { Element::EquationIdVectorType EquationId; LocalSystemVectorType RHS_Contribution; LocalSystemMatrixType LHS_Contribution; const ProcessInfo& CurrentProcessInfo = rModelPart.GetProcessInfo(); //for (ModelPart::NodeIterator itNode = rModelPart.NodesBegin(); itNode != rModelPart.NodesEnd(); ++itNode) #pragma omp parallel for for(int k = 0; k<static_cast<int>(rModelPart.Nodes().size()); k++) { auto itNode = rModelPart.NodesBegin() + k; (itNode->FastGetSolutionStepValue(REACTION)).clear(); // calculating relaxed acceleration const array_1d<double, 3 > & CurrentAcceleration = (itNode)->FastGetSolutionStepValue(ACCELERATION, 0); const array_1d<double, 3 > & OldAcceleration = (itNode)->FastGetSolutionStepValue(ACCELERATION, 1); const array_1d<double, 3> relaxed_acceleration = (1 - mAlphaBossak) CurrentAcceleration + mAlphaBossak * OldAcceleration; (itNode)->SetValue(RELAXED_ACCELERATION, relaxed_acceleration); } //for (ModelPart::ElementsContainerType::ptr_iterator itElem = rModelPart.Elements().ptr_begin(); itElem != rModelPart.Elements().ptr_end(); ++itElem) #pragma omp parallel for firstprivate(EquationId,RHS_Contribution,LHS_Contribution) for(int k = 0; k<static_cast<int>(rModelPart.Elements().size()); k++) { auto itElem = rModelPart.Elements().ptr_begin()+k; int thread_id = OpenMPUtils::ThisThread(); (itElem)->InitializeNonLinearIteration(CurrentProcessInfo); //KRATOS_WATCH(LHS_Contribution); //basic operations for the element considered (itElem)->CalculateLocalSystem(LHS_Contribution, RHS_Contribution, CurrentProcessInfo); //std::cout << rCurrentElement->Id() << " RHS = " << RHS_Contribution << std::endl; (itElem)->CalculateMassMatrix(mMass[thread_id], CurrentProcessInfo); (itElem)->CalculateLocalVelocityContribution(mDamp[thread_id], RHS_Contribution, CurrentProcessInfo); (itElem)->EquationIdVector(EquationId, CurrentProcessInfo); //adding the dynamic contributions (statics is already included) AddDynamicsToLHS(LHS_Contribution, mDamp[thread_id], mMass[thread_id], CurrentProcessInfo); AddDynamicsToRHS(itElem, RHS_Contribution, mDamp[thread_id], mMass[thread_id], CurrentProcessInfo); GeometryType& rGeom = (itElem)->GetGeometry(); unsigned int NumNodes = rGeom.PointsNumber(); unsigned int Dimension = rGeom.WorkingSpaceDimension(); unsigned int index = 0; for (unsigned int i = 0; i < NumNodes; i++) { auto& reaction = rGeom[i].FastGetSolutionStepValue(REACTION); double& target_value0 = reaction[0]; const double& origin_value0 = RHS_Contribution[index++]; #pragma omp atomic target_value0 -= origin_value0; double& target_value1 = reaction[1]; const double& origin_value1 = RHS_Contribution[index++]; #pragma omp atomic target_value1 -= origin_value1; if (Dimension == 3) { double& target_value2 = reaction[2]; const double& origin_value2 = RHS_Contribution[index++]; #pragma omp atomic target_value2 -= origin_value2; } // rGeom[i].FastGetSolutionStepValue(REACTION_X,0) -= RHS_Contribution[index++]; // rGeom[i].FastGetSolutionStepValue(REACTION_Y,0) -= RHS_Contribution[index++]; // if (Dimension == 3) rGeom[i].FastGetSolutionStepValue(REACTION_Z,0) -= RHS_Contribution[index++]; index++; // skip pressure dof } } rModelPart.GetCommunicator().AssembleCurrentData(REACTION); // Base scheme calls FinalizeSolutionStep method of elements and conditions Scheme<TSparseSpace, TDenseSpace>::FinalizeSolutionStep(rModelPart, A, Dx, b); } //********************************************************************************************** //********************************************************************************************** /// Free memory allocated by this object. void Clear() override { this->mpDofUpdater->Clear(); } /@} / /*@name Operations / /@{ / /@} / /*@name Access / /@{ / /@} / /*@name Inquiry / /@{ / /@} / /*@name Friends / /@{ / /@} / protected: /*@name Protected static Member Variables / /@{ / /@} / /*@name Protected member Variables / /@{ / double mAlphaBossak; double mBetaNewmark; double mGammaNewmark; double mMeshVelocity; double mRelaxationFactor = 1.0; double ma0; double ma1; double ma2; double ma3; double ma4; double ma5; double mam; std::vector< Matrix > mMass; std::vector< Matrix > mDamp; std::vector< Vector > mvel; std::vector< Vector > macc; std::vector< Vector > maccold; /@} / /*@name Protected Operators/ /@{ / /** On periodic boundaries, the nodal area and the values to project need to take into account contributions from elements on * both sides of the boundary. This is done using the conditions and the non-historical nodal data containers as follows:\n * 1- The partition that owns the PeriodicCondition adds the values on both nodes to their non-historical containers.\n * 2- The non-historical containers are added across processes, communicating the right value from the condition owner to all partitions.\n * 3- The value on all periodic nodes is replaced by the one received in step 2. / void PeriodicConditionProjectionCorrection(ModelPart& rModelPart) { const int num_nodes = rModelPart.NumberOfNodes(); const int num_conditions = rModelPart.NumberOfConditions(); #pragma omp parallel for for (int i = 0; i < num_nodes; i++) { auto it_node = rModelPart.NodesBegin() + i; it_node->SetValue(NODAL_AREA,0.0); it_node->SetValue(ADVPROJ,ZeroVector(3)); it_node->SetValue(DIVPROJ,0.0); } #pragma omp parallel for for (int i = 0; i < num_conditions; i++) { auto it_cond = rModelPart.ConditionsBegin() + i; if(it_cond->Is(PERIODIC)) { this->AssemblePeriodicContributionToProjections(it_cond->GetGeometry()); } } rModelPart.GetCommunicator().AssembleNonHistoricalData(NODAL_AREA); rModelPart.GetCommunicator().AssembleNonHistoricalData(ADVPROJ); rModelPart.GetCommunicator().AssembleNonHistoricalData(DIVPROJ); #pragma omp parallel for for (int i = 0; i < num_nodes; i++) { auto it_node = rModelPart.NodesBegin() + i; this->CorrectContributionsOnPeriodicNode(it_node); } } void AssemblePeriodicContributionToProjections(Geometry< Node<3> >& rGeometry) { unsigned int nodes_in_cond = rGeometry.PointsNumber(); double nodal_area = 0.0; array_1d<double,3> momentum_projection = ZeroVector(3); double mass_projection = 0.0; for ( unsigned int i = 0; i < nodes_in_cond; i++ ) { auto& r_node = rGeometry[i]; nodal_area += r_node.FastGetSolutionStepValue(NODAL_AREA); noalias(momentum_projection) += r_node.FastGetSolutionStepValue(ADVPROJ); mass_projection += r_node.FastGetSolutionStepValue(DIVPROJ); } for ( unsigned int i = 0; i < nodes_in_cond; i++ ) { auto& r_node = rGeometry[i]; /* Note that this loop is expected to be threadsafe in normal conditions, * since each node should belong to a single periodic link. However, I am * setting the locks for openmp in case that we try more complicated things * in the future (like having different periodic conditions for different * coordinate directions). / r_node.SetLock(); r_node.GetValue(NODAL_AREA) = nodal_area; noalias(r_node.GetValue(ADVPROJ)) = momentum_projection; r_node.GetValue(DIVPROJ) = mass_projection; r_node.UnSetLock(); } } void CorrectContributionsOnPeriodicNode(Node<3>& rNode) { if (rNode.GetValue(NODAL_AREA) != 0.0) // Only periodic nodes will have a non-historical NODAL_AREA set. { rNode.FastGetSolutionStepValue(NODAL_AREA) = rNode.GetValue(NODAL_AREA); noalias(rNode.FastGetSolutionStepValue(ADVPROJ)) = rNode.GetValue(ADVPROJ); rNode.FastGetSolutionStepValue(DIVPROJ) = rNode.GetValue(DIVPROJ); } } //****************************************************************************** //Updating first time Derivative //******************************************************************************* void UpdateDisplacement(array_1d<double, 3 > & CurrentDisplacement, const array_1d<double, 3 > & OldDisplacement, const array_1d<double, 3 > & OldVelocity, const array_1d<double, 3 > & OldAcceleration, const array_1d<double, 3 > & CurrentAcceleration) { noalias(CurrentDisplacement) = OldDisplacement + ma3 * OldVelocity + ma4 * OldAcceleration + ma5CurrentAcceleration; } //************************************************************************* void UpdateAcceleration(array_1d<double, 3 > & CurrentAcceleration, const array_1d<double, 3 > & DeltaVel, const array_1d<double, 3 > & OldAcceleration) { noalias(CurrentAcceleration) = ma0 * DeltaVel + ma2 * OldAcceleration; } //************************************************************************** / Kdyn = amM + D + a1K / void AddDynamicsToLHS(LocalSystemMatrixType& LHS_Contribution, LocalSystemMatrixType& D, LocalSystemMatrixType& M, const ProcessInfo& CurrentProcessInfo) { //multipling time scheme factor LHS_Contribution = ma1; // adding mass contribution to the dynamic stiffness if (M.size1() != 0) // if M matrix declared { noalias(LHS_Contribution) += mamM; } //adding damping contribution if (D.size1() != 0) // if M matrix declared { noalias(LHS_Contribution) += D; } } //************************************************************************* /// Add Bossak contributions from the inertial term to the RHS vector. / This essentially performs bdyn = b - Macc for the current element. Note that viscous/pressure contributions to the RHS are expected to be added by the element itself. * @param[in] rCurrentElement The fluid element we are assembling. * @param[in/out] rRHS_Contribution The right hand side term where the contribution will be added. * @param[in] rD The elemental velocity/pressure LHS matrix. * @param[in] rM The elemental acceleration LHS matrix. * @param[in] rCurrentProcessInfo ProcessInfo instance for the containing ModelPart. / void AddDynamicsToRHS( Element& rCurrentElement, LocalSystemVectorType& rRHS_Contribution, LocalSystemMatrixType& rD, LocalSystemMatrixType& rM, const ProcessInfo& rCurrentProcessInfo) { //adding inertia contribution if (rM.size1() != 0) { int k = OpenMPUtils::ThisThread(); rCurrentElement.GetSecondDerivativesVector(macc[k], 0); (macc[k]) = (1.00 - mAlphaBossak); rCurrentElement.GetSecondDerivativesVector(maccold[k], 1); noalias(macc[k]) += mAlphaBossak * maccold[k]; noalias(rRHS_Contribution) -= prod(rM, macc[k]); } } /// Add Bossak contributions from the inertial term to the RHS vector. /** This essentially performs bdyn = b - Macc for the current condition. Note that viscous/pressure contributions to the RHS are expected to be added by the element condition. * @param[in] rCurrentCondition The fluid condition we are assembling. * @param[in/out] rRHS_Contribution The right hand side term where the contribution will be added. * @param[in] rD The elemental velocity/pressure LHS matrix. * @param[in] rM The elemental acceleration LHS matrix. * @param[in] rCurrentProcessInfo ProcessInfo instance for the containing ModelPart. / void AddDynamicsToRHS( Condition& rCurrentCondition, LocalSystemVectorType& rRHS_Contribution, LocalSystemMatrixType& D, LocalSystemMatrixType& rM, const ProcessInfo& rCurrentProcessInfo) { //adding inertia contribution if (rM.size1() != 0) { int k = OpenMPUtils::ThisThread(); rCurrentCondition.GetSecondDerivativesVector(macc[k], 0); (macc[k]) = (1.00 - mAlphaBossak); rCurrentCondition.GetSecondDerivativesVector(maccold[k], 1); noalias(macc[k]) += mAlphaBossak * maccold[k]; noalias(rRHS_Contribution) -= prod(rM, macc[k]); } } /@} / /*@name Protected Operations/ /@{ / /@} / /*@name Protected Access / /@{ / /@} / /*@name Protected Inquiry / /@{ / /@} / /*@name Protected LifeCycle / /@{ / /@} / private: /*@name Static Member Variables / /@{ / /@} / /*@name Member Variables / /@{ / CoordinateTransformationUtils<LocalSystemMatrixType,LocalSystemVectorType,double> mRotationTool; const Variable<int>& mrPeriodicIdVar; Process::Pointer mpTurbulenceModel; typename TSparseSpace::DofUpdaterPointerType mpDofUpdater = TSparseSpace::CreateDofUpdater(); /@} / /*@name Private Operators/ /@{ / /@} / /*@name Private Operations/ /@{ / /@} / /*@name Private Access / /@{ / /@} / /*@name Private Inquiry / /@{ / /@} / /*@name Un accessible methods / /@{ / /@} / }; /* Class Scheme / /@} / /@name Type Definitions / /@{ / /@} / } /* namespace Kratos./ #endif / KRATOS_RESIDUALBASED_PREDICTOR_CORRECTOR_BOSSAK_SCHEME defined */
main.c	/* * Copyright (c) 2007-12 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, Haldeneggsteig 4, CH-8092 Zurich. Attn: Systems Group. / #include <barrelfish/barrelfish.h> #include <omp.h> #include <xomp/xomp.h> #include <flounder/flounder_support_ump.h> #include "xomptest.h" void do_process(uint32_t src, uint32_t dst) { if (src == NULL \|\| dst == 0) { return; } #pragma omp parallel for for (int j = 0; j < IT; j++) { for (int i = 0; i < MAX; i += IT) { dst[i + j] = src[i + j]; } } } int main(int argc, char argv[]) { errval_t err; xomp_wid_t wid; err = xomp_worker_parse_cmdline(argc, argv, &wid); switch (err_no(err)) { case SYS_ERR_OK: debug_printf("XOMP Test started. (WORKER) %u\n", argc); err = xomp_worker_init(wid); if (err_is_fail(err)) { USER_PANIC_ERR(err, "could not initialize the worker\n"); } break; case XOMP_ERR_BAD_INVOCATION: debug_printf("XOMP Test started. (MASTER) %u\n", argc); err = start_master(argc, argv); if (err_is_fail(err)) { USER_PANIC_ERR(err, "start_master"); } break; default: break; } if (err_is_fail(err)) { USER_PANIC_ERR(err, "during initialization"); } while (1) { messages_wait_and_handle_next(); } return 0; }

ep.c

/*-------------------------------------------------------------------- NAS Parallel Benchmarks 3.0 structured OpenMP C versions - EP This benchmark is an OpenMP C version of the NPB EP code. The OpenMP C 2.3 versions are derived by RWCP from the serial Fortran versions in "NPB 2.3-serial" developed by NAS. 3.0 translation is performed by the UVSQ. Permission to use, copy, distribute and modify this software for any purpose with or without fee is hereby granted. This software is provided "as is" without express or implied warranty. Information on OpenMP activities at RWCP is available at: http://pdplab.trc.rwcp.or.jp/pdperf/Omni/ Information on NAS Parallel Benchmarks 2.3 is available at: http://www.nas.nasa.gov/NAS/NPB/ --------------------------------------------------------------------*/ /*-------------------------------------------------------------------- Author: P. O. Frederickson D. H. Bailey A. C. Woo OpenMP C version: S. Satoh 3.0 structure translation: M. Popov --------------------------------------------------------------------*/ #include "../common/npb-C.h" #include "npbparams.h" /* parameters */ #define MK 16 #define MM (M - MK) #define NN (1 << MM) #define NK (1 << MK) #define NQ 10 #define EPSILON 1.0e-8 #define A 1220703125.0 #define S 271828183.0 #define TIMERS_ENABLED FALSE /* global variables */ /* common /storage/ */ static double x[2*NK]; static double q[NQ]; /*-------------------------------------------------------------------- program EMBAR c-------------------------------------------------------------------*/ /* c This is the serial version of the APP Benchmark 1, c the "embarassingly parallel" benchmark. c c M is the Log_2 of the number of complex pairs of uniform (0, 1) random c numbers. MK is the Log_2 of the size of each batch of uniform random c numbers. MK can be set for convenience on a given system, since it does c not affect the results. */ int main(int argc, char **argv) { double Mops, t1, t2, t3, t4, x1, x2, sx, sy, tm, an, tt, gc; double dum[3] = { 1.0, 1.0, 1.0 }; int np, ierr, node, no_nodes, i, ik, kk, l, k, nit, ierrcode, no_large_nodes, np_add, k_offset, j; int nthreads = 1; boolean verified; char size[13+1]; /* character*13 */ /* c Because the size of the problem is too large to store in a 32-bit c integer for some classes, we put it into a string (for printing). c Have to strip off the decimal point put in there by the floating c point print statement (internal file) */ printf("\n\n NAS Parallel Benchmarks 3.0 structured OpenMP C version" " - EP Benchmark\n"); sprintf(size, "%12.0f", pow(2.0, M+1)); #pragma omp parallel for firstprivate(j ) for (j = 13; j >= 1; j--) { if (size[j] == '.') size[j] = ' '; } printf(" Number of random numbers generated: %13s\n", size); verified = FALSE; /* c Compute the number of "batches" of random number pairs generated c per processor. Adjust if the number of processors does not evenly c divide the total number */ np = NN; /* c Call the random number generator functions and initialize c the x-array to reduce the effects of paging on the timings. c Also, call all mathematical functions that are used. Make c sure these initializations cannot be eliminated as dead code. */ vranlc(0, &(dum[0]), dum[1], &(dum[2])); dum[0] = randlc(&(dum[1]), dum[2]); #pragma omp parallel for private(i ) for (i = 0; i < 2*NK; i++) x[i] = -1.0e99; Mops = log(sqrt(fabs(max(1.0, 1.0)))); timer_clear(1); timer_clear(2); timer_clear(3); timer_start(1); vranlc(0, &t1, A, x); /* Compute AN = A ^ (2 * NK) (mod 2^46). */ t1 = A; for ( i = 1; i <= MK+1; i++) { t2 = randlc(&t1, t1); } an = t1; tt = S; gc = 0.0; sx = 0.0; sy = 0.0; #pragma omp parallel for firstprivate(i ) for ( i = 0; i <= NQ - 1; i++) { q[i] = 0.0; } /* c Each instance of this loop may be performed independently. We compute c the k offsets separately to take into account the fact that some nodes c have more numbers to generate than others */ k_offset = -1; { double t1, t2, t3, t4, x1, x2; int kk, i, ik, l; double qq[NQ]; /* private copy of q[0:NQ-1] */ #pragma omp parallel for firstprivate(i ) for (i = 0; i < NQ; i++) qq[i] = 0.0; #pragma omp parallel for reduction(+:sx) reduction(+:sy) for (k = 1; k <= np; k++) { kk = k_offset + k; t1 = S; t2 = an; /* Find starting seed t1 for this kk. */ for (i = 1; i <= 100; i++) { ik = kk / 2; if (2 * ik != kk) t3 = randlc(&t1, t2); if (ik == 0) break; t3 = randlc(&t2, t2); kk = ik; } /* Compute uniform pseudorandom numbers. */ if (TIMERS_ENABLED == TRUE) timer_start(3); vranlc(2*NK, &t1, A, x-1); if (TIMERS_ENABLED == TRUE) timer_stop(3); /* c Compute Gaussian deviates by acceptance-rejection method and c tally counts in concentric square annuli. This loop is not c vectorizable. */ if (TIMERS_ENABLED == TRUE) timer_start(2); for ( i = 0; i < NK; i++) { x1 = 2.0 * x[2*i] - 1.0; x2 = 2.0 * x[2*i+1] - 1.0; t1 = pow2(x1) + pow2(x2); if (t1 <= 1.0) { t2 = sqrt(-2.0 * log(t1) / t1); t3 = (x1 * t2); /* Xi */ t4 = (x2 * t2); /* Yi */ l = max(fabs(t3), fabs(t4)); qq[l] += 1.0; /* counts */ sx = sx + t3; /* sum of Xi */ sy = sy + t4; /* sum of Yi */ } } if (TIMERS_ENABLED == TRUE) timer_stop(2); } { #pragma omp parallel for firstprivate(i ) for (i = 0; i <= NQ - 1; i++) q[i] += qq[i]; } #if defined(_OPENMP) nthreads = omp_get_num_threads(); #endif /* _OPENMP */ } /* end of parallel region */ #pragma omp parallel for firstprivate(i ) reduction(+:gc) for (i = 0; i <= NQ-1; i++) { gc = gc + q[i]; } timer_stop(1); tm = timer_read(1); nit = 0; if (M == 24) { if((fabs((sx- (-3.247834652034740e3))/sx) <= EPSILON) && (fabs((sy- (-6.958407078382297e3))/sy) <= EPSILON)) { verified = TRUE; } } else if (M == 25) { if ((fabs((sx- (-2.863319731645753e3))/sx) <= EPSILON) && (fabs((sy- (-6.320053679109499e3))/sy) <= EPSILON)) { verified = TRUE; } } else if (M == 28) { if ((fabs((sx- (-4.295875165629892e3))/sx) <= EPSILON) && (fabs((sy- (-1.580732573678431e4))/sy) <= EPSILON)) { verified = TRUE; } } else if (M == 30) { if ((fabs((sx- (4.033815542441498e4))/sx) <= EPSILON) && (fabs((sy- (-2.660669192809235e4))/sy) <= EPSILON)) { verified = TRUE; } } else if (M == 32) { if ((fabs((sx- (4.764367927995374e4))/sx) <= EPSILON) && (fabs((sy- (-8.084072988043731e4))/sy) <= EPSILON)) { verified = TRUE; } } Mops = pow(2.0, M+1)/tm/1000000.0; printf("EP Benchmark Results: \n" "CPU Time = %10.4f\n" "N = 2^%5d\n" "No. Gaussian Pairs = %15.0f\n" "Sums = %25.15e %25.15e\n" "Counts:\n", tm, M, gc, sx, sy); for (i = 0; i <= NQ-1; i++) { printf("%3d %15.0f\n", i, q[i]); } c_print_results("EP", CLASS, M+1, 0, 0, nit, nthreads, tm, Mops, "Random numbers generated", verified, NPBVERSION, COMPILETIME, CS1, CS2, CS3, CS4, CS5, CS6, CS7); if (TIMERS_ENABLED == TRUE) { printf("Total time: %f", timer_read(1)); printf("Gaussian pairs: %f", timer_read(2)); printf("Random numbers: %f", timer_read(3)); } }

target_data_messages.c

// RUN: %clang_cc1 -triple x86_64-apple-macos10.7.0 -verify -fopenmp -ferror-limit 100 -o - %s // RUN: %clang_cc1 -triple x86_64-apple-macos10.7.0 -verify -fopenmp-simd -ferror-limit 100 -o - %s void foo() { } int main(int argc, char **argv) { int a; #pragma omp target data // expected-error {{expected at least one 'map' or 'use_device_ptr' clause for '#pragma omp target data'}} {} L1: foo(); #pragma omp target data map(a) allocate(a) // expected-error {{unexpected OpenMP clause 'allocate' in directive '#pragma omp target data'}} { foo(); goto L1; // expected-error {{use of undeclared label 'L1'}} } goto L2; // expected-error {{use of undeclared label 'L2'}} #pragma omp target data map(a) L2: foo(); #pragma omp target data map(a)(i) // expected-warning {{extra tokens at the end of '#pragma omp target data' are ignored}} { foo(); } #pragma omp target unknown // expected-warning {{extra tokens at the end of '#pragma omp target' are ignored}} { foo(); } return 0; }

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 128 #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->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) (x+4), sizeof(*clone_info->dash_pattern)); if (clone_info->dash_pattern == (double *) NULL) ThrowFatalException(ResourceLimitFatalError, "UnableToAllocateDashPattern"); (void) memcpy(clone_info->dash_pattern,draw_info->dash_pattern,(size_t) (x+4)*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->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) { 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); } 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 ((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) { *mvg_info->extent=(size_t) extent; 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); } 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(CompareSplayTreeString,RelinquishMagickMemory, RelinquishMagickMemory); macro=AcquireString(primitive); token=AcquireString(primitive); extent=strlen(token)+MagickPathExtent; for (q=primitive; *q != '\0'; ) { GetNextToken(q,&q,extent,token); if (*token == '\0') break; if (LocaleCompare("push",token) == 0) { register const char *end, *start; GetNextToken(q,&q,extent,token); if (*q == '"') { char name[MagickPathExtent]; const char *p; ssize_t n; /* Named macro (e.g. push graphic-context "wheel"). */ GetNextToken(q,&q,extent,token); start=q; end=q; (void) CopyMagickString(name,token,MagickPathExtent); n=1; for (p=q; *p != '\0'; ) { GetNextToken(p,&p,extent,token); 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. */ 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(status == 0 ? MagickFalse : MagickTrue); } primitive=(char *) NULL; if (*draw_info->primitive != '@') primitive=AcquireString(draw_info->primitive); else if ((strlen(draw_info->primitive) > 1) && (*(draw_info->primitive+1) != '-')) primitive=FileToString(draw_info->primitive+1,~0UL,exception); if (primitive == (char *) NULL) return(MagickFalse); primitive_extent=(double) strlen(primitive); (void) SetImageArtifact(image,"MVG",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. */ GetNextToken(q,&q,MagickPathExtent,keyword); 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); switch (*keyword) { case ';': break; case 'a': case 'A': { if (LocaleCompare("affine",keyword) == 0) { GetNextToken(q,&q,extent,token); affine.sx=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); GetNextToken(q,&q,extent,token); if (*token == ',') GetNextToken(q,&q,extent,token); affine.rx=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); GetNextToken(q,&q,extent,token); if (*token == ',') GetNextToken(q,&q,extent,token); affine.ry=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); GetNextToken(q,&q,extent,token); if (*token == ',') GetNextToken(q,&q,extent,token); affine.sy=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); GetNextToken(q,&q,extent,token); if (*token == ',') GetNextToken(q,&q,extent,token); affine.tx=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); GetNextToken(q,&q,extent,token); if (*token == ',') 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) { 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; GetNextToken(q,&q,extent,token); if (*token == '\0') { status=MagickFalse; 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. */ 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 (draw_info->compliance != SVGCompliance) status&=DrawClipPath(image,graphic_context[n], graphic_context[n]->clip_mask,exception); } break; } if (LocaleCompare("clip-rule",keyword) == 0) { ssize_t fill_rule; 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; 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. */ 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; 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) { GetNextToken(q,&q,extent,token); (void) CloneString(&graphic_context[n]->density,token); break; } if (LocaleCompare("direction",keyword) == 0) { ssize_t direction; 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) { 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) { 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; 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*opacity); break; } if (LocaleCompare("fill-rule",keyword) == 0) { ssize_t fill_rule; 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) { 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) { GetNextToken(q,&q,extent,token); (void) CloneString(&graphic_context[n]->family,token); break; } if (LocaleCompare("font-size",keyword) == 0) { 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; 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; 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; 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) { GetNextToken(q,&q,extent,token); break; } if (LocaleCompare("gravity",keyword) == 0) { ssize_t gravity; 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; 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) { 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) { 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) { 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) { 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. */ 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 (draw_info->compliance != SVGCompliance) status=SetImageMask(image,CompositePixelMask, graphic_context[n]->composite_mask,exception); } break; } break; } case 'o': case 'O': { if (LocaleCompare("offset",keyword) == 0) { GetNextToken(q,&q,extent,token); break; } if (LocaleCompare("opacity",keyword) == 0) { double opacity; 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 != OpaqueAlpha) graphic_context[n]->fill.alpha=graphic_context[n]->fill_alpha; graphic_context[n]->stroke_alpha*=opacity; if (graphic_context[n]->stroke_alpha != OpaqueAlpha) graphic_context[n]->stroke.alpha=graphic_context[n]->stroke_alpha; 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) { GetNextToken(q,&q,extent,token); 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) && (draw_info->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) { GetNextToken(q,&q,extent,token); if (LocaleCompare("class",token) == 0) { /* Class context. */ for (p=q; *q != '\0'; ) { GetNextToken(q,&q,extent,token); if (LocaleCompare(token,"pop") != 0) continue; GetNextToken(q,(const char **) NULL,extent,token); if (LocaleCompare(token,"class") != 0) continue; break; } GetNextToken(q,&q,extent,token); break; } if (LocaleCompare("clip-path",token) == 0) { char name[MaxTextExtent]; const char *clip_path; GetNextToken(q,&q,extent,token); (void) FormatLocaleString(name,MaxTextExtent,"%s",token); clip_path=(const char *) GetValueFromSplayTree(macros,name); if (clip_path != (const char *) NULL) (void) SetImageArtifact(image,name,clip_path); 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; GetNextToken(q,&q,extent,token); (void) CopyMagickString(name,token,MagickPathExtent); GetNextToken(q,&q,extent,token); (void) CopyMagickString(type,token,MagickPathExtent); GetNextToken(q,&q,extent,token); segment.x1=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); GetNextToken(q,&q,extent,token); if (*token == ',') GetNextToken(q,&q,extent,token); segment.y1=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); GetNextToken(q,&q,extent,token); if (*token == ',') GetNextToken(q,&q,extent,token); segment.x2=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); GetNextToken(q,&q,extent,token); if (*token == ',') GetNextToken(q,&q,extent,token); segment.y2=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); if (LocaleCompare(type,"radial") == 0) { GetNextToken(q,&q,extent,token); if (*token == ',') GetNextToken(q,&q,extent,token); } for (p=q; *q != '\0'; ) { GetNextToken(q,&q,extent,token); if (LocaleCompare(token,"pop") != 0) continue; 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); 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 == '"') GetNextToken(q,&q,extent,token); break; } if (LocaleCompare("mask",token) == 0) { GetNextToken(q,&q,extent,token); break; } if (LocaleCompare("pattern",token) == 0) { char key[2*MagickPathExtent], name[MagickPathExtent]; RectangleInfo bounds; GetNextToken(q,&q,extent,token); (void) CopyMagickString(name,token,MagickPathExtent); GetNextToken(q,&q,extent,token); bounds.x=(ssize_t) ceil(StringToDouble(token,&next_token)-0.5); if (token == next_token) ThrowPointExpectedException(token,exception); GetNextToken(q,&q,extent,token); if (*token == ',') GetNextToken(q,&q,extent,token); bounds.y=(ssize_t) ceil(StringToDouble(token,&next_token)-0.5); if (token == next_token) ThrowPointExpectedException(token,exception); GetNextToken(q,&q,extent,token); if (*token == ',') GetNextToken(q,&q,extent,token); bounds.width=(size_t) floor(StringToDouble(token,&next_token)+ 0.5); if (token == next_token) ThrowPointExpectedException(token,exception); GetNextToken(q,&q,extent,token); if (*token == ',') 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'; ) { GetNextToken(q,&q,extent,token); if (LocaleCompare(token,"pop") != 0) continue; 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); 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) { 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) { GetNextToken(q,&q,extent,token); affine.sx=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); GetNextToken(q,&q,extent,token); if (*token == ',') GetNextToken(q,&q,extent,token); affine.sy=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); break; } if (LocaleCompare("skewX",keyword) == 0) { 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) { 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; } GetNextToken(q,&q,extent,token); status&=QueryColorCompliance(token,AllCompliance,&stop_color, exception); stops[number_stops-1].color=stop_color; 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) { 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) { 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; GetNextToken(r,&r,extent,token); if (*token == ',') GetNextToken(r,&r,extent,token); for (x=0; IsPoint(token) != MagickFalse; x++) { GetNextToken(r,&r,extent,token); if (*token == ',') GetNextToken(r,&r,extent,token); } graphic_context[n]->dash_pattern=(double *) AcquireQuantumMemory((size_t) (2*x+4), 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+4)*sizeof(*graphic_context[n]->dash_pattern)); for (j=0; j < x; j++) { GetNextToken(q,&q,extent,token); if (*token == ',') 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; } GetNextToken(q,&q,extent,token); break; } if (LocaleCompare("stroke-dashoffset",keyword) == 0) { 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; 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; 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) { GetNextToken(q,&q,extent,token); graphic_context[n]->miterlimit=StringToUnsignedLong(token); break; } if (LocaleCompare("stroke-opacity",keyword) == 0) { double opacity; 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*opacity); break; } if (LocaleCompare("stroke-width",keyword) == 0) { 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; cursor=0.0; break; } if (LocaleCompare("text-align",keyword) == 0) { ssize_t align; 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; 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) { GetNextToken(q,&q,extent,token); graphic_context[n]->text_antialias=StringToLong(token) != 0 ? MagickTrue : MagickFalse; break; } if (LocaleCompare("text-undercolor",keyword) == 0) { GetNextToken(q,&q,extent,token); status&=QueryColorCompliance(token,AllCompliance, &graphic_context[n]->undercolor,exception); break; } if (LocaleCompare("translate",keyword) == 0) { GetNextToken(q,&q,extent,token); affine.tx=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); GetNextToken(q,&q,extent,token); if (*token == ',') 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. */ 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) { 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); GetNextToken(q,&q,extent,token); if (*token == ',') 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); GetNextToken(q,&q,extent,token); if (*token == ',') 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); GetNextToken(q,&q,extent,token); if (*token == ',') 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) { 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; GetNextToken(q,&q,extent,token); point.x=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); GetNextToken(q,&q,extent,token); if (*token == ',') GetNextToken(q,&q,extent,token); point.y=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); GetNextToken(q,(const char **) NULL,extent,token); if (*token == ',') 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; 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; if (coordinates > (MaxBezierCoordinates/4)) { (void) ThrowMagickException(exception,GetMagickModule(),DrawError, "TooManyBezierCoordinates","`%s'",token); status=MagickFalse; } break; } default: break; } if (coordinates > MaxBezierCoordinates) { (void) ThrowMagickException(exception,GetMagickModule(), ResourceLimitError,"MemoryAllocationFailed","`%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; } 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 != ',') 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; break; } case ImagePrimitive: { if (primitive_info[j].coordinates != 2) { status=MagickFalse; break; } 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) && (draw_info->compliance != SVGCompliance) && (graphic_context[n]->clip_mask != (char *) NULL) && (LocaleCompare(graphic_context[n]->clip_mask, graphic_context[n-1]->clip_mask) != 0)) 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 void LogPrimitiveInfo(const PrimitiveInfo *primitive_info) { const char *methods[] = { "point", "replace", "floodfill", "filltoborder", "reset", "?" }; PointInfo p, q, point; 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(primitive_info->point.x-0.5); y=(ssize_t) ceil(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(); if (LocaleNCompare(primitive_info->text,"data:",5) == 0) composite_images=ReadInlineImage(clone_info,primitive_info->text, exception); else { (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; status&=DrawAffineImage(image,composite_image,&affine,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; stroke_polygon=(PrimitiveInfo *) RelinquishMagickMemory(stroke_polygon); 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 ((fabs(radii.x) < MagickEpsilon) || (fabs(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; 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); p=(*mvg_info->primitive_info)+mvg_info->offset; mvg_info->offset+=p->coordinates; p+=p->coordinates; } 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(status == 0 ? MagickFalse : 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) quantum) quantum=(size_t) alpha; alpha=fabs(primitive_info[j].point.y-primitive_info[i].point.y); if (alpha > (double) quantum) quantum=(size_t) alpha; } } quantum=(size_t) MagickMin((double) quantum/number_coordinates, (double) BezierQuantum); control_points=quantum*number_coordinates; if (CheckPrimitiveExtent(mvg_info,control_points+1) == MagickFalse) return(MagickFalse); primitive_info=(*mvg_info->primitive_info)+mvg_info->offset; coefficients=(double *) AcquireQuantumMemory((size_t) number_coordinates,sizeof(*coefficients)); points=(PointInfo *) AcquireQuantumMemory((size_t) control_points, sizeof(*points)); if ((coefficients == (double *) NULL) || (points == (PointInfo *) NULL)) ThrowFatalException(ResourceLimitFatalError,"MemoryAllocationFailed"); /* 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) return(MagickFalse); p+=p->coordinates; } if (TracePoint(p,end) == MagickFalse) 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) || (coordinates > (double) GetMaxMemoryRequest())) { (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 { GetNextToken(p,&p,MagickPathExtent,token); if (*token == ',') GetNextToken(p,&p,MagickPathExtent,token); arc.x=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); GetNextToken(p,&p,MagickPathExtent,token); if (*token == ',') GetNextToken(p,&p,MagickPathExtent,token); arc.y=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); GetNextToken(p,&p,MagickPathExtent,token); if (*token == ',') GetNextToken(p,&p,MagickPathExtent,token); angle=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); GetNextToken(p,&p,MagickPathExtent,token); if (*token == ',') GetNextToken(p,&p,MagickPathExtent,token); large_arc=StringToLong(token) != 0 ? MagickTrue : MagickFalse; GetNextToken(p,&p,MagickPathExtent,token); if (*token == ',') GetNextToken(p,&p,MagickPathExtent,token); sweep=StringToLong(token) != 0 ? MagickTrue : MagickFalse; if (*token == ',') GetNextToken(p,&p,MagickPathExtent,token); GetNextToken(p,&p,MagickPathExtent,token); if (*token == ',') GetNextToken(p,&p,MagickPathExtent,token); x=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); GetNextToken(p,&p,MagickPathExtent,token); if (*token == ',') 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++) { GetNextToken(p,&p,MagickPathExtent,token); if (*token == ',') GetNextToken(p,&p,MagickPathExtent,token); x=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); GetNextToken(p,&p,MagickPathExtent,token); if (*token == ',') 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 { GetNextToken(p,&p,MagickPathExtent,token); if (*token == ',') 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 { GetNextToken(p,&p,MagickPathExtent,token); if (*token == ',') GetNextToken(p,&p,MagickPathExtent,token); x=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); GetNextToken(p,&p,MagickPathExtent,token); if (*token == ',') 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 { GetNextToken(p,&p,MagickPathExtent,token); if (*token == ',') GetNextToken(p,&p,MagickPathExtent,token); x=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); GetNextToken(p,&p,MagickPathExtent,token); if (*token == ',') 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++) { GetNextToken(p,&p,MagickPathExtent,token); if (*token == ',') GetNextToken(p,&p,MagickPathExtent,token); x=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); GetNextToken(p,&p,MagickPathExtent,token); if (*token == ',') 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++) { GetNextToken(p,&p,MagickPathExtent,token); if (*token == ',') GetNextToken(p,&p,MagickPathExtent,token); x=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); GetNextToken(p,&p,MagickPathExtent,token); if (*token == ',') 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++) { GetNextToken(p,&p,MagickPathExtent,token); if (*token == ',') GetNextToken(p,&p,MagickPathExtent,token); x=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); GetNextToken(p,&p,MagickPathExtent,token); if (*token == ',') 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 { GetNextToken(p,&p,MagickPathExtent,token); if (*token == ',') 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; if ((fabs(start.x-end.x) < MagickEpsilon) || (fabs(start.y-end.y) < MagickEpsilon)) { primitive_info->coordinates=0; return(MagickTrue); } 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); }

RecordTable.h

/* * Souffle - A Datalog Compiler * Copyright (c) 2020, The Souffle Developers. All rights reserved. * Licensed under the Universal Permissive License v 1.0 as shown at: * - https://opensource.org/licenses/UPL * - <souffle root>/licenses/SOUFFLE-UPL.txt */ /************************************************************************ * * @file RecordTable.h * * Data container implementing a map between records and their references. * Records are separated by arity, i.e., stored in different RecordMaps. * ***********************************************************************/ #pragma once #include "CompiledTuple.h" #include "RamTypes.h" #include <cassert> #include <cstddef> #include <limits> #include <memory> #include <unordered_map> #include <utility> #include <vector> namespace souffle { /** @brief Bidirectional mappping between records and record references */ class RecordMap { /** arity of record */ const size_t arity; /** hash function for unordered record map */ struct RecordHash { std::size_t operator()(std::vector<RamDomain> record) const { std::size_t seed = 0; std::hash<RamDomain> domainHash; for (RamDomain value : record) { seed ^= domainHash(value) + 0x9e3779b9 + (seed << 6) + (seed >> 2); } return seed; } }; /** map from records to references */ // TODO (b-scholz): replace vector<RamDomain> with something more memory-frugal std::unordered_map<std::vector<RamDomain>, RamDomain, RecordHash> recordToIndex; /** array of records; index represents record reference */ // TODO (b-scholz): replace vector<RamDomain> with something more memory-frugal std::vector<std::vector<RamDomain>> indexToRecord; public: explicit RecordMap(size_t arity) : arity(arity), indexToRecord(1) {} // note: index 0 element left free /** @brief converts record to a record reference */ // TODO (b-scholz): replace vector<RamDomain> with something more memory-frugal RamDomain pack(const std::vector<RamDomain>& vector) { RamDomain index; #pragma omp critical(record_pack) { auto pos = recordToIndex.find(vector); if (pos != recordToIndex.end()) { index = pos->second; } else { #pragma omp critical(record_unpack) { indexToRecord.push_back(vector); index = indexToRecord.size() - 1; recordToIndex[vector] = index; // assert that new index is smaller than the range assert(index != std::numeric_limits<RamDomain>::max()); } } } return index; } /** @brief convert record pointer to a record reference */ RamDomain pack(const RamDomain* tuple) { // TODO (b-scholz): data is unnecessarily copied // for a successful lookup. To avoid this, we should // compute a hash of the pointer-array and traverse through // the bucket list of the unordered map finding the record. // Note that in case of non-existence, the record still needs to be // copied for the newly created entry but this will be the less // frequent case. std::vector<RamDomain> tmp(arity); for (size_t i = 0; i < arity; i++) { tmp[i] = tuple[i]; } return pack(tmp); } /** @brief convert record reference to a record pointer */ const RamDomain* unpack(RamDomain index) const { const RamDomain* res; #pragma omp critical(record_unpack) res = indexToRecord[index].data(); return res; } }; class RecordTable { public: RecordTable() = default; virtual ~RecordTable() = default; /** @brief convert record to record reference */ RamDomain pack(RamDomain* tuple, size_t arity) { return lookupArity(arity).pack(tuple); } /** @brief convert record reference to a record */ const RamDomain* unpack(RamDomain ref, size_t arity) const { std::unordered_map<size_t, RecordMap>::const_iterator iter; #pragma omp critical(RecordTableGetForArity) { // Find a previously emplaced map iter = maps.find(arity); } assert(iter != maps.end() && "Attempting to unpack record for non-existing arity"); return (iter->second).unpack(ref); } private: /** @brief lookup RecordMap for a given arity; if it does not exist, create new RecordMap */ RecordMap& lookupArity(size_t arity) { std::unordered_map<size_t, RecordMap>::iterator mapsIterator; #pragma omp critical(RecordTableGetForArity) { // This will create a new map if it doesn't exist yet. mapsIterator = maps.emplace(arity, arity).first; } return mapsIterator->second; } /** Arity/RecordMap association */ std::unordered_map<size_t, RecordMap> maps; }; /** @brief helper to convert tuple to record reference for the synthesiser */ template <std::size_t Arity> inline RamDomain pack(RecordTable& recordTab, Tuple<RamDomain, Arity> tuple) { return recordTab.pack(static_cast<RamDomain*>(tuple.data), Arity); } } // namespace souffle

data.c

#include "../mesh.h" #include "../params.h" #include "../shared.h" #include "../umesh.h" #include <math.h> #include <stdlib.h> // Checks if two strings match #pragma omp declare target int device_strmatch(const char* str1, const char* str2) { int ii = 0; for (ii = 0; str1[ii] != '\0'; ++ii) { if (str1[ii] != str2[ii]) { return 0; } } return str1[ii] == str2[ii]; } #pragma omp end declare target // Allocates some double precision data size_t allocate_data(double** buf, size_t len) { if(!len) { return 0; } allocate_host_data(buf, len); double* local_buf = *buf; #pragma omp target enter data map(to : local_buf[ : len]) #pragma omp target teams distribute parallel for for (size_t ii = 0; ii < len; ++ii) { local_buf[ii] = 0.0; } return sizeof(double) * len; } // Allocates some int precision data size_t allocate_int_data(int** buf, size_t len) { if(!len) { return 0; } allocate_host_int_data(buf, len); int* local_buf = *buf; #pragma omp target enter data map(to : local_buf[ : len]) #pragma omp target teams distribute parallel for for (size_t ii = 0; ii < len; ++ii) { local_buf[ii] = 0; } return sizeof(int) * len; } // Allocates some int precision data size_t allocate_uint64_data(uint64_t** buf, size_t len) { if(!len) { return 0; } allocate_host_uint64_data(buf, len); uint64_t* local_buf = *buf; #pragma omp target enter data map(to : local_buf[ : len]) #pragma omp target teams distribute parallel for for (size_t ii = 0; ii < len; ++ii) { local_buf[ii] = 0; } return sizeof(uint64_t) * len; } // Allocates a host copy of some buffer void allocate_host_data(double** buf, size_t len) { #ifdef INTEL *buf = (double*)_mm_malloc(sizeof(double) * len, VEC_ALIGN); #else *buf = (double*)malloc(sizeof(double) * len); #endif if (*buf == NULL) { TERMINATE("Failed to allocate a data array.\n"); } } // Allocates a host copy of some integer buffer void allocate_host_int_data(int** buf, size_t len) { #ifdef INTEL *buf = (int*)_mm_malloc(sizeof(int) * len, VEC_ALIGN); #else *buf = (int*)malloc(sizeof(int) * len); #endif if (*buf == NULL) { TERMINATE("Failed to allocate a data array.\n"); } } void allocate_host_uint64_data(uint64_t** buf, const size_t len) { #ifdef INTEL *buf = (uint64_t*)_mm_malloc(sizeof(uint64_t) * len, VEC_ALIGN); #else *buf = (uint64_t*)malloc(sizeof(uint64_t) * len); #endif if (*buf == NULL) { TERMINATE("Failed to allocate a data array.\n"); } } // Allocates a data array void deallocate_data(double* buf) { #pragma omp target exit data map(delete : buf) } // Allocates a data array void deallocate_int_data(int* buf) { #pragma omp target exit data map(delete : buf) } // Allocates a data array void deallocate_host_data(double* buf) { #ifdef INTEL _mm_free(buf); #else free(buf); #endif } // Synchronise data void copy_buffer(const size_t len, double** src, double** dst, int send) { double* local_src = *src; if (send == SEND) { #pragma omp target update to(local_src[ : len]) } else { #pragma omp target update from(local_src[ : len]) } *dst = *src; } // Move a host buffer onto the device void move_host_buffer_to_device(const size_t len, double** src, double** dst) { double* local_src = *src; #pragma omp target enter data map(to : local_src[ : len]) *dst = *src; } // Initialises mesh data in device specific manner void mesh_data_init_2d(const int local_nx, const int local_ny, const int global_nx, const int global_ny, const int pad, const int x_off, const int y_off, const double width, const double height, double* edgex, double* edgey, double* edgedx, double* edgedy, double* celldx, double* celldy) { // Simple uniform rectilinear initialisation #pragma omp target teams distribute parallel for for (int ii = 0; ii < local_nx + 1; ++ii) { edgedx[ii] = width / (global_nx); // Note: correcting for padding edgex[ii] = edgedx[ii] * (x_off + ii - pad); } #pragma omp target teams distribute parallel for for (int ii = 0; ii < local_nx; ++ii) { celldx[ii] = width / (global_nx); } #pragma omp target teams distribute parallel for for (int ii = 0; ii < local_ny + 1; ++ii) { edgedy[ii] = height / (global_ny); // Note: correcting for padding edgey[ii] = edgedy[ii] * (y_off + ii - pad); } #pragma omp target teams distribute parallel for for (int ii = 0; ii < local_ny; ++ii) { celldy[ii] = height / (global_ny); } } // Initialises mesh data in device specific manner void mesh_data_init_3d(const int local_nx, const int local_ny, const int local_nz, const int global_nx, const int global_ny, const int global_nz, const int pad, const int x_off, const int y_off, const int z_off, const double width, const double height, const double depth, double* edgex, double* edgey, double* edgez, double* edgedx, double* edgedy, double* edgedz, double* celldx, double* celldy, double* celldz) { // Initialise as in the 2d case mesh_data_init_2d(local_nx, local_ny, global_nx, global_ny, pad, x_off, y_off, width, height, edgex, edgey, edgedx, edgedy, celldx, celldy); // Simple uniform rectilinear initialisation #pragma omp target teams distribute parallel for for (int ii = 0; ii < local_nz + 1; ++ii) { edgedz[ii] = depth / (global_nz); edgez[ii] = edgedz[ii] * (z_off + ii - pad); } #pragma omp target teams distribute parallel for for (int ii = 0; ii < local_nz; ++ii) { celldz[ii] = depth / (global_nz); } } // Initialise state data in device specific manner void set_problem_2d(const int local_nx, const int local_ny, const int pad, const double mesh_width, const double mesh_height, const double* edgex, const double* edgey, const int ndims, const char* problem_def_filename, double* rho, double* e, double* x) { char* keys = (char*)malloc(sizeof(char) * MAX_KEYS * MAX_STR_LEN); #pragma omp target enter data map(to : keys[ : MAX_KEYS* MAX_STR_LEN]) double* values; allocate_data(&values, MAX_KEYS); int nentries = 0; while (1) { char specifier[MAX_STR_LEN]; sprintf(specifier, "problem_%d", nentries++); int nkeys = 0; if (!get_key_value_parameter(specifier, problem_def_filename, keys, values, &nkeys)) { break; } copy_buffer(MAX_KEYS, &values, &values, SEND); #pragma omp target update to(keys[ : MAX_KEYS* MAX_STR_LEN]) // The last four keys are the bound specification double xpos = values[nkeys - 4] * mesh_width; double ypos = values[nkeys - 3] * mesh_height; double width = values[nkeys - 2] * mesh_width; double height = values[nkeys - 1] * mesh_height; int failed = 0; // Loop through the mesh and set the problem #pragma omp target teams distribute parallel for \ map(tofrom : failed) reduction(+ : failed) for (int ii = pad; ii < local_ny - pad; ++ii) { for (int jj = pad; jj < local_nx - pad; ++jj) { double global_xpos = edgex[jj]; double global_ypos = edgey[ii]; // Check we are in bounds of the problem entry if (global_xpos >= xpos && global_ypos >= ypos && global_xpos < xpos + width && global_ypos < ypos + height) { // The upper bound excludes the bounding box for the entry for (int kk = 0; kk < nkeys - (2 * ndims); ++kk) { const char* key = &keys[kk * MAX_STR_LEN]; if (device_strmatch(key, "density")) { rho[ii * local_nx + jj] = values[kk]; } else if (device_strmatch(key, "energy")) { e[ii * local_nx + jj] = values[kk]; } else if (device_strmatch(key, "temperature")) { x[ii * local_nx + jj] = values[kk]; } else { failed++; } } } } } if (failed) { TERMINATE("Found unrecognised key in %s.\n", problem_def_filename); } } free(keys); deallocate_data(values); } // Initialise state data in device specific manner void set_problem_3d(const int local_nx, const int local_ny, const int local_nz, const int pad, const double mesh_width, const double mesh_height, const double mesh_depth, const double* edgex, const double* edgey, const double* edgez, const int ndims, const char* problem_def_filename, double* rho, double* e, double* x) { char* keys = (char*)malloc(sizeof(char) * MAX_KEYS * MAX_STR_LEN); #pragma omp target enter data map(to : keys[ : MAX_KEYS* MAX_STR_LEN]) double* values; allocate_data(&values, MAX_KEYS); int nentries = 0; while (1) { char specifier[MAX_STR_LEN]; sprintf(specifier, "problem_%d", nentries++); int nkeys = 0; if (!get_key_value_parameter(specifier, problem_def_filename, keys, values, &nkeys)) { break; } copy_buffer(MAX_KEYS, &values, &values, SEND); #pragma omp target update to(keys[ : MAX_KEYS* MAX_STR_LEN]) // The last four keys are the bound specification double xpos = values[nkeys - 6] * mesh_width; double ypos = values[nkeys - 5] * mesh_height; double zpos = values[nkeys - 4] * mesh_depth; double width = values[nkeys - 3] * mesh_width; double height = values[nkeys - 2] * mesh_height; double depth = values[nkeys - 1] * mesh_depth; int failed = 0; // Loop through the mesh and set the problem #pragma omp target teams distribute parallel for \ map(tofrom: failed) reduction(+: failed) for (int ii = pad; ii < local_nz - pad; ++ii) { for (int jj = pad; jj < local_ny - pad; ++jj) { for (int kk = pad; kk < local_nx - pad; ++kk) { double global_xpos = edgex[kk]; double global_ypos = edgey[jj]; double global_zpos = edgez[ii]; // Check we are in bounds of the problem entry if (global_xpos >= xpos && global_ypos >= ypos && global_zpos >= zpos && global_xpos < xpos + width && global_ypos < ypos + height && global_zpos < zpos + depth) { // The upper bound excludes the bounding box for the entry for (int ee = 0; ee < nkeys - (2 * ndims); ++ee) { const int index = (ii * local_nx * local_ny) + (jj * local_nx) + (kk); const char* key = &keys[ee * MAX_STR_LEN]; if (device_strmatch(key, "density")) { rho[(index)] = values[ee]; } else if (device_strmatch(key, "energy")) { e[(index)] = values[ee]; } else if (device_strmatch(key, "temperature")) { x[(index)] = values[ee]; } else { failed++; } } } } } } if(failed) { TERMINATE("Found unrecognised key in %s.\n", problem_def_filename); } } free(keys); deallocate_data(values); } // Finds the normals for all boundary cells void find_boundary_normals(UnstructuredMesh* umesh, int* boundary_edge_list) { const int nnodes = umesh->nnodes; const int nboundary_nodes = umesh->nboundary_nodes; const int* boundary_index = umesh->boundary_index; const double* nodes_x0 = umesh->nodes_x0; const double* nodes_y0 = umesh->nodes_y0; int* boundary_type = umesh->boundary_type; double* boundary_normal_x = umesh->boundary_normal_x; double* boundary_normal_y = umesh->boundary_normal_y; // Loop through all of the boundary cells and find their normals #pragma omp target teams distribute parallel for for (int nn = 0; nn < nnodes; ++nn) { const int bi = boundary_index[(nn)]; if (bi == IS_INTERIOR) { continue; } double normal_x = 0.0; double normal_y = 0.0; for (int bb1 = 0; bb1 < nboundary_nodes; ++bb1) { const int node0 = boundary_edge_list[bb1 * 2]; const int node1 = boundary_edge_list[bb1 * 2 + 1]; if (node0 == nn || node1 == nn) { const double node0_x = nodes_x0[(node0)]; const double node0_y = nodes_y0[(node0)]; const double node1_x = nodes_x0[(node1)]; const double node1_y = nodes_y0[(node1)]; normal_x += node0_y - node1_y; normal_y += -(node0_x - node1_x); } } // We are fixed if we are one of the four corners if ((nodes_x0[(nn)] == 0.0 || nodes_x0[(nn)] == 1.0) && (nodes_y0[(nn)] == 0.0 || nodes_y0[(nn)] == 1.0)) { boundary_type[(bi)] = IS_CORNER; } else { boundary_type[(bi)] = IS_BOUNDARY; } const double normal_mag = sqrt(normal_x * normal_x + normal_y * normal_y); boundary_normal_x[(bi)] = normal_x / normal_mag; boundary_normal_y[(bi)] = normal_y / normal_mag; } }

GB_binop__min_uint8.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 Generated/ folder, do not edit it (auto-generated). #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__min_uint8) // A.*B function (eWiseMult): GB (_AemultB) // A.*B function (eWiseMult): GB (_AemultB_02__min_uint8) // A.*B function (eWiseMult): GB (_AemultB_03__min_uint8) // A.*B function (eWiseMult): GB (_AemultB_bitmap__min_uint8) // A*D function (colscale): GB (_AxD__min_uint8) // D*A function (rowscale): GB (_DxB__min_uint8) // C+=B function (dense accum): GB (_Cdense_accumB__min_uint8) // C+=b function (dense accum): GB (_Cdense_accumb__min_uint8) // C+=A+B function (dense ewise3): GB (_Cdense_ewise3_accum__min_uint8) // C=A+B function (dense ewise3): GB (_Cdense_ewise3_noaccum__min_uint8) // C=scalar+B GB (_bind1st__min_uint8) // C=scalar+B' GB (_bind1st_tran__min_uint8) // C=A+scalar GB (_bind2nd__min_uint8) // C=A'+scalar GB (_bind2nd_tran__min_uint8) // C type: uint8_t // A type: uint8_t // B,b type: uint8_t // BinaryOp: cij = GB_IMIN (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, i, j) \ z = GB_IMIN (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_MIN || GxB_NO_UINT8 || GxB_NO_MIN_UINT8) //------------------------------------------------------------------------------ // 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__min_uint8) ( 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__min_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__min_uint8) ( 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__min_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__min_uint8) ( 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 uint8_t *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__min_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 *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__min_uint8) ( 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__min_uint8) ( 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__min_uint8) ( 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__min_uint8) ( 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__min_uint8) ( 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__min_uint8) ( 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 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++) { if (!GBB (Bb, p)) continue ; uint8_t bij = Bx [p] ; Cx [p] = GB_IMIN (x, bij) ; } return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // Cx = op (Ax,y): apply a binary operator to a matrix with scalar bind2nd //------------------------------------------------------------------------------ GrB_Info GB (_bind2nd__min_uint8) ( 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 ; 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++) { if (!GBB (Ab, p)) continue ; uint8_t aij = Ax [p] ; Cx [p] = GB_IMIN (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) \ { \ uint8_t aij = Ax [pA] ; \ Cx [pC] = GB_IMIN (x, aij) ; \ } GrB_Info GB (_bind1st_tran__min_uint8) ( 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 \ uint8_t #if GB_DISABLE return (GrB_NO_VALUE) ; #else uint8_t x = (*((const uint8_t *) x_input)) ; #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 typecasting (in spite of the macro name) #undef GB_CAST_OP #define GB_CAST_OP(pC,pA) \ { \ uint8_t aij = Ax [pA] ; \ Cx [pC] = GB_IMIN (aij, y) ; \ } GrB_Info GB (_bind2nd_tran__min_uint8) ( 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 uint8_t y = (*((const uint8_t *) y_input)) ; #include "GB_unop_transpose.c" return (GrB_SUCCESS) ; #endif } #endif

3d7pt.c

/* * 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] = 4; tile_size[1] = 4; tile_size[2] = 24; tile_size[3] = 2048; 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 #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] = alpha * (A[t%2][i][j][k]) + beta * (A[t%2][i - 1][j][k] + A[t%2][i][j - 1][k] + A[t%2][i][j][k - 1] + A[t%2][i + 1][j][k] + A[t%2][i][j + 1][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, "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; }

requires-4.c

#pragma omp requires unified_shared_memory,unified_address,reverse_offload void foo (void) { #pragma omp target ; } #pragma omp requires unified_shared_memory /* { dg-error "'unified_shared_memory' clause used lexically after first target construct or offloading API" } */ #pragma omp requires unified_address /* { dg-error "'unified_address' clause used lexically after first target construct or offloading API" } */ #pragma omp requires reverse_offload /* { dg-error "'reverse_offload' clause used lexically after first target construct or offloading API" } */ /* { dg-prune-output "not supported yet" } */

core_zher2k.c

/** * * @file * * PLASMA is a software package provided by: * University of Tennessee, US, * University of Manchester, UK. * * @precisions normal z -> c * **/ #include <plasma_core_blas.h> #include "plasma_types.h" #include "core_lapack.h" #undef REAL #define COMPLEX /***************************************************************************//** * * @ingroup core_her2k * * Performs one of the Hermitian rank 2k operations * * \f[ C = \alpha A \times B^H + conjg( \alpha ) B \times A^H + \beta C, \f] * or * \f[ C = \alpha A^H \times B + conjg( \alpha ) B^H \times A + \beta C, \f] * * where alpha is a complex scalar, beta is a real scalar, * C is an n-by-n Hermitian matrix, and A and B are n-by-k matrices * in the first case and k-by-n matrices in the second case. * ******************************************************************************* * * @param[in] uplo * - PlasmaUpper: Upper triangle of C is stored; * - PlasmaLower: Lower triangle of C is stored. * * @param[in] trans * - PlasmaNoTrans: * \f[ C = \alpha A \times B^H * + conjg( \alpha ) B \times A^H + \beta C; \f] * - PlasmaConjTrans: * \f[ C = \alpha A^H \times B * + conjg( \alpha ) B^H \times A + \beta C. \f] * * @param[in] n * The order of the matrix C. n >= zero. * * @param[in] k * If trans = PlasmaNoTrans, number of columns of the A and B matrices; * if trans = PlasmaConjTrans, number of rows of the A and B matrices. * * @param[in] alpha * The scalar alpha. * * @param[in] A * An lda-by-ka matrix. * If trans = PlasmaNoTrans, ka = k; * if trans = PlasmaConjTrans, ka = n. * * @param[in] lda * The leading dimension of the array A. * If trans = PlasmaNoTrans, lda >= max(1, n); * if trans = PlasmaConjTrans, lda >= max(1, k). * * @param[in] B * An ldb-by-kb matrix. * If trans = PlasmaNoTrans, kb = k; * if trans = PlasmaConjTrans, kb = n. * * @param[in] ldb * The leading dimension of the array B. * If trans = PlasmaNoTrans, ldb >= max(1, n); * if trans = PlasmaConjTrans, ldb >= max(1, k). * * @param[in] beta * The scalar beta. * * @param[in,out] C * An ldc-by-n matrix. * On exit, the uplo part of the matrix is overwritten * by the uplo part of the updated matrix. * * @param[in] ldc * The leading dimension of the array C. ldc >= max(1, n). * ******************************************************************************/ __attribute__((weak)) void plasma_core_zher2k(plasma_enum_t uplo, plasma_enum_t trans, int n, int k, plasma_complex64_t alpha, const plasma_complex64_t *A, int lda, const plasma_complex64_t *B, int ldb, double beta, plasma_complex64_t *C, int ldc) { cblas_zher2k(CblasColMajor, (CBLAS_UPLO)uplo, (CBLAS_TRANSPOSE)trans, n, k, CBLAS_SADDR(alpha), A, lda, B, ldb, beta, C, ldc); } /******************************************************************************/ void plasma_core_omp_zher2k( plasma_enum_t uplo, plasma_enum_t trans, int n, int k, plasma_complex64_t alpha, const plasma_complex64_t *A, int lda, const plasma_complex64_t *B, int ldb, double beta, plasma_complex64_t *C, int ldc, plasma_sequence_t *sequence, plasma_request_t *request) { int ak; int bk; if (trans == PlasmaNoTrans) { ak = k; bk = k; } else { ak = n; bk = n; } #pragma omp task depend(in:A[0:lda*ak]) \ depend(in:B[0:ldb*bk]) \ depend(inout:C[0:ldc*n]) { if (sequence->status == PlasmaSuccess) plasma_core_zher2k(uplo, trans, n, k, alpha, A, lda, B, ldb, beta, C, ldc); } }

suma2.c

#include <omp.h> #include <stdlib.h> // biblioteca con funciones atoi(), malloc() y free() #include <stdio.h> // biblioteca donde se encuentra la función printf() #include <time.h>// biblioteca donde se encuentra la función clock_gettime() #define VECTOR_GLOBAL// descomentar para que los vectores sean variables ... // globales (su longitud no estará limitada por el ... // tamaño de la pila del programa) //#define PRINTF_ALL// comentar para quitar el printf ... // que imprime todos los componentes #ifdef VECTOR_GLOBAL #define MAX 33554432 //=2^25 double v1[MAX], v2[MAX], v3[MAX]; #endif int main(int argc, char** argv){ int i; //Leer argumento de entrada (nº de componentes del vector) if (argc<2){ printf("Faltan nº componentes del vector\n"); exit(-1); } unsigned int N = atoi(argv[1]); // Máximo N =2^32-1=4294967295 (sizeof(unsigned int) = 4 B) #pragma omp sections { #pragma omp section for(i=0; i<N/4; i++){ v3[i] = v1[i] + v2[i]; printf("/ Tamaño Vectores:%u / V1[%d]+V2[%d]=V3[%d](%8.6f+%8.6f=%8.6f) /\n",N,i,i,i,v1[i],v2[i],v3[i]); } #pragma omp section for(i=N/4; i<N/3; i++){ v3[i] = v1[i] + v2[i]; printf("/ Tamaño Vectores:%u / V1[%d]+V2[%d]=V3[%d](%8.6f+%8.6f=%8.6f) /\n",N,i,i,i,v1[i],v2[i],v3[i]); } #pragma omp section for(i=N/3; i<N/2; i++){ v3[i] = v1[i] + v2[i]; printf("/ Tamaño Vectores:%u / V1[%d]+V2[%d]=V3[%d](%8.6f+%8.6f=%8.6f) /\n",N,i,i,i,v1[i],v2[i],v3[i]); } #pragma omp section for(i=N/2; i<N; i++){ v3[i] = v1[i] + v2[i]; printf("/ Tamaño Vectores:%u / V1[%d]+V2[%d]=V3[%d](%8.6f+%8.6f=%8.6f) /\n",N,i,i,i,v1[i],v2[i],v3[i]); } } double start, end; start= omp_get_wtime(); //Calcular suma de vectores #pragma omp parallel for for(i=0; i<N; i++){ v3[i] = v1[i] + v2[i]; printf("/ Tamaño Vectores:%u / V1[%d]+V2[%d]=V3[%d](%8.6f+%8.6f=%8.6f) /\n",N,i,i,i,v1[i],v2[i],v3[i]); } end= omp_get_wtime(); double tiempo= 0; tiempo = end - start; printf("Tiempo(seg.):%11.9f\t / Tamaño Vectores:%u\n",tiempo,N); //printf("/ V1[8]+V2[8]=V3[8](%8.6f+%8.6f=%8.6f) /\n",v1[7],v2[7],v3[7]); printf("/ V1[11]+V2[11]=V3[11](%8.6f+%8.6f=%8.6f) /\n",v1[10],v2[10],v3[10]); return 0; }

dropout-inl.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. */ /*! * \file dropout-inl.h * \brief * \author Bing Xu */ #ifndef MXNET_OPERATOR_DROPOUT_INL_H_ #define MXNET_OPERATOR_DROPOUT_INL_H_ #include <dmlc/logging.h> #include <dmlc/parameter.h> #include <mxnet/operator.h> #include <map> #include <vector> #include <string> #include <utility> #include <algorithm> #include "./operator_common.h" #include "./mshadow_op.h" #include "../engine/openmp.h" #if defined(USE_MKL) && defined(_OPENMP) #include <omp.h> #include <mkl_vml_functions.h> #include <mkl_vsl.h> #endif // USE_MKL && _OPENMP namespace dropout { enum DropoutOpInputs {kData}; enum DropoutOpOutputs {kOut, kMask}; enum DropoutOpForwardResource {kRandom}; enum DropoutOpMode {kTraining, kAlways}; } // namespace dropout namespace mxnet { namespace op { #if defined(USE_MKL) && defined(_OPENMP) static void bernoulli_generate(int n, double p, int* r) { const int seed = 17 + rand() % 4096; // NOLINT(runtime/threadsafe_fn) const int nthr = engine::OpenMP::Get()->GetRecommendedOMPThreadCount(); # pragma omp parallel num_threads(nthr) { const int ithr = omp_get_thread_num(); const int avg_amount = (n + nthr - 1) / nthr; const int my_offset = ithr * avg_amount; const int my_amount = std::min(my_offset + avg_amount, n) - my_offset; if (my_amount > 0) { VSLStreamStatePtr stream; vslNewStream(&stream, VSL_BRNG_MCG31, seed); vslSkipAheadStream(stream, my_offset); viRngBernoulli(VSL_RNG_METHOD_BERNOULLI_ICDF, stream, my_amount, r + my_offset, p); vslDeleteStream(&stream); } } } #endif // USE_MKL && _OPENMP struct DropoutParam : public dmlc::Parameter<DropoutParam> { float p; int mode; DMLC_DECLARE_PARAMETER(DropoutParam) { DMLC_DECLARE_FIELD(p).set_default(0.5) .set_range(0, 1) .describe("Fraction of the input that gets dropped out during training time."); DMLC_DECLARE_FIELD(mode) .add_enum("training", dropout::kTraining) .add_enum("always", dropout::kAlways) .set_default(dropout::kTraining) .describe("Whether to only turn on dropout during training or to also turn on for inference."); } }; // struct DropoutParam template<typename xpu, typename DType> class DropoutOp : public Operator { public: explicit DropoutOp(DropoutParam param) { this->pkeep_ = 1.0f - param.p; this->mode_ = param.mode; } virtual void Forward(const OpContext &ctx, const std::vector<TBlob> &in_data, const std::vector<OpReqType> &req, const std::vector<TBlob> &out_data, const std::vector<TBlob> &aux_states) { using namespace mshadow; using namespace mshadow::expr; CHECK_EQ(in_data.size(), 1U); if (ctx.is_train) { CHECK_EQ(out_data.size(), 2U); } Stream<xpu> *s = ctx.get_stream<xpu>(); Tensor<xpu, 2, DType> data = in_data[dropout::kData].FlatTo2D<xpu, DType>(s); Tensor<xpu, 2, DType> out = out_data[dropout::kOut].FlatTo2D<xpu, DType>(s); if (ctx.is_train || mode_ == dropout::kAlways) { Tensor<xpu, 2, DType> mask = out_data[dropout::kMask].FlatTo2D<xpu, DType>(s); #if !defined(__CUDACC__) && defined(USE_MKL) && defined(_OPENMP) DType* outptr = out.dptr_; DType* dataptr = data.dptr_; auto maskptr = reinterpret_cast<int*>(mask.dptr_); int count = mask.shape_[0]*mask.shape_[1]; bernoulli_generate(count, this->pkeep_, maskptr); const float pk_1 = 1.0f / pkeep_; #pragma omp parallel for num_threads(engine::OpenMP::Get()->GetRecommendedOMPThreadCount()) for (int i = 0; i < count; ++i) { outptr[i] = dataptr[i] * maskptr[i] * pk_1; } #else Random<xpu> *prnd = ctx.requested[dropout::kRandom].get_random<xpu, real_t>(s); mask = tcast<DType>(F<mshadow_op::threshold>( prnd->uniform(mask.shape_), pkeep_) * (1.0f / pkeep_)); Assign(out, req[dropout::kOut], data * mask); #endif // USE_MKL && _OPENMP } else { Assign(out, req[dropout::kOut], F<mshadow_op::identity>(data)); } } virtual void Backward(const OpContext &ctx, const std::vector<TBlob> &out_grad, const std::vector<TBlob> &in_data, const std::vector<TBlob> &out_data, const std::vector<OpReqType> &req, const std::vector<TBlob> &in_grad, const std::vector<TBlob> &aux_states) { using namespace mshadow; using namespace mshadow::expr; CHECK_EQ(out_grad.size(), 1U); CHECK_EQ(in_grad.size(), 1U); Stream<xpu> *s = ctx.get_stream<xpu>(); Tensor<xpu, 2, DType> grad = out_grad[dropout::kOut].FlatTo2D<xpu, DType>(s); Tensor<xpu, 2, DType> mask = out_data[dropout::kMask].FlatTo2D<xpu, DType>(s); Tensor<xpu, 2, DType> gdata = in_grad[dropout::kData].FlatTo2D<xpu, DType>(s); if (ctx.is_train || mode_ == dropout::kAlways) { #if !defined(__CUDACC__) && defined(USE_MKL) && defined(_OPENMP) DType* ingradptr = gdata.dptr_; DType* outgradptr = grad.dptr_; auto maskptr = reinterpret_cast<int*>(mask.dptr_); int count = mask.shape_[0]*mask.shape_[1]; const float pk_1 = 1.0f / pkeep_; #pragma omp parallel for num_threads(engine::OpenMP::Get()->GetRecommendedOMPThreadCount()) for (int i = 0; i < count; ++i) { ingradptr[i] = outgradptr[i] * maskptr[i] * pk_1; } #else // USE_MKL && _OPENMP CHECK_EQ(grad.shape_.Size(), mask.shape_.Size()); Assign(gdata, req[dropout::kData], grad * mask); #endif // USE_MKL && _OPENMP } else { Assign(gdata, req[dropout::kData], F<mshadow_op::identity>(grad)); } } private: real_t pkeep_; int mode_; }; // class DropoutOp template<typename xpu> Operator *CreateOp(DropoutParam param, int dtype); #if DMLC_USE_CXX11 class DropoutProp : public OperatorProperty { public: void Init(const std::vector<std::pair<std::string, std::string> >& kwargs) override { param_.Init(kwargs); } std::map<std::string, std::string> GetParams() const override { return param_.__DICT__(); } bool InferShape(std::vector<TShape> *in_shape, std::vector<TShape> *out_shape, std::vector<TShape> *aux_shape) const override { using namespace mshadow; CHECK_EQ(in_shape->size(), 1U); const TShape &dshape = in_shape->at(0); if (dshape.ndim() == 0) return false; out_shape->clear(); out_shape->push_back(dshape); out_shape->push_back(dshape); return true; } bool InferType(std::vector<int> *in_type, std::vector<int> *out_type, std::vector<int> *aux_type) const override { CHECK_EQ(in_type->size(), 1U); int dtype = in_type->at(0); if (dtype == -1) { LOG(FATAL) << "input type to dropout is not specified."; return false; } size_t nout = this->ListOutputs().size(); out_type->clear(); for (size_t i = 0; i < nout; ++i) out_type->push_back(dtype); return true; } OperatorProperty* Copy() const override { auto ptr = new DropoutProp(); ptr->param_ = param_; return ptr; } std::string TypeString() const override { return "Dropout"; } std::vector<int> DeclareBackwardDependency( const std::vector<int> &out_grad, const std::vector<int> &in_data, const std::vector<int> &out_data) const override { return {out_grad[dropout::kOut], out_data[dropout::kMask]}; } std::vector<std::pair<int, void*> > BackwardInplaceOption( const std::vector<int> &out_grad, const std::vector<int> &in_data, const std::vector<int> &out_data, const std::vector<void*> &in_grad) const override { return {{out_grad[dropout::kOut], in_grad[dropout::kData]}}; } std::vector<std::pair<int, void*> > ForwardInplaceOption( const std::vector<int> &in_data, const std::vector<void*> &out_data) const override { return {{in_data[dropout::kData], out_data[dropout::kOut]}}; } std::vector<ResourceRequest> ForwardResource( const std::vector<TShape> &in_shape) const override { return {ResourceRequest::kRandom}; } int NumVisibleOutputs() const override { return 1; } int NumOutputs() const override { return 2; } std::vector<std::string> ListOutputs() const override { return {"output", "mask"}; } Operator* CreateOperator(Context ctx) const override { LOG(FATAL) << "Not Implemented"; return NULL; } Operator* CreateOperatorEx(Context ctx, std::vector<TShape> *in_shape, std::vector<int> *in_type) const override; private: DropoutParam param_; }; // class DropoutProp #endif // DMLC_USE_CXX11 } // namespace op } // namespace mxnet #endif // MXNET_OPERATOR_DROPOUT_INL_H_

blake2sp-ref.c

/* BLAKE2 reference source code package - reference C implementations Written in 2012 by Samuel Neves <sneves@dei.uc.pt> To the extent possible under law, the author(s) have dedicated all copyright and related and neighboring rights to this software to the public domain worldwide. This software is distributed without any warranty. You should have received a copy of the CC0 Public Domain Dedication along with this software. If not, see <http://creativecommons.org/publicdomain/zero/1.0/>. */ #include <stdlib.h> #include <string.h> #include <stdio.h> #if defined(_OPENMP) #include <omp.h> #endif #include "blake2.h" #include "blake2-impl.h" #define PARALLELISM_DEGREE 8 static inline int blake2sp_init_leaf( blake2s_state *S, uint8_t outlen, uint8_t keylen, uint64_t offset ) { blake2s_param P[1]; P->digest_length = outlen; P->key_length = keylen; P->fanout = PARALLELISM_DEGREE; P->depth = 2; store32( &P->leaf_length, 0 ); store48( P->node_offset, offset ); P->node_depth = 0; P->inner_length = outlen; memset( P->salt, 0, sizeof( P->salt ) ); memset( P->personal, 0, sizeof( P->personal ) ); return blake2s_init_param( S, P ); } static inline int blake2sp_init_root( blake2s_state *S, uint8_t outlen, uint8_t keylen ) { blake2s_param P[1]; P->digest_length = outlen; P->key_length = keylen; P->fanout = PARALLELISM_DEGREE; P->depth = 2; store32( &P->leaf_length, 0 ); store48( P->node_offset, 0ULL ); P->node_depth = 1; P->inner_length = outlen; memset( P->salt, 0, sizeof( P->salt ) ); memset( P->personal, 0, sizeof( P->personal ) ); return blake2s_init_param( S, P ); } int blake2sp_init( blake2sp_state *S, const uint8_t outlen ) { if( !outlen || outlen > BLAKE2S_OUTBYTES ) return -1; memset( S->buf, 0, sizeof( S->buf ) ); S->buflen = 0; if( blake2sp_init_root( S->R, outlen, 0 ) < 0 ) return -1; for( size_t i = 0; i < PARALLELISM_DEGREE; ++i ) if( blake2sp_init_leaf( S->S[i], outlen, 0, i ) < 0 ) return -1; S->R->last_node = 1; S->S[PARALLELISM_DEGREE - 1]->last_node = 1; return 0; } int blake2sp_init_key( blake2sp_state *S, const uint8_t outlen, const void *key, const uint8_t keylen ) { if( !outlen || outlen > BLAKE2S_OUTBYTES ) return -1; if( !key || !keylen || keylen > BLAKE2S_KEYBYTES ) return -1; memset( S->buf, 0, sizeof( S->buf ) ); S->buflen = 0; if( blake2sp_init_root( S->R, outlen, keylen ) < 0 ) return -1; for( size_t i = 0; i < PARALLELISM_DEGREE; ++i ) if( blake2sp_init_leaf( S->S[i], outlen, keylen, i ) < 0 ) return -1; S->R->last_node = 1; S->S[PARALLELISM_DEGREE - 1]->last_node = 1; { uint8_t block[BLAKE2S_BLOCKBYTES]; memset( block, 0, BLAKE2S_BLOCKBYTES ); memcpy( block, key, keylen ); for( size_t i = 0; i < PARALLELISM_DEGREE; ++i ) blake2s_update( S->S[i], block, BLAKE2S_BLOCKBYTES ); secure_zero_memory( block, BLAKE2S_BLOCKBYTES ); /* Burn the key from stack */ } return 0; } int blake2sp_update( blake2sp_state *S, const uint8_t *in, uint64_t inlen ) { size_t left = S->buflen; size_t fill = sizeof( S->buf ) - left; if( left && inlen >= fill ) { memcpy( S->buf + left, in, fill ); for( size_t i = 0; i < PARALLELISM_DEGREE; ++i ) blake2s_update( S->S[i], S->buf + i * BLAKE2S_BLOCKBYTES, BLAKE2S_BLOCKBYTES ); in += fill; inlen -= fill; left = 0; } #if defined(_OPENMP) #pragma omp parallel shared(S), num_threads(PARALLELISM_DEGREE) #else for( size_t id__ = 0; id__ < PARALLELISM_DEGREE; ++id__ ) #endif { #if defined(_OPENMP) size_t id__ = omp_get_thread_num(); #endif uint64_t inlen__ = inlen; const uint8_t *in__ = ( const uint8_t * )in; in__ += id__ * BLAKE2S_BLOCKBYTES; while( inlen__ >= PARALLELISM_DEGREE * BLAKE2S_BLOCKBYTES ) { blake2s_update( S->S[id__], in__, BLAKE2S_BLOCKBYTES ); in__ += PARALLELISM_DEGREE * BLAKE2S_BLOCKBYTES; inlen__ -= PARALLELISM_DEGREE * BLAKE2S_BLOCKBYTES; } } in += inlen - inlen % ( PARALLELISM_DEGREE * BLAKE2S_BLOCKBYTES ); inlen %= PARALLELISM_DEGREE * BLAKE2S_BLOCKBYTES; if( inlen > 0 ) memcpy( S->buf + left, in, inlen ); S->buflen = left + inlen; return 0; } int blake2sp_final( blake2sp_state *S, uint8_t *out, const uint8_t outlen ) { uint8_t hash[PARALLELISM_DEGREE][BLAKE2S_OUTBYTES]; for( size_t i = 0; i < PARALLELISM_DEGREE; ++i ) { if( S->buflen > i * BLAKE2S_BLOCKBYTES ) { size_t left = S->buflen - i * BLAKE2S_BLOCKBYTES; if( left > BLAKE2S_BLOCKBYTES ) left = BLAKE2S_BLOCKBYTES; blake2s_update( S->S[i], S->buf + i * BLAKE2S_BLOCKBYTES, left ); } blake2s_final( S->S[i], hash[i], BLAKE2S_OUTBYTES ); } for( size_t i = 0; i < PARALLELISM_DEGREE; ++i ) blake2s_update( S->R, hash[i], BLAKE2S_OUTBYTES ); blake2s_final( S->R, out, outlen ); return 0; } int blake2sp( uint8_t *out, const void *in, const void *key, uint8_t outlen, uint64_t inlen, uint8_t keylen ) { uint8_t hash[PARALLELISM_DEGREE][BLAKE2S_OUTBYTES]; blake2s_state S[PARALLELISM_DEGREE][1]; blake2s_state FS[1]; /* Verify parameters */ if ( NULL == in ) return -1; if ( NULL == out ) return -1; if ( NULL == key ) keylen = 0; for( size_t i = 0; i < PARALLELISM_DEGREE; ++i ) if( blake2sp_init_leaf( S[i], outlen, keylen, i ) < 0 ) return -1; S[PARALLELISM_DEGREE - 1]->last_node = 1; // mark last node if( keylen > 0 ) { uint8_t block[BLAKE2S_BLOCKBYTES]; memset( block, 0, BLAKE2S_BLOCKBYTES ); memcpy( block, key, keylen ); for( size_t i = 0; i < PARALLELISM_DEGREE; ++i ) blake2s_update( S[i], block, BLAKE2S_BLOCKBYTES ); secure_zero_memory( block, BLAKE2S_BLOCKBYTES ); /* Burn the key from stack */ } #if defined(_OPENMP) #pragma omp parallel shared(S,hash), num_threads(PARALLELISM_DEGREE) #else for( size_t id__ = 0; id__ < PARALLELISM_DEGREE; ++id__ ) #endif { #if defined(_OPENMP) size_t id__ = omp_get_thread_num(); #endif uint64_t inlen__ = inlen; const uint8_t *in__ = ( const uint8_t * )in; in__ += id__ * BLAKE2S_BLOCKBYTES; while( inlen__ >= PARALLELISM_DEGREE * BLAKE2S_BLOCKBYTES ) { blake2s_update( S[id__], in__, BLAKE2S_BLOCKBYTES ); in__ += PARALLELISM_DEGREE * BLAKE2S_BLOCKBYTES; inlen__ -= PARALLELISM_DEGREE * BLAKE2S_BLOCKBYTES; } if( inlen__ > id__ * BLAKE2S_BLOCKBYTES ) { const size_t left = inlen__ - id__ * BLAKE2S_BLOCKBYTES; const size_t len = left <= BLAKE2S_BLOCKBYTES ? left : BLAKE2S_BLOCKBYTES; blake2s_update( S[id__], in__, len ); } blake2s_final( S[id__], hash[id__], BLAKE2S_OUTBYTES ); } if( blake2sp_init_root( FS, outlen, keylen ) < 0 ) return -1; FS->last_node = 1; for( size_t i = 0; i < PARALLELISM_DEGREE; ++i ) blake2s_update( FS, hash[i], BLAKE2S_OUTBYTES ); blake2s_final( FS, out, outlen ); return 0; } #if defined(BLAKE2SP_SELFTEST) #include <string.h> #include "blake2-kat.h" int main( int argc, char **argv ) { uint8_t key[BLAKE2S_KEYBYTES]; uint8_t buf[KAT_LENGTH]; for( size_t i = 0; i < BLAKE2S_KEYBYTES; ++i ) key[i] = ( uint8_t )i; for( size_t i = 0; i < KAT_LENGTH; ++i ) buf[i] = ( uint8_t )i; for( size_t i = 0; i < KAT_LENGTH; ++i ) { uint8_t hash[BLAKE2S_OUTBYTES]; blake2sp( hash, buf, key, BLAKE2S_OUTBYTES, i, BLAKE2S_KEYBYTES ); if( 0 != memcmp( hash, blake2sp_keyed_kat[i], BLAKE2S_OUTBYTES ) ) { puts( "error" ); return -1; } } puts( "ok" ); return 0; } #endif

slow_flow_calculator_cython.c

/* Generated by Cython 0.25.2 */ /* BEGIN: Cython Metadata { "distutils": { "depends": [], "extra_compile_args": [ "-fopenmp" ], "extra_link_args": [ "-fopenmp" ] }, "module_name": "triplet_flow_loss.slow_flow_calculator_cython" } END: Cython Metadata */ #define 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 < 0x03020000) #error Cython requires Python 2.6+ or Python 3.2+. #else #define CYTHON_ABI "0_25_2" #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 #ifndef HAVE_LONG_LONG #if PY_VERSION_HEX >= 0x03030000 || (PY_MAJOR_VERSION == 2 && 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_ASYNC_SLOTS #define CYTHON_USE_ASYNC_SLOTS 0 #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 #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_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 #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_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 #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 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#if CYTHON_ATOMICS #define __pyx_add_acquisition_count(memview)\ __pyx_atomic_incr_aligned(__pyx_get_slice_count_pointer(memview), memview->lock) #define __pyx_sub_acquisition_count(memview)\ __pyx_atomic_decr_aligned(__pyx_get_slice_count_pointer(memview), memview->lock) #else #define __pyx_add_acquisition_count(memview)\ __pyx_add_acquisition_count_locked(__pyx_get_slice_count_pointer(memview), memview->lock) #define __pyx_sub_acquisition_count(memview)\ __pyx_sub_acquisition_count_locked(__pyx_get_slice_count_pointer(memview), memview->lock) #endif /* "../../../../../../usr/local/lib/python2.7/dist-packages/Cython/Includes/numpy/__init__.pxd":725 * # in Cython to enable them only on the right systems. * * ctypedef npy_int8 int8_t # <<<<<<<<<<<<<< * ctypedef npy_int16 int16_t * ctypedef npy_int32 int32_t */ typedef npy_int8 __pyx_t_5numpy_int8_t; /* "../../../../../../usr/local/lib/python2.7/dist-packages/Cython/Includes/numpy/__init__.pxd":726 * * ctypedef npy_int8 int8_t * ctypedef npy_int16 int16_t # <<<<<<<<<<<<<< * ctypedef npy_int32 int32_t * ctypedef npy_int64 int64_t */ typedef npy_int16 __pyx_t_5numpy_int16_t; /* "../../../../../../usr/local/lib/python2.7/dist-packages/Cython/Includes/numpy/__init__.pxd":727 * ctypedef npy_int8 int8_t * ctypedef npy_int16 int16_t * ctypedef npy_int32 int32_t # <<<<<<<<<<<<<< * ctypedef npy_int64 int64_t * #ctypedef npy_int96 int96_t */ typedef npy_int32 __pyx_t_5numpy_int32_t; /* "../../../../../../usr/local/lib/python2.7/dist-packages/Cython/Includes/numpy/__init__.pxd":728 * ctypedef npy_int16 int16_t * ctypedef npy_int32 int32_t * ctypedef npy_int64 int64_t # <<<<<<<<<<<<<< * #ctypedef npy_int96 int96_t * #ctypedef npy_int128 int128_t */ typedef npy_int64 __pyx_t_5numpy_int64_t; /* "../../../../../../usr/local/lib/python2.7/dist-packages/Cython/Includes/numpy/__init__.pxd":732 * #ctypedef npy_int128 int128_t * * ctypedef npy_uint8 uint8_t # <<<<<<<<<<<<<< * ctypedef npy_uint16 uint16_t * ctypedef npy_uint32 uint32_t */ typedef npy_uint8 __pyx_t_5numpy_uint8_t; /* "../../../../../../usr/local/lib/python2.7/dist-packages/Cython/Includes/numpy/__init__.pxd":733 * * ctypedef npy_uint8 uint8_t * ctypedef npy_uint16 uint16_t # <<<<<<<<<<<<<< * ctypedef npy_uint32 uint32_t * ctypedef npy_uint64 uint64_t */ typedef npy_uint16 __pyx_t_5numpy_uint16_t; /* "../../../../../../usr/local/lib/python2.7/dist-packages/Cython/Includes/numpy/__init__.pxd":734 * ctypedef npy_uint8 uint8_t * ctypedef npy_uint16 uint16_t * ctypedef npy_uint32 uint32_t # <<<<<<<<<<<<<< * ctypedef npy_uint64 uint64_t * #ctypedef npy_uint96 uint96_t */ typedef npy_uint32 __pyx_t_5numpy_uint32_t; /* "../../../../../../usr/local/lib/python2.7/dist-packages/Cython/Includes/numpy/__init__.pxd":735 * ctypedef npy_uint16 uint16_t * ctypedef npy_uint32 uint32_t * ctypedef npy_uint64 uint64_t # <<<<<<<<<<<<<< * #ctypedef npy_uint96 uint96_t * #ctypedef npy_uint128 uint128_t */ typedef npy_uint64 __pyx_t_5numpy_uint64_t; /* "../../../../../../usr/local/lib/python2.7/dist-packages/Cython/Includes/numpy/__init__.pxd":739 * #ctypedef npy_uint128 uint128_t * * ctypedef npy_float32 float32_t # <<<<<<<<<<<<<< * ctypedef npy_float64 float64_t * #ctypedef npy_float80 float80_t */ typedef npy_float32 __pyx_t_5numpy_float32_t; /* "../../../../../../usr/local/lib/python2.7/dist-packages/Cython/Includes/numpy/__init__.pxd":740 * * ctypedef npy_float32 float32_t * ctypedef npy_float64 float64_t # <<<<<<<<<<<<<< * #ctypedef npy_float80 float80_t * #ctypedef npy_float128 float128_t */ typedef npy_float64 __pyx_t_5numpy_float64_t; /* "../../../../../../usr/local/lib/python2.7/dist-packages/Cython/Includes/numpy/__init__.pxd":749 * # The int types are mapped a bit surprising -- * # numpy.int corresponds to 'l' and numpy.long to 'q' * ctypedef npy_long int_t # <<<<<<<<<<<<<< * ctypedef npy_longlong long_t * ctypedef npy_longlong longlong_t */ typedef npy_long __pyx_t_5numpy_int_t; /* "../../../../../../usr/local/lib/python2.7/dist-packages/Cython/Includes/numpy/__init__.pxd":750 * # numpy.int corresponds to 'l' and numpy.long to 'q' * ctypedef npy_long int_t * ctypedef npy_longlong long_t # <<<<<<<<<<<<<< * ctypedef npy_longlong longlong_t * */ typedef npy_longlong __pyx_t_5numpy_long_t; /* "../../../../../../usr/local/lib/python2.7/dist-packages/Cython/Includes/numpy/__init__.pxd":751 * ctypedef npy_long int_t * ctypedef npy_longlong long_t * ctypedef npy_longlong longlong_t # <<<<<<<<<<<<<< * * ctypedef npy_ulong uint_t */ typedef npy_longlong __pyx_t_5numpy_longlong_t; /* "../../../../../../usr/local/lib/python2.7/dist-packages/Cython/Includes/numpy/__init__.pxd":753 * ctypedef npy_longlong longlong_t * * ctypedef npy_ulong uint_t # <<<<<<<<<<<<<< * ctypedef npy_ulonglong ulong_t * ctypedef npy_ulonglong ulonglong_t */ typedef npy_ulong __pyx_t_5numpy_uint_t; /* "../../../../../../usr/local/lib/python2.7/dist-packages/Cython/Includes/numpy/__init__.pxd":754 * * ctypedef npy_ulong uint_t * ctypedef npy_ulonglong ulong_t # <<<<<<<<<<<<<< * ctypedef npy_ulonglong ulonglong_t * */ typedef npy_ulonglong __pyx_t_5numpy_ulong_t; /* "../../../../../../usr/local/lib/python2.7/dist-packages/Cython/Includes/numpy/__init__.pxd":755 * ctypedef npy_ulong uint_t * ctypedef npy_ulonglong ulong_t * ctypedef npy_ulonglong ulonglong_t # <<<<<<<<<<<<<< * * ctypedef npy_intp intp_t */ typedef npy_ulonglong __pyx_t_5numpy_ulonglong_t; /* "../../../../../../usr/local/lib/python2.7/dist-packages/Cython/Includes/numpy/__init__.pxd":757 * ctypedef npy_ulonglong ulonglong_t * * ctypedef npy_intp intp_t # <<<<<<<<<<<<<< * ctypedef npy_uintp uintp_t * */ typedef npy_intp __pyx_t_5numpy_intp_t; /* "../../../../../../usr/local/lib/python2.7/dist-packages/Cython/Includes/numpy/__init__.pxd":758 * * ctypedef npy_intp intp_t * ctypedef npy_uintp uintp_t # <<<<<<<<<<<<<< * * ctypedef npy_double float_t */ typedef npy_uintp __pyx_t_5numpy_uintp_t; 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/* GetModuleGlobalName.proto */ static CYTHON_INLINE PyObject *__Pyx_GetModuleGlobalName(PyObject *name); /* 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 ? 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static CYTHON_INLINE PyObject *__Pyx_GetItemInt_Fast(PyObject *o, Py_ssize_t i, int is_list, int wraparound, int boundscheck); /* 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 /* SliceObject.proto */ static CYTHON_INLINE PyObject* __Pyx_PyObject_GetSlice( PyObject* obj, Py_ssize_t cstart, Py_ssize_t cstop, PyObject** py_start, PyObject** py_stop, PyObject** py_slice, int has_cstart, int has_cstop, int wraparound); /* 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, int nargs, PyObject *kwargs); #else #define __Pyx_PyFunction_FastCallDict(func, args, nargs, kwargs) _PyFunction_FastCallDict(func, args, nargs, kwargs) #endif #endif /* 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 /* 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); /* ExtTypeTest.proto */ static CYTHON_INLINE int __Pyx_TypeTest(PyObject *obj, PyTypeObject *type); /* BufferFormatCheck.proto */ static CYTHON_INLINE int __Pyx_GetBufferAndValidate(Py_buffer* buf, PyObject* obj, __Pyx_TypeInfo* dtype, int flags, int nd, int cast, __Pyx_BufFmt_StackElem* stack); static CYTHON_INLINE void __Pyx_SafeReleaseBuffer(Py_buffer* info); 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); // PROTO /* MemviewSliceInit.proto */ #define __Pyx_BUF_MAX_NDIMS %(BUF_MAX_NDIMS)d #define __Pyx_MEMVIEW_DIRECT 1 #define __Pyx_MEMVIEW_PTR 2 #define __Pyx_MEMVIEW_FULL 4 #define __Pyx_MEMVIEW_CONTIG 8 #define __Pyx_MEMVIEW_STRIDED 16 #define __Pyx_MEMVIEW_FOLLOW 32 #define __Pyx_IS_C_CONTIG 1 #define __Pyx_IS_F_CONTIG 2 static int __Pyx_init_memviewslice( struct __pyx_memoryview_obj *memview, int ndim, __Pyx_memviewslice *memviewslice, int memview_is_new_reference); 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); /* PyThreadStateGet.proto */ #if CYTHON_FAST_THREAD_STATE #define __Pyx_PyThreadState_declare PyThreadState *__pyx_tstate; #define __Pyx_PyThreadState_assign __pyx_tstate = PyThreadState_GET(); #else #define __Pyx_PyThreadState_declare #define __Pyx_PyThreadState_assign #endif /* PyErrFetchRestore.proto */ #if CYTHON_FAST_THREAD_STATE #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); #else #define __Pyx_ErrRestoreWithState(type, value, tb) PyErr_Restore(type, value, tb) #define __Pyx_ErrFetchWithState(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); /* DictGetItem.proto */ #if PY_MAJOR_VERSION >= 3 && !CYTHON_COMPILING_IN_PYPY static PyObject *__Pyx_PyDict_GetItem(PyObject *d, PyObject* key) { PyObject *value; value = PyDict_GetItemWithError(d, key); if (unlikely(!value)) { if (!PyErr_Occurred()) { PyObject* args = PyTuple_Pack(1, key); if (likely(args)) PyErr_SetObject(PyExc_KeyError, args); Py_XDECREF(args); } return NULL; } Py_INCREF(value); return value; } #else #define __Pyx_PyDict_GetItem(d, key) PyObject_GetItem(d, key) #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); /* 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 /* 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 /* 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 /* ArgTypeTest.proto */ static CYTHON_INLINE int __Pyx_ArgTypeTest(PyObject *obj, PyTypeObject *type, int none_allowed, const char *name, int exact); /* 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 /* 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 *); /* 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)); /* 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); 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); Py_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); #else #define __Pyx_PyInt_AddObjC(op1, op2, intval, inplace)\ (inplace ? 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/* SetVTable.proto */ static int __Pyx_SetVtable(PyObject *dict, void *vtable); /* 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; /* None.proto */ static Py_ssize_t __Pyx_zeros[] = {0, 0, 0, 0, 0, 0, 0, 0}; static Py_ssize_t __Pyx_minusones[] = {-1, -1, -1, -1, -1, -1, -1, -1}; /* 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); /* CIntToPy.proto */ static CYTHON_INLINE PyObject* __Pyx_PyInt_From_long(long value); /* CIntToPy.proto */ static CYTHON_INLINE PyObject* __Pyx_PyInt_From_int(int value); /* MemviewDtypeToObject.proto */ static CYTHON_INLINE PyObject *__pyx_memview_get_float(const char *itemp); static CYTHON_INLINE int __pyx_memview_set_float(const char *itemp, PyObject *obj); /* RealImag.proto */ #if CYTHON_CCOMPLEX #ifdef __cplusplus #define __Pyx_CREAL(z) ((z).real()) #define __Pyx_CIMAG(z) ((z).imag()) #else #define __Pyx_CREAL(z) (__real__(z)) #define __Pyx_CIMAG(z) (__imag__(z)) #endif #else #define __Pyx_CREAL(z) ((z).real) #define __Pyx_CIMAG(z) ((z).imag) #endif #if defined(__cplusplus) && CYTHON_CCOMPLEX\ && (defined(_WIN32) || defined(__clang__) || (defined(__GNUC__) && (__GNUC__ >= 5 || __GNUC__ == 4 && __GNUC_MINOR__ >= 4 )) || __cplusplus >= 201103) #define __Pyx_SET_CREAL(z,x) ((z).real(x)) #define __Pyx_SET_CIMAG(z,y) ((z).imag(y)) #else #define __Pyx_SET_CREAL(z,x) __Pyx_CREAL(z) = (x) #define __Pyx_SET_CIMAG(z,y) __Pyx_CIMAG(z) = (y) #endif /* Arithmetic.proto */ #if CYTHON_CCOMPLEX #define __Pyx_c_eq_float(a, b) ((a)==(b)) #define __Pyx_c_sum_float(a, b) ((a)+(b)) #define __Pyx_c_diff_float(a, b) ((a)-(b)) #define __Pyx_c_prod_float(a, b) ((a)*(b)) #define __Pyx_c_quot_float(a, b) ((a)/(b)) #define __Pyx_c_neg_float(a) (-(a)) #ifdef __cplusplus #define __Pyx_c_is_zero_float(z) ((z)==(float)0) #define __Pyx_c_conj_float(z) (::std::conj(z)) #if 1 #define __Pyx_c_abs_float(z) (::std::abs(z)) #define __Pyx_c_pow_float(a, b) (::std::pow(a, b)) #endif #else #define __Pyx_c_is_zero_float(z) ((z)==0) #define __Pyx_c_conj_float(z) (conjf(z)) #if 1 #define __Pyx_c_abs_float(z) (cabsf(z)) #define __Pyx_c_pow_float(a, b) (cpowf(a, b)) #endif #endif #else static CYTHON_INLINE int __Pyx_c_eq_float(__pyx_t_float_complex, __pyx_t_float_complex); static CYTHON_INLINE __pyx_t_float_complex __Pyx_c_sum_float(__pyx_t_float_complex, __pyx_t_float_complex); static CYTHON_INLINE __pyx_t_float_complex __Pyx_c_diff_float(__pyx_t_float_complex, __pyx_t_float_complex); static CYTHON_INLINE __pyx_t_float_complex __Pyx_c_prod_float(__pyx_t_float_complex, __pyx_t_float_complex); static CYTHON_INLINE __pyx_t_float_complex __Pyx_c_quot_float(__pyx_t_float_complex, __pyx_t_float_complex); static CYTHON_INLINE __pyx_t_float_complex __Pyx_c_neg_float(__pyx_t_float_complex); static CYTHON_INLINE int __Pyx_c_is_zero_float(__pyx_t_float_complex); static CYTHON_INLINE __pyx_t_float_complex __Pyx_c_conj_float(__pyx_t_float_complex); #if 1 static CYTHON_INLINE float __Pyx_c_abs_float(__pyx_t_float_complex); static CYTHON_INLINE __pyx_t_float_complex __Pyx_c_pow_float(__pyx_t_float_complex, __pyx_t_float_complex); #endif #endif /* Arithmetic.proto */ #if CYTHON_CCOMPLEX #define __Pyx_c_eq_double(a, b) ((a)==(b)) #define __Pyx_c_sum_double(a, b) ((a)+(b)) #define __Pyx_c_diff_double(a, b) ((a)-(b)) #define __Pyx_c_prod_double(a, b) ((a)*(b)) #define __Pyx_c_quot_double(a, b) ((a)/(b)) #define __Pyx_c_neg_double(a) (-(a)) #ifdef __cplusplus #define __Pyx_c_is_zero_double(z) ((z)==(double)0) #define __Pyx_c_conj_double(z) (::std::conj(z)) #if 1 #define __Pyx_c_abs_double(z) (::std::abs(z)) #define __Pyx_c_pow_double(a, b) (::std::pow(a, b)) #endif #else #define __Pyx_c_is_zero_double(z) ((z)==0) #define __Pyx_c_conj_double(z) (conj(z)) #if 1 #define __Pyx_c_abs_double(z) (cabs(z)) #define __Pyx_c_pow_double(a, b) (cpow(a, b)) #endif #endif #else static CYTHON_INLINE int __Pyx_c_eq_double(__pyx_t_double_complex, __pyx_t_double_complex); static CYTHON_INLINE __pyx_t_double_complex __Pyx_c_sum_double(__pyx_t_double_complex, __pyx_t_double_complex); static CYTHON_INLINE __pyx_t_double_complex __Pyx_c_diff_double(__pyx_t_double_complex, __pyx_t_double_complex); static CYTHON_INLINE __pyx_t_double_complex __Pyx_c_prod_double(__pyx_t_double_complex, __pyx_t_double_complex); static CYTHON_INLINE __pyx_t_double_complex __Pyx_c_quot_double(__pyx_t_double_complex, __pyx_t_double_complex); static CYTHON_INLINE __pyx_t_double_complex __Pyx_c_neg_double(__pyx_t_double_complex); static CYTHON_INLINE int __Pyx_c_is_zero_double(__pyx_t_double_complex); static CYTHON_INLINE __pyx_t_double_complex __Pyx_c_conj_double(__pyx_t_double_complex); #if 1 static CYTHON_INLINE double __Pyx_c_abs_double(__pyx_t_double_complex); static CYTHON_INLINE __pyx_t_double_complex __Pyx_c_pow_double(__pyx_t_double_complex, __pyx_t_double_complex); #endif #endif /* CIntToPy.proto */ static CYTHON_INLINE PyObject* __Pyx_PyInt_From_enum__NPY_TYPES(enum NPY_TYPES value); /* 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 int __Pyx_PyInt_As_int(PyObject *); /* CIntFromPy.proto */ static CYTHON_INLINE char __Pyx_PyInt_As_char(PyObject *); /* CIntFromPy.proto */ static CYTHON_INLINE long __Pyx_PyInt_As_long(PyObject *); /* 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_dsdsds_float(PyObject *); /* ObjectToMemviewSlice.proto */ static CYTHON_INLINE __Pyx_memviewslice __Pyx_PyObject_to_MemoryviewSlice_dsds_int(PyObject *); /* ObjectToMemviewSlice.proto */ static CYTHON_INLINE __Pyx_memviewslice __Pyx_PyObject_to_MemoryviewSlice_dsds_float(PyObject *); /* CheckBinaryVersion.proto */ static int __Pyx_check_binary_version(void); /* PyIdentifierFromString.proto */ #if !defined(__Pyx_PyIdentifier_FromString) #if PY_MAJOR_VERSION < 3 #define __Pyx_PyIdentifier_FromString(s) PyString_FromString(s) #else #define __Pyx_PyIdentifier_FromString(s) PyUnicode_FromString(s) #endif #endif /* ModuleImport.proto */ static PyObject *__Pyx_ImportModule(const char *name); /* TypeImport.proto */ static PyTypeObject *__Pyx_ImportType(const char *module_name, const char *class_name, size_t size, int strict); /* 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 'cpython.buffer' */ /* Module declarations from 'libc.string' */ /* Module declarations from 'libc.stdio' */ /* Module declarations from '__builtin__' */ /* Module declarations from 'cpython.type' */ static PyTypeObject *__pyx_ptype_7cpython_4type_type = 0; /* Module declarations from 'cpython' */ /* Module declarations from 'cpython.object' */ /* Module declarations from 'cpython.ref' */ /* Module declarations from 'libc.stdlib' */ /* Module declarations from 'numpy' */ /* Module declarations from 'numpy' */ static PyTypeObject *__pyx_ptype_5numpy_dtype = 0; static PyTypeObject *__pyx_ptype_5numpy_flatiter = 0; static PyTypeObject *__pyx_ptype_5numpy_broadcast = 0; static PyTypeObject *__pyx_ptype_5numpy_ndarray = 0; static PyTypeObject *__pyx_ptype_5numpy_ufunc = 0; static CYTHON_INLINE char *__pyx_f_5numpy__util_dtypestring(PyArray_Descr *, char *, char *, int *); /*proto*/ /* Module declarations from 'libc.math' */ /* Module declarations from 'triplet_flow_loss.slow_flow_calculator_cython' */ 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 PyObject *__pyx_f_17triplet_flow_loss_27slow_flow_calculator_cython_compute_flow_helper(PyArrayObject *, PyArrayObject *, PyArrayObject *, int, PyArrayObject *, PyArrayObject *, int); /*proto*/ static void __pyx_f_17triplet_flow_loss_27slow_flow_calculator_cython_set_flow_at_point(int, int, float, float, __Pyx_memviewslice); /*proto*/ static CYTHON_INLINE float __pyx_f_17triplet_flow_loss_27slow_flow_calculator_cython_dist(__Pyx_memviewslice, __Pyx_memviewslice, int, int, int, int, int); /*proto*/ static CYTHON_INLINE int __pyx_f_17triplet_flow_loss_27slow_flow_calculator_cython_max_int(int, int); /*proto*/ static CYTHON_INLINE int __pyx_f_17triplet_flow_loss_27slow_flow_calculator_cython_min_int(int, int); /*proto*/ 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 __Pyx_TypeInfo __Pyx_TypeInfo_nn___pyx_t_5numpy_float32_t = { "float32_t", NULL, sizeof(__pyx_t_5numpy_float32_t), { 0 }, 0, 'R', 0, 0 }; static __Pyx_TypeInfo __Pyx_TypeInfo_nn___pyx_t_5numpy_int32_t = { "int32_t", NULL, sizeof(__pyx_t_5numpy_int32_t), { 0 }, 0, IS_UNSIGNED(__pyx_t_5numpy_int32_t) ? 'U' : 'I', IS_UNSIGNED(__pyx_t_5numpy_int32_t), 0 }; static __Pyx_TypeInfo __Pyx_TypeInfo_float = { "float", NULL, sizeof(float), { 0 }, 0, 'R', 0, 0 }; static __Pyx_TypeInfo __Pyx_TypeInfo_int = { "int", NULL, sizeof(int), { 0 }, 0, IS_UNSIGNED(int) ? 'U' : 'I', IS_UNSIGNED(int), 0 }; #define __Pyx_MODULE_NAME "triplet_flow_loss.slow_flow_calculator_cython" int __pyx_module_is_main_triplet_flow_loss__slow_flow_calculator_cython = 0; /* Implementation of 'triplet_flow_loss.slow_flow_calculator_cython' */ static PyObject *__pyx_builtin_range; static PyObject *__pyx_builtin_ValueError; static PyObject *__pyx_builtin_RuntimeError; static PyObject *__pyx_builtin_ImportError; static PyObject *__pyx_builtin_MemoryError; static PyObject *__pyx_builtin_enumerate; static PyObject *__pyx_builtin_Ellipsis; static PyObject *__pyx_builtin_TypeError; 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_id[] = "id"; static const char __pyx_k_np[] = "np"; static const char __pyx_k_obj[] = "obj"; static const char __pyx_k_base[] = "base"; static const char __pyx_k_main[] = "__main__"; static const char __pyx_k_mask[] = "mask"; static const char __pyx_k_math[] = "math"; 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_class[] = "__class__"; static const char __pyx_k_dtype[] = "dtype"; static const char __pyx_k_error[] = "error"; static const char __pyx_k_flags[] = "flags"; static const char __pyx_k_int32[] = "int32"; static const char __pyx_k_numpy[] = "numpy"; static const char __pyx_k_range[] = "range"; static const char __pyx_k_shape[] = "shape"; static const char __pyx_k_start[] = "start"; static const char __pyx_k_zeros[] = "zeros"; static const char __pyx_k_astype[] = "astype"; 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_struct[] = "struct"; static const char __pyx_k_unpack[] = "unpack"; static const char __pyx_k_asarray[] = "asarray"; static const char __pyx_k_float32[] = "float32"; static const char __pyx_k_fortran[] = "fortran"; static const char __pyx_k_memview[] = "memview"; static const char __pyx_k_Ellipsis[] = "Ellipsis"; static const char __pyx_k_itemsize[] = "itemsize"; static const char __pyx_k_TypeError[] = "TypeError"; static const char __pyx_k_enumerate[] = "enumerate"; static const char __pyx_k_IndexError[] = "IndexError"; static const char __pyx_k_ValueError[] = "ValueError"; static const char __pyx_k_pyx_vtable[] = "__pyx_vtable__"; static const char __pyx_k_ImportError[] = "ImportError"; static const char __pyx_k_MemoryError[] = "MemoryError"; static const char __pyx_k_array_equal[] = "array_equal"; static const char __pyx_k_interpolate[] = "interpolate"; static const char __pyx_k_RuntimeError[] = "RuntimeError"; static const char __pyx_k_compute_flow[] = "compute_flow"; static const char __pyx_k_left_features[] = "left_features"; static const char __pyx_k_pyx_getbuffer[] = "__pyx_getbuffer"; static const char __pyx_k_initialization[] = "initialization"; static const char __pyx_k_right_features[] = "right_features"; 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_feature_error_arr[] = "feature_error_arr"; static const char __pyx_k_interpolate_after[] = "interpolate_after"; static const char __pyx_k_strided_and_direct[] = "<strided and direct>"; 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_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_neighborhood_len_import[] = "neighborhood_len_import"; 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_itemsize_0_for_cython_array[] = "itemsize <= 0 for cython.array"; static const char __pyx_k_ndarray_is_not_C_contiguous[] = "ndarray is not C contiguous"; 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_home_davidm_DA_RNN_DA_RNN_lib_t[] = "/home/davidm/DA-RNN/DA-RNN/lib/triplet_flow_loss/slow_flow_calculator_cython.pyx"; static const char __pyx_k_numpy_core_multiarray_failed_to[] = "numpy.core.multiarray failed to import"; static const char __pyx_k_unknown_dtype_code_in_numpy_pxd[] = "unknown dtype code in numpy.pxd (%d)"; 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_Empty_shape_tuple_for_cython_arr[] = "Empty shape tuple for cython.array"; static const char __pyx_k_Format_string_allocated_too_shor[] = "Format string allocated too short, see comment in numpy.pxd"; 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_Non_native_byte_order_not_suppor[] = "Non-native byte order not supported"; 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_ndarray_is_not_Fortran_contiguou[] = "ndarray is not Fortran contiguous"; 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static PyObject *__pyx_codeobj__27; /* "triplet_flow_loss/slow_flow_calculator_cython.pyx":14 * * * def compute_flow(left_features, right_features, mask, initialization, neighborhood_len_import=6, interpolate_after=False): # <<<<<<<<<<<<<< * """ * Calculate optical flow using a nearest neighbor search. */ /* Python wrapper */ static PyObject *__pyx_pw_17triplet_flow_loss_27slow_flow_calculator_cython_1compute_flow(PyObject *__pyx_self, PyObject *__pyx_args, PyObject *__pyx_kwds); /*proto*/ static char __pyx_doc_17triplet_flow_loss_27slow_flow_calculator_cython_compute_flow[] = "\n Calculate optical flow using a nearest neighbor search.\n :param left_features: Feature array from the first image\n :param right_features: Feature array from the second image\n :param mask: An integer array of points to not compute flow from or to. 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} /* "triplet_flow_loss/slow_flow_calculator_cython.pyx":78 * set_flow_at_point(i, j, 0.0, 0.0, flow_arr) * else: * best_index_u = i # <<<<<<<<<<<<<< * best_index_v = j * */ /*else*/ { __pyx_v_best_index_u = __pyx_v_i; /* "triplet_flow_loss/slow_flow_calculator_cython.pyx":79 * else: * best_index_u = i * best_index_v = j # <<<<<<<<<<<<<< * * # set the starting distance to no be no movement. Otherwise the default will be large */ __pyx_v_best_index_v = __pyx_v_j; /* "triplet_flow_loss/slow_flow_calculator_cython.pyx":82 * * # set the starting distance to no be no movement. Otherwise the default will be large * current_dist = 10**5 # just a really big number # <<<<<<<<<<<<<< * * initial_i = <int> flow_arr[i, j, 1] + i */ __pyx_v_current_dist = 100000.0; /* "triplet_flow_loss/slow_flow_calculator_cython.pyx":84 * current_dist = 10**5 # just a really big number * * initial_i = <int> flow_arr[i, j, 1] + i # <<<<<<<<<<<<<< * initial_j = <int> flow_arr[i, j, 0] + j * current_dist = dist(left_features, right_features, i, j, initial_i, initial_j, feature_depth) */ __pyx_t_12 = __pyx_v_i; __pyx_t_13 = __pyx_v_j; __pyx_t_14 = 1; __pyx_v_initial_i = (((int)(*((float *) ( /* dim=2 */ (( /* dim=1 */ (( /* dim=0 */ (__pyx_v_flow_arr.data + __pyx_t_12 * __pyx_v_flow_arr.strides[0]) ) + __pyx_t_13 * __pyx_v_flow_arr.strides[1]) ) + __pyx_t_14 * __pyx_v_flow_arr.strides[2]) )))) + __pyx_v_i); /* "triplet_flow_loss/slow_flow_calculator_cython.pyx":85 * * initial_i = <int> flow_arr[i, j, 1] + i * initial_j = <int> flow_arr[i, j, 0] + j # <<<<<<<<<<<<<< * current_dist = dist(left_features, right_features, i, j, initial_i, initial_j, feature_depth) * best_dist = current_dist */ __pyx_t_15 = __pyx_v_i; __pyx_t_16 = __pyx_v_j; __pyx_t_17 = 0; __pyx_v_initial_j = (((int)(*((float *) ( /* dim=2 */ (( /* dim=1 */ (( /* dim=0 */ (__pyx_v_flow_arr.data + __pyx_t_15 * __pyx_v_flow_arr.strides[0]) ) + __pyx_t_16 * __pyx_v_flow_arr.strides[1]) ) + __pyx_t_17 * __pyx_v_flow_arr.strides[2]) )))) + __pyx_v_j); /* "triplet_flow_loss/slow_flow_calculator_cython.pyx":86 * initial_i = <int> flow_arr[i, j, 1] + i * initial_j = <int> flow_arr[i, j, 0] + j * current_dist = dist(left_features, right_features, i, j, initial_i, initial_j, feature_depth) # <<<<<<<<<<<<<< * best_dist = current_dist * */ __pyx_v_current_dist = __pyx_f_17triplet_flow_loss_27slow_flow_calculator_cython_dist(__pyx_v_left_features, __pyx_v_right_features, __pyx_v_i, __pyx_v_j, __pyx_v_initial_i, __pyx_v_initial_j, __pyx_v_feature_depth); /* "triplet_flow_loss/slow_flow_calculator_cython.pyx":87 * initial_j = <int> flow_arr[i, j, 0] + j * current_dist = dist(left_features, right_features, i, j, initial_i, initial_j, feature_depth) * best_dist = current_dist # <<<<<<<<<<<<<< * * start_a = max_int(0, initial_i - neighborhood_len/2) */ __pyx_v_best_dist = __pyx_v_current_dist; /* "triplet_flow_loss/slow_flow_calculator_cython.pyx":89 * best_dist = current_dist * * start_a = max_int(0, initial_i - neighborhood_len/2) # <<<<<<<<<<<<<< * stop_a = min_int(left_len_0, initial_i + (neighborhood_len - neighborhood_len/2)) * start_b = max_int(0, initial_j - neighborhood_len / 2) */ __pyx_v_start_a = __pyx_f_17triplet_flow_loss_27slow_flow_calculator_cython_max_int(0, (__pyx_v_initial_i - (__pyx_v_neighborhood_len / 2))); /* "triplet_flow_loss/slow_flow_calculator_cython.pyx":90 * * start_a = max_int(0, initial_i - neighborhood_len/2) * stop_a = min_int(left_len_0, initial_i + (neighborhood_len - neighborhood_len/2)) # <<<<<<<<<<<<<< * start_b = max_int(0, initial_j - neighborhood_len / 2) * stop_b = min_int(left_len_1, initial_j + (<int> neighborhood_len - <int> neighborhood_len / 2)) */ __pyx_v_stop_a = __pyx_f_17triplet_flow_loss_27slow_flow_calculator_cython_min_int(__pyx_v_left_len_0, (__pyx_v_initial_i + (__pyx_v_neighborhood_len - (__pyx_v_neighborhood_len / 2)))); /* "triplet_flow_loss/slow_flow_calculator_cython.pyx":91 * start_a = max_int(0, initial_i - neighborhood_len/2) * stop_a = min_int(left_len_0, initial_i + (neighborhood_len - neighborhood_len/2)) * start_b = max_int(0, initial_j - neighborhood_len / 2) # <<<<<<<<<<<<<< * stop_b = min_int(left_len_1, initial_j + (<int> neighborhood_len - <int> neighborhood_len / 2)) * for a in range(start_a, stop_a): */ __pyx_v_start_b = __pyx_f_17triplet_flow_loss_27slow_flow_calculator_cython_max_int(0, (__pyx_v_initial_j - (__pyx_v_neighborhood_len / 2))); /* "triplet_flow_loss/slow_flow_calculator_cython.pyx":92 * stop_a = min_int(left_len_0, initial_i + (neighborhood_len - neighborhood_len/2)) * start_b = max_int(0, initial_j - neighborhood_len / 2) * stop_b = min_int(left_len_1, initial_j + (<int> neighborhood_len - <int> neighborhood_len / 2)) # <<<<<<<<<<<<<< * for a in range(start_a, stop_a): * for b in range(start_b, stop_b): */ __pyx_v_stop_b = __pyx_f_17triplet_flow_loss_27slow_flow_calculator_cython_min_int(__pyx_v_left_len_1, (__pyx_v_initial_j + (((int)__pyx_v_neighborhood_len) - (((int)__pyx_v_neighborhood_len) / 2)))); /* "triplet_flow_loss/slow_flow_calculator_cython.pyx":93 * start_b = max_int(0, initial_j - neighborhood_len / 2) * stop_b = min_int(left_len_1, initial_j + (<int> neighborhood_len - <int> neighborhood_len / 2)) * for a in range(start_a, stop_a): # <<<<<<<<<<<<<< * for b in range(start_b, stop_b): * current_dist = dist(left_features, right_features, i, j, a, b, feature_depth) */ __pyx_t_18 = __pyx_v_stop_a; for (__pyx_t_19 = __pyx_v_start_a; __pyx_t_19 < __pyx_t_18; __pyx_t_19+=1) { __pyx_v_a = __pyx_t_19; /* "triplet_flow_loss/slow_flow_calculator_cython.pyx":94 * stop_b = min_int(left_len_1, initial_j + (<int> neighborhood_len - <int> neighborhood_len / 2)) * for a in range(start_a, stop_a): * for b in range(start_b, stop_b): # <<<<<<<<<<<<<< * current_dist = dist(left_features, right_features, i, j, a, b, feature_depth) * if current_dist < best_dist: */ __pyx_t_20 = __pyx_v_stop_b; for (__pyx_t_21 = __pyx_v_start_b; __pyx_t_21 < __pyx_t_20; __pyx_t_21+=1) { __pyx_v_b = __pyx_t_21; /* "triplet_flow_loss/slow_flow_calculator_cython.pyx":95 * for a in range(start_a, stop_a): * for b in range(start_b, stop_b): * current_dist = dist(left_features, right_features, i, j, a, b, feature_depth) # <<<<<<<<<<<<<< * if current_dist < best_dist: * best_dist = current_dist */ __pyx_v_current_dist = __pyx_f_17triplet_flow_loss_27slow_flow_calculator_cython_dist(__pyx_v_left_features, __pyx_v_right_features, __pyx_v_i, __pyx_v_j, __pyx_v_a, __pyx_v_b, __pyx_v_feature_depth); /* "triplet_flow_loss/slow_flow_calculator_cython.pyx":96 * for b in range(start_b, stop_b): * current_dist = dist(left_features, right_features, i, j, a, b, feature_depth) * if current_dist < best_dist: # <<<<<<<<<<<<<< * best_dist = current_dist * best_index_u = a */ __pyx_t_11 = ((__pyx_v_current_dist < __pyx_v_best_dist) != 0); if (__pyx_t_11) { /* "triplet_flow_loss/slow_flow_calculator_cython.pyx":97 * current_dist = dist(left_features, right_features, i, j, a, b, feature_depth) * if current_dist < best_dist: * best_dist = current_dist # <<<<<<<<<<<<<< * best_index_u = a * best_index_v = b */ __pyx_v_best_dist = __pyx_v_current_dist; /* "triplet_flow_loss/slow_flow_calculator_cython.pyx":98 * if current_dist < best_dist: * best_dist = current_dist * best_index_u = a # <<<<<<<<<<<<<< * best_index_v = b * */ __pyx_v_best_index_u = __pyx_v_a; /* "triplet_flow_loss/slow_flow_calculator_cython.pyx":99 * best_dist = current_dist * best_index_u = a * best_index_v = b # <<<<<<<<<<<<<< * * if interpolate_after == 1 and best_index_u != -1: */ __pyx_v_best_index_v = __pyx_v_b; /* "triplet_flow_loss/slow_flow_calculator_cython.pyx":96 * for b in range(start_b, stop_b): * current_dist = dist(left_features, right_features, i, j, a, b, feature_depth) * if current_dist < best_dist: # <<<<<<<<<<<<<< * best_dist = current_dist * best_index_u = a */ } } } /* "triplet_flow_loss/slow_flow_calculator_cython.pyx":101 * best_index_v = b * * if interpolate_after == 1 and best_index_u != -1: # <<<<<<<<<<<<<< * u1 = <int> best_index_u - 1 * if u1 < 0: */ __pyx_t_22 = ((__pyx_v_interpolate_after == 1) != 0); if (__pyx_t_22) { } else { __pyx_t_11 = __pyx_t_22; goto __pyx_L19_bool_binop_done; } __pyx_t_22 = ((__pyx_v_best_index_u != -1.0) != 0); __pyx_t_11 = __pyx_t_22; __pyx_L19_bool_binop_done:; if (__pyx_t_11) { /* "triplet_flow_loss/slow_flow_calculator_cython.pyx":102 * * if interpolate_after == 1 and best_index_u != -1: * u1 = <int> best_index_u - 1 # <<<<<<<<<<<<<< * if u1 < 0: * u1 = 0 */ __pyx_v_u1 = (((int)__pyx_v_best_index_u) - 1); /* "triplet_flow_loss/slow_flow_calculator_cython.pyx":103 * if interpolate_after == 1 and best_index_u != -1: * u1 = <int> best_index_u - 1 * if u1 < 0: # <<<<<<<<<<<<<< * u1 = 0 * if u1 >= right_len_0 - 3: */ __pyx_t_11 = ((__pyx_v_u1 < 0) != 0); if (__pyx_t_11) { /* "triplet_flow_loss/slow_flow_calculator_cython.pyx":104 * u1 = <int> best_index_u - 1 * if u1 < 0: * u1 = 0 # <<<<<<<<<<<<<< * if u1 >= right_len_0 - 3: * u1 = right_len_0 - 3 */ __pyx_v_u1 = 0; /* "triplet_flow_loss/slow_flow_calculator_cython.pyx":103 * if interpolate_after == 1 and best_index_u != -1: * u1 = <int> best_index_u - 1 * if u1 < 0: # <<<<<<<<<<<<<< * u1 = 0 * if u1 >= right_len_0 - 3: */ } /* "triplet_flow_loss/slow_flow_calculator_cython.pyx":105 * if u1 < 0: * u1 = 0 * if u1 >= right_len_0 - 3: # <<<<<<<<<<<<<< * u1 = right_len_0 - 3 * u2 = u1 + 2 */ __pyx_t_11 = ((__pyx_v_u1 >= (__pyx_v_right_len_0 - 3)) != 0); if (__pyx_t_11) { /* "triplet_flow_loss/slow_flow_calculator_cython.pyx":106 * u1 = 0 * if u1 >= right_len_0 - 3: * u1 = right_len_0 - 3 # <<<<<<<<<<<<<< * u2 = u1 + 2 * */ __pyx_v_u1 = (__pyx_v_right_len_0 - 3); /* "triplet_flow_loss/slow_flow_calculator_cython.pyx":105 * if u1 < 0: * u1 = 0 * if u1 >= right_len_0 - 3: # <<<<<<<<<<<<<< * u1 = right_len_0 - 3 * u2 = u1 + 2 */ } /* "triplet_flow_loss/slow_flow_calculator_cython.pyx":107 * if u1 >= right_len_0 - 3: * u1 = right_len_0 - 3 * u2 = u1 + 2 # <<<<<<<<<<<<<< * * dist1 = dist(left_features, right_features, i, j, u1, <int> best_index_v, feature_depth) */ __pyx_v_u2 = (__pyx_v_u1 + 2); /* "triplet_flow_loss/slow_flow_calculator_cython.pyx":109 * u2 = u1 + 2 * * dist1 = dist(left_features, right_features, i, j, u1, <int> best_index_v, feature_depth) # <<<<<<<<<<<<<< * dist2 = dist(left_features, right_features, i, j, u2, <int> best_index_v, feature_depth) * best_index_u = dist1 / (dist1 + dist2 + 0.00001) * u2 + dist2 / (dist1 + dist2 + 0.00001) * u1 */ __pyx_v_dist1 = __pyx_f_17triplet_flow_loss_27slow_flow_calculator_cython_dist(__pyx_v_left_features, __pyx_v_right_features, __pyx_v_i, __pyx_v_j, __pyx_v_u1, ((int)__pyx_v_best_index_v), __pyx_v_feature_depth); /* "triplet_flow_loss/slow_flow_calculator_cython.pyx":110 * * dist1 = dist(left_features, right_features, i, j, u1, <int> best_index_v, feature_depth) * dist2 = dist(left_features, right_features, i, j, u2, <int> best_index_v, feature_depth) # <<<<<<<<<<<<<< * best_index_u = dist1 / (dist1 + dist2 + 0.00001) * u2 + dist2 / (dist1 + dist2 + 0.00001) * u1 * # if not (u1 <= best_index_u and u2 >= best_index_u): */ __pyx_v_dist2 = __pyx_f_17triplet_flow_loss_27slow_flow_calculator_cython_dist(__pyx_v_left_features, __pyx_v_right_features, __pyx_v_i, __pyx_v_j, __pyx_v_u2, ((int)__pyx_v_best_index_v), __pyx_v_feature_depth); /* "triplet_flow_loss/slow_flow_calculator_cython.pyx":111 * dist1 = dist(left_features, right_features, i, j, u1, <int> best_index_v, feature_depth) * dist2 = dist(left_features, right_features, i, j, u2, <int> best_index_v, feature_depth) * best_index_u = dist1 / (dist1 + dist2 + 0.00001) * u2 + dist2 / (dist1 + dist2 + 0.00001) * u1 # <<<<<<<<<<<<<< * # if not (u1 <= best_index_u and u2 >= best_index_u): * # printf("i %3i, j, %3i, u1 %2i, u2 %2i, best_index_v %2.1f, dist1 %3.2f,\t dist2 %3.2f,\t best_index_u %3.1lf\n", i, j, u1, u2, best_index_v, dist1, dist2, best_index_u) */ __pyx_v_best_index_u = (((__pyx_v_dist1 / ((__pyx_v_dist1 + __pyx_v_dist2) + 0.00001)) * __pyx_v_u2) + ((__pyx_v_dist2 / ((__pyx_v_dist1 + __pyx_v_dist2) + 0.00001)) * __pyx_v_u1)); /* "triplet_flow_loss/slow_flow_calculator_cython.pyx":115 * # printf("i %3i, j, %3i, u1 %2i, u2 %2i, best_index_v %2.1f, dist1 %3.2f,\t dist2 %3.2f,\t best_index_u %3.1lf\n", i, j, u1, u2, best_index_v, dist1, dist2, best_index_u) * * v1 = <int> best_index_v - 1 # <<<<<<<<<<<<<< * if v1 < 0: * v1 = 0 */ __pyx_v_v1 = (((int)__pyx_v_best_index_v) - 1); /* "triplet_flow_loss/slow_flow_calculator_cython.pyx":116 * * v1 = <int> best_index_v - 1 * if v1 < 0: # <<<<<<<<<<<<<< * v1 = 0 * if v1 >= right_len_1 - 3: */ __pyx_t_11 = ((__pyx_v_v1 < 0) != 0); if (__pyx_t_11) { /* "triplet_flow_loss/slow_flow_calculator_cython.pyx":117 * v1 = <int> best_index_v - 1 * if v1 < 0: * v1 = 0 # <<<<<<<<<<<<<< * if v1 >= right_len_1 - 3: * v1 = right_len_1 - 3 */ __pyx_v_v1 = 0; /* "triplet_flow_loss/slow_flow_calculator_cython.pyx":116 * * v1 = <int> best_index_v - 1 * if v1 < 0: # <<<<<<<<<<<<<< * v1 = 0 * if v1 >= right_len_1 - 3: */ } /* "triplet_flow_loss/slow_flow_calculator_cython.pyx":118 * if v1 < 0: * v1 = 0 * if v1 >= right_len_1 - 3: # <<<<<<<<<<<<<< * v1 = right_len_1 - 3 * v2 = v1 + 2 */ __pyx_t_11 = ((__pyx_v_v1 >= (__pyx_v_right_len_1 - 3)) != 0); if (__pyx_t_11) { /* "triplet_flow_loss/slow_flow_calculator_cython.pyx":119 * v1 = 0 * if v1 >= right_len_1 - 3: * v1 = right_len_1 - 3 # <<<<<<<<<<<<<< * v2 = v1 + 2 * */ __pyx_v_v1 = (__pyx_v_right_len_1 - 3); /* "triplet_flow_loss/slow_flow_calculator_cython.pyx":118 * if v1 < 0: * v1 = 0 * if v1 >= right_len_1 - 3: # <<<<<<<<<<<<<< * v1 = right_len_1 - 3 * v2 = v1 + 2 */ } /* "triplet_flow_loss/slow_flow_calculator_cython.pyx":120 * if v1 >= right_len_1 - 3: * v1 = right_len_1 - 3 * v2 = v1 + 2 # <<<<<<<<<<<<<< * * dist1 = dist(left_features, right_features, i, j, <int> best_index_u, v1, feature_depth) */ __pyx_v_v2 = (__pyx_v_v1 + 2); /* "triplet_flow_loss/slow_flow_calculator_cython.pyx":122 * v2 = v1 + 2 * * dist1 = dist(left_features, right_features, i, j, <int> best_index_u, v1, feature_depth) # <<<<<<<<<<<<<< * dist2 = dist(left_features, right_features, i, j, <int> best_index_u, v2, feature_depth) * best_index_v = (dist1 + 0.00001) / (dist1 + dist2 + 0.00002) * v2 + (dist2 + 0.00001) / (dist1 + dist2 + 0.00002) * v1 */ __pyx_v_dist1 = __pyx_f_17triplet_flow_loss_27slow_flow_calculator_cython_dist(__pyx_v_left_features, __pyx_v_right_features, __pyx_v_i, __pyx_v_j, ((int)__pyx_v_best_index_u), __pyx_v_v1, __pyx_v_feature_depth); /* "triplet_flow_loss/slow_flow_calculator_cython.pyx":123 * * dist1 = dist(left_features, right_features, i, j, <int> best_index_u, v1, feature_depth) * dist2 = dist(left_features, right_features, i, j, <int> best_index_u, v2, feature_depth) # <<<<<<<<<<<<<< * best_index_v = (dist1 + 0.00001) / (dist1 + dist2 + 0.00002) * v2 + (dist2 + 0.00001) / (dist1 + dist2 + 0.00002) * v1 * # if not (v1 <= best_index_v and v2 >= best_index_v): */ __pyx_v_dist2 = __pyx_f_17triplet_flow_loss_27slow_flow_calculator_cython_dist(__pyx_v_left_features, __pyx_v_right_features, __pyx_v_i, __pyx_v_j, ((int)__pyx_v_best_index_u), __pyx_v_v2, __pyx_v_feature_depth); /* "triplet_flow_loss/slow_flow_calculator_cython.pyx":124 * dist1 = dist(left_features, right_features, i, j, <int> best_index_u, v1, feature_depth) * dist2 = dist(left_features, right_features, i, j, <int> best_index_u, v2, feature_depth) * best_index_v = (dist1 + 0.00001) / (dist1 + dist2 + 0.00002) * v2 + (dist2 + 0.00001) / (dist1 + dist2 + 0.00002) * v1 # <<<<<<<<<<<<<< * # if not (v1 <= best_index_v and v2 >= best_index_v): * # printf("i %3i, j, %3i, v1 %2i, v2 %2i, best_index_u %2.1f, dist1 %3.2f,\t dist2 %3.2f,\t best_index_v %3.1lf\n", i, j, v1, v2, best_index_u, dist1, dist2, best_index_v) */ __pyx_v_best_index_v = ((((__pyx_v_dist1 + 0.00001) / ((__pyx_v_dist1 + __pyx_v_dist2) + 0.00002)) * __pyx_v_v2) + (((__pyx_v_dist2 + 0.00001) / ((__pyx_v_dist1 + __pyx_v_dist2) + 0.00002)) * __pyx_v_v1)); /* "triplet_flow_loss/slow_flow_calculator_cython.pyx":101 * best_index_v = b * * if interpolate_after == 1 and best_index_u != -1: # <<<<<<<<<<<<<< * u1 = <int> best_index_u - 1 * if u1 < 0: */ } /* "triplet_flow_loss/slow_flow_calculator_cython.pyx":128 * # printf("i %3i, j, %3i, v1 %2i, v2 %2i, best_index_u %2.1f, dist1 %3.2f,\t dist2 %3.2f,\t best_index_v %3.1lf\n", i, j, v1, v2, best_index_u, dist1, dist2, best_index_v) * * if best_index_u != -1: # <<<<<<<<<<<<<< * set_flow_at_point(i, j, best_index_v - j, best_index_u - i, flow_arr) * feature_errors[i, j] = <float> dist(left_features, right_features, i, j, <int> best_index_u, <int> best_index_v, feature_depth) */ __pyx_t_11 = ((__pyx_v_best_index_u != -1.0) != 0); if (__pyx_t_11) { /* "triplet_flow_loss/slow_flow_calculator_cython.pyx":129 * * if best_index_u != -1: * set_flow_at_point(i, j, best_index_v - j, best_index_u - i, flow_arr) # <<<<<<<<<<<<<< * feature_errors[i, j] = <float> dist(left_features, right_features, i, j, <int> best_index_u, <int> best_index_v, feature_depth) * else: */ __pyx_f_17triplet_flow_loss_27slow_flow_calculator_cython_set_flow_at_point(__pyx_v_i, __pyx_v_j, (__pyx_v_best_index_v - __pyx_v_j), (__pyx_v_best_index_u - __pyx_v_i), __pyx_v_flow_arr); 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__pyx_t_2 = (__pyx_v_negative_step != 0); if (__pyx_t_2) { /* "View.MemoryView":834 * elif start >= shape: * if negative_step: * start = shape - 1 # <<<<<<<<<<<<<< * else: * start = shape */ __pyx_v_start = (__pyx_v_shape - 1); /* "View.MemoryView":833 * start = 0 * elif start >= shape: * if negative_step: # <<<<<<<<<<<<<< * start = shape - 1 * else: */ goto __pyx_L14; } /* "View.MemoryView":836 * start = shape - 1 * else: * start = shape # <<<<<<<<<<<<<< * else: * if negative_step: */ /*else*/ { __pyx_v_start = __pyx_v_shape; } __pyx_L14:; /* "View.MemoryView":832 * if start < 0: * start = 0 * elif start >= shape: # <<<<<<<<<<<<<< * if negative_step: * start = shape - 1 */ } __pyx_L12:; /* "View.MemoryView":827 * * * if have_start: # <<<<<<<<<<<<<< * if start < 0: * start += shape */ goto __pyx_L11; } /* "View.MemoryView":838 * 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":839 * else: * if negative_step: * start = shape - 1 # <<<<<<<<<<<<<< * else: * start = 0 */ __pyx_v_start = (__pyx_v_shape - 1); /* "View.MemoryView":838 * start = shape * else: * if negative_step: # <<<<<<<<<<<<<< * start = shape - 1 * else: */ goto __pyx_L15; } /* "View.MemoryView":841 * start = shape - 1 * else: * start = 0 # <<<<<<<<<<<<<< * * if have_stop: */ /*else*/ { __pyx_v_start = 0; } __pyx_L15:; } __pyx_L11:; /* "View.MemoryView":843 * start = 0 * * if have_stop: # <<<<<<<<<<<<<< * if stop < 0: * stop += shape */ __pyx_t_2 = (__pyx_v_have_stop != 0); if (__pyx_t_2) { /* "View.MemoryView":844 * * if have_stop: * if stop < 0: # <<<<<<<<<<<<<< * stop += shape * if stop < 0: */ __pyx_t_2 = ((__pyx_v_stop < 0) != 0); if (__pyx_t_2) { /* "View.MemoryView":845 * if have_stop: * if stop < 0: * stop += shape # <<<<<<<<<<<<<< * if stop < 0: * stop = 0 */ __pyx_v_stop = (__pyx_v_stop + __pyx_v_shape); /* "View.MemoryView":846 * if stop < 0: * stop += shape * if 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__pyx_t_1 = __Pyx_TypeCheck(((PyObject *)__pyx_v_memview), __pyx_memoryviewslice_type); __pyx_t_2 = (__pyx_t_1 != 0); if (__pyx_t_2) { /* "View.MemoryView":1078 * * if isinstance(memview, _memoryviewslice): * to_object_func = (<_memoryviewslice> memview).to_object_func # <<<<<<<<<<<<<< * to_dtype_func = (<_memoryviewslice> memview).to_dtype_func * else: */ __pyx_t_3 = ((struct __pyx_memoryviewslice_obj *)__pyx_v_memview)->to_object_func; __pyx_v_to_object_func = __pyx_t_3; /* "View.MemoryView":1079 * if isinstance(memview, _memoryviewslice): * to_object_func = (<_memoryviewslice> memview).to_object_func * to_dtype_func = (<_memoryviewslice> memview).to_dtype_func # <<<<<<<<<<<<<< * else: * to_object_func = NULL */ __pyx_t_4 = ((struct __pyx_memoryviewslice_obj *)__pyx_v_memview)->to_dtype_func; __pyx_v_to_dtype_func = __pyx_t_4; /* "View.MemoryView":1077 * cdef int (*to_dtype_func)(char *, object) except 0 * * if isinstance(memview, _memoryviewslice): # <<<<<<<<<<<<<< * to_object_func 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__pyx_memoryview_fromslice((__pyx_v_memviewslice[0]), __pyx_v_memview->view.ndim, __pyx_v_to_object_func, __pyx_v_to_dtype_func, __pyx_v_memview->dtype_is_object); if (unlikely(!__pyx_t_5)) __PYX_ERR(2, 1084, __pyx_L1_error) __Pyx_GOTREF(__pyx_t_5); __pyx_r = __pyx_t_5; __pyx_t_5 = 0; goto __pyx_L0; /* "View.MemoryView":1070 * * @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. */ /* function exit 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":1092 * * * 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":1093 * * 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":1094 * 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":1093 * * cdef Py_ssize_t abs_py_ssize_t(Py_ssize_t arg) nogil: * if arg < 0: # <<<<<<<<<<<<<< * return -arg * else: */ } /* "View.MemoryView":1096 * return -arg * else: * return arg # <<<<<<<<<<<<<< * * @cname('__pyx_get_best_slice_order') */ /*else*/ { __pyx_r = __pyx_v_arg; goto __pyx_L0; } /* "View.MemoryView":1092 * * * 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":1099 * * @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; /* "View.MemoryView":1104 * """ * cdef int i * cdef Py_ssize_t c_stride = 0 # <<<<<<<<<<<<<< * cdef Py_ssize_t f_stride = 0 * */ __pyx_v_c_stride = 0; /* "View.MemoryView":1105 * 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":1107 * 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 > -1L; __pyx_t_1-=1) { __pyx_v_i = __pyx_t_1; /* "View.MemoryView":1108 * * 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":1109 * 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":1110 * if mslice.shape[i] > 1: * c_stride = mslice.strides[i] * break # <<<<<<<<<<<<<< * * for i in range(ndim): */ goto __pyx_L4_break; /* "View.MemoryView":1108 * * for i in range(ndim - 1, -1, -1): * if mslice.shape[i] > 1: # <<<<<<<<<<<<<< * c_stride = mslice.strides[i] * break */ } } __pyx_L4_break:; /* "View.MemoryView":1112 * break * * for i in range(ndim): # <<<<<<<<<<<<<< * if mslice.shape[i] > 1: * f_stride = mslice.strides[i] */ __pyx_t_1 = __pyx_v_ndim; for (__pyx_t_3 = 0; __pyx_t_3 < __pyx_t_1; __pyx_t_3+=1) { __pyx_v_i = __pyx_t_3; /* "View.MemoryView":1113 * * 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":1114 * 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":1115 * 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":1113 * * for i in range(ndim): * if mslice.shape[i] > 1: # <<<<<<<<<<<<<< * f_stride = mslice.strides[i] * break */ } } __pyx_L7_break:; /* "View.MemoryView":1117 * 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":1118 * * 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":1117 * break * * if abs_py_ssize_t(c_stride) <= abs_py_ssize_t(f_stride): # <<<<<<<<<<<<<< * return 'C' * else: */ } /* "View.MemoryView":1120 * return 'C' * else: * return 'F' # <<<<<<<<<<<<<< * * @cython.cdivision(True) */ /*else*/ { __pyx_r = 'F'; goto __pyx_L0; } /* "View.MemoryView":1099 * * @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":1123 * * @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; /* "View.MemoryView":1130 * * 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":1131 * 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":1132 * 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":1133 * 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":1135 * 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":1136 * * 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":1137 * 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":1136 * * 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":1138 * 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): */ memcpy(__pyx_v_dst_data, __pyx_v_src_data, (__pyx_v_itemsize * __pyx_v_dst_extent)); /* "View.MemoryView":1136 * * 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":1140 * 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; for (__pyx_t_5 = 0; __pyx_t_5 < __pyx_t_4; __pyx_t_5+=1) { __pyx_v_i = __pyx_t_5; /* "View.MemoryView":1141 * else: * for i in range(dst_extent): * memcpy(dst_data, src_data, itemsize) # <<<<<<<<<<<<<< * src_data += src_stride * dst_data += dst_stride */ memcpy(__pyx_v_dst_data, __pyx_v_src_data, __pyx_v_itemsize); /* "View.MemoryView":1142 * for i in range(dst_extent): * memcpy(dst_data, src_data, itemsize) * src_data += src_stride # <<<<<<<<<<<<<< * dst_data += dst_stride * else: */ __pyx_v_src_data = (__pyx_v_src_data + __pyx_v_src_stride); /* "View.MemoryView":1143 * memcpy(dst_data, src_data, itemsize) * src_data += src_stride * dst_data += dst_stride # <<<<<<<<<<<<<< * else: * for i in range(dst_extent): */ __pyx_v_dst_data = (__pyx_v_dst_data + __pyx_v_dst_stride); } } __pyx_L4:; /* "View.MemoryView":1135 * 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): */ goto __pyx_L3; } /* "View.MemoryView":1145 * dst_data += dst_stride * else: * for i in range(dst_extent): # <<<<<<<<<<<<<< * _copy_strided_to_strided(src_data, src_strides + 1, * dst_data, dst_strides + 1, */ /*else*/ { __pyx_t_4 = __pyx_v_dst_extent; for (__pyx_t_5 = 0; __pyx_t_5 < __pyx_t_4; __pyx_t_5+=1) { __pyx_v_i = __pyx_t_5; /* "View.MemoryView":1146 * else: * for i in range(dst_extent): * _copy_strided_to_strided(src_data, src_strides + 1, # <<<<<<<<<<<<<< * dst_data, dst_strides + 1, * src_shape + 1, dst_shape + 1, */ _copy_strided_to_strided(__pyx_v_src_data, (__pyx_v_src_strides + 1), __pyx_v_dst_data, (__pyx_v_dst_strides + 1), (__pyx_v_src_shape + 1), (__pyx_v_dst_shape + 1), (__pyx_v_ndim - 1), __pyx_v_itemsize); /* "View.MemoryView":1150 * src_shape + 1, dst_shape + 1, * ndim - 1, itemsize) * src_data += src_stride # <<<<<<<<<<<<<< * dst_data += dst_stride * */ __pyx_v_src_data = (__pyx_v_src_data + __pyx_v_src_stride); /* "View.MemoryView":1151 * ndim - 1, itemsize) * src_data += src_stride * dst_data += dst_stride # <<<<<<<<<<<<<< * * cdef void copy_strided_to_strided(__Pyx_memviewslice *src, */ __pyx_v_dst_data = (__pyx_v_dst_data + __pyx_v_dst_stride); } } __pyx_L3:; /* "View.MemoryView":1123 * * @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, */ /* function exit code */ } /* "View.MemoryView":1153 * dst_data += dst_stride * * cdef void copy_strided_to_strided(__Pyx_memviewslice *src, # <<<<<<<<<<<<<< * __Pyx_memviewslice *dst, * int ndim, size_t itemsize) nogil: */ static void copy_strided_to_strided(__Pyx_memviewslice *__pyx_v_src, __Pyx_memviewslice *__pyx_v_dst, int __pyx_v_ndim, size_t __pyx_v_itemsize) { /* "View.MemoryView":1156 * __Pyx_memviewslice *dst, * int ndim, size_t itemsize) nogil: * _copy_strided_to_strided(src.data, src.strides, dst.data, dst.strides, # <<<<<<<<<<<<<< * src.shape, dst.shape, ndim, itemsize) * */ _copy_strided_to_strided(__pyx_v_src->data, __pyx_v_src->strides, __pyx_v_dst->data, __pyx_v_dst->strides, __pyx_v_src->shape, __pyx_v_dst->shape, __pyx_v_ndim, __pyx_v_itemsize); /* "View.MemoryView":1153 * dst_data += dst_stride * * cdef void copy_strided_to_strided(__Pyx_memviewslice *src, # <<<<<<<<<<<<<< * __Pyx_memviewslice *dst, * int ndim, size_t itemsize) nogil: */ /* function exit code */ } /* "View.MemoryView":1160 * * @cname('__pyx_memoryview_slice_get_size') * cdef Py_ssize_t slice_get_size(__Pyx_memviewslice *src, int ndim) nogil: # <<<<<<<<<<<<<< * "Return the size of the memory occupied by the slice in number of bytes" * cdef int i */ static Py_ssize_t __pyx_memoryview_slice_get_size(__Pyx_memviewslice *__pyx_v_src, int __pyx_v_ndim) { int __pyx_v_i; Py_ssize_t __pyx_v_size; Py_ssize_t __pyx_r; Py_ssize_t __pyx_t_1; int __pyx_t_2; int __pyx_t_3; /* "View.MemoryView":1163 * "Return the size of the memory occupied by the slice in number of bytes" * cdef int i * cdef 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Py_INCREF((((PyObject **)__pyx_v_data)[0])); /* "View.MemoryView":1367 * for i in range(shape[0]): * if ndim == 1: * if inc: # <<<<<<<<<<<<<< * Py_INCREF((<PyObject **> data)[0]) * else: */ goto __pyx_L6; } /* "View.MemoryView":1370 * Py_INCREF((<PyObject **> data)[0]) * else: * Py_DECREF((<PyObject **> data)[0]) # <<<<<<<<<<<<<< * else: * refcount_objects_in_slice(data, shape + 1, strides + 1, */ /*else*/ { Py_DECREF((((PyObject **)__pyx_v_data)[0])); } __pyx_L6:; /* "View.MemoryView":1366 * * for i in range(shape[0]): * if ndim == 1: # <<<<<<<<<<<<<< * if inc: * Py_INCREF((<PyObject **> data)[0]) */ goto __pyx_L5; } /* "View.MemoryView":1372 * Py_DECREF((<PyObject **> data)[0]) * else: * refcount_objects_in_slice(data, shape + 1, strides + 1, # <<<<<<<<<<<<<< * ndim - 1, inc) * */ /*else*/ { /* "View.MemoryView":1373 * else: * refcount_objects_in_slice(data, shape + 1, strides + 1, * ndim - 1, inc) # <<<<<<<<<<<<<< * * data += strides[0] */ __pyx_memoryview_refcount_objects_in_slice(__pyx_v_data, (__pyx_v_shape + 1), (__pyx_v_strides + 1), (__pyx_v_ndim - 1), __pyx_v_inc); } __pyx_L5:; /* "View.MemoryView":1375 * ndim - 1, inc) * * data += strides[0] # <<<<<<<<<<<<<< * * */ __pyx_v_data = (__pyx_v_data + (__pyx_v_strides[0])); } /* "View.MemoryView":1361 * * @cname('__pyx_memoryview_refcount_objects_in_slice') * cdef void refcount_objects_in_slice(char *data, Py_ssize_t *shape, # <<<<<<<<<<<<<< * Py_ssize_t *strides, int ndim, bint inc): * cdef Py_ssize_t i */ /* function exit code */ __Pyx_RefNannyFinishContext(); } /* "View.MemoryView":1381 * * @cname('__pyx_memoryview_slice_assign_scalar') * cdef void slice_assign_scalar(__Pyx_memviewslice *dst, int ndim, # <<<<<<<<<<<<<< * size_t itemsize, void *item, * bint dtype_is_object) nogil: */ static void __pyx_memoryview_slice_assign_scalar(__Pyx_memviewslice *__pyx_v_dst, int __pyx_v_ndim, size_t __pyx_v_itemsize, void *__pyx_v_item, int __pyx_v_dtype_is_object) { /* "View.MemoryView":1384 * size_t itemsize, void *item, * bint dtype_is_object) nogil: * refcount_copying(dst, dtype_is_object, ndim, False) # <<<<<<<<<<<<<< * _slice_assign_scalar(dst.data, dst.shape, dst.strides, ndim, * itemsize, item) */ __pyx_memoryview_refcount_copying(__pyx_v_dst, __pyx_v_dtype_is_object, __pyx_v_ndim, 0); /* "View.MemoryView":1385 * bint dtype_is_object) nogil: * refcount_copying(dst, dtype_is_object, ndim, False) * _slice_assign_scalar(dst.data, dst.shape, dst.strides, ndim, # <<<<<<<<<<<<<< * itemsize, item) * refcount_copying(dst, dtype_is_object, ndim, True) */ __pyx_memoryview__slice_assign_scalar(__pyx_v_dst->data, __pyx_v_dst->shape, __pyx_v_dst->strides, __pyx_v_ndim, __pyx_v_itemsize, __pyx_v_item); /* "View.MemoryView":1387 * _slice_assign_scalar(dst.data, dst.shape, dst.strides, ndim, * itemsize, item) * refcount_copying(dst, dtype_is_object, ndim, True) # <<<<<<<<<<<<<< * * */ __pyx_memoryview_refcount_copying(__pyx_v_dst, __pyx_v_dtype_is_object, __pyx_v_ndim, 1); /* "View.MemoryView":1381 * * @cname('__pyx_memoryview_slice_assign_scalar') * cdef void slice_assign_scalar(__Pyx_memviewslice *dst, int ndim, # <<<<<<<<<<<<<< * size_t itemsize, void *item, * bint dtype_is_object) nogil: */ /* function exit code */ } /* "View.MemoryView":1391 * * @cname('__pyx_memoryview__slice_assign_scalar') * cdef void _slice_assign_scalar(char *data, Py_ssize_t *shape, # <<<<<<<<<<<<<< * Py_ssize_t *strides, int ndim, * size_t itemsize, void *item) nogil: */ static void __pyx_memoryview__slice_assign_scalar(char *__pyx_v_data, Py_ssize_t *__pyx_v_shape, Py_ssize_t *__pyx_v_strides, int __pyx_v_ndim, size_t __pyx_v_itemsize, void *__pyx_v_item) { CYTHON_UNUSED Py_ssize_t __pyx_v_i; Py_ssize_t __pyx_v_stride; Py_ssize_t __pyx_v_extent; int __pyx_t_1; Py_ssize_t __pyx_t_2; Py_ssize_t __pyx_t_3; /* "View.MemoryView":1395 * size_t itemsize, void *item) nogil: * cdef Py_ssize_t i * cdef Py_ssize_t stride = strides[0] # <<<<<<<<<<<<<< * cdef Py_ssize_t extent = shape[0] * */ __pyx_v_stride = (__pyx_v_strides[0]); /* "View.MemoryView":1396 * cdef Py_ssize_t i * cdef Py_ssize_t stride = strides[0] * cdef Py_ssize_t extent = shape[0] # <<<<<<<<<<<<<< * * if ndim == 1: */ __pyx_v_extent = (__pyx_v_shape[0]); /* "View.MemoryView":1398 * cdef Py_ssize_t extent = shape[0] * * if ndim == 1: # <<<<<<<<<<<<<< * for i in range(extent): * memcpy(data, item, itemsize) */ __pyx_t_1 = ((__pyx_v_ndim == 1) != 0); if (__pyx_t_1) { /* "View.MemoryView":1399 * * if ndim == 1: * for i in range(extent): # <<<<<<<<<<<<<< * memcpy(data, item, itemsize) * data += stride */ __pyx_t_2 = __pyx_v_extent; for (__pyx_t_3 = 0; __pyx_t_3 < __pyx_t_2; __pyx_t_3+=1) { __pyx_v_i = __pyx_t_3; /* "View.MemoryView":1400 * if ndim == 1: * for i in range(extent): * memcpy(data, item, itemsize) # <<<<<<<<<<<<<< * data += stride * else: */ memcpy(__pyx_v_data, __pyx_v_item, __pyx_v_itemsize); /* "View.MemoryView":1401 * for i in range(extent): * memcpy(data, item, itemsize) * data += stride # <<<<<<<<<<<<<< * else: * for i in range(extent): */ __pyx_v_data = (__pyx_v_data + __pyx_v_stride); } /* "View.MemoryView":1398 * cdef Py_ssize_t extent = shape[0] * * if ndim == 1: # <<<<<<<<<<<<<< * for i in range(extent): * memcpy(data, item, itemsize) */ goto __pyx_L3; } /* "View.MemoryView":1403 * data += stride * else: * for i in range(extent): # <<<<<<<<<<<<<< * _slice_assign_scalar(data, shape + 1, strides + 1, * ndim - 1, itemsize, item) */ /*else*/ { __pyx_t_2 = __pyx_v_extent; for (__pyx_t_3 = 0; __pyx_t_3 < __pyx_t_2; __pyx_t_3+=1) { __pyx_v_i = __pyx_t_3; /* "View.MemoryView":1404 * else: * for i in range(extent): * _slice_assign_scalar(data, shape + 1, strides + 1, # <<<<<<<<<<<<<< * ndim - 1, itemsize, item) * data += stride */ __pyx_memoryview__slice_assign_scalar(__pyx_v_data, (__pyx_v_shape + 1), (__pyx_v_strides + 1), (__pyx_v_ndim - 1), __pyx_v_itemsize, __pyx_v_item); /* "View.MemoryView":1406 * _slice_assign_scalar(data, shape + 1, strides + 1, * ndim - 1, itemsize, item) * data += stride # <<<<<<<<<<<<<< * * */ __pyx_v_data = (__pyx_v_data + __pyx_v_stride); } } __pyx_L3:; /* "View.MemoryView":1391 * * @cname('__pyx_memoryview__slice_assign_scalar') * cdef void _slice_assign_scalar(char *data, Py_ssize_t *shape, # <<<<<<<<<<<<<< * Py_ssize_t *strides, int ndim, * size_t itemsize, void *item) nogil: */ /* function exit code */ } static struct __pyx_vtabstruct_array __pyx_vtable_array; static PyObject *__pyx_tp_new_array(PyTypeObject *t, PyObject *a, PyObject *k) { struct __pyx_array_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_array_obj *)o); p->__pyx_vtab = __pyx_vtabptr_array; p->mode = ((PyObject*)Py_None); Py_INCREF(Py_None); p->_format = ((PyObject*)Py_None); Py_INCREF(Py_None); if (unlikely(__pyx_array___cinit__(o, a, k) < 0)) goto bad; return o; bad: Py_DECREF(o); o = 0; return NULL; } static void __pyx_tp_dealloc_array(PyObject *o) { struct __pyx_array_obj *p = (struct __pyx_array_obj *)o; #if PY_VERSION_HEX >= 0x030400a1 if (unlikely(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); ++Py_REFCNT(o); __pyx_array___dealloc__(o); --Py_REFCNT(o); 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 = 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}, {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 = { 0, /*sq_length*/ 0, /*sq_concat*/ 0, /*sq_repeat*/ __pyx_sq_item_array, /*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_array = { 0, /*mp_length*/ __pyx_array___getitem__, /*mp_subscript*/ __pyx_mp_ass_subscript_array, /*mp_ass_subscript*/ }; static PyBufferProcs __pyx_tp_as_buffer_array = { #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_array_getbuffer, /*bf_getbuffer*/ 0, /*bf_releasebuffer*/ }; static PyTypeObject __pyx_type___pyx_array = { PyVarObject_HEAD_INIT(0, 0) "triplet_flow_loss.slow_flow_calculator_cython.array", /*tp_name*/ sizeof(struct __pyx_array_obj), /*tp_basicsize*/ 0, /*tp_itemsize*/ __pyx_tp_dealloc_array, /*tp_dealloc*/ 0, /*tp_print*/ 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 }; 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 PY_VERSION_HEX >= 0x030400a1 if (unlikely(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[] = { {0, 0, 0, 0} }; static PyTypeObject __pyx_type___pyx_MemviewEnum = { PyVarObject_HEAD_INIT(0, 0) "triplet_flow_loss.slow_flow_calculator_cython.Enum", /*tp_name*/ sizeof(struct __pyx_MemviewEnum_obj), /*tp_basicsize*/ 0, /*tp_itemsize*/ __pyx_tp_dealloc_Enum, /*tp_dealloc*/ 0, /*tp_print*/ 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 }; 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 PY_VERSION_HEX >= 0x030400a1 if (unlikely(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); ++Py_REFCNT(o); __pyx_memoryview___dealloc__(o); --Py_REFCNT(o); 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}, {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) "triplet_flow_loss.slow_flow_calculator_cython.memoryview", /*tp_name*/ sizeof(struct __pyx_memoryview_obj), /*tp_basicsize*/ 0, /*tp_itemsize*/ __pyx_tp_dealloc_memoryview, /*tp_dealloc*/ 0, /*tp_print*/ 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 }; static struct __pyx_vtabstruct__memoryviewslice __pyx_vtable__memoryviewslice; static PyObject *__pyx_tp_new__memoryviewslice(PyTypeObject *t, PyObject *a, PyObject *k) { struct __pyx_memoryviewslice_obj *p; PyObject *o = __pyx_tp_new_memoryview(t, a, k); if (unlikely(!o)) return 0; p = ((struct __pyx_memoryviewslice_obj *)o); p->__pyx_base.__pyx_vtab = (struct __pyx_vtabstruct_memoryview*)__pyx_vtabptr__memoryviewslice; p->from_object = Py_None; Py_INCREF(Py_None); p->from_slice.memview = NULL; return o; } static void __pyx_tp_dealloc__memoryviewslice(PyObject *o) { struct __pyx_memoryviewslice_obj *p = (struct __pyx_memoryviewslice_obj *)o; #if PY_VERSION_HEX >= 0x030400a1 if (unlikely(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); ++Py_REFCNT(o); __pyx_memoryviewslice___dealloc__(o); --Py_REFCNT(o); PyErr_Restore(etype, eval, etb); } Py_CLEAR(p->from_object); PyObject_GC_Track(o); __pyx_tp_dealloc_memoryview(o); } static int __pyx_tp_traverse__memoryviewslice(PyObject *o, visitproc v, void *a) { int e; struct __pyx_memoryviewslice_obj *p = (struct __pyx_memoryviewslice_obj *)o; e = __pyx_tp_traverse_memoryview(o, v, a); if (e) return e; if (p->from_object) { e = (*v)(p->from_object, a); if (e) return e; } return 0; } static int __pyx_tp_clear__memoryviewslice(PyObject *o) { PyObject* tmp; struct __pyx_memoryviewslice_obj *p = (struct __pyx_memoryviewslice_obj *)o; __pyx_tp_clear_memoryview(o); tmp = ((PyObject*)p->from_object); p->from_object = Py_None; Py_INCREF(Py_None); Py_XDECREF(tmp); 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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)); } /* PyObjectCall */ #if CYTHON_COMPILING_IN_CPYTHON static CYTHON_INLINE PyObject* __Pyx_PyObject_Call(PyObject *func, PyObject *arg, PyObject *kw) { PyObject *result; ternaryfunc call = func->ob_type->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 /* SliceObject */ static CYTHON_INLINE PyObject* __Pyx_PyObject_GetSlice(PyObject* obj, Py_ssize_t cstart, Py_ssize_t cstop, PyObject** _py_start, PyObject** _py_stop, PyObject** _py_slice, int has_cstart, int has_cstop, CYTHON_UNUSED int wraparound) { #if CYTHON_USE_TYPE_SLOTS PyMappingMethods* mp; #if PY_MAJOR_VERSION < 3 PySequenceMethods* ms = Py_TYPE(obj)->tp_as_sequence; if (likely(ms && ms->sq_slice)) { if (!has_cstart) { if (_py_start && (*_py_start != Py_None)) { cstart = __Pyx_PyIndex_AsSsize_t(*_py_start); if ((cstart == (Py_ssize_t)-1) && PyErr_Occurred()) goto bad; } else cstart = 0; } if (!has_cstop) { if (_py_stop && (*_py_stop != Py_None)) { cstop = __Pyx_PyIndex_AsSsize_t(*_py_stop); if ((cstop == (Py_ssize_t)-1) && PyErr_Occurred()) goto bad; } else cstop = PY_SSIZE_T_MAX; } if (wraparound && unlikely((cstart < 0) | (cstop < 0)) && likely(ms->sq_length)) { Py_ssize_t l = ms->sq_length(obj); if (likely(l >= 0)) { if (cstop < 0) { cstop += l; if (cstop < 0) cstop = 0; } if (cstart < 0) { cstart += l; if (cstart < 0) cstart = 0; } } else { if (!PyErr_ExceptionMatches(PyExc_OverflowError)) goto bad; PyErr_Clear(); } } return ms->sq_slice(obj, cstart, cstop); } #endif mp = Py_TYPE(obj)->tp_as_mapping; if (likely(mp && mp->mp_subscript)) #endif { PyObject* result; PyObject *py_slice, *py_start, *py_stop; if (_py_slice) { py_slice = *_py_slice; } else { PyObject* owned_start = NULL; PyObject* owned_stop = NULL; if (_py_start) { py_start = *_py_start; } else { if (has_cstart) { owned_start = py_start = PyInt_FromSsize_t(cstart); if (unlikely(!py_start)) goto bad; } else py_start = Py_None; } if (_py_stop) { py_stop = *_py_stop; } else { if (has_cstop) { owned_stop = py_stop = PyInt_FromSsize_t(cstop); if (unlikely(!py_stop)) { Py_XDECREF(owned_start); goto bad; } } else py_stop = Py_None; } py_slice = PySlice_New(py_start, py_stop, Py_None); Py_XDECREF(owned_start); Py_XDECREF(owned_stop); if (unlikely(!py_slice)) goto bad; } #if CYTHON_USE_TYPE_SLOTS result = mp->mp_subscript(obj, py_slice); #else result = PyObject_GetItem(obj, py_slice); #endif if (!_py_slice) { Py_DECREF(py_slice); } return result; } PyErr_Format(PyExc_TypeError, "'%.200s' object is unsliceable", Py_TYPE(obj)->tp_name); bad: return NULL; } /* PyFunctionFastCall */ #if CYTHON_FAST_PYCALL #include "frameobject.h" static PyObject* __Pyx_PyFunction_FastCallNoKw(PyCodeObject *co, PyObject **args, Py_ssize_t na, PyObject *globals) { PyFrameObject *f; PyThreadState *tstate = PyThreadState_GET(); 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 = f->f_localsplus; 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, int 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, nargs, k, (int)nk, d, (int)nd, kwdefs, closure); #else result = PyEval_EvalCodeEx(co, globals, (PyObject *)NULL, args, nargs, k, (int)nk, d, (int)nd, closure); #endif Py_XDECREF(kwtuple); done: Py_LeaveRecursiveCall(); return result; } #endif // CPython < 3.6 #endif // CYTHON_FAST_PYCALL /* 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); assert(PyCFunction_Check(func)); assert(METH_FASTCALL == (PyCFunction_GET_FLAGS(func) & ~(METH_CLASS | METH_STATIC | METH_COEXIST))); 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()); return (*((__Pyx_PyCFunctionFast)meth)) (self, args, nargs, NULL); } #endif // CYTHON_FAST_PYCCALL /* 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 #ifdef __Pyx_CyFunction_USED if (likely(PyCFunction_Check(func) || PyObject_TypeCheck(func, __pyx_CyFunctionType))) { #else if (likely(PyCFunction_Check(func))) { #endif if (likely(PyCFunction_GET_FLAGS(func) & METH_O)) { return __Pyx_PyObject_CallMethO(func, arg); #if CYTHON_FAST_PYCCALL } else if (PyCFunction_GET_FLAGS(func) & METH_FASTCALL) { 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 /* 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(PyObject_TypeCheck(obj, type))) return 1; PyErr_Format(PyExc_TypeError, "Cannot convert %.200s to %.200s", Py_TYPE(obj)->tp_name, type->tp_name); return 0; } /* BufferFormatCheck */ static CYTHON_INLINE int __Pyx_IsLittleEndian(void) { unsigned int n = 1; return *(unsigned char*)(&n) != 0; } 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 '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 '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 '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 CYTHON_INLINE PyObject * __pyx_buffmt_parse_array(__Pyx_BufFmt_Context* ctx, const char** tsp) { const char *ts = *tsp; int i = 0, number; int ndim = ctx->head->field->type->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; 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_IsLittleEndian()) { PyErr_SetString(PyExc_ValueError, "Little-endian buffer not supported on big-endian compiler"); return NULL; } ctx->new_packmode = '='; ++ts; break; case '>': case '!': if (__Pyx_IsLittleEndian()) { 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; } 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->enc_count += ctx->new_count; ctx->new_count = 1; got_Z = 0; ++ts; break; } 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; } } } } static CYTHON_INLINE void __Pyx_ZeroBuffer(Py_buffer* buf) { buf->buf = NULL; buf->obj = NULL; buf->strides = __Pyx_zeros; buf->shape = __Pyx_zeros; buf->suboffsets = __Pyx_minusones; } static CYTHON_INLINE int __Pyx_GetBufferAndValidate( Py_buffer* buf, PyObject* obj, __Pyx_TypeInfo* dtype, int flags, int nd, int cast, __Pyx_BufFmt_StackElem* stack) { if (obj == Py_None || obj == NULL) { __Pyx_ZeroBuffer(buf); return 0; } buf->buf = NULL; if (__Pyx_GetBuffer(obj, buf, flags) == -1) goto fail; if (buf->ndim != nd) { PyErr_Format(PyExc_ValueError, "Buffer has wrong number of dimensions (expected %d, got %d)", nd, buf->ndim); goto fail; } if (!cast) { __Pyx_BufFmt_Context ctx; __Pyx_BufFmt_Init(&ctx, stack, dtype); if (!__Pyx_BufFmt_CheckString(&ctx, buf->format)) goto fail; } if ((unsigned)buf->itemsize != dtype->size) { PyErr_Format(PyExc_ValueError, "Item size of buffer (%" CYTHON_FORMAT_SSIZE_T "d byte%s) does not match size of '%s' (%" CYTHON_FORMAT_SSIZE_T "d byte%s)", buf->itemsize, (buf->itemsize > 1) ? "s" : "", dtype->name, (Py_ssize_t)dtype->size, (dtype->size > 1) ? "s" : ""); goto fail; } if (buf->suboffsets == NULL) buf->suboffsets = __Pyx_minusones; return 0; fail:; __Pyx_ZeroBuffer(buf); return -1; } static CYTHON_INLINE void __Pyx_SafeReleaseBuffer(Py_buffer* info) { if (info->buf == NULL) return; if (info->suboffsets == __Pyx_minusones) info->suboffsets = NULL; __Pyx_ReleaseBuffer(info); } /* 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 (!buf) { PyErr_SetString(PyExc_ValueError, "buf is NULL."); goto fail; } else if (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; } static CYTHON_INLINE void __pyx_fatalerror(const char *fmt, ...) { va_list vargs; char msg[200]; #ifdef HAVE_STDARG_PROTOTYPES va_start(vargs, fmt); #else va_start(vargs); #endif vsnprintf(msg, 200, fmt, vargs); Py_FatalError(msg); va_end(vargs); } 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 (!memview || (PyObject *) memview == Py_None) return; if (__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 (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 (!memview ) { return; } else if ((PyObject *) memview == Py_None) { memslice->memview = NULL; return; } if (__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 (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; } } /* 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 PY_VERSION_HEX >= 0x03030000 if (cause) { #else if (cause && cause != Py_None) { #endif 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 = PyThreadState_GET(); 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 /* 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"); } /* SaveResetException */ #if CYTHON_FAST_THREAD_STATE static CYTHON_INLINE void __Pyx__ExceptionSave(PyThreadState *tstate, PyObject **type, PyObject **value, PyObject **tb) { *type = tstate->exc_type; *value = tstate->exc_value; *tb = tstate->exc_traceback; 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; 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; Py_XDECREF(tmp_type); Py_XDECREF(tmp_value); Py_XDECREF(tmp_tb); } #endif /* PyErrExceptionMatches */ #if CYTHON_FAST_THREAD_STATE 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; return PyErr_GivenExceptionMatches(exc_type, err); } #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 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; 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; } /* ArgTypeTest */ static void __Pyx_RaiseArgumentTypeInvalid(const char* name, PyObject *obj, PyTypeObject *type) { PyErr_Format(PyExc_TypeError, "Argument '%.200s' has incorrect type (expected %.200s, got %.200s)", name, type->tp_name, Py_TYPE(obj)->tp_name); } static CYTHON_INLINE int __Pyx_ArgTypeTest(PyObject *obj, PyTypeObject *type, int none_allowed, const char *name, int exact) { if (unlikely(!type)) { PyErr_SetString(PyExc_SystemError, "Missing type object"); return 0; } if (none_allowed && obj == Py_None) return 1; else if (exact) { if (likely(Py_TYPE(obj) == type)) return 1; #if PY_MAJOR_VERSION == 2 else if ((type == &PyBaseString_Type) && likely(__Pyx_PyBaseString_CheckExact(obj))) return 1; #endif } else { if (likely(PyObject_TypeCheck(obj, type))) return 1; } __Pyx_RaiseArgumentTypeInvalid(name, obj, type); return 0; } /* 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 = 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; } 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_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 } /* GetAttr */ static CYTHON_INLINE PyObject *__Pyx_GetAttr(PyObject *o, PyObject *n) { #if CYTHON_COMPILING_IN_CPYTHON #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); } /* 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; } length = stop - start; if (unlikely(length <= 0)) return PyUnicode_FromUnicode(NULL, 0); cstring += start; if (decode_func) { return decode_func(cstring, length, errors); } else { return PyUnicode_Decode(cstring, length, encoding, errors); } } /* 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; 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; *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_VERSION_HEX < 0x03030000 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 (strchr(__Pyx_MODULE_NAME, '.')) { #if PY_VERSION_HEX < 0x03030000 PyObject *py_level = PyInt_FromLong(1); if (!py_level) goto bad; module = PyObject_CallFunctionObjArgs(py_import, name, global_dict, empty_dict, list, py_level, NULL); Py_DECREF(py_level); #else module = PyImport_ImportModuleLevelObject( name, global_dict, empty_dict, list, 1); #endif if (!module) { if (!PyErr_ExceptionMatches(PyExc_ImportError)) goto bad; PyErr_Clear(); } } level = 0; } #endif if (!module) { #if PY_VERSION_HEX < 0x03030000 PyObject *py_level = PyInt_FromLong(level); if (!py_level) goto bad; module = PyObject_CallFunctionObjArgs(py_import, name, global_dict, empty_dict, list, py_level, NULL); Py_DECREF(py_level); #else module = PyImport_ImportModuleLevelObject( name, global_dict, empty_dict, list, level); #endif } } bad: #if PY_VERSION_HEX < 0x03030000 Py_XDECREF(py_import); #endif Py_XDECREF(empty_list); Py_XDECREF(empty_dict); return module; } /* PyIntBinop */ #if !CYTHON_COMPILING_IN_PYPY static PyObject* __Pyx_PyInt_AddObjC(PyObject *op1, PyObject *op2, CYTHON_UNUSED long intval, CYTHON_UNUSED int inplace) { #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 } 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 } 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 } 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 } 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 } 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 } 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); } /* WriteUnraisableException */ static void __Pyx_WriteUnraisable(const char *name, CYTHON_UNUSED int clineno, CYTHON_UNUSED int lineno, CYTHON_UNUSED const char *filename, int full_traceback, CYTHON_UNUSED int nogil) { PyObject *old_exc, *old_val, *old_tb; PyObject *ctx; __Pyx_PyThreadState_declare #ifdef WITH_THREAD PyGILState_STATE state; if (nogil) state = PyGILState_Ensure(); #ifdef _MSC_VER else state = (PyGILState_STATE)-1; #endif #endif __Pyx_PyThreadState_assign __Pyx_ErrFetch(&old_exc, &old_val, &old_tb); if (full_traceback) { Py_XINCREF(old_exc); Py_XINCREF(old_val); Py_XINCREF(old_tb); __Pyx_ErrRestore(old_exc, old_val, old_tb); PyErr_PrintEx(1); } #if PY_MAJOR_VERSION < 3 ctx = PyString_FromString(name); #else ctx = PyUnicode_FromString(name); #endif __Pyx_ErrRestore(old_exc, old_val, old_tb); if (!ctx) { PyErr_WriteUnraisable(Py_None); } else { PyErr_WriteUnraisable(ctx); Py_DECREF(ctx); } #ifdef WITH_THREAD if (nogil) PyGILState_Release(state); #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; } /* 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 = 0; PyObject *py_srcfile = 0; PyObject *py_funcname = 0; #if PY_MAJOR_VERSION < 3 py_srcfile = PyString_FromString(filename); #else py_srcfile = PyUnicode_FromString(filename); #endif if (!py_srcfile) goto bad; if (c_line) { #if PY_MAJOR_VERSION < 3 py_funcname = PyString_FromFormat( "%s (%s:%d)", funcname, __pyx_cfilenm, c_line); #else py_funcname = PyUnicode_FromFormat( "%s (%s:%d)", funcname, __pyx_cfilenm, c_line); #endif } else { #if PY_MAJOR_VERSION < 3 py_funcname = PyString_FromString(funcname); #else py_funcname = PyUnicode_FromString(funcname); #endif } if (!py_funcname) goto bad; 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); Py_DECREF(py_funcname); return py_code; bad: Py_XDECREF(py_srcfile); Py_XDECREF(py_funcname); 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; 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( PyThreadState_GET(), /*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 (PyObject_TypeCheck(obj, __pyx_ptype_5numpy_ndarray)) return __pyx_pw_5numpy_7ndarray_1__getbuffer__(obj, view, flags); if (PyObject_TypeCheck(obj, __pyx_array_type)) return __pyx_array_getbuffer(obj, view, flags); if (PyObject_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 (PyObject_TypeCheck(obj, __pyx_ptype_5numpy_ndarray)) { __pyx_pw_5numpy_7ndarray_3__releasebuffer__(obj, view); return; } Py_DECREF(obj); view->obj = NULL; } #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; } /* CIntToPy */ static CYTHON_INLINE PyObject* __Pyx_PyInt_From_long(long value) { const long neg_one = (long) -1, const_zero = (long) 0; 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); } } /* 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;\ } /* CIntToPy */ static CYTHON_INLINE PyObject* __Pyx_PyInt_From_int(int value) { const int neg_one = (int) -1, const_zero = (int) 0; 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); } } /* MemviewDtypeToObject */ static CYTHON_INLINE PyObject *__pyx_memview_get_float(const char *itemp) { return (PyObject *) PyFloat_FromDouble(*(float *) itemp); } static CYTHON_INLINE int __pyx_memview_set_float(const char *itemp, PyObject *obj) { float value = __pyx_PyFloat_AsFloat(obj); if ((value == (float)-1) && PyErr_Occurred()) return 0; *(float *) itemp = value; return 1; } /* Declarations */ #if CYTHON_CCOMPLEX #ifdef __cplusplus static CYTHON_INLINE __pyx_t_float_complex __pyx_t_float_complex_from_parts(float x, float y) { return ::std::complex< float >(x, y); } #else static CYTHON_INLINE __pyx_t_float_complex __pyx_t_float_complex_from_parts(float x, float y) { return x + y*(__pyx_t_float_complex)_Complex_I; } #endif #else static CYTHON_INLINE __pyx_t_float_complex __pyx_t_float_complex_from_parts(float x, float y) { __pyx_t_float_complex z; z.real = x; z.imag = y; return z; } #endif /* Arithmetic */ #if CYTHON_CCOMPLEX #else static CYTHON_INLINE int __Pyx_c_eq_float(__pyx_t_float_complex a, __pyx_t_float_complex b) { return (a.real == b.real) && (a.imag == b.imag); } static CYTHON_INLINE __pyx_t_float_complex __Pyx_c_sum_float(__pyx_t_float_complex a, __pyx_t_float_complex b) { __pyx_t_float_complex z; z.real = a.real + b.real; z.imag = a.imag + b.imag; return z; } static CYTHON_INLINE __pyx_t_float_complex __Pyx_c_diff_float(__pyx_t_float_complex a, __pyx_t_float_complex b) { __pyx_t_float_complex z; z.real = a.real - b.real; z.imag = a.imag - b.imag; return z; } static CYTHON_INLINE __pyx_t_float_complex __Pyx_c_prod_float(__pyx_t_float_complex a, __pyx_t_float_complex b) { __pyx_t_float_complex z; z.real = a.real * b.real - a.imag * b.imag; z.imag = a.real * b.imag + a.imag * b.real; return z; } #if 1 static CYTHON_INLINE __pyx_t_float_complex __Pyx_c_quot_float(__pyx_t_float_complex a, __pyx_t_float_complex b) { if (b.imag == 0) { return __pyx_t_float_complex_from_parts(a.real / b.real, a.imag / b.real); } else if (fabsf(b.real) >= fabsf(b.imag)) { if (b.real == 0 && b.imag == 0) { return __pyx_t_float_complex_from_parts(a.real / b.real, a.imag / b.imag); } else { float r = b.imag / b.real; float s = 1.0 / (b.real + b.imag * r); return __pyx_t_float_complex_from_parts( (a.real + a.imag * r) * s, (a.imag - a.real * r) * s); } } else { float r = b.real / b.imag; float s = 1.0 / (b.imag + b.real * r); return __pyx_t_float_complex_from_parts( (a.real * r + a.imag) * s, (a.imag * r - a.real) * s); } } #else static CYTHON_INLINE __pyx_t_float_complex __Pyx_c_quot_float(__pyx_t_float_complex a, __pyx_t_float_complex b) { if (b.imag == 0) { return __pyx_t_float_complex_from_parts(a.real / b.real, a.imag / b.real); } else { float denom = b.real * b.real + b.imag * b.imag; return __pyx_t_float_complex_from_parts( (a.real * b.real + a.imag * b.imag) / denom, (a.imag * b.real - a.real * b.imag) / denom); } } #endif static CYTHON_INLINE __pyx_t_float_complex __Pyx_c_neg_float(__pyx_t_float_complex a) { __pyx_t_float_complex z; z.real = -a.real; z.imag = -a.imag; return z; } static CYTHON_INLINE int __Pyx_c_is_zero_float(__pyx_t_float_complex a) { return (a.real == 0) && (a.imag == 0); } static CYTHON_INLINE __pyx_t_float_complex __Pyx_c_conj_float(__pyx_t_float_complex a) { __pyx_t_float_complex z; z.real = a.real; z.imag = -a.imag; return z; } #if 1 static CYTHON_INLINE float __Pyx_c_abs_float(__pyx_t_float_complex z) { #if !defined(HAVE_HYPOT) || defined(_MSC_VER) return sqrtf(z.real*z.real + z.imag*z.imag); #else return hypotf(z.real, z.imag); #endif } static CYTHON_INLINE __pyx_t_float_complex __Pyx_c_pow_float(__pyx_t_float_complex a, __pyx_t_float_complex b) { __pyx_t_float_complex z; float r, lnr, theta, z_r, z_theta; if (b.imag == 0 && b.real == (int)b.real) { if (b.real < 0) { float denom = a.real * a.real + a.imag * a.imag; a.real = a.real / denom; a.imag = -a.imag / denom; b.real = -b.real; } switch ((int)b.real) { case 0: z.real = 1; z.imag = 0; return z; case 1: return a; case 2: z = __Pyx_c_prod_float(a, a); return __Pyx_c_prod_float(a, a); case 3: z = __Pyx_c_prod_float(a, a); return __Pyx_c_prod_float(z, a); case 4: z = __Pyx_c_prod_float(a, a); return __Pyx_c_prod_float(z, z); } } if (a.imag == 0) { if (a.real == 0) { return a; } else if (b.imag == 0) { z.real = powf(a.real, b.real); z.imag = 0; return z; } else if (a.real > 0) { r = a.real; theta = 0; } else { r = -a.real; theta = atan2f(0, -1); } } else { r = __Pyx_c_abs_float(a); theta = atan2f(a.imag, a.real); } lnr = logf(r); z_r = expf(lnr * b.real - theta * b.imag); z_theta = theta * b.real + lnr * b.imag; z.real = z_r * cosf(z_theta); z.imag = z_r * sinf(z_theta); return z; } #endif #endif /* Declarations */ #if CYTHON_CCOMPLEX #ifdef __cplusplus static CYTHON_INLINE __pyx_t_double_complex __pyx_t_double_complex_from_parts(double x, double y) { return ::std::complex< double >(x, y); } #else static CYTHON_INLINE __pyx_t_double_complex __pyx_t_double_complex_from_parts(double x, double y) { return x + y*(__pyx_t_double_complex)_Complex_I; } #endif #else static CYTHON_INLINE __pyx_t_double_complex __pyx_t_double_complex_from_parts(double x, double y) { __pyx_t_double_complex z; z.real = x; z.imag = y; return z; } #endif /* Arithmetic */ #if CYTHON_CCOMPLEX #else static CYTHON_INLINE int __Pyx_c_eq_double(__pyx_t_double_complex a, __pyx_t_double_complex b) { return (a.real == b.real) && (a.imag == b.imag); } static CYTHON_INLINE __pyx_t_double_complex __Pyx_c_sum_double(__pyx_t_double_complex a, __pyx_t_double_complex b) { __pyx_t_double_complex z; z.real = a.real + b.real; z.imag = a.imag + b.imag; return z; } static CYTHON_INLINE __pyx_t_double_complex __Pyx_c_diff_double(__pyx_t_double_complex a, __pyx_t_double_complex b) { __pyx_t_double_complex z; z.real = a.real - b.real; z.imag = a.imag - b.imag; return z; } static CYTHON_INLINE __pyx_t_double_complex __Pyx_c_prod_double(__pyx_t_double_complex a, __pyx_t_double_complex b) { __pyx_t_double_complex z; z.real = a.real * b.real - a.imag * b.imag; z.imag = a.real * b.imag + a.imag * b.real; return z; } #if 1 static CYTHON_INLINE __pyx_t_double_complex __Pyx_c_quot_double(__pyx_t_double_complex a, __pyx_t_double_complex b) { if (b.imag == 0) { return __pyx_t_double_complex_from_parts(a.real / b.real, a.imag / b.real); } else if (fabs(b.real) >= fabs(b.imag)) { if (b.real == 0 && b.imag == 0) { return __pyx_t_double_complex_from_parts(a.real / b.real, a.imag / b.imag); } else { double r = b.imag / b.real; double s = 1.0 / (b.real + b.imag * r); return __pyx_t_double_complex_from_parts( (a.real + a.imag * r) * s, (a.imag - a.real * r) * s); } } else { double r = b.real / b.imag; double s = 1.0 / (b.imag + b.real * r); return __pyx_t_double_complex_from_parts( (a.real * r + a.imag) * s, (a.imag * r - a.real) * s); } } #else static CYTHON_INLINE __pyx_t_double_complex __Pyx_c_quot_double(__pyx_t_double_complex a, __pyx_t_double_complex b) { if (b.imag == 0) { return __pyx_t_double_complex_from_parts(a.real / b.real, a.imag / b.real); } else { double denom = b.real * b.real + b.imag * b.imag; return __pyx_t_double_complex_from_parts( (a.real * b.real + a.imag * b.imag) / denom, (a.imag * b.real - a.real * b.imag) / denom); } } #endif static CYTHON_INLINE __pyx_t_double_complex __Pyx_c_neg_double(__pyx_t_double_complex a) { __pyx_t_double_complex z; z.real = -a.real; z.imag = -a.imag; return z; } static CYTHON_INLINE int __Pyx_c_is_zero_double(__pyx_t_double_complex a) { return (a.real == 0) && (a.imag == 0); } static CYTHON_INLINE __pyx_t_double_complex __Pyx_c_conj_double(__pyx_t_double_complex a) { __pyx_t_double_complex z; z.real = a.real; z.imag = -a.imag; return z; } #if 1 static CYTHON_INLINE double __Pyx_c_abs_double(__pyx_t_double_complex z) { #if !defined(HAVE_HYPOT) || defined(_MSC_VER) return sqrt(z.real*z.real + z.imag*z.imag); #else return hypot(z.real, z.imag); #endif } static CYTHON_INLINE __pyx_t_double_complex __Pyx_c_pow_double(__pyx_t_double_complex a, __pyx_t_double_complex b) { __pyx_t_double_complex z; double r, lnr, theta, z_r, z_theta; if (b.imag == 0 && b.real == (int)b.real) { if (b.real < 0) { double denom = a.real * a.real + a.imag * a.imag; a.real = a.real / denom; a.imag = -a.imag / denom; b.real = -b.real; } switch ((int)b.real) { case 0: z.real = 1; z.imag = 0; return z; case 1: return a; case 2: z = __Pyx_c_prod_double(a, a); return __Pyx_c_prod_double(a, a); case 3: z = __Pyx_c_prod_double(a, a); return __Pyx_c_prod_double(z, a); case 4: z = __Pyx_c_prod_double(a, a); return __Pyx_c_prod_double(z, z); } } if (a.imag == 0) { if (a.real == 0) { return a; } else if (b.imag == 0) { z.real = pow(a.real, b.real); z.imag = 0; return z; } else if (a.real > 0) { r = a.real; theta = 0; } else { r = -a.real; theta = atan2(0, -1); } } else { r = __Pyx_c_abs_double(a); theta = atan2(a.imag, a.real); } lnr = log(r); z_r = exp(lnr * b.real - theta * b.imag); z_theta = theta * b.real + lnr * b.imag; z.real = z_r * cos(z_theta); z.imag = z_r * sin(z_theta); return z; } #endif #endif /* CIntToPy */ static CYTHON_INLINE PyObject* __Pyx_PyInt_From_enum__NPY_TYPES(enum NPY_TYPES value) { const enum NPY_TYPES neg_one = (enum NPY_TYPES) -1, const_zero = (enum NPY_TYPES) 0; const int is_unsigned = neg_one > const_zero; if (is_unsigned) { if (sizeof(enum NPY_TYPES) < sizeof(long)) { return PyInt_FromLong((long) value); } else if (sizeof(enum NPY_TYPES) <= sizeof(unsigned long)) { return PyLong_FromUnsignedLong((unsigned long) value); #ifdef HAVE_LONG_LONG } else if (sizeof(enum NPY_TYPES) <= sizeof(unsigned PY_LONG_LONG)) { return PyLong_FromUnsignedLongLong((unsigned PY_LONG_LONG) value); #endif } } else { if (sizeof(enum NPY_TYPES) <= sizeof(long)) { return PyInt_FromLong((long) value); #ifdef HAVE_LONG_LONG } else if (sizeof(enum NPY_TYPES) <= 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(enum NPY_TYPES), little, !is_unsigned); } } /* 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 (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 int __Pyx_PyInt_As_int(PyObject *x) { const int neg_one = (int) -1, const_zero = (int) 0; 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; } /* CIntFromPy */ static CYTHON_INLINE char __Pyx_PyInt_As_char(PyObject *x) { const char neg_one = (char) -1, const_zero = (char) 0; 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; } /* CIntFromPy */ static CYTHON_INLINE long __Pyx_PyInt_As_long(PyObject *x) { const long neg_one = (long) -1, const_zero = (long) 0; 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; } /* 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 (buf->strides[dim] != sizeof(void *)) { PyErr_Format(PyExc_ValueError, "Buffer is not indirectly contiguous " "in dimension %d.", dim); goto fail; } } else if (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 (stride < buf->itemsize) { PyErr_SetString(PyExc_ValueError, "Buffer and memoryview are not contiguous " "in the same dimension."); goto fail; } } } else { if (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 (spec & (__Pyx_MEMVIEW_PTR)) { PyErr_Format(PyExc_ValueError, "C-contiguous buffer is not indirect in " "dimension %d", dim); goto fail; } else if (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 (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 (!buf->suboffsets || (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 (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 (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 (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 (!__Pyx_BufFmt_CheckString(&ctx, buf->format)) goto fail; } if ((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; } for (i = 0; i < ndim; i++) { spec = axes_specs[i]; if (!__pyx_check_strides(buf, i, ndim, spec)) goto fail; if (!__pyx_check_suboffsets(buf, i, ndim, spec)) goto fail; } if (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_dsdsds_float(PyObject *obj) { __Pyx_memviewslice result = { 0, 0, { 0 }, { 0 }, { 0 } }; __Pyx_BufFmt_StackElem stack[1]; int axes_specs[] = { (__Pyx_MEMVIEW_DIRECT | __Pyx_MEMVIEW_STRIDED), (__Pyx_MEMVIEW_DIRECT | __Pyx_MEMVIEW_STRIDED), (__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, 3, &__Pyx_TypeInfo_float, 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_dsds_int(PyObject *obj) { __Pyx_memviewslice result = { 0, 0, { 0 }, { 0 }, { 0 } }; __Pyx_BufFmt_StackElem stack[1]; int axes_specs[] = { (__Pyx_MEMVIEW_DIRECT | __Pyx_MEMVIEW_STRIDED), (__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, 2, &__Pyx_TypeInfo_int, 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_dsds_float(PyObject *obj) { __Pyx_memviewslice result = { 0, 0, { 0 }, { 0 }, { 0 } }; __Pyx_BufFmt_StackElem stack[1]; int axes_specs[] = { (__Pyx_MEMVIEW_DIRECT | __Pyx_MEMVIEW_STRIDED), (__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, 2, &__Pyx_TypeInfo_float, stack, &result, obj); if (unlikely(retcode == -1)) goto __pyx_fail; return result; __pyx_fail: result.memview = NULL; result.data = NULL; return result; } /* 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; } /* ModuleImport */ #ifndef __PYX_HAVE_RT_ImportModule #define __PYX_HAVE_RT_ImportModule static PyObject *__Pyx_ImportModule(const char *name) { PyObject *py_name = 0; PyObject *py_module = 0; py_name = __Pyx_PyIdentifier_FromString(name); if (!py_name) goto bad; py_module = PyImport_Import(py_name); Py_DECREF(py_name); return py_module; bad: Py_XDECREF(py_name); return 0; } #endif /* TypeImport */ #ifndef __PYX_HAVE_RT_ImportType #define __PYX_HAVE_RT_ImportType static PyTypeObject *__Pyx_ImportType(const char *module_name, const char *class_name, size_t size, int strict) { PyObject *py_module = 0; PyObject *result = 0; PyObject *py_name = 0; char warning[200]; Py_ssize_t basicsize; #ifdef Py_LIMITED_API PyObject *py_basicsize; #endif py_module = __Pyx_ImportModule(module_name); if (!py_module) goto bad; py_name = __Pyx_PyIdentifier_FromString(class_name); if (!py_name) goto bad; result = PyObject_GetAttr(py_module, py_name); Py_DECREF(py_name); py_name = 0; Py_DECREF(py_module); py_module = 0; if (!result) goto bad; if (!PyType_Check(result)) { PyErr_Format(PyExc_TypeError, "%.200s.%.200s is not a type object", module_name, class_name); goto bad; } #ifndef Py_LIMITED_API basicsize = ((PyTypeObject *)result)->tp_basicsize; #else py_basicsize = PyObject_GetAttrString(result, "__basicsize__"); if (!py_basicsize) goto bad; basicsize = PyLong_AsSsize_t(py_basicsize); Py_DECREF(py_basicsize); py_basicsize = 0; if (basicsize == (Py_ssize_t)-1 && PyErr_Occurred()) goto bad; #endif if (!strict && (size_t)basicsize > size) { PyOS_snprintf(warning, sizeof(warning), "%s.%s size changed, may indicate binary incompatibility. Expected %zd, got %zd", module_name, class_name, basicsize, size); if (PyErr_WarnEx(NULL, warning, 0) < 0) goto bad; } else if ((size_t)basicsize != size) { PyErr_Format(PyExc_ValueError, "%.200s.%.200s has the wrong size, try recompiling. Expected %zd, got %zd", module_name, class_name, basicsize, size); goto bad; } return (PyTypeObject *)result; bad: Py_XDECREF(py_module); Py_XDECREF(result); return NULL; } #endif /* 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; ++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 char* __Pyx_PyObject_AsString(PyObject* o) { Py_ssize_t ignore; return __Pyx_PyObject_AsStringAndSize(o, &ignore); } static CYTHON_INLINE char* __Pyx_PyObject_AsStringAndSize(PyObject* o, Py_ssize_t *length) { #if CYTHON_COMPILING_IN_CPYTHON && (__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)) { #if PY_VERSION_HEX < 0x03030000 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 if (__Pyx_PyUnicode_READY(o) == -1) return NULL; #if __PYX_DEFAULT_STRING_ENCODING_IS_ASCII if (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 } 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 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 (PyInt_Check(x) || PyLong_Check(x)) #else if (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 = PyNumber_Int(x); } else if (m && m->nb_long) { name = "long"; res = PyNumber_Long(x); } #else if (m && m->nb_int) { name = "int"; res = PyNumber_Long(x); } #endif #else res = PyNumber_Int(x); #endif if (res) { #if PY_MAJOR_VERSION < 3 if (!PyInt_Check(res) && !PyLong_Check(res)) { #else if (!PyLong_Check(res)) { #endif PyErr_Format(PyExc_TypeError, "__%.4s__ returned non-%.4s (type %.200s)", name, name, Py_TYPE(res)->tp_name); Py_DECREF(res); return NULL; } } 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(x); } #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 PyObject * __Pyx_PyInt_FromSize_t(size_t ival) { return PyInt_FromSize_t(ival); } #endif /* Py_PYTHON_H */

DRB020-privatemissing-var-yes.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. */ /* tmp should be put as private to avoid race condition Data race pair: tmp@65 vs. tmp@66 */ #include <stdlib.h> #include <omp.h> int main(int argc,char *argv[]) { int i; int tmp; int len = 100; if (argc > 1) len = atoi(argv[1]); int a[len]; #pragma omp parallel for private (i) for (i = 0; i <= len - 1; i += 1) { a[i] = i; } #pragma omp parallel for private (tmp,i) for (i = 0; i <= len - 1; i += 1) { tmp = a[i] + i; a[i] = tmp; } for (i = 0; i <= len - 1; i += 1) { printf("%d\n",a[i]); } return 0; }

residualbased_block_builder_and_solver.h

// | / | // ' / __| _` | __| _ \ __| // . \ | ( | | ( |\__ ` // _|\_\_| \__,_|\__|\___/ ____/ // Multi-Physics // // License: BSD License // Kratos default license: kratos/license.txt // // Main authors: Riccardo Rossi // Collaborators: Vicente Mataix // // #if !defined(KRATOS_RESIDUAL_BASED_BLOCK_BUILDER_AND_SOLVER ) #define KRATOS_RESIDUAL_BASED_BLOCK_BUILDER_AND_SOLVER /* System includes */ #include <unordered_set> /* External includes */ /* Project includes */ #include "includes/define.h" #include "solving_strategies/builder_and_solvers/builder_and_solver.h" #include "includes/model_part.h" #include "includes/key_hash.h" #include "utilities/timer.h" #include "utilities/openmp_utils.h" #include "utilities/variable_utils.h" #include "includes/kratos_flags.h" #include "includes/lock_object.h" #include "utilities/sparse_matrix_multiplication_utility.h" namespace Kratos { ///@name Kratos Globals ///@{ ///@} ///@name Type Definitions ///@{ ///@} ///@name Enum's ///@{ ///@} ///@name Functions ///@{ ///@} ///@name Kratos Classes ///@{ /** * @class ResidualBasedEliminationBuilderAndSolver * @ingroup KratosCore * @brief Current class provides an implementation for standard builder and solving operations. * @details The RHS is constituted by the unbalanced loads (residual) * Degrees of freedom are reordered putting the restrained degrees of freedom at * the end of the system ordered in reverse order with respect to the DofSet. * Imposition of the dirichlet conditions is naturally dealt with as the residual already contains * this information. * Calculation of the reactions involves a cost very similiar to the calculation of the total residual * @tparam TSparseSpace The sparse system considered * @tparam TDenseSpace The dense system considered * @tparam TLinearSolver The linear solver considered * @author Riccardo Rossi */ template<class TSparseSpace, class TDenseSpace, //= DenseSpace<double>, class TLinearSolver //= LinearSolver<TSparseSpace,TDenseSpace> > class ResidualBasedBlockBuilderAndSolver : public BuilderAndSolver< TSparseSpace, TDenseSpace, TLinearSolver > { public: ///@name Type Definitions ///@{ /// Definition of the flags KRATOS_DEFINE_LOCAL_FLAG( SILENT_WARNINGS ); // Scaling enum enum class SCALING_DIAGONAL {NO_SCALING = 0, CONSIDER_NORM_DIAGONAL = 1, CONSIDER_MAX_DIAGONAL = 2, CONSIDER_PRESCRIBED_DIAGONAL = 3}; /// Definition of the pointer KRATOS_CLASS_POINTER_DEFINITION(ResidualBasedBlockBuilderAndSolver); /// Definition of the base class typedef BuilderAndSolver<TSparseSpace, TDenseSpace, TLinearSolver> BaseType; // The size_t types typedef std::size_t SizeType; typedef std::size_t IndexType; /// Definition of the classes from the base class typedef typename BaseType::TSchemeType TSchemeType; typedef typename BaseType::TDataType TDataType; typedef typename BaseType::DofsArrayType DofsArrayType; typedef typename BaseType::TSystemMatrixType TSystemMatrixType; typedef typename BaseType::TSystemVectorType TSystemVectorType; typedef typename BaseType::LocalSystemVectorType LocalSystemVectorType; typedef typename BaseType::LocalSystemMatrixType LocalSystemMatrixType; typedef typename BaseType::TSystemMatrixPointerType TSystemMatrixPointerType; typedef typename BaseType::TSystemVectorPointerType TSystemVectorPointerType; typedef typename BaseType::NodesArrayType NodesArrayType; typedef typename BaseType::ElementsArrayType ElementsArrayType; typedef typename BaseType::ConditionsArrayType ConditionsArrayType; /// Additional definitions typedef PointerVectorSet<Element, IndexedObject> ElementsContainerType; typedef Element::EquationIdVectorType EquationIdVectorType; typedef Element::DofsVectorType DofsVectorType; typedef boost::numeric::ublas::compressed_matrix<double> CompressedMatrixType; /// DoF types definition typedef Node<3> NodeType; typedef typename NodeType::DofType DofType; typedef typename DofType::Pointer DofPointerType; ///@} ///@name Life Cycle ///@{ /** * @brief Default constructor. (with parameters) */ explicit ResidualBasedBlockBuilderAndSolver( typename TLinearSolver::Pointer pNewLinearSystemSolver, Parameters ThisParameters ) : BaseType(pNewLinearSystemSolver) { // Validate default parameters Parameters default_parameters = Parameters(R"( { "name" : "ResidualBasedBlockBuilderAndSolver", "block_builder" : true, "diagonal_values_for_dirichlet_dofs" : "use_max_diagonal", "silent_warnings" : false })" ); ThisParameters.ValidateAndAssignDefaults(default_parameters); // Setting flags const std::string& r_diagonal_values_for_dirichlet_dofs = ThisParameters["diagonal_values_for_dirichlet_dofs"].GetString(); std::set<std::string> available_options_for_diagonal = {"no_scaling","use_max_diagonal","use_diagonal_norm","defined_in_process_info"}; if (available_options_for_diagonal.find(r_diagonal_values_for_dirichlet_dofs) == available_options_for_diagonal.end()) { std::stringstream msg; msg << "Currently prescribed diagonal values for dirichlet dofs : " << r_diagonal_values_for_dirichlet_dofs << "\n"; msg << "Admissible values for the diagonal scaling are : no_scaling, use_max_diagonal, use_diagonal_norm, or defined_in_process_info" << "\n"; KRATOS_ERROR << msg.str() << std::endl; } // The first option will not consider any scaling (the diagonal values will be replaced with 1) if (r_diagonal_values_for_dirichlet_dofs == "no_scaling") { mScalingDiagonal = SCALING_DIAGONAL::NO_SCALING; } else if (r_diagonal_values_for_dirichlet_dofs == "use_max_diagonal") { mScalingDiagonal = SCALING_DIAGONAL::CONSIDER_MAX_DIAGONAL; } else if (r_diagonal_values_for_dirichlet_dofs == "use_diagonal_norm") { // On this case the norm of the diagonal will be considered mScalingDiagonal = SCALING_DIAGONAL::CONSIDER_NORM_DIAGONAL; } else { // Otherwise we will assume we impose a numerical value mScalingDiagonal = SCALING_DIAGONAL::CONSIDER_PRESCRIBED_DIAGONAL; } mOptions.Set(SILENT_WARNINGS, ThisParameters["silent_warnings"].GetBool()); } /** * @brief Default constructor. */ explicit ResidualBasedBlockBuilderAndSolver(typename TLinearSolver::Pointer pNewLinearSystemSolver) : BaseType(pNewLinearSystemSolver) { mScalingDiagonal = SCALING_DIAGONAL::NO_SCALING; } /** Destructor. */ ~ResidualBasedBlockBuilderAndSolver() override { } ///@} ///@name Operators ///@{ ///@} ///@name Operations ///@{ /** * @brief Function to perform the build of the RHS. The vector could be sized as the total number * of dofs or as the number of unrestrained ones * @param pScheme The integration scheme considered * @param rModelPart The model part of the problem to solve * @param A The LHS matrix * @param b The RHS vector */ void Build( typename TSchemeType::Pointer pScheme, ModelPart& rModelPart, TSystemMatrixType& A, TSystemVectorType& b) override { KRATOS_TRY KRATOS_ERROR_IF(!pScheme) << "No scheme provided!" << std::endl; // Getting the elements from the model const int nelements = static_cast<int>(rModelPart.Elements().size()); // Getting the array of the conditions const int nconditions = static_cast<int>(rModelPart.Conditions().size()); const ProcessInfo& CurrentProcessInfo = rModelPart.GetProcessInfo(); ModelPart::ElementsContainerType::iterator el_begin = rModelPart.ElementsBegin(); ModelPart::ConditionsContainerType::iterator cond_begin = rModelPart.ConditionsBegin(); //contributions to the system LocalSystemMatrixType LHS_Contribution = LocalSystemMatrixType(0, 0); LocalSystemVectorType RHS_Contribution = LocalSystemVectorType(0); //vector containing the localization in the system of the different //terms Element::EquationIdVectorType EquationId; // assemble all elements double start_build = OpenMPUtils::GetCurrentTime(); #pragma omp parallel firstprivate(nelements,nconditions, LHS_Contribution, RHS_Contribution, EquationId ) { # pragma omp for schedule(guided, 512) nowait for (int k = 0; k < nelements; k++) { ModelPart::ElementsContainerType::iterator it = el_begin + k; //detect if the element is active or not. If the user did not make any choice the element //is active by default bool element_is_active = true; if ((it)->IsDefined(ACTIVE)) element_is_active = (it)->Is(ACTIVE); if (element_is_active) { //calculate elemental contribution pScheme->CalculateSystemContributions(*it, LHS_Contribution, RHS_Contribution, EquationId, CurrentProcessInfo); //assemble the elemental contribution Assemble(A, b, LHS_Contribution, RHS_Contribution, EquationId); // clean local elemental memory pScheme->CleanMemory(*it); } } #pragma omp for schedule(guided, 512) for (int k = 0; k < nconditions; k++) { ModelPart::ConditionsContainerType::iterator it = cond_begin + k; //detect if the element is active or not. If the user did not make any choice the element //is active by default bool condition_is_active = true; if ((it)->IsDefined(ACTIVE)) condition_is_active = (it)->Is(ACTIVE); if (condition_is_active) { //calculate elemental contribution pScheme->CalculateSystemContributions(*it, LHS_Contribution, RHS_Contribution, EquationId, CurrentProcessInfo); //assemble the elemental contribution Assemble(A, b, LHS_Contribution, RHS_Contribution, EquationId); // clean local elemental memory pScheme->CleanMemory(*it); } } } const double stop_build = OpenMPUtils::GetCurrentTime(); KRATOS_INFO_IF("ResidualBasedBlockBuilderAndSolver", (this->GetEchoLevel() >= 1 && rModelPart.GetCommunicator().MyPID() == 0)) << "Build time: " << stop_build - start_build << std::endl; KRATOS_INFO_IF("ResidualBasedBlockBuilderAndSolver", (this->GetEchoLevel() > 2 && rModelPart.GetCommunicator().MyPID() == 0)) << "Finished parallel building" << std::endl; KRATOS_CATCH("") } /** * @brief Function to perform the building of the LHS * @details Depending on the implementation choosen the size of the matrix could * be equal to the total number of Dofs or to the number of unrestrained dofs * @param pScheme The integration scheme considered * @param rModelPart The model part of the problem to solve * @param A The LHS matrix */ void BuildLHS( typename TSchemeType::Pointer pScheme, ModelPart& rModelPart, TSystemMatrixType& rA ) override { KRATOS_TRY KRATOS_ERROR_IF(!pScheme) << "No scheme provided!" << std::endl; // Getting the elements from the model const int nelements = static_cast<int>(rModelPart.Elements().size()); // Getting the array of the conditions const int nconditions = static_cast<int>(rModelPart.Conditions().size()); const ProcessInfo& r_current_process_info = rModelPart.GetProcessInfo(); const auto it_elem_begin = rModelPart.ElementsBegin(); const auto it_cond_begin = rModelPart.ConditionsBegin(); // Contributions to the system LocalSystemMatrixType lhs_contribution(0, 0); // Vector containing the localization in the system of the different terms Element::EquationIdVectorType equation_id; // Assemble all elements double start_build = OpenMPUtils::GetCurrentTime(); #pragma omp parallel firstprivate(nelements, nconditions, lhs_contribution, equation_id ) { # pragma omp for schedule(guided, 512) nowait for (int k = 0; k < nelements; ++k) { auto it_elem = it_elem_begin + k; // Detect if the element is active or not. If the user did not make any choice the element is active by default bool element_is_active = true; if (it_elem->IsDefined(ACTIVE)) element_is_active = it_elem->Is(ACTIVE); if (element_is_active) { // Calculate elemental contribution pScheme->CalculateLHSContribution(*it_elem, lhs_contribution, equation_id, r_current_process_info); // Assemble the elemental contribution AssembleLHS(rA, lhs_contribution, equation_id); // Clean local elemental memory pScheme->CleanMemory(*it_elem); } } #pragma omp for schedule(guided, 512) for (int k = 0; k < nconditions; ++k) { auto it_cond = it_cond_begin + k; // Detect if the element is active or not. If the user did not make any choice the element is active by default bool condition_is_active = true; if (it_cond->IsDefined(ACTIVE)) condition_is_active = it_cond->Is(ACTIVE); if (condition_is_active) { // Calculate elemental contribution pScheme->CalculateLHSContribution(*it_cond, lhs_contribution, equation_id, r_current_process_info); // Assemble the elemental contribution AssembleLHS(rA, lhs_contribution, equation_id); // Clean local elemental memory pScheme->CleanMemory(*it_cond); } } } const double stop_build = OpenMPUtils::GetCurrentTime(); KRATOS_INFO_IF("ResidualBasedBlockBuilderAndSolver", this->GetEchoLevel() >= 1) << "Build time LHS: " << stop_build - start_build << std::endl; KRATOS_INFO_IF("ResidualBasedBlockBuilderAndSolver", this->GetEchoLevel() > 2) << "Finished parallel building LHS" << std::endl; KRATOS_CATCH("") } /** * @brief Build a rectangular matrix of size n*N where "n" is the number of unrestrained degrees of freedom * and "N" is the total number of degrees of freedom involved. * @details This matrix is obtained by building the total matrix without the lines corresponding to the fixed * degrees of freedom (but keeping the columns!!) * @param pScheme The integration scheme considered * @param rModelPart The model part of the problem to solve * @param A The LHS matrix */ void BuildLHS_CompleteOnFreeRows( typename TSchemeType::Pointer pScheme, ModelPart& rModelPart, TSystemMatrixType& A) override { KRATOS_TRY TSystemVectorType tmp(A.size1(), 0.0); this->Build(pScheme, rModelPart, A, tmp); KRATOS_CATCH("") } /** * @brief This is a call to the linear system solver * @param A The LHS matrix * @param Dx The Unknowns vector * @param b The RHS vector */ void SystemSolve( TSystemMatrixType& A, TSystemVectorType& Dx, TSystemVectorType& b ) override { KRATOS_TRY double norm_b; if (TSparseSpace::Size(b) != 0) norm_b = TSparseSpace::TwoNorm(b); else norm_b = 0.00; if (norm_b != 0.00) { //do solve BaseType::mpLinearSystemSolver->Solve(A, Dx, b); } else TSparseSpace::SetToZero(Dx); if(mT.size1() != 0) //if there are master-slave constraints { //recover solution of the original problem TSystemVectorType Dxmodified = Dx; TSparseSpace::Mult(mT, Dxmodified, Dx); } //prints informations about the current time KRATOS_INFO_IF("ResidualBasedBlockBuilderAndSolver", this->GetEchoLevel() > 1) << *(BaseType::mpLinearSystemSolver) << std::endl; KRATOS_CATCH("") } /** * @brief This is a call to the linear system solver (taking into account some physical particularities of the problem) * @param rA The LHS matrix * @param rDx The Unknowns vector * @param rb The RHS vector * @param rModelPart The model part of the problem to solve */ virtual void SystemSolveWithPhysics( TSystemMatrixType& rA, TSystemVectorType& rDx, TSystemVectorType& rb, ModelPart& rModelPart ) { if(rModelPart.MasterSlaveConstraints().size() != 0) { TSystemVectorType Dxmodified(rb.size()); InternalSystemSolveWithPhysics(rA, Dxmodified, rb, rModelPart); //recover solution of the original problem TSparseSpace::Mult(mT, Dxmodified, rDx); } else { InternalSystemSolveWithPhysics(rA, rDx, rb, rModelPart); } } /** *@brief This is a call to the linear system solver (taking into account some physical particularities of the problem) * @param A The LHS matrix * @param Dx The Unknowns vector * @param b The RHS vector * @param rModelPart The model part of the problem to solve */ void InternalSystemSolveWithPhysics( TSystemMatrixType& A, TSystemVectorType& Dx, TSystemVectorType& b, ModelPart& rModelPart ) { KRATOS_TRY double norm_b; if (TSparseSpace::Size(b) != 0) norm_b = TSparseSpace::TwoNorm(b); else norm_b = 0.00; if (norm_b != 0.00) { //provide physical data as needed if(BaseType::mpLinearSystemSolver->AdditionalPhysicalDataIsNeeded() ) BaseType::mpLinearSystemSolver->ProvideAdditionalData(A, Dx, b, BaseType::mDofSet, rModelPart); //do solve BaseType::mpLinearSystemSolver->Solve(A, Dx, b); } else { TSparseSpace::SetToZero(Dx); KRATOS_WARNING_IF("ResidualBasedBlockBuilderAndSolver", mOptions.IsNot(SILENT_WARNINGS)) << "ATTENTION! setting the RHS to zero!" << std::endl; } // Prints informations about the current time KRATOS_INFO_IF("ResidualBasedBlockBuilderAndSolver", this->GetEchoLevel() > 1) << *(BaseType::mpLinearSystemSolver) << std::endl; KRATOS_CATCH("") } /** * @brief Function to perform the building and solving phase at the same time. * @details It is ideally the fastest and safer function to use when it is possible to solve * just after building * @param pScheme The integration scheme considered * @param rModelPart The model part of the problem to solve * @param A The LHS matrix * @param Dx The Unknowns vector * @param b The RHS vector */ void BuildAndSolve( typename TSchemeType::Pointer pScheme, ModelPart& rModelPart, TSystemMatrixType& A, TSystemVectorType& Dx, TSystemVectorType& b) override { KRATOS_TRY Timer::Start("Build"); Build(pScheme, rModelPart, A, b); Timer::Stop("Build"); if(rModelPart.MasterSlaveConstraints().size() != 0) { Timer::Start("ApplyConstraints"); ApplyConstraints(pScheme, rModelPart, A, b); Timer::Stop("ApplyConstraints"); } ApplyDirichletConditions(pScheme, rModelPart, A, Dx, b); KRATOS_INFO_IF("ResidualBasedBlockBuilderAndSolver", ( this->GetEchoLevel() == 3)) << "Before the solution of the system" << "\nSystem Matrix = " << A << "\nUnknowns vector = " << Dx << "\nRHS vector = " << b << std::endl; const double start_solve = OpenMPUtils::GetCurrentTime(); Timer::Start("Solve"); SystemSolveWithPhysics(A, Dx, b, rModelPart); Timer::Stop("Solve"); const double stop_solve = OpenMPUtils::GetCurrentTime(); KRATOS_INFO_IF("ResidualBasedBlockBuilderAndSolver", (this->GetEchoLevel() >=1 && rModelPart.GetCommunicator().MyPID() == 0)) << "System solve time: " << stop_solve - start_solve << std::endl; KRATOS_INFO_IF("ResidualBasedBlockBuilderAndSolver", ( this->GetEchoLevel() == 3)) << "After the solution of the system" << "\nSystem Matrix = " << A << "\nUnknowns vector = " << Dx << "\nRHS vector = " << b << std::endl; KRATOS_CATCH("") } /** * @brief Function to perform the building and solving phase at the same time Linearizing with the database at the old iteration * @details It is ideally the fastest and safer function to use when it is possible to solve just after building * @param pScheme The pointer to the integration scheme * @param rModelPart The model part to compute * @param rA The LHS matrix of the system of equations * @param rDx The vector of unkowns * @param rb The RHS vector of the system of equations * @param MoveMesh tells if the update of the scheme needs to be performed when calling the Update of the scheme */ void BuildAndSolveLinearizedOnPreviousIteration( typename TSchemeType::Pointer pScheme, ModelPart& rModelPart, TSystemMatrixType& rA, TSystemVectorType& rDx, TSystemVectorType& rb, const bool MoveMesh ) override { KRATOS_INFO_IF("BlockBuilderAndSolver", this->GetEchoLevel() > 0) << "Linearizing on Old iteration" << std::endl; KRATOS_ERROR_IF(rModelPart.GetBufferSize() == 1) << "BlockBuilderAndSolver: \n" << "The buffer size needs to be at least 2 in order to use \n" << "BuildAndSolveLinearizedOnPreviousIteration \n" << "current buffer size for modelpart: " << rModelPart.Name() << std::endl << "is :" << rModelPart.GetBufferSize() << " Please set IN THE STRATEGY SETTINGS " << " UseOldStiffnessInFirstIteration=false " << std::endl; DofsArrayType fixed_dofs; for(auto& r_dof : BaseType::mDofSet){ if(r_dof.IsFixed()){ fixed_dofs.push_back(&r_dof); r_dof.FreeDof(); } } //TODO: Here we need to take the vector from other ones because // We cannot create a trilinos vector without a communicator. To be improved! TSystemVectorType dx_prediction(rDx); TSystemVectorType rhs_addition(rb); //we know it is zero here, so we do not need to set it // Here we bring back the database to before the prediction, // but we store the prediction increment in dx_prediction. // The goal is that the stiffness is computed with the // converged configuration at the end of the previous step. const auto it_dof_begin = BaseType::mDofSet.begin(); #pragma omp parallel for for (int i = 0; i < static_cast<int>(BaseType::mDofSet.size()); ++i) { auto it_dof = it_dof_begin + i; //NOTE: this is initialzed to - the value of dx prediction dx_prediction[it_dof->EquationId()] = -(it_dof->GetSolutionStepValue() - it_dof->GetSolutionStepValue(1)); } // Use UpdateDatabase to bring back the solution to how it was at the end of the previous step pScheme->Update(rModelPart, BaseType::mDofSet, rA, dx_prediction, rb); if (MoveMesh) { VariableUtils().UpdateCurrentPosition(rModelPart.Nodes(),DISPLACEMENT,0); } this->Build(pScheme, rModelPart, rA, rb); // Put back the prediction into the database TSparseSpace::InplaceMult(dx_prediction, -1.0); //change sign to dx_prediction TSparseSpace::UnaliasedAdd(rDx, 1.0, dx_prediction); // Use UpdateDatabase to bring back the solution // to where it was taking into account BCs // it is done here so that constraints are correctly taken into account right after pScheme->Update(rModelPart, BaseType::mDofSet, rA, dx_prediction, rb); if (MoveMesh) { VariableUtils().UpdateCurrentPosition(rModelPart.Nodes(),DISPLACEMENT,0); } // Apply rb -= A*dx_prediction TSparseSpace::Mult(rA, dx_prediction, rhs_addition); TSparseSpace::UnaliasedAdd(rb, -1.0, rhs_addition); for(auto& dof : fixed_dofs) dof.FixDof(); if (!rModelPart.MasterSlaveConstraints().empty()) { this->ApplyConstraints(pScheme, rModelPart, rA, rb); } this->ApplyDirichletConditions(pScheme, rModelPart, rA, rDx, rb); this->SystemSolveWithPhysics(rA, rDx, rb, rModelPart); } /** * @brief Corresponds to the previews, but the System's matrix is considered already built and only the RHS is built again * @param pScheme The integration scheme considered * @param rModelPart The model part of the problem to solve * @param rA The LHS matrix * @param rDx The Unknowns vector * @param rb The RHS vector */ void BuildRHSAndSolve( typename TSchemeType::Pointer pScheme, ModelPart& rModelPart, TSystemMatrixType& rA, TSystemVectorType& rDx, TSystemVectorType& rb ) override { KRATOS_TRY Timer::Start("BuildRHS"); BuildRHS(pScheme, rModelPart, rb); Timer::Stop("BuildRHS"); if(rModelPart.MasterSlaveConstraints().size() != 0) { Timer::Start("ApplyRHSConstraints"); ApplyRHSConstraints(pScheme, rModelPart, rb); Timer::Stop("ApplyRHSConstraints"); } ApplyDirichletConditions(pScheme, rModelPart, rA, rDx, rb); KRATOS_INFO_IF("ResidualBasedBlockBuilderAndSolver", ( this->GetEchoLevel() == 3)) << "Before the solution of the system" << "\nSystem Matrix = " << rA << "\nUnknowns vector = " << rDx << "\nRHS vector = " << rb << std::endl; const double start_solve = OpenMPUtils::GetCurrentTime(); Timer::Start("Solve"); SystemSolveWithPhysics(rA, rDx, rb, rModelPart); Timer::Stop("Solve"); const double stop_solve = OpenMPUtils::GetCurrentTime(); KRATOS_INFO_IF("ResidualBasedBlockBuilderAndSolver", (this->GetEchoLevel() >=1 && rModelPart.GetCommunicator().MyPID() == 0)) << "System solve time: " << stop_solve - start_solve << std::endl; KRATOS_INFO_IF("ResidualBasedBlockBuilderAndSolver", ( this->GetEchoLevel() == 3)) << "After the solution of the system" << "\nSystem Matrix = " << rA << "\nUnknowns vector = " << rDx << "\nRHS vector = " << rb << std::endl; KRATOS_CATCH("") } /** * @brief Function to perform the build of the RHS. * @details The vector could be sized as the total number of dofs or as the number of unrestrained ones * @param pScheme The integration scheme considered * @param rModelPart The model part of the problem to solve */ void BuildRHS( typename TSchemeType::Pointer pScheme, ModelPart& rModelPart, TSystemVectorType& b) override { KRATOS_TRY BuildRHSNoDirichlet(pScheme,rModelPart,b); const int ndofs = static_cast<int>(BaseType::mDofSet.size()); //NOTE: dofs are assumed to be numbered consecutively in the BlockBuilderAndSolver #pragma omp parallel for firstprivate(ndofs) for (int k = 0; k<ndofs; k++) { typename DofsArrayType::iterator dof_iterator = BaseType::mDofSet.begin() + k; const std::size_t i = dof_iterator->EquationId(); if (dof_iterator->IsFixed()) b[i] = 0.0; } KRATOS_CATCH("") } /** * @brief Builds the list of the DofSets involved in the problem by "asking" to each element * and condition its Dofs. * @details The list of dofs is stores insde the BuilderAndSolver as it is closely connected to the * way the matrix and RHS are built * @param pScheme The integration scheme considered * @param rModelPart The model part of the problem to solve */ void SetUpDofSet( typename TSchemeType::Pointer pScheme, ModelPart& rModelPart ) override { KRATOS_TRY; KRATOS_INFO_IF("ResidualBasedBlockBuilderAndSolver", ( this->GetEchoLevel() > 1 && rModelPart.GetCommunicator().MyPID() == 0)) << "Setting up the dofs" << std::endl; //Gets the array of elements from the modeler ElementsArrayType& r_elements_array = rModelPart.Elements(); const int number_of_elements = static_cast<int>(r_elements_array.size()); DofsVectorType dof_list, second_dof_list; // NOTE: The second dof list is only used on constraints to include master/slave relations unsigned int nthreads = OpenMPUtils::GetNumThreads(); typedef std::unordered_set < NodeType::DofType::Pointer, DofPointerHasher> set_type; KRATOS_INFO_IF("ResidualBasedBlockBuilderAndSolver", ( this->GetEchoLevel() > 2)) << "Number of threads" << nthreads << "\n" << std::endl; KRATOS_INFO_IF("ResidualBasedBlockBuilderAndSolver", ( this->GetEchoLevel() > 2)) << "Initializing element loop" << std::endl; /** * Here we declare three sets. * - The global set: Contains all the DoF of the system * - The slave set: The DoF that are not going to be solved, due to MPC formulation */ set_type dof_global_set; dof_global_set.reserve(number_of_elements*20); #pragma omp parallel firstprivate(dof_list, second_dof_list) { const ProcessInfo& r_current_process_info = rModelPart.GetProcessInfo(); // We cleate the temporal set and we reserve some space on them set_type dofs_tmp_set; dofs_tmp_set.reserve(20000); // Gets the array of elements from the modeler #pragma omp for schedule(guided, 512) nowait for (int i = 0; i < number_of_elements; ++i) { auto it_elem = r_elements_array.begin() + i; // Gets list of Dof involved on every element pScheme->GetDofList(*it_elem, dof_list, r_current_process_info); dofs_tmp_set.insert(dof_list.begin(), dof_list.end()); } // Gets the array of conditions from the modeler ConditionsArrayType& r_conditions_array = rModelPart.Conditions(); const int number_of_conditions = static_cast<int>(r_conditions_array.size()); #pragma omp for schedule(guided, 512) nowait for (int i = 0; i < number_of_conditions; ++i) { auto it_cond = r_conditions_array.begin() + i; // Gets list of Dof involved on every element pScheme->GetDofList(*it_cond, dof_list, r_current_process_info); dofs_tmp_set.insert(dof_list.begin(), dof_list.end()); } // Gets the array of constraints from the modeler auto& r_constraints_array = rModelPart.MasterSlaveConstraints(); const int number_of_constraints = static_cast<int>(r_constraints_array.size()); #pragma omp for schedule(guided, 512) nowait for (int i = 0; i < number_of_constraints; ++i) { auto it_const = r_constraints_array.begin() + i; // Gets list of Dof involved on every element it_const->GetDofList(dof_list, second_dof_list, r_current_process_info); dofs_tmp_set.insert(dof_list.begin(), dof_list.end()); dofs_tmp_set.insert(second_dof_list.begin(), second_dof_list.end()); } // We merge all the sets in one thread #pragma omp critical { dof_global_set.insert(dofs_tmp_set.begin(), dofs_tmp_set.end()); } } KRATOS_INFO_IF("ResidualBasedBlockBuilderAndSolver", ( this->GetEchoLevel() > 2)) << "Initializing ordered array filling\n" << std::endl; DofsArrayType Doftemp; BaseType::mDofSet = DofsArrayType(); Doftemp.reserve(dof_global_set.size()); for (auto it= dof_global_set.begin(); it!= dof_global_set.end(); it++) { Doftemp.push_back( *it ); } Doftemp.Sort(); BaseType::mDofSet = Doftemp; //Throws an exception if there are no Degrees Of Freedom involved in the analysis KRATOS_ERROR_IF(BaseType::mDofSet.size() == 0) << "No degrees of freedom!" << std::endl; KRATOS_INFO_IF("ResidualBasedBlockBuilderAndSolver", ( this->GetEchoLevel() > 2)) << "Number of degrees of freedom:" << BaseType::mDofSet.size() << std::endl; BaseType::mDofSetIsInitialized = true; KRATOS_INFO_IF("ResidualBasedBlockBuilderAndSolver", ( this->GetEchoLevel() > 2 && rModelPart.GetCommunicator().MyPID() == 0)) << "Finished setting up the dofs" << std::endl; #ifdef KRATOS_DEBUG // If reactions are to be calculated, we check if all the dofs have reactions defined // This is tobe done only in debug mode if (BaseType::GetCalculateReactionsFlag()) { for (auto dof_iterator = BaseType::mDofSet.begin(); dof_iterator != BaseType::mDofSet.end(); ++dof_iterator) { KRATOS_ERROR_IF_NOT(dof_iterator->HasReaction()) << "Reaction variable not set for the following : " <<std::endl << "Node : "<<dof_iterator->Id()<< std::endl << "Dof : "<<(*dof_iterator)<<std::endl<<"Not possible to calculate reactions."<<std::endl; } } #endif KRATOS_CATCH(""); } /** * @brief Organises the dofset in order to speed up the building phase * @param rModelPart The model part of the problem to solve */ void SetUpSystem( ModelPart& rModelPart ) override { //int free_id = 0; BaseType::mEquationSystemSize = BaseType::mDofSet.size(); int ndofs = static_cast<int>(BaseType::mDofSet.size()); #pragma omp parallel for firstprivate(ndofs) for (int i = 0; i < static_cast<int>(ndofs); i++) { typename DofsArrayType::iterator dof_iterator = BaseType::mDofSet.begin() + i; dof_iterator->SetEquationId(i); } } //************************************************************************** //************************************************************************** void ResizeAndInitializeVectors( typename TSchemeType::Pointer pScheme, TSystemMatrixPointerType& pA, TSystemVectorPointerType& pDx, TSystemVectorPointerType& pb, ModelPart& rModelPart ) override { KRATOS_TRY if (pA == NULL) //if the pointer is not initialized initialize it to an empty matrix { TSystemMatrixPointerType pNewA = TSystemMatrixPointerType(new TSystemMatrixType(0, 0)); pA.swap(pNewA); } if (pDx == NULL) //if the pointer is not initialized initialize it to an empty matrix { TSystemVectorPointerType pNewDx = TSystemVectorPointerType(new TSystemVectorType(0)); pDx.swap(pNewDx); } if (pb == NULL) //if the pointer is not initialized initialize it to an empty matrix { TSystemVectorPointerType pNewb = TSystemVectorPointerType(new TSystemVectorType(0)); pb.swap(pNewb); } TSystemMatrixType& A = *pA; TSystemVectorType& Dx = *pDx; TSystemVectorType& b = *pb; //resizing the system vectors and matrix if (A.size1() == 0 || BaseType::GetReshapeMatrixFlag() == true) //if the matrix is not initialized { A.resize(BaseType::mEquationSystemSize, BaseType::mEquationSystemSize, false); ConstructMatrixStructure(pScheme, A, rModelPart); } else { if (A.size1() != BaseType::mEquationSystemSize || A.size2() != BaseType::mEquationSystemSize) { KRATOS_ERROR <<"The equation system size has changed during the simulation. This is not permited."<<std::endl; A.resize(BaseType::mEquationSystemSize, BaseType::mEquationSystemSize, true); ConstructMatrixStructure(pScheme, A, rModelPart); } } if (Dx.size() != BaseType::mEquationSystemSize) Dx.resize(BaseType::mEquationSystemSize, false); TSparseSpace::SetToZero(Dx); if (b.size() != BaseType::mEquationSystemSize) { b.resize(BaseType::mEquationSystemSize, false); } TSparseSpace::SetToZero(b); ConstructMasterSlaveConstraintsStructure(rModelPart); KRATOS_CATCH("") } //************************************************************************** //************************************************************************** void InitializeSolutionStep( ModelPart& rModelPart, TSystemMatrixType& rA, TSystemVectorType& rDx, TSystemVectorType& rb) override { KRATOS_TRY BaseType::InitializeSolutionStep(rModelPart, rA, rDx, rb); // Getting process info const ProcessInfo& r_process_info = rModelPart.GetProcessInfo(); // Computing constraints const int n_constraints = static_cast<int>(rModelPart.MasterSlaveConstraints().size()); auto constraints_begin = rModelPart.MasterSlaveConstraintsBegin(); #pragma omp parallel for schedule(guided, 512) firstprivate(n_constraints, constraints_begin) for (int k = 0; k < n_constraints; ++k) { auto it = constraints_begin + k; it->InitializeSolutionStep(r_process_info); // Here each constraint constructs and stores its T and C matrices. Also its equation slave_ids. } KRATOS_CATCH("") } //************************************************************************** //************************************************************************** void FinalizeSolutionStep( ModelPart& rModelPart, TSystemMatrixType& rA, TSystemVectorType& rDx, TSystemVectorType& rb) override { BaseType::FinalizeSolutionStep(rModelPart, rA, rDx, rb); // Getting process info const ProcessInfo& r_process_info = rModelPart.GetProcessInfo(); // Computing constraints const int n_constraints = static_cast<int>(rModelPart.MasterSlaveConstraints().size()); const auto constraints_begin = rModelPart.MasterSlaveConstraintsBegin(); #pragma omp parallel for schedule(guided, 512) firstprivate(n_constraints, constraints_begin) for (int k = 0; k < n_constraints; ++k) { auto it = constraints_begin + k; it->FinalizeSolutionStep(r_process_info); } } //************************************************************************** //************************************************************************** void CalculateReactions( typename TSchemeType::Pointer pScheme, ModelPart& rModelPart, TSystemMatrixType& A, TSystemVectorType& Dx, TSystemVectorType& b) override { TSparseSpace::SetToZero(b); //refresh RHS to have the correct reactions BuildRHSNoDirichlet(pScheme, rModelPart, b); const int ndofs = static_cast<int>(BaseType::mDofSet.size()); //NOTE: dofs are assumed to be numbered consecutively in the BlockBuilderAndSolver #pragma omp parallel for firstprivate(ndofs) for (int k = 0; k<ndofs; k++) { typename DofsArrayType::iterator dof_iterator = BaseType::mDofSet.begin() + k; const int i = (dof_iterator)->EquationId(); (dof_iterator)->GetSolutionStepReactionValue() = -b[i]; } } /** * @brief Applies the dirichlet conditions. This operation may be very heavy or completely * unexpensive depending on the implementation choosen and on how the System Matrix is built. * @details For explanation of how it works for a particular implementation the user * should refer to the particular Builder And Solver choosen * @param pScheme The integration scheme considered * @param rModelPart The model part of the problem to solve * @param rA The LHS matrix * @param rDx The Unknowns vector * @param rb The RHS vector */ void ApplyDirichletConditions( typename TSchemeType::Pointer pScheme, ModelPart& rModelPart, TSystemMatrixType& rA, TSystemVectorType& rDx, TSystemVectorType& rb ) override { const std::size_t system_size = rA.size1(); Vector scaling_factors (system_size); const auto it_dof_iterator_begin = BaseType::mDofSet.begin(); const int ndofs = static_cast<int>(BaseType::mDofSet.size()); // NOTE: dofs are assumed to be numbered consecutively in the BlockBuilderAndSolver #pragma omp parallel for firstprivate(ndofs) for (int k = 0; k<ndofs; k++) { auto it_dof_iterator = it_dof_iterator_begin + k; if (it_dof_iterator->IsFixed()) { scaling_factors[k] = 0.0; } else { scaling_factors[k] = 1.0; } } double* Avalues = rA.value_data().begin(); std::size_t* Arow_indices = rA.index1_data().begin(); std::size_t* Acol_indices = rA.index2_data().begin(); // The diagonal considered mScaleFactor = GetScaleNorm(rModelPart, rA); // Detect if there is a line of all zeros and set the diagonal to a 1 if this happens #pragma omp parallel firstprivate(system_size) { std::size_t col_begin = 0, col_end = 0; bool empty = true; #pragma omp for for (int k = 0; k < static_cast<int>(system_size); ++k) { col_begin = Arow_indices[k]; col_end = Arow_indices[k + 1]; empty = true; for (std::size_t j = col_begin; j < col_end; ++j) { if(Avalues[j] != 0.0) { empty = false; break; } } if(empty) { rA(k, k) = mScaleFactor; rb[k] = 0.0; } } } #pragma omp parallel for firstprivate(system_size) for (int k = 0; k < static_cast<int>(system_size); ++k) { std::size_t col_begin = Arow_indices[k]; std::size_t col_end = Arow_indices[k+1]; const double k_factor = scaling_factors[k]; if (k_factor == 0.0) { // Zero out the whole row, except the diagonal for (std::size_t j = col_begin; j < col_end; ++j) if (static_cast<int>(Acol_indices[j]) != k ) Avalues[j] = 0.0; // Zero out the RHS rb[k] = 0.0; } else { // Zero out the column which is associated with the zero'ed row for (std::size_t j = col_begin; j < col_end; ++j) if(scaling_factors[ Acol_indices[j] ] == 0 ) Avalues[j] = 0.0; } } } /** * @brief Applies the constraints with master-slave relation matrix (RHS only) * @param pScheme The integration scheme considered * @param rModelPart The model part of the problem to solve * @param rb The RHS vector */ void ApplyRHSConstraints( typename TSchemeType::Pointer pScheme, ModelPart& rModelPart, TSystemVectorType& rb ) override { KRATOS_TRY if (rModelPart.MasterSlaveConstraints().size() != 0) { BuildMasterSlaveConstraints(rModelPart); // We compute the transposed matrix of the global relation matrix TSystemMatrixType T_transpose_matrix(mT.size2(), mT.size1()); SparseMatrixMultiplicationUtility::TransposeMatrix<TSystemMatrixType, TSystemMatrixType>(T_transpose_matrix, mT, 1.0); TSystemVectorType b_modified(rb.size()); TSparseSpace::Mult(T_transpose_matrix, rb, b_modified); TSparseSpace::Copy(b_modified, rb); // Apply diagonal values on slaves #pragma omp parallel for for (int i = 0; i < static_cast<int>(mSlaveIds.size()); ++i) { const IndexType slave_equation_id = mSlaveIds[i]; if (mInactiveSlaveDofs.find(slave_equation_id) == mInactiveSlaveDofs.end()) { rb[slave_equation_id] = 0.0; } } } KRATOS_CATCH("") } /** * @brief Applies the constraints with master-slave relation matrix * @param pScheme The integration scheme considered * @param rModelPart The model part of the problem to solve * @param rA The LHS matrix * @param rb The RHS vector */ void ApplyConstraints( typename TSchemeType::Pointer pScheme, ModelPart& rModelPart, TSystemMatrixType& rA, TSystemVectorType& rb ) override { KRATOS_TRY if (rModelPart.MasterSlaveConstraints().size() != 0) { BuildMasterSlaveConstraints(rModelPart); // We compute the transposed matrix of the global relation matrix TSystemMatrixType T_transpose_matrix(mT.size2(), mT.size1()); SparseMatrixMultiplicationUtility::TransposeMatrix<TSystemMatrixType, TSystemMatrixType>(T_transpose_matrix, mT, 1.0); TSystemVectorType b_modified(rb.size()); TSparseSpace::Mult(T_transpose_matrix, rb, b_modified); TSparseSpace::Copy(b_modified, rb); TSystemMatrixType auxiliar_A_matrix(mT.size2(), rA.size2()); SparseMatrixMultiplicationUtility::MatrixMultiplication(T_transpose_matrix, rA, auxiliar_A_matrix); //auxiliar = T_transpose * rA T_transpose_matrix.resize(0, 0, false); //free memory SparseMatrixMultiplicationUtility::MatrixMultiplication(auxiliar_A_matrix, mT, rA); //A = auxilar * T NOTE: here we are overwriting the old A matrix! auxiliar_A_matrix.resize(0, 0, false); //free memory const double max_diag = GetMaxDiagonal(rA); // Apply diagonal values on slaves #pragma omp parallel for for (int i = 0; i < static_cast<int>(mSlaveIds.size()); ++i) { const IndexType slave_equation_id = mSlaveIds[i]; if (mInactiveSlaveDofs.find(slave_equation_id) == mInactiveSlaveDofs.end()) { rA(slave_equation_id, slave_equation_id) = max_diag; rb[slave_equation_id] = 0.0; } } } KRATOS_CATCH("") } /** * @brief This function is intended to be called at the end of the solution step to clean up memory storage not needed */ void Clear() override { BaseType::Clear(); mSlaveIds.clear(); mMasterIds.clear(); mInactiveSlaveDofs.clear(); mT.resize(0,0,false); mConstantVector.resize(0,false); } /** * @brief This function is designed to be called once to perform all the checks needed * on the input provided. Checks can be "expensive" as the function is designed * to catch user's errors. * @param rModelPart The model part of the problem to solve * @return 0 all ok */ int Check(ModelPart& rModelPart) override { KRATOS_TRY return 0; KRATOS_CATCH(""); } ///@} ///@name Access ///@{ ///@} ///@name Inquiry ///@{ ///@} ///@name Input and output ///@{ /// Turn back information as a string. std::string Info() const override { return "ResidualBasedBlockBuilderAndSolver"; } /// Print information about this object. void PrintInfo(std::ostream& rOStream) const override { rOStream << Info(); } /// Print object's data. void PrintData(std::ostream& rOStream) const override { rOStream << Info(); } ///@} ///@name Friends ///@{ ///@} protected: ///@name Protected static Member Variables ///@{ ///@} ///@name Protected member Variables ///@{ TSystemMatrixType mT; /// This is matrix containing the global relation for the constraints TSystemVectorType mConstantVector; /// This is vector containing the rigid movement of the constraint std::vector<IndexType> mSlaveIds; /// The equation ids of the slaves std::vector<IndexType> mMasterIds; /// The equation ids of the master std::unordered_set<IndexType> mInactiveSlaveDofs; /// The set containing the inactive slave dofs double mScaleFactor = 1.0; /// The manuallyset scale factor SCALING_DIAGONAL mScalingDiagonal; /// We identify the scaling considered for the dirichlet dofs Flags mOptions; /// Some flags used internally ///@} ///@name Protected Operators ///@{ ///@} ///@name Protected Operations ///@{ void BuildRHSNoDirichlet( typename TSchemeType::Pointer pScheme, ModelPart& rModelPart, TSystemVectorType& b) { KRATOS_TRY //Getting the Elements ElementsArrayType& pElements = rModelPart.Elements(); //getting the array of the conditions ConditionsArrayType& ConditionsArray = rModelPart.Conditions(); const ProcessInfo& CurrentProcessInfo = rModelPart.GetProcessInfo(); //contributions to the system LocalSystemMatrixType LHS_Contribution = LocalSystemMatrixType(0, 0); LocalSystemVectorType RHS_Contribution = LocalSystemVectorType(0); //vector containing the localization in the system of the different //terms Element::EquationIdVectorType EquationId; // assemble all elements //for (typename ElementsArrayType::ptr_iterator it = pElements.ptr_begin(); it != pElements.ptr_end(); ++it) const int nelements = static_cast<int>(pElements.size()); #pragma omp parallel firstprivate(nelements, RHS_Contribution, EquationId) { #pragma omp for schedule(guided, 512) nowait for (int i=0; i<nelements; i++) { typename ElementsArrayType::iterator it = pElements.begin() + i; //detect if the element is active or not. If the user did not make any choice the element //is active by default bool element_is_active = true; if( (it)->IsDefined(ACTIVE) ) { element_is_active = (it)->Is(ACTIVE); } if(element_is_active) { //calculate elemental Right Hand Side Contribution pScheme->CalculateRHSContribution(*it, RHS_Contribution, EquationId, CurrentProcessInfo); //assemble the elemental contribution AssembleRHS(b, RHS_Contribution, EquationId); } } LHS_Contribution.resize(0, 0, false); RHS_Contribution.resize(0, false); // assemble all conditions const int nconditions = static_cast<int>(ConditionsArray.size()); #pragma omp for schedule(guided, 512) for (int i = 0; i<nconditions; i++) { auto it = ConditionsArray.begin() + i; //detect if the element is active or not. If the user did not make any choice the element //is active by default bool condition_is_active = true; if( (it)->IsDefined(ACTIVE) ) { condition_is_active = (it)->Is(ACTIVE); } if(condition_is_active) { //calculate elemental contribution pScheme->CalculateRHSContribution(*it, RHS_Contribution, EquationId, CurrentProcessInfo); //assemble the elemental contribution AssembleRHS(b, RHS_Contribution, EquationId); } } } KRATOS_CATCH("") } virtual void ConstructMasterSlaveConstraintsStructure(ModelPart& rModelPart) { if (rModelPart.MasterSlaveConstraints().size() > 0) { const ProcessInfo& r_current_process_info = rModelPart.GetProcessInfo(); // Vector containing the localization in the system of the different terms DofsVectorType slave_dof_list, master_dof_list; // Constraint initial iterator const auto it_const_begin = rModelPart.MasterSlaveConstraints().begin(); std::vector<std::unordered_set<IndexType>> indices(BaseType::mDofSet.size()); std::vector<LockObject> lock_array(indices.size()); #pragma omp parallel firstprivate(slave_dof_list, master_dof_list) { Element::EquationIdVectorType slave_ids(3); Element::EquationIdVectorType master_ids(3); std::unordered_map<IndexType, std::unordered_set<IndexType>> temp_indices; #pragma omp for schedule(guided, 512) nowait for (int i_const = 0; i_const < static_cast<int>(rModelPart.MasterSlaveConstraints().size()); ++i_const) { auto it_const = it_const_begin + i_const; // Detect if the constraint is active or not. If the user did not make any choice the constraint // It is active by default bool constraint_is_active = true; if( it_const->IsDefined(ACTIVE) ) { constraint_is_active = it_const->Is(ACTIVE); } if(constraint_is_active) { it_const->EquationIdVector(slave_ids, master_ids, r_current_process_info); // Slave DoFs for (auto &id_i : slave_ids) { temp_indices[id_i].insert(master_ids.begin(), master_ids.end()); } } } // Merging all the temporal indexes for (int i = 0; i < static_cast<int>(temp_indices.size()); ++i) { lock_array[i].SetLock(); indices[i].insert(temp_indices[i].begin(), temp_indices[i].end()); lock_array[i].UnSetLock(); } } mSlaveIds.clear(); mMasterIds.clear(); for (int i = 0; i < static_cast<int>(indices.size()); ++i) { if (indices[i].size() == 0) // Master dof! mMasterIds.push_back(i); else // Slave dof mSlaveIds.push_back(i); indices[i].insert(i); // Ensure that the diagonal is there in T } // Count the row sizes std::size_t nnz = 0; for (IndexType i = 0; i < indices.size(); ++i) nnz += indices[i].size(); mT = TSystemMatrixType(indices.size(), indices.size(), nnz); mConstantVector.resize(indices.size(), false); double *Tvalues = mT.value_data().begin(); IndexType *Trow_indices = mT.index1_data().begin(); IndexType *Tcol_indices = mT.index2_data().begin(); // Filling the index1 vector - DO NOT MAKE PARALLEL THE FOLLOWING LOOP! Trow_indices[0] = 0; for (int i = 0; i < static_cast<int>(mT.size1()); i++) Trow_indices[i + 1] = Trow_indices[i] + indices[i].size(); #pragma omp parallel for for (int i = 0; i < static_cast<int>(mT.size1()); ++i) { const IndexType row_begin = Trow_indices[i]; const IndexType row_end = Trow_indices[i + 1]; IndexType k = row_begin; for (auto it = indices[i].begin(); it != indices[i].end(); ++it) { Tcol_indices[k] = *it; Tvalues[k] = 0.0; k++; } indices[i].clear(); //deallocating the memory std::sort(&Tcol_indices[row_begin], &Tcol_indices[row_end]); } mT.set_filled(indices.size() + 1, nnz); Timer::Stop("ConstraintsRelationMatrixStructure"); } } virtual void BuildMasterSlaveConstraints(ModelPart& rModelPart) { KRATOS_TRY TSparseSpace::SetToZero(mT); TSparseSpace::SetToZero(mConstantVector); // The current process info const ProcessInfo& r_current_process_info = rModelPart.GetProcessInfo(); // Vector containing the localization in the system of the different terms DofsVectorType slave_dof_list, master_dof_list; // Contributions to the system Matrix transformation_matrix = LocalSystemMatrixType(0, 0); Vector constant_vector = LocalSystemVectorType(0); // Vector containing the localization in the system of the different terms Element::EquationIdVectorType slave_equation_ids, master_equation_ids; const int number_of_constraints = static_cast<int>(rModelPart.MasterSlaveConstraints().size()); // We clear the set mInactiveSlaveDofs.clear(); #pragma omp parallel firstprivate(transformation_matrix, constant_vector, slave_equation_ids, master_equation_ids) { std::unordered_set<IndexType> auxiliar_inactive_slave_dofs; #pragma omp for schedule(guided, 512) for (int i_const = 0; i_const < number_of_constraints; ++i_const) { auto it_const = rModelPart.MasterSlaveConstraints().begin() + i_const; // Detect if the constraint is active or not. If the user did not make any choice the constraint // It is active by default bool constraint_is_active = true; if (it_const->IsDefined(ACTIVE)) constraint_is_active = it_const->Is(ACTIVE); if (constraint_is_active) { it_const->CalculateLocalSystem(transformation_matrix, constant_vector, r_current_process_info); it_const->EquationIdVector(slave_equation_ids, master_equation_ids, r_current_process_info); for (IndexType i = 0; i < slave_equation_ids.size(); ++i) { const IndexType i_global = slave_equation_ids[i]; // Assemble matrix row AssembleRowContribution(mT, transformation_matrix, i_global, i, master_equation_ids); // Assemble constant vector const double constant_value = constant_vector[i]; double& r_value = mConstantVector[i_global]; #pragma omp atomic r_value += constant_value; } } else { // Taking into account inactive constraints it_const->EquationIdVector(slave_equation_ids, master_equation_ids, r_current_process_info); auxiliar_inactive_slave_dofs.insert(slave_equation_ids.begin(), slave_equation_ids.end()); } } // We merge all the sets in one thread #pragma omp critical { mInactiveSlaveDofs.insert(auxiliar_inactive_slave_dofs.begin(), auxiliar_inactive_slave_dofs.end()); } } // Setting the master dofs into the T and C system for (auto eq_id : mMasterIds) { mConstantVector[eq_id] = 0.0; mT(eq_id, eq_id) = 1.0; } // Setting inactive slave dofs in the T and C system for (auto eq_id : mInactiveSlaveDofs) { mConstantVector[eq_id] = 0.0; mT(eq_id, eq_id) = 1.0; } KRATOS_CATCH("") } virtual void ConstructMatrixStructure( typename TSchemeType::Pointer pScheme, TSystemMatrixType& A, ModelPart& rModelPart) { //filling with zero the matrix (creating the structure) Timer::Start("MatrixStructure"); // Getting the elements from the model const int nelements = static_cast<int>(rModelPart.Elements().size()); // Getting the array of the conditions const int nconditions = static_cast<int>(rModelPart.Conditions().size()); const ProcessInfo& CurrentProcessInfo = rModelPart.GetProcessInfo(); ModelPart::ElementsContainerType::iterator el_begin = rModelPart.ElementsBegin(); ModelPart::ConditionsContainerType::iterator cond_begin = rModelPart.ConditionsBegin(); const std::size_t equation_size = BaseType::mEquationSystemSize; std::vector< LockObject > lock_array(equation_size); std::vector<std::unordered_set<std::size_t> > indices(equation_size); #pragma omp parallel for firstprivate(equation_size) for (int iii = 0; iii < static_cast<int>(equation_size); iii++) { indices[iii].reserve(40); } Element::EquationIdVectorType ids(3, 0); #pragma omp parallel for firstprivate(nelements, ids) for (int iii=0; iii<nelements; iii++) { typename ElementsContainerType::iterator i_element = el_begin + iii; pScheme->EquationId(*i_element, ids, CurrentProcessInfo); for (std::size_t i = 0; i < ids.size(); i++) { lock_array[ids[i]].SetLock(); auto& row_indices = indices[ids[i]]; row_indices.insert(ids.begin(), ids.end()); lock_array[ids[i]].UnSetLock(); } } #pragma omp parallel for firstprivate(nconditions, ids) for (int iii = 0; iii<nconditions; iii++) { typename ConditionsArrayType::iterator i_condition = cond_begin + iii; pScheme->EquationId(*i_condition, ids, CurrentProcessInfo); for (std::size_t i = 0; i < ids.size(); i++) { lock_array[ids[i]].SetLock(); auto& row_indices = indices[ids[i]]; row_indices.insert(ids.begin(), ids.end()); lock_array[ids[i]].UnSetLock(); } } //destroy locks lock_array = std::vector< LockObject >(); //count the row sizes unsigned int nnz = 0; for (unsigned int i = 0; i < indices.size(); i++) { nnz += indices[i].size(); } A = CompressedMatrixType(indices.size(), indices.size(), nnz); double* Avalues = A.value_data().begin(); std::size_t* Arow_indices = A.index1_data().begin(); std::size_t* Acol_indices = A.index2_data().begin(); //filling the index1 vector - DO NOT MAKE PARALLEL THE FOLLOWING LOOP! Arow_indices[0] = 0; for (int i = 0; i < static_cast<int>(A.size1()); i++) { Arow_indices[i+1] = Arow_indices[i] + indices[i].size(); } #pragma omp parallel for for (int i = 0; i < static_cast<int>(A.size1()); i++) { const unsigned int row_begin = Arow_indices[i]; const unsigned int row_end = Arow_indices[i+1]; unsigned int k = row_begin; for (auto it = indices[i].begin(); it != indices[i].end(); it++) { Acol_indices[k] = *it; Avalues[k] = 0.0; k++; } indices[i].clear(); //deallocating the memory std::sort(&Acol_indices[row_begin], &Acol_indices[row_end]); } A.set_filled(indices.size()+1, nnz); Timer::Stop("MatrixStructure"); } void Assemble( TSystemMatrixType& A, TSystemVectorType& b, const LocalSystemMatrixType& LHS_Contribution, const LocalSystemVectorType& RHS_Contribution, Element::EquationIdVectorType& EquationId ) { unsigned int local_size = LHS_Contribution.size1(); for (unsigned int i_local = 0; i_local < local_size; i_local++) { unsigned int i_global = EquationId[i_local]; double& r_a = b[i_global]; const double& v_a = RHS_Contribution(i_local); #pragma omp atomic r_a += v_a; AssembleRowContribution(A, LHS_Contribution, i_global, i_local, EquationId); } } //************************************************************************** void AssembleLHS( TSystemMatrixType& rA, const LocalSystemMatrixType& rLHSContribution, Element::EquationIdVectorType& rEquationId ) { const SizeType local_size = rLHSContribution.size1(); for (IndexType i_local = 0; i_local < local_size; i_local++) { const IndexType i_global = rEquationId[i_local]; AssembleRowContribution(rA, rLHSContribution, i_global, i_local, rEquationId); } } //************************************************************************** void AssembleRHS( TSystemVectorType& b, LocalSystemVectorType& RHS_Contribution, Element::EquationIdVectorType& EquationId ) { unsigned int local_size = RHS_Contribution.size(); for (unsigned int i_local = 0; i_local < local_size; i_local++) { unsigned int i_global = EquationId[i_local]; // ASSEMBLING THE SYSTEM VECTOR double& b_value = b[i_global]; const double& rhs_value = RHS_Contribution[i_local]; #pragma omp atomic b_value += rhs_value; } } inline void AssembleRowContribution(TSystemMatrixType& A, const Matrix& Alocal, const unsigned int i, const unsigned int i_local, Element::EquationIdVectorType& EquationId) { double* values_vector = A.value_data().begin(); std::size_t* index1_vector = A.index1_data().begin(); std::size_t* index2_vector = A.index2_data().begin(); size_t left_limit = index1_vector[i]; // size_t right_limit = index1_vector[i+1]; //find the first entry size_t last_pos = ForwardFind(EquationId[0],left_limit,index2_vector); size_t last_found = EquationId[0]; double& r_a = values_vector[last_pos]; const double& v_a = Alocal(i_local,0); #pragma omp atomic r_a += v_a; //now find all of the other entries size_t pos = 0; for (unsigned int j=1; j<EquationId.size(); j++) { unsigned int id_to_find = EquationId[j]; if(id_to_find > last_found) { pos = ForwardFind(id_to_find,last_pos+1,index2_vector); } else if(id_to_find < last_found) { pos = BackwardFind(id_to_find,last_pos-1,index2_vector); } else { pos = last_pos; } double& r = values_vector[pos]; const double& v = Alocal(i_local,j); #pragma omp atomic r += v; last_found = id_to_find; last_pos = pos; } } /** * @brief This method returns the scale norm considering for scaling the diagonal * @param rModelPart The problem model part * @param rA The LHS matrix * @return The scale norm */ double GetScaleNorm( ModelPart& rModelPart, TSystemMatrixType& rA ) { switch (mScalingDiagonal) { case SCALING_DIAGONAL::NO_SCALING: return 1.0; case SCALING_DIAGONAL::CONSIDER_PRESCRIBED_DIAGONAL: { const ProcessInfo& r_current_process_info = rModelPart.GetProcessInfo(); KRATOS_ERROR_IF_NOT(r_current_process_info.Has(BUILD_SCALE_FACTOR)) << "Scale factor not defined at process info" << std::endl; return r_current_process_info.GetValue(BUILD_SCALE_FACTOR); } case SCALING_DIAGONAL::CONSIDER_NORM_DIAGONAL: return GetDiagonalNorm(rA)/static_cast<double>(rA.size1()); case SCALING_DIAGONAL::CONSIDER_MAX_DIAGONAL: return GetMaxDiagonal(rA); // return TSparseSpace::TwoNorm(rA)/static_cast<double>(rA.size1()); default: return GetMaxDiagonal(rA); } } /** * @brief This method returns the diagonal norm considering for scaling the diagonal * @param rA The LHS matrix * @return The diagonal norm */ double GetDiagonalNorm(TSystemMatrixType& rA) { double diagonal_norm = 0.0; #pragma omp parallel for reduction(+:diagonal_norm) for(int i = 0; i < static_cast<int>(TSparseSpace::Size1(rA)); ++i) { diagonal_norm += std::pow(rA(i,i), 2); } return std::sqrt(diagonal_norm); } /** * @brief This method returns the diagonal max value * @param rA The LHS matrix * @return The diagonal max value */ double GetAveragevalueDiagonal(TSystemMatrixType& rA) { return 0.5 * (GetMaxDiagonal(rA) + GetMinDiagonal(rA)); } /** * @brief This method returns the diagonal max value * @param rA The LHS matrix * @return The diagonal max value */ double GetMaxDiagonal(TSystemMatrixType& rA) { // // NOTE: Reduction failing in MSVC // double max_diag = 0.0; // #pragma omp parallel for reduction(max:max_diag) // for(int i = 0; i < static_cast<int>(TSparseSpace::Size1(rA)); ++i) { // max_diag = std::max(max_diag, std::abs(rA(i,i))); // } // return max_diag; // Creating a buffer for parallel vector fill const int num_threads = OpenMPUtils::GetNumThreads(); Vector max_vector(num_threads, 0.0); #pragma omp parallel for for(int i = 0; i < static_cast<int>(TSparseSpace::Size1(rA)); ++i) { const int id = OpenMPUtils::ThisThread(); const double abs_value_ii = std::abs(rA(i,i)); if (abs_value_ii > max_vector[id]) max_vector[id] = abs_value_ii; } double max_diag = 0.0; for(int i = 0; i < num_threads; ++i) { max_diag = std::max(max_diag, max_vector[i]); } return max_diag; } /** * @brief This method returns the diagonal min value * @param rA The LHS matrix * @return The diagonal min value */ double GetMinDiagonal(TSystemMatrixType& rA) { // // NOTE: Reduction failing in MSVC // double min_diag = std::numeric_limits<double>::max(); // #pragma omp parallel for reduction(min:min_diag) // for(int i = 0; i < static_cast<int>(TSparseSpace::Size1(rA)); ++i) { // min_diag = std::min(min_diag, std::abs(rA(i,i))); // } // return min_diag; // Creating a buffer for parallel vector fill const int num_threads = OpenMPUtils::GetNumThreads(); Vector min_vector(num_threads, std::numeric_limits<double>::max()); #pragma omp parallel for for(int i = 0; i < static_cast<int>(TSparseSpace::Size1(rA)); ++i) { const int id = OpenMPUtils::ThisThread(); const double abs_value_ii = std::abs(rA(i,i)); if (abs_value_ii < min_vector[id]) min_vector[id] = abs_value_ii; } double min_diag = std::numeric_limits<double>::max(); for(int i = 0; i < num_threads; ++i) { min_diag = std::min(min_diag, min_vector[i]); } return min_diag; } ///@} ///@name Protected Access ///@{ ///@} ///@name Protected Inquiry ///@{ ///@} ///@name Protected LifeCycle ///@{ ///@} private: ///@name Static Member Variables ///@{ ///@} ///@name Member Variables ///@{ ///@} ///@name Private Operators ///@{ ///@} ///@name Private Operations ///@{ inline void AddUnique(std::vector<std::size_t>& v, const std::size_t& candidate) { std::vector<std::size_t>::iterator i = v.begin(); std::vector<std::size_t>::iterator endit = v.end(); while (i != endit && (*i) != candidate) { i++; } if (i == endit) { v.push_back(candidate); } } //****************************************************************************************** //****************************************************************************************** inline void CreatePartition(unsigned int number_of_threads, const int number_of_rows, DenseVector<unsigned int>& partitions) { partitions.resize(number_of_threads + 1); int partition_size = number_of_rows / number_of_threads; partitions[0] = 0; partitions[number_of_threads] = number_of_rows; for (unsigned int i = 1; i < number_of_threads; i++) { partitions[i] = partitions[i - 1] + partition_size; } } inline unsigned int ForwardFind(const unsigned int id_to_find, const unsigned int start, const size_t* index_vector) { unsigned int pos = start; while(id_to_find != index_vector[pos]) pos++; return pos; } inline unsigned int BackwardFind(const unsigned int id_to_find, const unsigned int start, const size_t* index_vector) { unsigned int pos = start; while(id_to_find != index_vector[pos]) pos--; return pos; } ///@} ///@name Private Operations ///@{ ///@} ///@name Private Access ///@{ ///@} ///@name Private Inquiry ///@{ ///@} ///@name Un accessible methods ///@{ ///@} }; /* Class ResidualBasedBlockBuilderAndSolver */ ///@} ///@name Type Definitions ///@{ // Here one should use the KRATOS_CREATE_LOCAL_FLAG, but it does not play nice with template parameters template<class TSparseSpace, class TDenseSpace, class TLinearSolver> const Kratos::Flags ResidualBasedBlockBuilderAndSolver<TSparseSpace, TDenseSpace, TLinearSolver>::SILENT_WARNINGS(Kratos::Flags::Create(0)); ///@} } /* namespace Kratos.*/ #endif /* KRATOS_RESIDUAL_BASED_BLOCK_BUILDER_AND_SOLVER defined */

c_print_results.c

/*****************************************************************/ /****** C _ P R I N T _ R E S U L T S ******/ /*****************************************************************/ #include <stdlib.h> #include <stdio.h> #include <omp.h> void c_print_results( char *name, char class, int n1, int n2, int n3, int niter, double t, double mops, char *optype, int passed_verification, char *npbversion, char *compiletime, char *cc, char *clink, char *c_lib, char *c_inc, char *cflags, char *clinkflags ) { int num_threads; char *num_threads_set; /* figure out number of threads used */ #pragma omp parallel shared(num_threads) { #pragma omp master num_threads = omp_get_num_threads(); } num_threads_set = getenv("OMP_NUM_THREADS"); if (!num_threads_set) num_threads_set = "unset"; printf( "\n\n %s Benchmark Completed\n", name ); printf( " Class = %c\n", class ); if( n2 == 0 && n3 == 0 ) printf( " Size = %12d\n", n1 ); /* as in IS */ else printf( " Size = %3dx %3dx %3d\n", n1,n2,n3 ); printf( " Iterations = %12d\n", niter ); printf( " Time in seconds = %12.2f\n", t ); printf( " Total threads = %12d\n", num_threads); printf( " Request threads = %12s\n", num_threads_set); printf( " Mop/s total = %12.2f\n", mops ); printf( " Mop/s/thread = %12.2f\n", mops/(double)num_threads ); printf( " Operation type = %24s\n", optype); if( passed_verification ) printf( " Verification = SUCCESSFUL\n" ); else printf( " Verification = UNSUCCESSFUL\n" ); printf( " Version = %12s\n", npbversion ); printf( " Compile date = %12s\n", compiletime ); printf( "\n Compile options:\n" ); printf( " CC = %s\n", cc ); printf( " CLINK = %s\n", clink ); printf( " C_LIB = %s\n", c_lib ); printf( " C_INC = %s\n", c_inc ); printf( " CFLAGS = %s\n", cflags ); printf( " CLINKFLAGS = %s\n", clinkflags ); printf( "\n\n" ); printf( " Please send all errors/feedbacks to:\n\n" ); printf( " NPB Development Team\n" ); printf( " npb@nas.nasa.gov\n\n" ); /* printf( " Please send the results of this run to:\n\n" ); printf( " NPB Development Team\n" ); printf( " Internet: npb@nas.nasa.gov\n \n" ); printf( " If email is not available, send this to:\n\n" ); printf( " MS T27A-1\n" ); printf( " NASA Ames Research Center\n" ); printf( " Moffett Field, CA 94035-1000\n\n" ); printf( " Fax: 650-604-3957\n\n" ); */ }

blas.c

#include "blas.h" #include <math.h> #include <assert.h> #include <float.h> #include <stdio.h> #include <stdlib.h> #include <string.h> void reorg_cpu(float *x, int out_w, int out_h, int out_c, int batch, int stride, int forward, float *out) { int b,i,j,k; int in_c = out_c/(stride*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); for(b = 0; b < batch; ++b){ for(k = 0; k < out_c; ++k){ for(j = 0; j < out_h; ++j){ for(i = 0; i < out_w; ++i){ int in_index = i + out_w*(j + out_h*(k + out_c*b)); int c2 = k % in_c; int offset = k / in_c; int w2 = i*stride + offset % stride; int h2 = j*stride + offset / stride; int out_index = w2 + out_w*stride*(h2 + out_h*stride*(c2 + in_c*b)); if(forward) out[out_index] = x[in_index]; // used by default for forward (i.e. forward = 0) else out[in_index] = x[out_index]; } } } } } void flatten(float *x, int size, int layers, int batch, int forward) { float* swap = (float*)calloc(size * layers * batch, sizeof(float)); int i,c,b; for(b = 0; b < batch; ++b){ for(c = 0; c < layers; ++c){ for(i = 0; i < size; ++i){ int i1 = b*layers*size + c*size + i; int i2 = b*layers*size + i*layers + c; if (forward) swap[i2] = x[i1]; else swap[i1] = x[i2]; } } } memcpy(x, swap, size*layers*batch*sizeof(float)); free(swap); } void weighted_sum_cpu(float *a, float *b, float *s, int n, float *c) { int i; for(i = 0; i < n; ++i){ c[i] = s[i]*a[i] + (1-s[i])*(b ? b[i] : 0); } } void weighted_delta_cpu(float *a, float *b, float *s, float *da, float *db, float *ds, int n, float *dc) { int i; for(i = 0; i < n; ++i){ if(da) da[i] += dc[i] * s[i]; if(db) db[i] += dc[i] * (1-s[i]); ds[i] += dc[i] * (a[i] - b[i]); } } void shortcut_cpu(int batch, int w1, int h1, int c1, float *add, int w2, int h2, int c2, float *out) { int stride = w1/w2; int sample = w2/w1; assert(stride == h1/h2); assert(sample == h2/h1); if(stride < 1) stride = 1; if(sample < 1) sample = 1; int minw = (w1 < w2) ? w1 : w2; int minh = (h1 < h2) ? h1 : h2; int minc = (c1 < c2) ? c1 : c2; int i,j,k,b; for(b = 0; b < batch; ++b){ for(k = 0; k < minc; ++k){ for(j = 0; j < minh; ++j){ for(i = 0; i < minw; ++i){ int out_index = i*sample + w2*(j*sample + h2*(k + c2*b)); int add_index = i*stride + w1*(j*stride + h1*(k + c1*b)); out[out_index] += add[add_index]; } } } } } void mean_cpu(float *x, int batch, int filters, int spatial, float *mean) { float scale = 1./(batch * spatial); int i,j,k; for(i = 0; i < filters; ++i){ mean[i] = 0; for(j = 0; j < batch; ++j){ for(k = 0; k < spatial; ++k){ int index = j*filters*spatial + i*spatial + k; mean[i] += x[index]; } } mean[i] *= scale; } } void variance_cpu(float *x, float *mean, int batch, int filters, int spatial, float *variance) { float scale = 1./(batch * spatial - 1); int i,j,k; for(i = 0; i < filters; ++i){ variance[i] = 0; for(j = 0; j < batch; ++j){ for(k = 0; k < spatial; ++k){ int index = j*filters*spatial + i*spatial + k; variance[i] += pow((x[index] - mean[i]), 2); } } variance[i] *= scale; } } void normalize_cpu(float *x, float *mean, float *variance, int batch, int filters, int spatial) { #pragma omp simd collapse(2) for(int b = 0; b < batch; ++b){ for(int f = 0; f < filters; ++f){ float meanf = mean[f]; float sqrtvarfc = sqrt(variance[f]) + .000001f; for(int i = 0; i < spatial; ++i){ int index = b*filters*spatial + f*spatial + i; x[index] = (x[index] - meanf) / sqrtvarfc; } } } } #pragma omp declare simd void const_cpu(int N, float ALPHA, float *X, int INCX) { int NINCX = N * INCX; #pragma omp simd for(int i = 0; i < NINCX; i += INCX){ X[i] = ALPHA; } } #pragma omp declare simd aligned(X,Y:16) void mul_cpu(int N, float *__restrict__ X, int INCX, float *__restrict__ Y, int INCY) { #pragma omp simd aligned(X,Y:16) safelen(4) for(int i = 0; i < N; ++i){ Y[i*INCY] *= X[i*INCX]; } } #pragma omp declare simd aligned(X,Y:16) void pow_cpu(int N, float ALPHA, float *__restrict__ X, int INCX, float *__restrict__ Y, int INCY) { #pragma omp simd aligned(X,Y:16) safelen(4) for(int i = 0; i < N; ++i){ Y[i*INCY] = pow(X[i*INCX], ALPHA); } } #pragma omp declare simd aligned(X,Y:16) void axpy_cpu(int N, float ALPHA, float *__restrict__ X, int INCX, float *__restrict__ Y, int INCY) { #pragma omp simd aligned(X,Y:16) safelen(4) for(int i = 0; i < N; ++i){ Y[i*INCY] += ALPHA*X[i*INCX]; } } #pragma omp declare simd void scal_cpu(int N, float ALPHA, float *X, int INCX) { int NINCX = N * INCX; #pragma omp simd for(int i = 0; i < NINCX; i += INCX){ X[i] *= ALPHA; } } #pragma omp declare simd void fill_cpu(int N, float ALPHA, float *X, int INCX) { int NINCX; if (INCX == 1 && ALPHA == 0) { memset(X, 0, N * sizeof(float)); } else { NINCX = N * INCX; #pragma omp simd for(int i = 0; i < NINCX; i += INCX){ X[i] = ALPHA; } } } void deinter_cpu(int NX, float *X, int NY, float *Y, int B, float *OUT) { int i, j; int index = 0; for(j = 0; j < B; ++j) { for(i = 0; i < NX; ++i){ if(X) X[j*NX + i] += OUT[index]; ++index; } for(i = 0; i < NY; ++i){ if(Y) Y[j*NY + i] += OUT[index]; ++index; } } } void inter_cpu(int NX, float *X, int NY, float *Y, int B, float *OUT) { int i, j; int index = 0; for(j = 0; j < B; ++j) { for(i = 0; i < NX; ++i){ OUT[index++] = X[j*NX + i]; } for(i = 0; i < NY; ++i){ OUT[index++] = Y[j*NY + i]; } } } #pragma omp declare simd aligned(X,Y:16) void copy_cpu(int N, float *__restrict__ X, int INCX, float *__restrict__ Y, int INCY) { #pragma omp simd aligned(X,Y:16) safelen(4) for(int i = 0; i < N; ++i){ Y[i*INCY] = X[i*INCX]; } } #pragma omp declare simd aligned(X,Y,Z:16) void mult_add_into_cpu(int N, float *__restrict__ X, float *__restrict__ Y, float *__restrict__ Z) { #pragma omp simd aligned(X,Y,Z:16) safelen(4) for(int i = 0; i < N; ++i){ Z[i] += X[i]*Y[i]; } } void smooth_l1_cpu(int n, float *pred, float *truth, float *delta, float *error) { int i; for(i = 0; i < n; ++i){ float diff = truth[i] - pred[i]; float abs_val = fabs(diff); if(abs_val < 1) { error[i] = diff * diff; delta[i] = diff; } else { error[i] = 2*abs_val - 1; delta[i] = (diff > 0) ? 1 : -1; } } } void l1_cpu(int n, float *pred, float *truth, float *delta, float *error) { int i; for(i = 0; i < n; ++i){ float diff = truth[i] - pred[i]; error[i] = fabs(diff); delta[i] = diff > 0 ? 1 : -1; } } void softmax_x_ent_cpu(int n, float *pred, float *truth, float *delta, float *error) { int i; for(i = 0; i < n; ++i){ float t = truth[i]; float p = pred[i]; error[i] = (t) ? -log(p) : 0; delta[i] = t-p; } } void logistic_x_ent_cpu(int n, float *pred, float *truth, float *delta, float *error) { int i; for(i = 0; i < n; ++i){ float t = truth[i]; float p = pred[i]; error[i] = -t*log(p) - (1-t)*log(1-p); delta[i] = t-p; } } void l2_cpu(int n, float *pred, float *truth, float *delta, float *error) { int i; for(i = 0; i < n; ++i){ float diff = truth[i] - pred[i]; error[i] = diff * diff; delta[i] = diff; } } #pragma omp declare simd aligned(X,Y:16) float dot_cpu(int N, float *__restrict__ X, int INCX, float *__restrict__ Y, int INCY) { int i; float dot = 0; #pragma omp simd reduction(+:dot) for(i = 0; i < N; ++i){ dot += X[i*INCX] * Y[i*INCY]; } return dot; } void softmax(float *input, int n, float temp, float *output, int stride) { int i; float sum = 0; float largest = -FLT_MAX; for(i = 0; i < n; ++i){ if(input[i*stride] > largest) largest = input[i*stride]; } for(i = 0; i < n; ++i){ float e = exp(input[i*stride]/temp - largest/temp); sum += e; output[i*stride] = e; } for(i = 0; i < n; ++i){ output[i*stride] /= sum; } } void softmax_cpu(float *input, int n, int batch, int batch_offset, int groups, int group_offset, int stride, float temp, float *output) { int g, b; for(b = 0; b < batch; ++b){ for(g = 0; g < groups; ++g){ softmax(input + b*batch_offset + g*group_offset, n, temp, output + b*batch_offset + g*group_offset, stride); } } } void upsample_cpu(float *in, int w, int h, int c, int batch, int stride, int forward, float scale, float *out) { int i, j, k, b; for (b = 0; b < batch; ++b) { for (k = 0; k < c; ++k) { for (j = 0; j < h*stride; ++j) { for (i = 0; i < w*stride; ++i) { int in_index = b*w*h*c + k*w*h + (j / stride)*w + i / stride; int out_index = b*w*h*c*stride*stride + k*w*h*stride*stride + j*w*stride + i; if (forward) out[out_index] = scale*in[in_index]; else in[in_index] += scale*out[out_index]; } } } } }

postgres_fmt_plug.c

/* PostgreSQL MD5 challenge-response cracker patch for JtR. Hacked together * during October of 2012 by Dhiru Kholia <dhiru.kholia at gmail.com>. * * Use Ettercap to get PostgreSQL MD5 challenge-response pairs in JtR format. * E.g. ettercap -Tq -r /home/user/sample.pcap * * Input format: * $postgres$user*salt*hash * * This software is Copyright (c) 2012, Dhiru Kholia <dhiru.kholia at gmail.com> * and Copyright magnum 2013, * 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. */ #if FMT_EXTERNS_H extern struct fmt_main fmt_postgres; #elif FMT_REGISTERS_H john_register_one(&fmt_postgres); #else #include <string.h> #include <errno.h> #ifdef _OPENMP static int omp_t = 1; #include <omp.h> #ifndef OMP_SCALE #define OMP_SCALE 2048 // scaled on K8-dual HT #endif #endif #include "md5.h" #include "arch.h" #include "misc.h" #include "common.h" #include "formats.h" #include "params.h" #include "options.h" #include "memdbg.h" #define FORMAT_LABEL "postgres" #define FORMAT_NAME "PostgreSQL C/R" #define FORMAT_TAG "$postgres$" #define FORMAT_TAG_LEN (sizeof(FORMAT_TAG)-1) #define FORMAT_TAG2 "$postgre$" #define FORMAT_TAG2_LEN (sizeof(FORMAT_TAG2)-1) #define ALGORITHM_NAME "MD5 32/" ARCH_BITS_STR #define BENCHMARK_COMMENT "" #define BENCHMARK_LENGTH -1 #define PLAINTEXT_LENGTH 32 #define BINARY_SIZE 16 #define BINARY_ALIGN MEM_ALIGN_WORD #define SALT_SIZE sizeof(struct custom_salt) #define SALT_ALIGN MEM_ALIGN_NONE #define MAX_USERNAME_LEN 64 #define MIN_KEYS_PER_CRYPT 1 #define MAX_KEYS_PER_CRYPT 1 static struct fmt_tests postgres_tests[] = { {"$postgres$postgres*f063f05d*1d586cc8d137e5f1733f234d224393e8", "openwall"}, {"$postgres$postgres*c31803a2*1c4e11fb51835c3bbe9851ec91ec1375", "password"}, /* $postgre$ is supported but deprecated */ {"$postgre$postgres*684697c8*bf2a64f35feba7bf1b633d60393c1356", "openwall"}, /* $postgres$ with longer user name */ {"$postgres$Twelve_chars*55393156*c01df9affa7573ef32ec143759f3e005", "HookFish__2"}, {"$postgres$postgres*65687433*b782eca219ad84b58f26d25e19a1bbc9", "thisisalongstring"}, {"$postgres$postgres*33374273*77e0016f1b92cdea7291ab0ed21798b8", "string with space"}, {"$postgres$postgres*6f734f37*d5451e93f6ac9a0d30336ec106e91cf5", "123456789"}, {"$postgres$postgres*3348654b*0f0f46a3dfebf45f4320d2edeabc318f", ""}, {NULL} }; static char (*saved_key)[PLAINTEXT_LENGTH + 1]; static ARCH_WORD_32 (*crypt_out)[BINARY_SIZE / sizeof(ARCH_WORD_32)]; static struct custom_salt { unsigned char user[MAX_USERNAME_LEN + 1]; unsigned char salt[4]; } *cur_salt; static void init(struct fmt_main *self) { #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(self->params.max_keys_per_crypt, sizeof(*saved_key)); crypt_out = mem_calloc(self->params.max_keys_per_crypt, sizeof(*crypt_out)); } static void done(void) { MEM_FREE(crypt_out); MEM_FREE(saved_key); } static int valid(char *ciphertext, struct fmt_main *self) { const char *p; int extra; if (strncmp(ciphertext, FORMAT_TAG, FORMAT_TAG_LEN)) return 0; /* Check hash */ if (!(p = strrchr(ciphertext, '*'))) return 0; if (hexlenl(&p[1], &extra) != 2*BINARY_SIZE || extra) return 0; /* Check salt */ p -= 9; if (*p != '*') return 0; if (hexlenl(&p[1], 0) != 8) return 0; /* Check username length */ if (p - ciphertext - FORMAT_TAG_LEN > MAX_USERNAME_LEN) return 0; return 1; } static char *prepare(char *split_fields[10], struct fmt_main *self) { static char out[FORMAT_TAG_LEN + sizeof(struct custom_salt) + 2*BINARY_SIZE +2+1]; /* Replace deprecated tag */ if (*split_fields[1] && !strncmp(split_fields[1], FORMAT_TAG2, FORMAT_TAG2_LEN)) { snprintf(out, sizeof(out), "%s%s", FORMAT_TAG, &split_fields[1][FORMAT_TAG2_LEN]); if (valid(out, self)) return out; } return split_fields[1]; } static void *get_salt(char *ciphertext) { char *ctcopy = strdup(ciphertext); char *keeptr = ctcopy; char *p; int i; static struct custom_salt cs; ctcopy += FORMAT_TAG_LEN; /* skip over "$postgres$" */ p = strtokm(ctcopy, "*"); memset(&cs, 0, sizeof(cs)); strnzcpy((char*)cs.user, p, MAX_USERNAME_LEN + 1); p = strtokm(NULL, "*"); for (i = 0; i < 4; i++) cs.salt[i] = atoi16[ARCH_INDEX(p[i * 2])] * 16 + atoi16[ARCH_INDEX(p[i * 2 + 1])]; MEM_FREE(keeptr); return (void *)&cs; } 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 get_hash_0(int index) { return crypt_out[index][0] & PH_MASK_0; } static int get_hash_1(int index) { return crypt_out[index][0] & PH_MASK_1; } static int get_hash_2(int index) { return crypt_out[index][0] & PH_MASK_2; } static int get_hash_3(int index) { return crypt_out[index][0] & PH_MASK_3; } static int get_hash_4(int index) { return crypt_out[index][0] & PH_MASK_4; } static int get_hash_5(int index) { return crypt_out[index][0] & PH_MASK_5; } static int get_hash_6(int index) { return crypt_out[index][0] & PH_MASK_6; } static void set_salt(void *salt) { cur_salt = (struct custom_salt *)salt; } 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 int crypt_all(int *pcount, struct db_salt *salt) { const int count = *pcount; int index = 0; #ifdef _OPENMP #pragma omp parallel for #endif #if defined(_OPENMP) || MAX_KEYS_PER_CRYPT > 1 for (index = 0; index < count; index++) #endif { MD5_CTX ctx; unsigned char out[32]; MD5_Init(&ctx); MD5_Update(&ctx, saved_key[index], strlen(saved_key[index])); MD5_Update(&ctx, cur_salt->user, strlen((char*)cur_salt->user)); MD5_Final((unsigned char*)crypt_out[index], &ctx); hex_encode((unsigned char*)crypt_out[index], 16, out); MD5_Init(&ctx); MD5_Update(&ctx, out, 32); MD5_Update(&ctx, cur_salt->salt, 4); MD5_Final((unsigned char*)crypt_out[index], &ctx); } return count; } static int cmp_all(void *binary, int count) { int index = 0; #if defined(_OPENMP) || MAX_KEYS_PER_CRYPT > 1 for (; index < count; index++) #endif if (!memcmp(binary, crypt_out[index], ARCH_SIZE)) return 1; return 0; } static int cmp_one(void *binary, int index) { return !memcmp(binary, crypt_out[index], BINARY_SIZE); } static int cmp_exact(char *source, int index) { return 1; } static void postgres_set_key(char *key, int index) { int saved_len = strlen(key); if (saved_len > PLAINTEXT_LENGTH) saved_len = PLAINTEXT_LENGTH; memcpy(saved_key[index], key, saved_len); saved_key[index][saved_len] = 0; } static char *get_key(int index) { return saved_key[index]; } struct fmt_main fmt_postgres = { { 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_OMP | FMT_OMP_BAD, { NULL }, { FORMAT_TAG, FORMAT_TAG2 }, postgres_tests }, { init, done, fmt_default_reset, prepare, valid, fmt_default_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 }, fmt_default_salt_hash, NULL, set_salt, postgres_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 */

utils.c

#include <stdio.h> #include <stdlib.h> #include <time.h> #include <omp.h> void print_mat(int n , int** mat) { int i,j; for (i = 0; i < n; i++){ printf("%X: ",mat[i]); for (j = 0; j < n; j++){ printf("%d ",mat[i][j]); } printf("\n"); } printf("\n"); } void free_mat(int n, int** mat) { int i; for(i = 0; i < n; i++) { free(mat[i]); } free(mat); } int** make_rand_mat(int n, int max_val) { double begin,end; int i,j; int** mat = malloc(sizeof(int*)*n); begin = omp_get_wtime(); srand(time(NULL)); // generate rand seed from current time #pragma omp parallel for private(i,j) firstprivate (n) for (i = 0; i < n; i++) { mat[i] = malloc(sizeof(int)*n); #pragma omp parallel for private(j) for (j = 0; j < n; j++) { mat[i][j] = rand() % max_val; } } end = omp_get_wtime(); printf("matrix initialization with random numbers took %lf seconds\n", end - begin); return mat; } int* make_rand_mat_1d(int n, int max_val) { double begin,end; int* mat = malloc(n*n*sizeof(int)); int i; begin = omp_get_wtime(); srand(time(NULL)); // generate rand seed from current time #pragma omp parallel for private(i) firstprivate (n) for (i = 0; i < n*n; i++) { mat[i] = 1; //rand() % max_val; } end = omp_get_wtime(); printf("matrix initialization with random numbers took %lf seconds\n", end - begin); return mat; } int** make_zero_mat(int n) { double begin,end; int i,j; int** mat = malloc (sizeof(int*)*n); begin = omp_get_wtime(); srand(time(NULL)); // generate rand seed from current time #pragma omp parallel for private(i,j) firstprivate (n) for (i = 0; i < n; i++) { mat[i] = calloc(n, sizeof(int)); } end = omp_get_wtime(); printf("matrix initialization with zeros took %lf seconds\n", end - begin); return mat; } int* make_zero_mat_1d(int n) { double begin,end; int i; int* mat = malloc (n*n*sizeof(int*)); begin = omp_get_wtime(); srand(time(NULL)); // generate rand seed from current time mat = calloc(n*n, sizeof(int)); end = omp_get_wtime(); printf("matrix initialization with zeros took %lf seconds\n", end - begin); return mat; } int compare_pat(int n, int* bad_i, int* bad_j, int** mat1, int** mat2) { int i,j; for(i = 0; i < n; i++) { for(j = 0; j < n; j++) { if(mat1[i][j] - mat2[i][j]) { *bad_i = i; *bad_j = j; return 1; } } } return 0; }

2mm.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 "2mm.h" /* Array initialization. */ static void init_array( int ni, int nj, int nk, int nl, DATA_TYPE *alpha, DATA_TYPE *beta, DATA_TYPE POLYBENCH_2D( A, NI, NK, ni, nl ), DATA_TYPE POLYBENCH_2D( B, NK, NJ, nk, nj ), DATA_TYPE POLYBENCH_2D( C, NL, NJ, nl, nj ), DATA_TYPE POLYBENCH_2D( D, NI, NL, ni, nl ) ) { int i, j; *alpha = 32412; *beta = 2123; 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 < nl; i++ ) for ( j = 0; j < nj; j++ ) { C[i][j] = ( ( DATA_TYPE ) i * ( j + 3 ) ) / nl; } for ( i = 0; i < ni; 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( D, NI, NL, ni, nl ) ) { int i, j; for ( i = 0; i < ni; i++ ) for ( j = 0; j < nl; j++ ) { fprintf ( stderr, DATA_PRINTF_MODIFIER, D[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_2mm( int ni, int nj, int nk, int nl, DATA_TYPE alpha, DATA_TYPE beta, DATA_TYPE POLYBENCH_2D( tmp, 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( C, NL, NJ, nl, nj ), DATA_TYPE POLYBENCH_2D( D, NI, NL, ni, nl ) ) { int i, j, k; //~ #pragma omp parallel //~ { #pragma omp parallel for private (j, k) for ( i = 0; i < _PB_NI; i++ ) for ( j = 0; j < _PB_NJ; j++ ) { tmp[i][j] = 0; for ( k = 0; k < _PB_NK; ++k ) { tmp[i][j] += alpha * A[i][k] * B[k][j]; } } #pragma omp parallel for private (j, k) for ( i = 0; i < _PB_NI; i++ ) for ( j = 0; j < _PB_NL; j++ ) { D[i][j] *= beta; for ( k = 0; k < _PB_NJ; ++k ) { D[i][j] += tmp[i][k] * C[k][j]; } } //~ } } static void * xmalloc ( size_t num ) { void* new = NULL; int ret = posix_memalign ( &new, 32, num ); if ( ! new || ret ) { fprintf ( stderr, "[PolyBench] posix_memalign: cannot allocate memory" ); exit ( 1 ); } return new; } void *polybench_alloc_data( unsigned long long int n, int elt_size ) { /* FIXME: detect overflow! */ size_t val = n; void * ret; val *= elt_size; ret = xmalloc( val ); return ret; } int main( int argc, char** argv ) { /* Retrieve problem size. */ int ni = NI; int nj = NJ; int nk = NK; int nl = NL; /* Variable declaration/allocation. */ DATA_TYPE alpha; DATA_TYPE beta; POLYBENCH_2D_ARRAY_DECL( tmp, 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( C, DATA_TYPE, NL, NJ, nl, nj ); POLYBENCH_2D_ARRAY_DECL( D, DATA_TYPE, NI, NL, ni, nl ); POLYBENCH_2D_ARRAY_ALLOC( tmp, DATA_TYPE, NI, NJ, ni, nj ); POLYBENCH_2D_ARRAY_ALLOC( A, DATA_TYPE, NI, NK, ni, nk ); POLYBENCH_2D_ARRAY_ALLOC( B, DATA_TYPE, NK, NJ, nk, nj ); POLYBENCH_2D_ARRAY_ALLOC( C, DATA_TYPE, NL, NJ, nl, nj ); POLYBENCH_2D_ARRAY_ALLOC( D, DATA_TYPE, NI, NL, ni, nl ); /* Initialize array(s). */ init_array ( ni, nj, nk, nl, &alpha, &beta, POLYBENCH_ARRAY( A ), POLYBENCH_ARRAY( B ), POLYBENCH_ARRAY( C ), POLYBENCH_ARRAY( D ) ); /* Run kernel. */ kernel_2mm ( ni, nj, nk, nl, alpha, beta, POLYBENCH_ARRAY( tmp ), POLYBENCH_ARRAY( A ), POLYBENCH_ARRAY( B ), POLYBENCH_ARRAY( C ), POLYBENCH_ARRAY( D ) ); /* 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( D ) ) ); /* Be clean. */ POLYBENCH_FREE_ARRAY( tmp ); POLYBENCH_FREE_ARRAY( A ); POLYBENCH_FREE_ARRAY( B ); POLYBENCH_FREE_ARRAY( C ); POLYBENCH_FREE_ARRAY( D ); return 0; }

pr64769.c

/* PR tree-optimization/64769 */ /* { dg-do compile } */ /* { dg-options "-fopenmp-simd" } */ #pragma omp declare simd linear(i) void foo (int i) { }

pqECDSA_verify.c

/* Name: pqECDSA_verify.c Author: Tan Teik Guan Description: Verify function for pq resistance for ECDSA using ZKBoo. Modified from MPC_SHA256_VERIFIER.c */ /* ============================================================================ Name : MPC_SHA256_VERIFIER.c Author : Sobuno Version : 0.1 Description : Verifies a proof for SHA-256 generated by MPC_SHA256.c ============================================================================ */ #include <stdbool.h> #include <stdint.h> #include <stdio.h> #include <stdlib.h> #include <string.h> #include <sys/time.h> #include "pqECDSA_shared.h" int NUM_ROUNDS = 100; int numLoops = 1; void printbits(uint32_t n) { if (n) { printbits(n >> 1); printf("%d", n & 1); } } int main(int argc, char * argv[]) { setbuf(stdout, NULL); init_EVP(); openmp_thread_setup(); unsigned char tbs[MSG_SIZE]; unsigned char r[MSG_SIZE]; unsigned char S[MSG_SIZE]; int i; if (argc != 5) { printf("Usage: %s <number of rounds (e.g. 20, 40, 60, 80, 100)> <to be signed (Hex 64 char)> <Signature r (Hex 64 char)> <Signature s (Hex 64 char)\n",argv[0]); return -1; } NUM_ROUNDS = atoi(argv[1]); hexToBin32(argv[2],tbs); hexToBin32(argv[3],r); hexToBin32(argv[4],S); printf("Iterations of SHA: %d\n", NUM_ROUNDS); a as[NUM_ROUNDS]; z zs[NUM_ROUNDS]; FILE *file; char outputFile[3*sizeof(int) + 8]; sprintf(outputFile, "ECDSA%i.bin", NUM_ROUNDS); file = fopen(outputFile, "rb"); if (!file) { printf("Unable to open file!"); return -1; } fread(&as, sizeof(a), NUM_ROUNDS, file); fread(&zs, sizeof(z), NUM_ROUNDS, file); fclose(file); struct timeval begin, delta; gettimeofday(&begin,NULL); for (int loops=0;loops<numLoops;loops++) { int err = 0; uint32_t y[32]; for (int i = 0; i< 32; i++) y[i] = as[0].yp[0][i]^as[0].yp[1][i]^as[0].yp[2][i]; int es[NUM_ROUNDS*2]; H3(y,as, NUM_ROUNDS, es); #pragma omp parallel for for(int i = 0; i<(NUM_ROUNDS); i++) { unsigned char bufx[32],bufy[32]; MP_INT bigS,bigr; MP_INT Pubx,Puby; MP_INT bigu1,bigu2; MP_INT bigGx, bigGy; MP_INT biginvS; MP_INT bigH,mod; err = 0; mpz_init(&bigS); mpz_init(&bigr); mpz_init(&Pubx); mpz_init(&Puby); ecReconstruct(&(as[i].yp[0][0]),&(as[i].yp[1][0]),&(as[i].yp[2][0]),&(as[i].yp[0][8]),&(as[i].yp[1][8]),&(as[i].yp[2][8]),bufx,bufy); mpz_import(&Pubx,32,1,1,0,0,bufx); mpz_import(&Puby,32,1,1,0,0,bufy); mpz_import(&bigr,8,1,4,0,0,&(as[0].yp[0][16])); mpz_import(&bigS,32,1,1,0,0,r); if (mpz_cmp(&bigr,&bigS)) { printf("signature r does not match: "); mpz_out_str(stdout,16,&bigr); printf("vs "); mpz_out_str(stdout,16,&bigS); printf("\n"); err |= 1; } reconstruct(&(as[0].yp[0][24]),&(as[0].yp[1][24]),&(as[0].yp[2][24]),bufx); mpz_import(&bigS,32,1,1,0,0,bufx); for (int i=0; i<32;i++) { if (bufx[i] != S[i]) { printf("signature S at byte %d [%02X][%02x] does not match\n",i,bufx[i],S[i]); err |= 2; } } // printf("verifying signature for ECDSA(tbs): "); mpz_init(&biginvS); mpz_init(&bigu1); mpz_init(&bigu2); mpz_init(&bigH); mpz_import(&bigH,32,1,1,0,0,tbs); mpz_init_set_str(&mod,CURVE_N,16); ecInvMod(&biginvS,&bigS,&mod); mpz_mul(&bigu1,&bigH,&biginvS); mpz_mod(&bigu1,&bigu1,&mod); mpz_mul(&bigu2,&bigr,&biginvS); mpz_mod(&bigu2,&bigu2,&mod); mpz_init_set_str(&bigGx,CURVE_Gx,16); mpz_init_set_str(&bigGy,CURVE_Gy,16); ecMul(&bigGx,&bigGy,&bigu1); ecMul(&Pubx,&Puby,&bigu2); ecAddPoint(&bigGx,&bigGy,&Pubx,&Puby); mpz_mod(&bigGx,&bigGx,&mod); if (mpz_cmp(&bigGx,&bigr)) { printf("invalid r. computed r : "); mpz_out_str(stdout,16,&bigGx); printf("\n"); err |= 4; } if (!err) { int verifyResult = verify(as[i], es[i], zs[i]); if (verifyResult != 0) { printf("round [%d] : Not Verified rc = %d\n", i, verifyResult); } else { printf("round [%d] ok \n",i); } } else printf("round [%d] error code = %d\n",i,err); mpz_clear(&biginvS); mpz_clear(&bigu1); mpz_clear(&bigu2); mpz_clear(&bigH); mpz_clear(&bigS); mpz_clear(&bigr); mpz_clear(&Pubx); mpz_clear(&Puby); mpz_clear(&mod); mpz_clear(&bigGx); mpz_clear(&bigGy); } } gettimeofday(&delta,NULL); unsigned long inMilli = (delta.tv_sec - begin.tv_sec)*1000000 + (delta.tv_usec - begin.tv_usec); inMilli /= 1000; printf("Total time for %d loops of %d rounds: %ju miliseconds\n", numLoops,NUM_ROUNDS,(uintmax_t)inMilli); printf("Time taken for 1 loops: %ju miliseconds\n", (uintmax_t)inMilli/numLoops); openmp_thread_cleanup(); cleanup_EVP(); return EXIT_SUCCESS; }

grid.c

/* Copyright 2014-2015 The Regents of the University of California. * Copyright 2015-2018 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. * * 2011, 2015, 2018 Martin Uecker <martin.uecker@med.uni-goettingen.de> * 2014 Frank Ong <frankong@berkeley.edu> */ #include <math.h> #include <complex.h> #include <assert.h> #include <string.h> #include "num/multind.h" #include "num/flpmath.h" #include "num/specfun.h" #include "misc/nested.h" #include "misc/misc.h" #include "grid.h" #define KB_BETA 13.9086 // 13.8551 // 2x oversampling #define KB_WIDTH 3 #ifndef KB128 static double kb(double beta, double x) { if (fabs(x) >= 0.5) return 0.; return bessel_i0(beta * sqrt(1. - pow(2. * x, 2.))) / bessel_i0(beta); } static void kb_precompute(double beta, int n, float table[n + 1]) { for (int i = 0; i < n + 1; i++) table[i] = kb(beta, (double)(i) / (double)(n - 1) / 2.); } #endif static double I0_beta(double beta) { #ifndef KB128 return bessel_i0(beta); #else assert(KB_BETA == beta); return 118509.158946; #endif } const float kb_table128[129] = { 1.0000000000000000, 0.9995847139398653, 0.9983398161018390, 0.9962681840754728, 0.9933746024007669, 0.9896657454602714, 0.9851501536396374, 0.9798382028675283, 0.9737420676763386, 0.9668756779551011, 0.9592546695947362, 0.9508963292536357, 0.9418195334980564, 0.9320446825968820, 0.9215936292739139, 0.9104896027426631, 0.8987571283688524, 0.8864219433239096, 0.8735109086091393, 0.8600519178443380, 0.8460738032267725, 0.8316062390762707, 0.8166796433899514, 0.8013250778354499, 0.7855741466147803, 0.7694588946318385, 0.7530117053952898, 0.7362651990850234, 0.7192521312046796, 0.7020052922349470, 0.6845574086924412, 0.6669410459871208, 0.6491885134575039, 0.6313317719473744, 0.6134023442704702, 0.5954312288909031, 0.5774488171268115, 0.5594848141632452, 0.5415681641375969, 0.5237269795371914, 0.5059884751240438, 0.4883789065765270, 0.4709235140117633, 0.4536464705263341, 0.4365708358662894, 0.4197185153108639, 0.4031102238276424, 0.3867654555305848, 0.3707024584462233, 0.3549382145678427, 0.3394884251524746, 0.3243675011914082, 0.3095885589616078, 0.2951634205431575, 0.2811026191666483, 0.2674154092344597, 0.2541097808412017, 0.2411924786012657, 0.2286690245755740, 0.2165437450752543, 0.2048198011071496, 0.1934992222148726, 0.1825829434594916, 0.1720708452759937, 0.1619617959353290, 0.1522536963371723, 0.1429435268554672, 0.1340273959573592, 0.1255005903162311, 0.1173576261411828, 0.1095923014483913, 0.1021977490043101, 0.0951664896765205, 0.0884904859351842, 0.0821611952563688, 0.0761696231879639, 0.0705063758493464, 0.0651617116473479, 0.0601255920032731, 0.0553877308986640, 0.0509376430610617, 0.0467646906251106, 0.0428581281188566, 0.0392071456399203, 0.0358009101012748, 0.0326286044415178, 0.0296794647097185, 0.0269428149500251, 0.0244080998261697, 0.0220649149406994, 0.0199030348181235, 0.0179124385351197, 0.0160833329944038, 0.0144061738517878, 0.0128716841182598, 0.0114708704705587, 0.0101950373146533, 0.0090357986567118, 0.0079850878455423, 0.0070351652590612, 0.0061786240150858, 0.0054083937936397, 0.0047177428639869, 0.0041002784147792, 0.0035499452900106, 0.0030610232369345, 0.0026281227747268, 0.0022461797944939, 0.0019104490022500, 0.0016164963167613, 0.0013601903336964, 0.0011376929663821, 0.0009454493716780, 0.0007801772670918, 0.0006388557423128, 0.0005187136648862, 0.0004172177758400, 0.0003320605667526, 0.0002611480250751, 0.0002025873295356, 0.0001546745722200, 0.0001158825784783, 0.0000848488902175, 0.0000603639724392, 0.0000413596971257, 0.0000268981528101, 0.0000161608224276, 0.0000000000000000, 0.0000000000000000, }; static double ftkb(double beta, double x) { double a = sqrt(pow(beta, 2.) - pow(M_PI * x, 2.)); return ((0. == a) ? 1. : (sinh(a) / a)) / I0_beta(beta); } static float rolloff(float x, double beta, float width) { return (float)ftkb(beta, x * width) / ftkb(beta, 0.); } // Linear interpolation static float lerp(float a, float b, float c) { return (1. - c) * a + c * b; } // Linear interpolation look up static float intlookup(int n, const float table[n + 1], float x) { float fpart; // fpart = modff(x * n, &ipart); // int index = ipart; int index = (int)(x * (n - 1)); fpart = x * (n - 1) - (float)index; #if 1 assert(index >= 0); assert(index <= n); assert(fpart >= 0.); assert(fpart <= 1.); #endif float l = lerp(table[index], table[index + 1], fpart); #if 1 assert(l <= 1.); assert(0 >= 0.); #endif return l; } void gridH(const struct grid_conf_s* conf, const complex float* traj, const long ksp_dims[4], complex float* dst, const long grid_dims[4], const complex float* grid) { long C = ksp_dims[3]; #ifndef KB128 // precompute kaiser bessel table int kb_size = 500; float kb_table[kb_size + 1]; kb_precompute(conf->beta, kb_size, kb_table); #else assert(KB_BETA == beta); int kb_size = 128; const float* kb_table = kb_table128; #endif assert(1 == ksp_dims[0]); long samples = ksp_dims[1] * ksp_dims[2]; #pragma omp parallel for for(int i = 0; i < samples; i++) { float pos[3]; pos[0] = conf->os * (creal(traj[i * 3 + 0])); pos[1] = conf->os * (creal(traj[i * 3 + 1])); pos[2] = conf->os * (creal(traj[i * 3 + 2])); pos[0] += (grid_dims[0] > 1) ? ((float)grid_dims[0] / 2.) : 0.; pos[1] += (grid_dims[1] > 1) ? ((float)grid_dims[1] / 2.) : 0.; pos[2] += (grid_dims[2] > 1) ? ((float)grid_dims[2] / 2.) : 0.; complex float val[C]; for (int j = 0; j < C; j++) val[j] = 0.0; grid_pointH(C, 3, grid_dims, pos, val, grid, conf->periodic, conf->width, kb_size, kb_table); for (int j = 0; j < C; j++) dst[j * samples + i] += val[j]; } } void grid(const struct grid_conf_s* conf, const complex float* traj, const long grid_dims[4], complex float* grid, const long ksp_dims[4], const complex float* src) { long C = ksp_dims[3]; #ifndef KB128 // precompute kaiser bessel table int kb_size = 500; float kb_table[kb_size + 1]; kb_precompute(conf->beta, kb_size, kb_table); #else assert(KB_BETA == beta); int kb_size = 128; const float* kb_table = kb_table128; #endif assert(1 == ksp_dims[0]); long samples = ksp_dims[1] * ksp_dims[2]; // grid #pragma omp parallel for for(int i = 0; i < samples; i++) { float pos[3]; pos[0] = conf->os * (creal(traj[i * 3 + 0])); pos[1] = conf->os * (creal(traj[i * 3 + 1])); pos[2] = conf->os * (creal(traj[i * 3 + 2])); pos[0] += (grid_dims[0] > 1) ? ((float) grid_dims[0] / 2.) : 0.; pos[1] += (grid_dims[1] > 1) ? ((float) grid_dims[1] / 2.) : 0.; pos[2] += (grid_dims[2] > 1) ? ((float) grid_dims[2] / 2.) : 0.; complex float val[C]; for (int j = 0; j < C; j++) val[j] = src[j * samples + i]; grid_point(C, 3, grid_dims, pos, grid, val, conf->periodic, conf->width, kb_size, kb_table); } } static void grid2_dims(unsigned int D, const long trj_dims[D], const long ksp_dims[D], const long grid_dims[D]) { assert(D >= 4); assert(md_check_compat(D - 3, ~0, grid_dims + 3, ksp_dims + 3)); // assert(md_check_compat(D - 3, ~(MD_BIT(0) | MD_BIT(1)), trj_dims + 3, ksp_dims + 3)); assert(md_check_bounds(D - 3, ~0, trj_dims + 3, ksp_dims + 3)); assert(3 == trj_dims[0]); assert(1 == trj_dims[3]); assert(1 == ksp_dims[0]); } void grid2(const struct grid_conf_s* conf, unsigned int D, const long trj_dims[D], const complex float* traj, const long grid_dims[D], complex float* dst, const long ksp_dims[D], const complex float* src) { grid2_dims(D, trj_dims, ksp_dims, grid_dims); long ksp_strs[D]; md_calc_strides(D, ksp_strs, ksp_dims, CFL_SIZE); long trj_strs[D]; md_calc_strides(D, trj_strs, trj_dims, CFL_SIZE); long grid_strs[D]; md_calc_strides(D, grid_strs, grid_dims, CFL_SIZE); long pos[D]; for (unsigned int i = 0; i < D; i++) pos[i] = 0; do { grid(conf, &MD_ACCESS(D, trj_strs, pos, traj), grid_dims, &MD_ACCESS(D, grid_strs, pos, dst), ksp_dims, &MD_ACCESS(D, ksp_strs, pos, src)); } while(md_next(D, ksp_dims, (~0 ^ 15), pos)); } void grid2H(const struct grid_conf_s* conf, unsigned int D, const long trj_dims[D], const complex float* traj, const long ksp_dims[D], complex float* dst, const long grid_dims[D], const complex float* src) { grid2_dims(D, trj_dims, ksp_dims, grid_dims); long ksp_strs[D]; md_calc_strides(D, ksp_strs, ksp_dims, CFL_SIZE); long trj_strs[D]; md_calc_strides(D, trj_strs, trj_dims, CFL_SIZE); long grid_strs[D]; md_calc_strides(D, grid_strs, grid_dims, CFL_SIZE); long pos[D]; for (unsigned int i = 0; i < D; i++) pos[i] = 0; do { gridH(conf, &MD_ACCESS(D, trj_strs, pos, traj), ksp_dims, &MD_ACCESS(D, ksp_strs, pos, dst), grid_dims, &MD_ACCESS(D, grid_strs, pos, src)); } while(md_next(D, ksp_dims, (~0 ^ 15), pos)); } typedef void CLOSURE_TYPE(grid_update_t)(int ind, float d); #ifndef __clang__ #define VLA(x) x #else // blocks extension does not play well even with arguments which // just look like variably-modified types #define VLA(x) #endif static void grid_point_gen(int N, const long dims[VLA(N)], const float pos[VLA(N)], bool periodic, float width, int kb_size, const float kb_table[VLA(kb_size + 1)], grid_update_t update) { #ifndef __clang__ int sti[N]; int eni[N]; int off[N]; #else // blocks extension does not play well with variably-modified types int* sti = alloca(sizeof(int[N])); int* eni = alloca(sizeof(int[N])); int* off = alloca(sizeof(int[N])); #endif for (int j = 0; j < N; j++) { sti[j] = (int)ceil(pos[j] - width); eni[j] = (int)floor(pos[j] + width); off[j] = 0; if (sti[j] > eni[j]) return; if (!periodic) { sti[j] = MAX(sti[j], 0); eni[j] = MIN(eni[j], dims[j] - 1); } else { while (sti[j] + off[j] < 0) off[j] += dims[j]; } if (1 == dims[j]) { assert(0. == pos[j]); // ==0. fails nondeterministically for test_nufft_forward bbdec08cb sti[j] = 0; eni[j] = 0; } } __block NESTED(void, grid_point_r, (int N, int ind, float d)) // __block for recursion { if (0 == N) { update(ind, d); } else { N--; for (int w = sti[N]; w <= eni[N]; w++) { float frac = fabs(((float)w - pos[N])); float d2 = d * intlookup(kb_size, kb_table, frac / width); int ind2 = (ind * dims[N] + ((w + off[N]) % dims[N])); grid_point_r(N, ind2, d2); } } }; grid_point_r(N, 0, 1.); } void grid_point(unsigned int ch, int N, const long dims[VLA(N)], const float pos[VLA(N)], complex float* dst, const complex float val[VLA(ch)], bool periodic, float width, int kb_size, const float kb_table[kb_size + 1]) { NESTED(void, update, (int ind, float d)) { for (unsigned int c = 0; c < ch; c++) { // we are allowed to update real and imaginary part independently which works atomically #pragma omp atomic __real(dst[ind + c * dims[0] * dims[1] * dims[2]]) += __real(val[c]) * d; #pragma omp atomic __imag(dst[ind + c * dims[0] * dims[1] * dims[2]]) += __imag(val[c]) * d; } }; grid_point_gen(N, dims, pos, periodic, width, kb_size, kb_table, update); } void grid_pointH(unsigned int ch, int N, const long dims[VLA(N)], const float pos[VLA(N)], complex float val[VLA(ch)], const complex float* src, bool periodic, float width, int kb_size, const float kb_table[kb_size + 1]) { NESTED(void, update, (int ind, float d)) { for (unsigned int c = 0; c < ch; c++) { // we are allowed to update real and imaginary part independently which works atomically #pragma omp atomic __real(val[c]) += __real(src[ind + c * dims[0] * dims[1] * dims[2]]) * d; #pragma omp atomic __imag(val[c]) += __imag(src[ind + c * dims[0] * dims[1] * dims[2]]) * d; } }; grid_point_gen(N, dims, pos, periodic, width, kb_size, kb_table, update); } double calc_beta(float os, float width) { return M_PI * sqrt(pow((width * 2. / os) * (os - 0.5), 2.) - 0.8); } static float pos(int d, int i) { return (1 == d) ? 0. : (((float)i - (float)d / 2.) / (float)d); } void rolloff_correction(float os, float width, float beta, const long dimensions[3], complex float* dst) { UNUSED(os); #pragma omp parallel for collapse(3) for (int z = 0; z < dimensions[2]; z++) for (int y = 0; y < dimensions[1]; y++) for (int x = 0; x < dimensions[0]; x++) dst[x + dimensions[0] * (y + z * dimensions[1])] = 1. / ( rolloff(pos(dimensions[0], x), beta, width) * rolloff(pos(dimensions[1], y), beta, width) * rolloff(pos(dimensions[2], z), beta, width) ); }

GB_unop__cos_fp64_fp64.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 Generated2/ folder, do not edit it // (it is auto-generated from Generator/*). #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__cos_fp64_fp64) // op(A') function: GB (_unop_tran__cos_fp64_fp64) // C type: double // A type: double // cast: double cij = aij // unaryop: cij = cos (aij) #define GB_ATYPE \ double #define GB_CTYPE \ double // aij = Ax [pA] #define GB_GETA(aij,Ax,pA) \ double aij = Ax [pA] #define GB_CX(p) Cx [p] // unary operator #define GB_OP(z, x) \ z = cos (x) ; // casting #define GB_CAST(z, aij) \ double z = aij ; // cij = op (aij) #define GB_CAST_OP(pC,pA) \ { \ /* aij = Ax [pA] */ \ double aij = Ax [pA] ; \ /* Cx [pC] = op (cast (aij)) */ \ double z = aij ; \ Cx [pC] = cos (z) ; \ } // disable this operator and use the generic case if these conditions hold #define GB_DISABLE \ (GxB_NO_COS || GxB_NO_FP64) //------------------------------------------------------------------------------ // Cx = op (cast (Ax)): apply a unary operator //------------------------------------------------------------------------------ GrB_Info GB (_unop_apply__cos_fp64_fp64) ( double *Cx, // Cx and Ax may be aliased const double *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 ; if (Ab == NULL) { #pragma omp parallel for num_threads(nthreads) schedule(static) for (p = 0 ; p < anz ; p++) { double aij = Ax [p] ; double z = aij ; Cx [p] = cos (z) ; } } 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 ; double aij = Ax [p] ; double z = aij ; Cx [p] = cos (z) ; } } return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // C = op (cast (A')): transpose, typecast, and apply a unary operator //------------------------------------------------------------------------------ GrB_Info GB (_unop_tran__cos_fp64_fp64) ( 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

linAlgAXMY.c

/* The MIT License (MIT) Copyright (c) 2017 Tim Warburton, Noel Chalmers, Jesse Chan, Ali Karakus 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. */ extern "C" void FUNC(axmy)(const dlong & N, const dfloat& alpha, const dfloat * __restrict__ cpu_w, dfloat * __restrict__ cpu_a){ #ifdef __NEKRS__OMP__ #pragma omp parallel for #endif for(int i=0;i<N;++i){ const dfloat ai = cpu_a[i]; const dfloat wi = cpu_w[i]; cpu_a[i] = alpha*ai*wi; } } extern "C" void FUNC(axmyMany)(const dlong & N, const dlong & Nfields, const dlong & offset, const dlong & mode, const dfloat & alpha, const dfloat * __restrict__ cpu_w, dfloat * __restrict__ cpu_a){ #ifdef __NEKRS__OMP__ #pragma omp parallel for collapse(2) #endif for(int fld=0;fld<Nfields;fld++) { for(int i=0;i<N;++i){ const dlong id = i + fld*offset; const dfloat ai = cpu_a[id]; const dfloat wi = cpu_w[i + mode * fld * offset]; cpu_a[id] = alpha*ai*wi; } } } extern "C" void FUNC(axmyVector)(const dlong & N, const dlong & offset, const dlong & mode, const dfloat & alpha, const dfloat * __restrict__ cpu_w, dfloat * __restrict__ cpu_a){ #ifdef __NEKRS__OMP__ #pragma omp parallel for collapse(2) #endif for(int fld=0;fld<p_NVec;fld++) { for(int i=0;i<N;++i){ const dlong id = i + fld*offset; const dfloat ai = cpu_a[id]; const dfloat wi = cpu_w[i + mode * fld * offset]; cpu_a[id] = alpha*ai*wi; } } }

GB_unaryop__identity_uint8_uint16.c

//------------------------------------------------------------------------------ // GB_unaryop: hard-coded functions for each built-in unary operator //------------------------------------------------------------------------------ // SuiteSparse:GraphBLAS, Timothy A. Davis, (c) 2017-2019, 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_uint8_uint16 // op(A') function: GB_tran__identity_uint8_uint16 // C type: uint8_t // A type: uint16_t // cast: uint8_t cij = (uint8_t) aij // unaryop: cij = aij #define GB_ATYPE \ uint16_t #define GB_CTYPE \ uint8_t // aij = Ax [pA] #define GB_GETA(aij,Ax,pA) \ uint16_t aij = Ax [pA] #define GB_CX(p) Cx [p] // unary operator #define GB_OP(z, x) \ z = x ; // casting #define GB_CASTING(z, x) \ uint8_t z = (uint8_t) x ; // 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 (x, aij) ; \ GB_OP (GB_CX (pC), x) ; \ } // disable this operator and use the generic case if these conditions hold #define GB_DISABLE \ (GxB_NO_IDENTITY || GxB_NO_UINT8 || GxB_NO_UINT16) //------------------------------------------------------------------------------ // Cx = op (cast (Ax)): apply a unary operator //------------------------------------------------------------------------------ GrB_Info GB_unop__identity_uint8_uint16 ( uint8_t *restrict Cx, const uint16_t *restrict Ax, int64_t anz, int nthreads ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else #pragma omp parallel for num_threads(nthreads) schedule(static) for (int64_t 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_uint8_uint16 ( GrB_Matrix C, const GrB_Matrix A, int64_t *restrict *Rowcounts, GBI_single_iterator Iter, const int64_t *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

GB_unaryop__minv_int32_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__minv_int32_uint64 // op(A') function: GB_tran__minv_int32_uint64 // C type: int32_t // A type: uint64_t // cast: int32_t cij = (int32_t) aij // unaryop: cij = GB_IMINV_SIGNED (aij, 32) #define GB_ATYPE \ uint64_t #define GB_CTYPE \ int32_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 = GB_IMINV_SIGNED (x, 32) ; // casting #define GB_CASTING(z, aij) \ int32_t z = (int32_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_MINV || GxB_NO_INT32 || GxB_NO_UINT64) //------------------------------------------------------------------------------ // Cx = op (cast (Ax)): apply a unary operator //------------------------------------------------------------------------------ GrB_Info GB_unop__minv_int32_uint64 ( int32_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__minv_int32_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

lsh_index.h

/*********************************************************************** * Software License Agreement (BSD License) * * Copyright 2008-2009 Marius Muja (mariusm@cs.ubc.ca). All rights reserved. * Copyright 2008-2009 David G. Lowe (lowe@cs.ubc.ca). All rights reserved. * * THE BSD LICENSE * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. 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. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``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 AUTHOR 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: Vincent Rabaud *************************************************************************/ #ifndef FLANN_LSH_INDEX_H_ #define FLANN_LSH_INDEX_H_ #include <algorithm> #include <cassert> #include <cstring> #include <map> #include <vector> #include "flann/general.h" #include "flann/algorithms/nn_index.h" #include "flann/util/matrix.h" #include "flann/util/result_set.h" #include "flann/util/heap.h" #include "flann/util/lsh_table.h" #include "flann/util/allocator.h" #include "flann/util/random.h" #include "flann/util/saving.h" namespace flann { struct LshIndexParams : public IndexParams { LshIndexParams(unsigned int table_number = 12, unsigned int key_size = 20, unsigned int multi_probe_level = 2) { (* this)["algorithm"] = FLANN_INDEX_LSH; // The number of hash tables to use (*this)["table_number"] = table_number; // The length of the key in the hash tables (*this)["key_size"] = key_size; // Number of levels to use in multi-probe (0 for standard LSH) (*this)["multi_probe_level"] = multi_probe_level; } }; /** * Randomized kd-tree index * * Contains the k-d trees and other information for indexing a set of points * for nearest-neighbor matching. */ template<typename Distance> class LshIndex : public NNIndex<Distance> { public: typedef typename Distance::ElementType ElementType; typedef typename Distance::ResultType DistanceType; typedef Eigen::Matrix<ElementType, Eigen::Dynamic, Eigen::Dynamic> MatrixType; typedef Eigen::Matrix<ElementType, Eigen::Dynamic, 1> VectorType; typedef Eigen::Matrix<DistanceType, Eigen::Dynamic, Eigen::Dynamic> DistanceMatrix; typedef Eigen::Matrix<DistanceType, Eigen::Dynamic, 1> DistanceVector; typedef Eigen::Matrix<size_t, Eigen::Dynamic, Eigen::Dynamic> IndexMatrix; typedef Eigen::Matrix<size_t, Eigen::Dynamic, 1> IndexVector; typedef NNIndex<Distance> BaseClass; /** Constructor * @param params parameters passed to the LSH algorithm * @param d the distance used */ LshIndex(const IndexParams& params = LshIndexParams(), Distance d = Distance()) : BaseClass(params, d) { table_number_ = get_param<unsigned int>(index_params_,"table_number",12); key_size_ = get_param<unsigned int>(index_params_,"key_size",20); multi_probe_level_ = get_param<unsigned int>(index_params_,"multi_probe_level",2); fill_xor_mask(0, key_size_, multi_probe_level_, xor_masks_); } /** Constructor * @param input_data dataset with the input features * @param params parameters passed to the LSH algorithm * @param d the distance used */ LshIndex(const Matrix<ElementType>& input_data, const IndexParams& params = LshIndexParams(), Distance d = Distance()) : BaseClass(params, d) { table_number_ = get_param<unsigned int>(index_params_,"table_number",12); key_size_ = get_param<unsigned int>(index_params_,"key_size",20); multi_probe_level_ = get_param<unsigned int>(index_params_,"multi_probe_level",2); fill_xor_mask(0, key_size_, multi_probe_level_, xor_masks_); setDataset(input_data); } LshIndex(const LshIndex& other) : BaseClass(other), tables_(other.tables_), table_number_(other.table_number_), key_size_(other.key_size_), multi_probe_level_(other.multi_probe_level_), xor_masks_(other.xor_masks_) { } LshIndex& operator=(LshIndex other) { this->swap(other); return *this; } virtual ~LshIndex() { freeIndex(); } BaseClass* clone() const { return new LshIndex(*this); } using BaseClass::buildIndex; void addPoints(const Matrix<ElementType>& points, float rebuild_threshold = 2) { assert(points.cols==veclen_); size_t old_size = size_; extendDataset(points); if (rebuild_threshold>1 && size_at_build_*rebuild_threshold<size_) { buildIndex(); } else { for (unsigned int i = 0; i < table_number_; ++i) { lsh::LshTable<ElementType>& table = tables_[i]; for (size_t i=old_size;i<size_;++i) { table.add(i, points_[i]); } } } } flann_algorithm_t getType() const { return FLANN_INDEX_LSH; } template<typename Archive> void serialize(Archive& ar) { ar.setObject(this); ar & *static_cast<NNIndex<Distance>*>(this); ar & table_number_; ar & key_size_; ar & multi_probe_level_; ar & xor_masks_; ar & tables_; if (Archive::is_loading::value) { index_params_["algorithm"] = getType(); index_params_["table_number"] = table_number_; index_params_["key_size"] = key_size_; index_params_["multi_probe_level"] = multi_probe_level_; } } void saveIndex(FILE* stream) { serialization::SaveArchive sa(stream); sa & *this; } void loadIndex(FILE* stream) { serialization::LoadArchive la(stream); la & *this; } /** * Computes the index memory usage * Returns: memory used by the index */ int usedMemory() const { return size_ * sizeof(int); } /** * \brief Perform k-nearest neighbor search * \param[in] queries The query points for which to find the nearest neighbors * \param[out] indices The indices of the nearest neighbors found * \param[out] dists Distances to the nearest neighbors found * \param[in] knn Number of nearest neighbors to return * \param[in] params Search parameters */ int knnSearch(const Matrix<ElementType>& queries, Matrix<size_t>& indices, Matrix<DistanceType>& dists, size_t knn, const SearchParams& params) const { assert(queries.cols == veclen_); assert(indices.rows >= queries.rows); assert(dists.rows >= queries.rows); assert(indices.cols >= knn); assert(dists.cols >= knn); int count = 0; if (params.use_heap==FLANN_True) { #pragma omp parallel num_threads(params.cores) { KNNUniqueResultSet<DistanceType> resultSet(knn); #pragma omp for schedule(static) reduction(+:count) for (int i = 0; i < (int)queries.rows; i++) { resultSet.clear(); findNeighbors(resultSet, queries[i], params); size_t n = std::min(resultSet.size(), knn); resultSet.copy(indices[i], dists[i], n, params.sorted); indices_to_ids(indices[i], indices[i], n); count += n; } } } else { #pragma omp parallel num_threads(params.cores) { KNNResultSet<DistanceType> resultSet(knn); #pragma omp for schedule(static) reduction(+:count) for (int i = 0; i < (int)queries.rows; i++) { resultSet.clear(); findNeighbors(resultSet, queries[i], params); size_t n = std::min(resultSet.size(), knn); resultSet.copy(indices[i], dists[i], n, params.sorted); indices_to_ids(indices[i], indices[i], n); count += n; } } } return count; } /** * \brief Perform k-nearest neighbor search * \param[in] queries The query points for which to find the nearest neighbors * \param[out] indices The indices of the nearest neighbors found * \param[out] dists Distances to the nearest neighbors found * \param[in] knn Number of nearest neighbors to return * \param[in] params Search parameters */ int knnSearch(const Matrix<ElementType>& queries, std::vector< std::vector<size_t> >& indices, std::vector<std::vector<DistanceType> >& dists, size_t knn, const SearchParams& params) const { assert(queries.cols == veclen_); if (indices.size() < queries.rows ) indices.resize(queries.rows); if (dists.size() < queries.rows ) dists.resize(queries.rows); int count = 0; if (params.use_heap==FLANN_True) { #pragma omp parallel num_threads(params.cores) { KNNUniqueResultSet<DistanceType> resultSet(knn); #pragma omp for schedule(static) reduction(+:count) for (int i = 0; i < (int)queries.rows; i++) { resultSet.clear(); findNeighbors(resultSet, queries[i], params); size_t n = std::min(resultSet.size(), knn); indices[i].resize(n); dists[i].resize(n); if (n > 0) { resultSet.copy(&indices[i][0], &dists[i][0], n, params.sorted); indices_to_ids(&indices[i][0], &indices[i][0], n); } count += n; } } } else { #pragma omp parallel num_threads(params.cores) { KNNResultSet<DistanceType> resultSet(knn); #pragma omp for schedule(static) reduction(+:count) for (int i = 0; i < (int)queries.rows; i++) { resultSet.clear(); findNeighbors(resultSet, queries[i], params); size_t n = std::min(resultSet.size(), knn); indices[i].resize(n); dists[i].resize(n); if (n > 0) { resultSet.copy(&indices[i][0], &dists[i][0], n, params.sorted); indices_to_ids(&indices[i][0], &indices[i][0], n); } count += n; } } } return count; } /** * Find set of nearest neighbors to vec. Their indices are stored inside * the result object. * * Params: * result = the result object in which the indices of the nearest-neighbors are stored * vec = the vector for which to search the nearest neighbors * maxCheck = the maximum number of restarts (in a best-bin-first manner) */ void findNeighbors(ResultSet<DistanceType>& result, const ElementType* vec, const SearchParams& /*searchParams*/) const { getNeighbors(vec, result); } protected: /** * Builds the index */ void buildIndexImpl() { tables_.resize(table_number_); std::vector<std::pair<size_t,ElementType*> > features; features.reserve(points_.size()); for (size_t i=0;i<points_.size();++i) { features.push_back(std::make_pair(i, points_[i])); } for (unsigned int i = 0; i < table_number_; ++i) { lsh::LshTable<ElementType>& table = tables_[i]; table = lsh::LshTable<ElementType>(veclen_, key_size_); // Add the features to the table table.add(features); } } void freeIndex() { /* nothing to do here */ } private: /** Defines the comparator on score and index */ typedef std::pair<float, unsigned int> ScoreIndexPair; struct SortScoreIndexPairOnSecond { bool operator()(const ScoreIndexPair& left, const ScoreIndexPair& right) const { return left.second < right.second; } }; /** Fills the different xor masks to use when getting the neighbors in multi-probe LSH * @param key the key we build neighbors from * @param lowest_index the lowest index of the bit set * @param level the multi-probe level we are at * @param xor_masks all the xor mask */ void fill_xor_mask(lsh::BucketKey key, int lowest_index, unsigned int level, std::vector<lsh::BucketKey>& xor_masks) { xor_masks.push_back(key); if (level == 0) return; for (int index = lowest_index - 1; index >= 0; --index) { // Create a new key lsh::BucketKey new_key = key | (lsh::BucketKey(1) << index); fill_xor_mask(new_key, index, level - 1, xor_masks); } } /** Performs the approximate nearest-neighbor search. * @param vec the feature to analyze * @param do_radius flag indicating if we check the radius too * @param radius the radius if it is a radius search * @param do_k flag indicating if we limit the number of nn * @param k_nn the number of nearest neighbors * @param checked_average used for debugging */ void getNeighbors(const ElementType* vec, bool do_radius, float radius, bool do_k, unsigned int k_nn, float& checked_average) { static std::vector<ScoreIndexPair> score_index_heap; if (do_k) { unsigned int worst_score = std::numeric_limits<unsigned int>::max(); typename std::vector<lsh::LshTable<ElementType> >::const_iterator table = tables_.begin(); typename std::vector<lsh::LshTable<ElementType> >::const_iterator table_end = tables_.end(); for (; table != table_end; ++table) { size_t key = table->getKey(vec); std::vector<lsh::BucketKey>::const_iterator xor_mask = xor_masks_.begin(); std::vector<lsh::BucketKey>::const_iterator xor_mask_end = xor_masks_.end(); for (; xor_mask != xor_mask_end; ++xor_mask) { size_t sub_key = key ^ (*xor_mask); const lsh::Bucket* bucket = table->getBucketFromKey(sub_key); if (bucket == 0) continue; // Go over each descriptor index std::vector<lsh::FeatureIndex>::const_iterator training_index = bucket->begin(); std::vector<lsh::FeatureIndex>::const_iterator last_training_index = bucket->end(); DistanceType hamming_distance; // Process the rest of the candidates for (; training_index < last_training_index; ++training_index) { if (removed_ && removed_points_.test(*training_index)) continue; hamming_distance = distance_(vec, points_[*training_index].point, veclen_); if (hamming_distance < worst_score) { // Insert the new element score_index_heap.push_back(ScoreIndexPair(hamming_distance, training_index)); std::push_heap(score_index_heap.begin(), score_index_heap.end()); if (score_index_heap.size() > (unsigned int)k_nn) { // Remove the highest distance value as we have too many elements std::pop_heap(score_index_heap.begin(), score_index_heap.end()); score_index_heap.pop_back(); // Keep track of the worst score worst_score = score_index_heap.front().first; } } } } } } else { typename std::vector<lsh::LshTable<ElementType> >::const_iterator table = tables_.begin(); typename std::vector<lsh::LshTable<ElementType> >::const_iterator table_end = tables_.end(); for (; table != table_end; ++table) { size_t key = table->getKey(vec); std::vector<lsh::BucketKey>::const_iterator xor_mask = xor_masks_.begin(); std::vector<lsh::BucketKey>::const_iterator xor_mask_end = xor_masks_.end(); for (; xor_mask != xor_mask_end; ++xor_mask) { size_t sub_key = key ^ (*xor_mask); const lsh::Bucket* bucket = table->getBucketFromKey(sub_key); if (bucket == 0) continue; // Go over each descriptor index std::vector<lsh::FeatureIndex>::const_iterator training_index = bucket->begin(); std::vector<lsh::FeatureIndex>::const_iterator last_training_index = bucket->end(); DistanceType hamming_distance; // Process the rest of the candidates for (; training_index < last_training_index; ++training_index) { if (removed_ && removed_points_.test(*training_index)) continue; // Compute the Hamming distance hamming_distance = distance_(vec, points_[*training_index].point, veclen_); if (hamming_distance < radius) score_index_heap.push_back(ScoreIndexPair(hamming_distance, training_index)); } } } } } /** Performs the approximate nearest-neighbor search. * This is a slower version than the above as it uses the ResultSet * @param vec the feature to analyze */ void getNeighbors(const ElementType* vec, ResultSet<DistanceType>& result) const { typename std::vector<lsh::LshTable<ElementType> >::const_iterator table = tables_.begin(); typename std::vector<lsh::LshTable<ElementType> >::const_iterator table_end = tables_.end(); for (; table != table_end; ++table) { size_t key = table->getKey(vec); std::vector<lsh::BucketKey>::const_iterator xor_mask = xor_masks_.begin(); std::vector<lsh::BucketKey>::const_iterator xor_mask_end = xor_masks_.end(); for (; xor_mask != xor_mask_end; ++xor_mask) { size_t sub_key = key ^ (*xor_mask); const lsh::Bucket* bucket = table->getBucketFromKey(sub_key); if (bucket == 0) continue; // Go over each descriptor index std::vector<lsh::FeatureIndex>::const_iterator training_index = bucket->begin(); std::vector<lsh::FeatureIndex>::const_iterator last_training_index = bucket->end(); DistanceType hamming_distance; // Process the rest of the candidates for (; training_index < last_training_index; ++training_index) { if (removed_ && removed_points_.test(*training_index)) continue; // Compute the Hamming distance hamming_distance = distance_(vec, points_[*training_index], veclen_); result.addPoint(hamming_distance, *training_index); } } } } void swap(LshIndex& other) { BaseClass::swap(other); std::swap(tables_, other.tables_); std::swap(size_at_build_, other.size_at_build_); std::swap(table_number_, other.table_number_); std::swap(key_size_, other.key_size_); std::swap(multi_probe_level_, other.multi_probe_level_); std::swap(xor_masks_, other.xor_masks_); } /** The different hash tables */ std::vector<lsh::LshTable<ElementType> > tables_; /** table number */ unsigned int table_number_; /** key size */ unsigned int key_size_; /** How far should we look for neighbors in multi-probe LSH */ unsigned int multi_probe_level_; /** The XOR masks to apply to a key to get the neighboring buckets */ std::vector<lsh::BucketKey> xor_masks_; USING_BASECLASS_SYMBOLS }; } #endif //FLANN_LSH_INDEX_H_

DRB064-outeronly2-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. */ /* Only the outmost loop can be parallelized. The inner loop has loop carried true data dependence. However, the loop is not parallelized so no race condition. */ #include <omp.h> double b[100][100]; #define N 100 int init() { int i; int j; int k; #pragma omp parallel for private (i,j) for (i = 0; i <= 99; i += 1) { #pragma omp parallel for private (j) for (j = 0; j <= 99; j += 1) { b[i][j] = (i * j); } } return 0; } void foo(int n,int m) { int i; int j; #pragma omp parallel for private (i,j) firstprivate (n,m) for (i = 0; i <= n - 1; i += 1) { // Be careful about bounds of j for (j = 1; j <= m - 1; j += 1) { b[i][j] = b[i][j - 1]; } } } int print() { int i; int j; int k; for (i = 0; i <= 99; i += 1) { for (j = 0; j <= 99; j += 1) { printf("%lf\n",b[i][j]); } } return 0; } int main() { init(); foo(100,100); print(); return 0; }

main.c

#include <stdlib.h> #include <stdio.h> #include <omp.h> #include <string.h> int number_of_threads; double **A; double **L; double **U; void crout0(double **L, double **U, int n) { int i, j, k; double sum = 0; for (i = 0; i < n; i++) { U[i][i] = 1; } for (j = 0; j < n; j++) { for (i = j; i < n; i++) { sum = 0; for (k = 0; k < j; k++) { sum = sum + L[i][k] * U[k][j]; } L[i][j] = A[i][j] - sum; } for (i = j; i < n; i++) { sum = 0; for(k = 0; k < j; k++) { sum = sum + L[j][k] * U[k][i]; } if (L[j][j] == 0) { exit(0); } U[j][i] = (A[j][i] - sum) / L[j][j]; } } } void crout1(double **L, double **U, int n, int number_of_threads) { int i, j, k; double sum = 0; #pragma omp parallel for num_threads(number_of_threads) private(i) for (i = 0; i < n; i++) { U[i][i] = 1; } for (j = 0; j < n; j++) { #pragma omp parallel for num_threads(number_of_threads) private(i,k,sum) for (i = j; i < n; i++) { sum = 0; for (k = 0; k < j; k++) { sum = sum + L[i][k] * U[k][j]; } L[i][j] = A[i][j] - sum; } #pragma omp parallel for num_threads(number_of_threads) private(i,k,sum) for (int i = j; i < n; i++) { double sum = 0; for(int k = 0; k < j; k++) { sum = sum + L[j][k] * U[k][i]; } if (L[j][j] == 0) { exit(0); } U[j][i] = (A[j][i] - sum) / L[j][j]; } } } void crout2(double **L, double **U, int n, int number_of_threads) { int i,j,k; double sum = 0, sum1 = 0, sum2 = 0; #pragma omp parallel sections num_threads(number_of_threads) private(i) { #pragma omp section { for (i = 0; i < n/16; i++) U[i][i] = 1; } #pragma omp section { for (i = n/16; i < 2*n/16; i++) U[i][i] = 1; } #pragma omp section { for (i = 2*n/16; i < 3*n/16; i++) U[i][i] = 1; } #pragma omp section { for (i = 3*n/16; i < 4*n/16; i++) U[i][i] = 1; } #pragma omp section { for (i = 4*n/16; i < 5*n/16; i++) U[i][i] = 1; } #pragma omp section { for (i = 5*n/16; i < 6*n/16; i++) U[i][i] = 1; } #pragma omp section { for (i = 6*n/16; i < 7*n/16; i++) U[i][i] = 1; } #pragma omp section { for (i = 7*n/16; i < 8*n/16; i++) U[i][i] = 1; } #pragma omp section { for (i = 8*n/16; i < 9*n/16; i++) U[i][i] = 1; } #pragma omp section { for (i = 9*n/16; i < 10*n/16; i++) U[i][i] = 1; } #pragma omp section { for (i = 10*n/16; i < 11*n/16; i++) U[i][i] = 1; } #pragma omp section { for (i = 11*n/16; i < 12*n/16; i++) U[i][i] = 1; } #pragma omp section { for (i = 12*n/16; i < 13*n/16; i++) U[i][i] = 1; } #pragma omp section { for (i = 13*n/16; i < 14*n/16; i++) U[i][i] = 1; } #pragma omp section { for (i = 14*n/16; i < 15*n/16; i++) U[i][i] = 1; } #pragma omp section { for (i = 15*n/16; i < n; i++) U[i][i] = 1; } } for (j = 0; j < n; j++) { sum = 0 ; for (k = 0; k < j; k++) { sum = sum + L[j][k] * U[k][j]; } L[j][j] = A[j][j] - sum; #pragma omp parallel sections num_threads(number_of_threads) private(sum,i,k) { #pragma omp section { for (i = j+1 + (0*(n-j-1))/8; i < j+1 + (1*(n-j-1))/8; i++) { sum = 0; for (k = 0; k < j; k++) { sum = sum + L[i][k] * U[k][j]; } L[i][j] = A[i][j] - sum; } } #pragma omp section { for (i = j+1 + (1*(n-j-1))/8; i < j+1 + (2*(n-j-1))/8; i++) { sum = 0; for (k = 0; k < j; k++) { sum = sum + L[i][k] * U[k][j]; } L[i][j] = A[i][j] - sum; } } #pragma omp section { for (i = j+1 + (2*(n-j-1)/8); i < j+1 + (3*(n-j-1))/8; i++) { sum = 0; for (k = 0; k < j; k++) { sum = sum + L[i][k] * U[k][j]; } L[i][j] = A[i][j] - sum; } } #pragma omp section { for (i = j+1 + (3*(n-j-1))/8; i < j+1 + (4*(n-j-1))/8; i++) { sum = 0; for (k = 0; k < j; k++) { sum = sum + L[i][k] * U[k][j]; } L[i][j] = A[i][j] - sum; } } #pragma omp section { for (i = j+1 + (4*(n-j-1))/8; i < j+1 + (5*(n-j-1))/8; i++) { sum = 0; for (k = 0; k < j; k++) { sum = sum + L[i][k] * U[k][j]; } L[i][j] = A[i][j] - sum; } } #pragma omp section { for (i = j+1 + (5*(n-j-1))/8; i < j+1 + (6*(n-j-1))/8; i++) { sum = 0; for (k = 0; k < j; k++) { sum = sum + L[i][k] * U[k][j]; } L[i][j] = A[i][j] - sum; } } #pragma omp section { for (i = j+1 + (6*(n-j-1))/8; i < j+1 + (7*(n-j-1))/8; i++) { sum = 0; for (k = 0; k < j; k++) { sum = sum + L[i][k] * U[k][j]; } L[i][j] = A[i][j] - sum; } } #pragma omp section { for (i = j+1 + (7*(n-j-1))/8; i < j+1 + (8*(n-j-1))/8; i++) { sum = 0; for (k = 0; k < j; k++) { sum = sum + L[i][k] * U[k][j]; } L[i][j] = A[i][j] - sum; } } #pragma omp section { for (i = j + (0*(n-j))/8; i < j + (1*(n-j))/8; i++) { sum = 0; for(k = 0; k < j; k++) { sum = sum + L[j][k] * U[k][i]; } if (L[j][j] == 0) { exit(0); } U[j][i] = (A[j][i] - sum) / L[j][j]; } } #pragma omp section { for (i = j + (1*(n-j))/8; i < j + (2*(n-j))/8; i++) { sum = 0; for(k = 0; k < j; k++) { sum = sum + L[j][k] * U[k][i]; } if (L[j][j] == 0) { exit(0); } U[j][i] = (A[j][i] - sum) / L[j][j]; } } #pragma omp section { for (i = j + (2*(n-j))/8; i < j + (3*(n-j))/8; i++) { sum = 0; for(k = 0; k < j; k++) { sum = sum + L[j][k] * U[k][i]; } if (L[j][j] == 0) { exit(0); } U[j][i] = (A[j][i] - sum) / L[j][j]; } } #pragma omp section { for (i = j + (3*(n-j))/8; i < j + (4*(n-j))/8; i++) { sum = 0; for(k = 0; k < j; k++) { sum = sum + L[j][k] * U[k][i]; } if (L[j][j] == 0) { exit(0); } U[j][i] = (A[j][i] - sum) / L[j][j]; } } #pragma omp section { for (i = j + (4*(n-j))/8; i < j + (5*(n-j))/8; i++) { sum = 0; for(k = 0; k < j; k++) { sum = sum + L[j][k] * U[k][i]; } if (L[j][j] == 0) { exit(0); } U[j][i] = (A[j][i] - sum) / L[j][j]; } } #pragma omp section { for (i = j + (5*(n-j))/8; i < j + (6*(n-j))/8; i++) { sum = 0; for(k = 0; k < j; k++) { sum = sum + L[j][k] * U[k][i]; } if (L[j][j] == 0) { exit(0); } U[j][i] = (A[j][i] - sum) / L[j][j]; } } #pragma omp section { for (i = j + (6*(n-j))/8; i < j + (7*(n-j))/8; i++) { sum = 0; for(k = 0; k < j; k++) { sum = sum + L[j][k] * U[k][i]; } if (L[j][j] == 0) { exit(0); } U[j][i] = (A[j][i] - sum) / L[j][j]; } } #pragma omp section { for (i = j + (7*(n-j))/8; i < j + (8*(n-j))/8; i++) { sum = 0; for(k = 0; k < j; k++) { sum = sum + L[j][k] * U[k][i]; } if (L[j][j] == 0) { exit(0); } U[j][i] = (A[j][i] - sum) / L[j][j]; } } } } } void crout3(double **L, double **U, int n, int number_of_threads) { #pragma omp parallel num_threads(number_of_threads) for (int i = 0; i < n; i++) { U[i][i] = 1; } for (int j = 0; j < n; j++) { double sum = 0; for (int k = 0; k < j; k++) { sum = sum + L[j][k] * U[k][j]; } L[j][j] = A[j][j] - sum; #pragma omp parallel sections { #pragma omp section { #pragma omp parallel for num_threads(number_of_threads) for (int i = j+1; i < n; i++) { double sum = 0; for (int k = 0; k < j; k++) { sum = sum + L[i][k] * U[k][j]; } L[i][j] = A[i][j] - sum; } } #pragma omp section { #pragma omp parallel for num_threads(number_of_threads) for (int i = j; i < n; i++) { double sum = 0; for(int k = 0; k < j; k++) { sum = sum + L[j][k] * U[k][i]; } if (L[j][j] == 0) { exit(0); } U[j][i] = (A[j][i] - sum) / L[j][j]; } } } } } void print_array(double **arr,int n,char *c){ printf("\n--------------------------- %s ---------------------------\n",c); for(int i=0; i<n; i++){ for(int j=0; j<n; j++) printf("%f\t",arr[i][j]); printf("\n"); } printf("----------------------------------------------------------\n\n"); } void write_output(char fname[], double** arr, int n){ FILE *f = fopen(fname, "w"); for( int i = 0; i < n; i++){ for(int j = 0; j < n; j++){ fprintf(f, "%0.12f ", arr[i][j]); } fprintf(f, "\n"); } fclose(f); } int main(int argc, char* argv[]) { omp_set_nested(1); int n; char *input_filename; int strategy; if (argc != 5) {printf("Enter 5 arguments only. Eg.\"executable_filename n input_filename number_of_threads strategy\"\n");return 0;} n = atoi(argv[1]); input_filename = argv[2]; number_of_threads = atoi(argv[3]); strategy = atoi(argv[4]); char *not = argv[3]; A=(double **)malloc(n*sizeof(double*)); for(int i=0;i<n;++i) A[i]=(double *)malloc(n*sizeof(double)); FILE *fptr; if ((fptr = fopen(input_filename, "r")) == NULL) { printf("Error! can't open the input file."); exit(1); } for(int i = 0; i < n; i++) { for(int j = 0; j < n; j++) { if (!fscanf(fptr, "%lf", &A[i][j])) break; } } fclose(fptr); L=(double **)malloc(n*sizeof(double*)); for(int i=0;i<n;++i) L[i]=(double *)malloc(n*sizeof(double)); U=(double **)malloc(n*sizeof(double*)); for(int i=0;i<n;++i) U[i]=(double *)malloc(n*sizeof(double)); if (strategy==0) { crout0(L,U,n); char lf[12] = "output_L_0_"; char uf[12] = "output_U_0_"; char extension[5] = ".txt"; char *f1 = (char *) malloc(256); f1[0]='\0'; char *f2 = (char *) malloc(256); f2[0]='\0'; strcat(f1,lf); strcat(f1,not); strcat(f1,extension); strcat(f2,uf); strcat(f2,not); strcat(f2,extension); write_output(f1,L,n); write_output(f2,U,n); // print_array(L,n,"L"); // print_array(U,n,"U"); } else if(strategy==1){ crout1(L,U,n,number_of_threads); char lf[12] = "output_L_1_"; char uf[12] = "output_U_1_"; char extension[5] = ".txt"; char *f1 = (char *) malloc(256); f1[0]='\0'; char *f2 = (char *) malloc(256); f2[0]='\0'; strcat(f1,lf); strcat(f1,not); strcat(f1,extension); strcat(f2,uf); strcat(f2,not); strcat(f2,extension); write_output(f1,L,n); write_output(f2,U,n); // print_array(L,n,"L"); // print_array(U,n,"U"); } else if(strategy==2){ crout2(L,U,n,number_of_threads); char lf[12] = "output_L_2_"; char uf[12] = "output_U_2_"; char extension[5] = ".txt"; char *f1 = (char *) malloc(256); f1[0]='\0'; char *f2 = (char *) malloc(256); f2[0]='\0'; strcat(f1,lf); strcat(f1,not); strcat(f1,extension); strcat(f2,uf); strcat(f2,not); strcat(f2,extension); write_output(f1,L,n); write_output(f2,U,n); // print_array(L,n,"L"); // print_array(U,n,"U"); } else if(strategy==3){ crout3(L,U,n,number_of_threads); char lf[12] = "output_L_3_"; char uf[12] = "output_U_3_"; char extension[5] = ".txt"; char *f1 = (char *) malloc(256); f1[0]='\0'; char *f2 = (char *) malloc(256); f2[0]='\0'; strcat(f1,lf); strcat(f1,not); strcat(f1,extension); strcat(f2,uf); strcat(f2,not); strcat(f2,extension); write_output(f1,L,n); write_output(f2,U,n); // print_array(L,n,"L"); // print_array(U,n,"U"); } }

scheduled-clauseModificado4.c

#include <stdio.h> #include <stdlib.h> #ifdef _OPENMP #include <omp.h> #else #define omp_get_thread_num() 0 #endif int main(int argc, char **argv) { int i, n = 16,chunk, a[n],suma=0; int modifier; omp_sched_t kind; if(argc < 2) { fprintf(stderr,"\nFalta chunk \n"); exit(-1); } chunk = atoi(argv[1]); for (i=0; i<n; i++) a[i] = i; #pragma omp parallel { #pragma omp for firstprivate(suma) \ lastprivate(suma) schedule(dynamic,chunk) for (i=0; i<n; i++) { suma = suma + a[i]; printf(" thread %d suma a[%d] suma=%d \n", omp_get_thread_num(),i,suma); } #pragma omp single { printf("omp_get_num_threads: %d \n",omp_get_num_threads()); printf("omp_get_num_procs: %d \n",omp_get_num_procs()); printf("omp_in_parallel: %d \n",omp_in_parallel()); } } printf("Fuera de 'parallel for' suma=%d\n",suma); printf("Fuera de la región paralell: \n"); printf("omp_get_num_threads: %d \n",omp_get_num_threads()); printf("omp_get_num_procs: %d \n",omp_get_num_procs()); printf("omo_in_parallel: %d",omp_in_parallel()); }

loop-15.c

/* { dg-do run } */ volatile int ji = 100, ki = 2; volatile unsigned int ju = 100, ku = 2; volatile long long int jll = 100, kll = 2; volatile unsigned long long int jull = 100, kull = 2; unsigned long long l; void f0 (void) { int i, j, k; unsigned int j2, k2; #pragma omp for reduction(+: l) schedule(runtime) for (i = ji; i < ki; i++) l++; if (l != 0) __builtin_abort (); #pragma omp parallel for reduction(+: l) schedule(runtime) for (i = ji; i < ki; i++) l++; if (l != 0) __builtin_abort (); #pragma omp for reduction(+: l) collapse(3) schedule(runtime) for (j = 0; j < 4; j++) for (i = ji; i < ki; i++) for (k = 0; k < 5; k += 2) l++; if (l != 0) __builtin_abort (); #pragma omp parallel for reduction(+: l) collapse(3) schedule(runtime) for (j = 0; j < 4; j++) for (i = ji; i < ki; i++) for (k = 0; k < 5; k += 2) l++; if (l != 0) __builtin_abort (); #pragma omp for reduction(+: l) collapse(3) schedule(runtime) for (j2 = 0; j2 < 4; j2++) for (i = ji; i < ki; i++) for (k2 = 0; k2 < 5; k2 += 2) l++; if (l != 0) __builtin_abort (); #pragma omp parallel for reduction(+: l) collapse(3) schedule(runtime) for (j2 = 0; j2 < 4; j2++) for (i = ji; i < ki; i++) for (k2 = 0; k2 < 5; k2 += 2) l++; if (l != 0) __builtin_abort (); #pragma omp parallel for reduction(+: l) collapse(3) schedule(runtime) for (j = 0; j < 4; j++) for (i = ji; i < ki; i++) for (k = ki + 10; k < ji - 10; k += 2) l++; if (l != 0) __builtin_abort (); #pragma omp parallel for reduction(+: l) collapse(3) schedule(runtime) for (j = ki + 10; j < ji - 10; j++) for (i = ji; i < ki; i++) for (k = 0; k < 5; k += 2) l++; if (l != 0) __builtin_abort (); } void f1 (void) { unsigned int i, j, k; int j2, k2; #pragma omp for reduction(+: l) schedule(runtime) for (i = ju; i < ku; i++) l++; if (l != 0) __builtin_abort (); #pragma omp parallel for reduction(+: l) schedule(runtime) for (i = ju; i < ku; i++) l++; if (l != 0) __builtin_abort (); #pragma omp for reduction(+: l) collapse(3) schedule(runtime) for (j = 0; j < 4; j++) for (i = ju; i < ku; i++) for (k = 0; k < 5; k += 2) l++; if (l != 0) __builtin_abort (); #pragma omp parallel for reduction(+: l) collapse(3) schedule(runtime) for (j = 0; j < 4; j++) for (i = ju; i < ku; i++) for (k = 0; k < 5; k += 2) l++; if (l != 0) __builtin_abort (); #pragma omp for reduction(+: l) collapse(3) schedule(runtime) for (j2 = 0; j2 < 4; j2++) for (i = ju; i < ku; i++) for (k2 = 0; k2 < 5; k2 += 2) l++; if (l != 0) __builtin_abort (); #pragma omp parallel for reduction(+: l) collapse(3) schedule(runtime) for (j2 = 0; j2 < 4; j2++) for (i = ju; i < ku; i++) for (k2 = 0; k2 < 5; k2 += 2) l++; if (l != 0) __builtin_abort (); #pragma omp parallel for reduction(+: l) collapse(3) schedule(runtime) for (j = 0; j < 4; j++) for (i = ju; i < ku; i++) for (k = ku; k < ju; k += 2) l++; if (l != 0) __builtin_abort (); #pragma omp parallel for reduction(+: l) collapse(3) schedule(runtime) for (j = ku; j < ju; j++) for (i = ju; i < ku; i++) for (k = 0; k < 5; k += 2) l++; if (l != 0) __builtin_abort (); } void f2 (void) { long long int i, j, k; unsigned long long int j2, k2; #pragma omp for reduction(+: l) schedule(runtime) for (i = jll; i < kll; i++) l++; if (l != 0) __builtin_abort (); #pragma omp parallel for reduction(+: l) schedule(runtime) for (i = jll; i < kll; i++) l++; if (l != 0) __builtin_abort (); #pragma omp for reduction(+: l) collapse(3) schedule(runtime) for (j = 0; j < 4; j++) for (i = jll; i < kll; i++) for (k = 0; k < 5; k += 2) l++; if (l != 0) __builtin_abort (); #pragma omp parallel for reduction(+: l) collapse(3) schedule(runtime) for (j = 0; j < 4; j++) for (i = jll; i < kll; i++) for (k = 0; k < 5; k += 2) l++; if (l != 0) __builtin_abort (); #pragma omp for reduction(+: l) collapse(3) schedule(runtime) for (j2 = 0; j2 < 4; j2++) for (i = jll; i < kll; i++) for (k2 = 0; k2 < 5; k2 += 2) l++; if (l != 0) __builtin_abort (); #pragma omp parallel for reduction(+: l) collapse(3) schedule(runtime) for (j2 = 0; j2 < 4; j2++) for (i = jll; i < kll; i++) for (k2 = 0; k2 < 5; k2 += 2) l++; if (l != 0) __builtin_abort (); #pragma omp parallel for reduction(+: l) collapse(3) schedule(runtime) for (j = 0; j < 4; j++) for (i = jll; i < kll; i++) for (k = kll; k < jll; k += 2) l++; if (l != 0) __builtin_abort (); #pragma omp parallel for reduction(+: l) collapse(3) schedule(runtime) for (j = kll; j < jll; j++) for (i = jll; i < kll; i++) for (k = 0; k < 5; k += 2) l++; if (l != 0) __builtin_abort (); } void f3 (void) { unsigned long long int i, j, k; long long int j2, k2; #pragma omp for reduction(+: l) schedule(runtime) for (i = jull; i < kull; i++) l++; if (l != 0) __builtin_abort (); #pragma omp parallel for reduction(+: l) schedule(runtime) for (i = jull; i < kull; i++) l++; if (l != 0) __builtin_abort (); #pragma omp for reduction(+: l) collapse(3) schedule(runtime) for (j = 0; j < 4; j++) for (i = jull; i < kull; i++) for (k = 0; k < 5; k += 2) l++; if (l != 0) __builtin_abort (); #pragma omp parallel for reduction(+: l) collapse(3) schedule(runtime) for (j = 0; j < 4; j++) for (i = jull; i < kull; i++) for (k = 0; k < 5; k += 2) l++; if (l != 0) __builtin_abort (); #pragma omp for reduction(+: l) collapse(3) schedule(runtime) for (j2 = 0; j2 < 4; j2++) for (i = jull; i < kull; i++) for (k2 = 0; k2 < 5; k2 += 2) l++; if (l != 0) __builtin_abort (); #pragma omp parallel for reduction(+: l) collapse(3) schedule(runtime) for (j2 = 0; j2 < 4; j2++) for (i = jull; i < kull; i++) for (k2 = 0; k2 < 5; k2 += 2) l++; if (l != 0) __builtin_abort (); #pragma omp parallel for reduction(+: l) collapse(3) schedule(runtime) for (j = 0; j < 4; j++) for (i = jull; i < kull; i++) for (k = kull; k < jull; k += 2) l++; if (l != 0) __builtin_abort (); #pragma omp parallel for reduction(+: l) collapse(3) schedule(runtime) for (j = kull; j < jull; j++) for (i = jull; i < kull; i++) for (k = 0; k < 5; k += 2) l++; if (l != 0) __builtin_abort (); } int main () { f0 (); f1 (); f2 (); f3 (); return 0; }

layer_example_bf16_sparse_A_multi-instance_mem.c

/****************************************************************************** * Copyright (c) Intel Corporation - All rights reserved. * * This file is part of the LIBXSMM library. * * * * For information on the license, see the LICENSE file. * * Further information: https://github.com/hfp/libxsmm/ * * SPDX-License-Identifier: BSD-3-Clause * ******************************************************************************/ /* Evangelos Georganas (Intel Corp.) ******************************************************************************/ #include <libxsmm.h> #include <stdlib.h> #include <string.h> #include <stdio.h> #include <math.h> #if defined(_OPENMP) # include <omp.h> #endif /* include c-based dnn library */ #include "../common/dnn_common.h" //#define PRINT_PROGRESS #define CHKERR_LIBXSMM_DNN(A) { const int chkerr_libxsmm_dnn_ = A; if (LIBXSMM_DNN_SUCCESS != chkerr_libxsmm_dnn_) { \ fprintf(stderr, "%s\n", libxsmm_dnn_get_error(chkerr_libxsmm_dnn_)); global_status = chkerr_libxsmm_dnn_; } \ } double mean(double *array, int N) { double res = 0.0; int i; for (i = 0; i < N; i++) { res += array[i]; } res = res/(double)N; return res; } double std(double *array, int N) { double m = mean(array, N); int i; double res = 0.0; for (i = 0; i < N; i++) { res += (array[i] - m) * (array[i] - m); } res = sqrt(res/(double)N); return res; } void shuffle_array(unsigned int *array, int n) { if (n > 1) { int i; for (i = 0; i < n - 1; i++) { int j = i + rand() / (RAND_MAX / (n - i) + 1); unsigned int t = array[j]; array[j] = array[i]; array[i] = t; } } } unsigned int random_mask_half_full(int sparsity_factor ) { int __i; unsigned int id_array[32]; unsigned int cur_bitmap = 0; for (__i = 0; __i < 32; __i++) { id_array[__i] = __i; } shuffle_array(id_array, 32); for (__i = 0; __i < 32/sparsity_factor; __i++) { unsigned int cur_bit = (1 << id_array[__i]); cur_bitmap = cur_bitmap | cur_bit; } return cur_bitmap; } int main(int argc, char* argv[]) { float *naive_input, *naive_output, *naive_filter, *naive_bias; libxsmm_bfloat16 *naive_input_bf16, *naive_filter_bf16, *naive_output_bf16, *naive_bias_bf16; float *naive_libxsmm_output_f32; libxsmm_bfloat16 *naive_libxsmm_output_bf16; libxsmm_bfloat16 *filter_libxsmm_sparse; unsigned int *sparse_idx_libxsmm; libxsmm_bfloat16 **input_libxsmm, **output_libxsmm, **filter_libxsmm, **bias_libxsmm; unsigned char **relumask_libxsmm; char *nuke_buffer; naive_fullyconnected_t naive_param; char** scratch; size_t scratch_size = 0; unsigned long long *dummies; /* some parameters we can overwrite via cli, default is some inner layer of overfeat */ int iters = 100; /* repetitions of benchmark */ int nImg = 32; /* mini-batch size, "N" */ int nIFm = 256; /* number of input feature maps, "C" */ int nOFm = 256; /* number of input feature maps, "C" */ int fuse_type = 0; /* 0: nothing fused, 1: relu fused, 2: elementwise fused, 3: relu and elementwise fused */ int bn = 32; int bk = 32; int bc = 32; int sparsity_factor = 2; int nuke_caches = 1; int warmup_acts = 1; int nthreads_per_instance = 1; const char *const env_check = getenv("CHECK"); const double check = LIBXSMM_ABS(0 == env_check ? 1 : atof(env_check)); #if defined(_OPENMP) int nThreads = omp_get_max_threads(); /* number of threads */ #else int nThreads = 1; /* number of threads */ #endif unsigned long long nuke_size = ((unsigned long long)( (unsigned long long)2 * (unsigned long long)1024 * (unsigned long long)1024 * (unsigned long long)1024 + (unsigned long long)nThreads)/ (unsigned long long) nThreads) * (unsigned long long) nThreads; unsigned long long l_start, l_end; double l_total = 0.0; double *l_totals; double gflop = 0.0; double *gflop_array; double m, s, min_gflops, max_gflops, iter_flops; int i; libxsmm_dnn_fullyconnected_desc fullyconnected_desc; libxsmm_dnn_fullyconnected **libxsmm_handle; libxsmm_dnn_tensor **libxsmm_input; libxsmm_dnn_tensor **libxsmm_output; libxsmm_dnn_tensor **libxsmm_filter; libxsmm_dnn_tensor **libxsmm_bias; libxsmm_dnn_tensor **libxsmm_relumask; libxsmm_dnn_err_t status; libxsmm_dnn_err_t global_status = LIBXSMM_DNN_SUCCESS; libxsmm_matdiff_info norms_fwd, diff; libxsmm_matdiff_clear(&norms_fwd); libxsmm_matdiff_clear(&diff); if (argc > 1 && !strncmp(argv[1], "-h", 3)) { printf("Usage: %s iters MB nIFm nOFm fuse_type bn bk bc sparsity_factor \n", argv[0]); return 0; } libxsmm_rng_set_seed(1); /* reading new values from cli */ i = 1; if (argc > i) iters = atoi(argv[i++]); if (argc > i) nImg = atoi(argv[i++]); if (argc > i) nIFm = atoi(argv[i++]); if (argc > i) nOFm = atoi(argv[i++]); if (argc > i) fuse_type = atoi(argv[i++]); if (argc > i) bn = atoi(argv[i++]); if (argc > i) bk = atoi(argv[i++]); if (argc > i) bc = atoi(argv[i++]); if (argc > i) sparsity_factor = atoi(argv[i++]); if (argc > i) nuke_caches = atoi(argv[i++]); if (argc > i) warmup_acts = atoi(argv[i++]); if (argc > i) nthreads_per_instance = atoi(argv[i++]); if ( nImg % bn != 0 ) { bn = nImg; } if ( nIFm % bc != 0 ) { bc = nIFm; } if ( nOFm % bk != 0 ) { bk = nOFm; } if ( (fuse_type < 0) || (fuse_type > 5) ) { printf("Fuse type needs to be 0 (None), 1 (Bias), 2 (ReLU), 3 (Sigmoid), 4 (Bias+ReLU), 5 (Bias+Sigmoid)\n"); return -1; } if ((bk != 32) || (bc != 32)) { printf("BK and BC supported values are only 32 (provided are bk=%d bc=%d)!\n", bk, bc); return -1; } if (nuke_caches > 0) { printf("#############################################\n"); printf("# WEIGHTS are COLD before performance run...#\n"); printf("#############################################\n"); } else { printf("#############################################\n"); printf("# WEIGHTS are HOT before performance run... #\n"); printf("#############################################\n"); } if (warmup_acts > 0) { printf("#############################################\n"); printf("# ACTS are HOT before performance run... #\n"); printf("#############################################\n"); } else { printf("#############################################\n"); printf("# ACTS are COLD before performance run... #\n"); printf("#############################################\n"); } /* set struct for naive convolution */ naive_param.N = nImg; naive_param.C = nIFm; naive_param.K = nOFm; naive_param.fuse_type = fuse_type; #if defined(__SSE3__) _MM_SET_FLUSH_ZERO_MODE(_MM_FLUSH_ZERO_ON); _MM_SET_DENORMALS_ZERO_MODE(_MM_DENORMALS_ZERO_ON); _MM_SET_ROUNDING_MODE(_MM_ROUND_NEAREST); #endif /* print some summary */ printf("##########################################\n"); printf("# Setting Up (Common) #\n"); printf("##########################################\n"); printf("PARAMS: N:%d C:%d K:%d\n", nImg, nIFm, nOFm); printf("PARAMS: ITERS:%d", iters); if (LIBXSMM_FEQ(0, check)) printf(" Threads:%d\n", nThreads); else printf("\n"); printf("SIZE Input (MB): %10.2f MiB\n", (double)(nImg*nIFm*sizeof(libxsmm_bfloat16))/(1024.0*1024.0) ); printf("SIZE Output (MB): %10.2f MiB\n", (double)(nImg*nOFm*sizeof(libxsmm_bfloat16))/(1024.0*1024.0) ); printf("SIZE Filter (sparse): %10.2f MiB\n", (double)(nIFm*nOFm*sizeof(libxsmm_bfloat16)/sparsity_factor)/(1024.0*1024.0) ); /* Allocate arrays of pointers/data structures for all threads */ input_libxsmm = (libxsmm_bfloat16**) libxsmm_aligned_malloc( nThreads*sizeof(libxsmm_bfloat16*), 2097152); output_libxsmm = (libxsmm_bfloat16**) libxsmm_aligned_malloc( nThreads*sizeof(libxsmm_bfloat16*), 2097152); filter_libxsmm = (libxsmm_bfloat16**) libxsmm_aligned_malloc( nThreads*sizeof(libxsmm_bfloat16*), 2097152); bias_libxsmm = (libxsmm_bfloat16**) libxsmm_aligned_malloc( nThreads*sizeof(libxsmm_bfloat16*), 2097152); relumask_libxsmm = (unsigned char**) libxsmm_aligned_malloc( nThreads*sizeof(unsigned char*), 2097152); nuke_buffer = (char*) libxsmm_aligned_malloc( nuke_size*sizeof(char), 2097152); if (nuke_buffer == NULL) { fprintf(stderr, "Nuke buffer alloc failed....\n"); exit(EXIT_FAILURE); } dummies = (unsigned long long*) libxsmm_aligned_malloc( nThreads*sizeof(unsigned long long), 2097152); l_totals = (double*) libxsmm_aligned_malloc( nThreads*iters*sizeof(double), 2097152); gflop_array = (double*) libxsmm_aligned_malloc( nThreads*sizeof(double), 2097152); for (i = 0; i < nThreads; i++) { input_libxsmm[i] = (libxsmm_bfloat16*)libxsmm_aligned_malloc( nImg*nIFm*sizeof(libxsmm_bfloat16), 2097152); output_libxsmm[i] = (libxsmm_bfloat16*)libxsmm_aligned_malloc( nImg*nOFm*sizeof(libxsmm_bfloat16), 2097152); filter_libxsmm[i] = (libxsmm_bfloat16*)libxsmm_aligned_malloc( nIFm*nOFm*sizeof(libxsmm_bfloat16), 2097152); bias_libxsmm[i] = (libxsmm_bfloat16*)libxsmm_aligned_malloc( nOFm *sizeof(libxsmm_bfloat16), 2097152); relumask_libxsmm[i] = (unsigned char*)libxsmm_aligned_malloc( nImg*nOFm*sizeof(unsigned char), 2097152); gflop_array[i] = 0.0; } /* allocate data */ naive_input = (float*)libxsmm_aligned_malloc( nImg*nIFm*sizeof(float), 2097152); naive_output = (float*)libxsmm_aligned_malloc( nImg*nOFm*sizeof(float), 2097152); naive_filter = (float*)libxsmm_aligned_malloc( nIFm*nOFm*sizeof(float), 2097152); naive_bias = (float*)libxsmm_aligned_malloc( nOFm *sizeof(float), 2097152); naive_input_bf16 = (libxsmm_bfloat16*)libxsmm_aligned_malloc( nImg*nIFm*sizeof(libxsmm_bfloat16), 2097152); naive_output_bf16 = (libxsmm_bfloat16*)libxsmm_aligned_malloc( nImg*nOFm*sizeof(libxsmm_bfloat16), 2097152); naive_filter_bf16 = (libxsmm_bfloat16*)libxsmm_aligned_malloc( nIFm*nOFm*sizeof(libxsmm_bfloat16), 2097152); naive_bias_bf16 = (libxsmm_bfloat16*)libxsmm_aligned_malloc( nOFm *sizeof(libxsmm_bfloat16), 2097152); naive_libxsmm_output_bf16 = (libxsmm_bfloat16*)libxsmm_aligned_malloc( nImg*nOFm*sizeof(libxsmm_bfloat16), 2097152); naive_libxsmm_output_f32 = (float*)libxsmm_aligned_malloc( nImg*nOFm*sizeof(float), 2097152); filter_libxsmm_sparse = (libxsmm_bfloat16*)libxsmm_aligned_malloc( nIFm*nOFm*sizeof(libxsmm_bfloat16), 2097152); sparse_idx_libxsmm = (unsigned int*)libxsmm_aligned_malloc( nIFm*nOFm*sizeof(unsigned int), 2097152); /* initialize data */ init_buf( naive_input, nImg*nIFm, 0, 0 ); init_buf( naive_output, nImg*nOFm, 0, 0 ); init_buf( naive_filter, nIFm*nOFm, 0, 0 ); init_buf( naive_bias, nOFm, 0, 0 ); libxsmm_rne_convert_fp32_bf16( naive_input, naive_input_bf16, nImg*nIFm ); libxsmm_rne_convert_fp32_bf16( naive_output, naive_output_bf16, nImg*nOFm ); libxsmm_rne_convert_fp32_bf16( naive_filter, naive_filter_bf16, nIFm*nOFm ); libxsmm_rne_convert_fp32_bf16( naive_bias, naive_bias_bf16, nOFm ); printf("\n"); printf("##########################################\n"); printf("# Setting Up (custom-Storage) #\n"); printf("##########################################\n"); /* setup LIBXSMM handle */ fullyconnected_desc.N = nImg; fullyconnected_desc.C = nIFm; fullyconnected_desc.K = nOFm; fullyconnected_desc.bn = bn; fullyconnected_desc.bk = bk; fullyconnected_desc.bc = bc; fullyconnected_desc.threads = nthreads_per_instance; fullyconnected_desc.datatype_in = LIBXSMM_DNN_DATATYPE_BF16; fullyconnected_desc.datatype_out = LIBXSMM_DNN_DATATYPE_BF16; fullyconnected_desc.buffer_format = LIBXSMM_DNN_TENSOR_FORMAT_NCPACKED; fullyconnected_desc.filter_format = LIBXSMM_DNN_TENSOR_FORMAT_CKPACKED; fullyconnected_desc.compressed_A = 1; fullyconnected_desc.sparsity_factor_A = sparsity_factor; if ( fuse_type == 0 ) { fullyconnected_desc.fuse_ops = LIBXSMM_DNN_FULLYCONNECTED_FUSE_NONE; } else if ( fuse_type == 1 ) { fullyconnected_desc.fuse_ops = LIBXSMM_DNN_FULLYCONNECTED_FUSE_BIAS; } else if ( fuse_type == 2 ) { fullyconnected_desc.fuse_ops = LIBXSMM_DNN_FULLYCONNECTED_FUSE_RELU; } else if ( fuse_type == 3 ) { fullyconnected_desc.fuse_ops = LIBXSMM_DNN_FULLYCONNECTED_FUSE_SIGMOID; } else if ( fuse_type == 4 ) { fullyconnected_desc.fuse_ops = LIBXSMM_DNN_FULLYCONNECTED_FUSE_BIAS_RELU; } else if ( fuse_type == 5 ) { fullyconnected_desc.fuse_ops = LIBXSMM_DNN_FULLYCONNECTED_FUSE_BIAS_SIGMOID; } else { /* cannot happen */ } libxsmm_handle = (libxsmm_dnn_fullyconnected**) libxsmm_aligned_malloc( nThreads*sizeof(libxsmm_dnn_fullyconnected*), 2097152); libxsmm_input = (libxsmm_dnn_tensor**) libxsmm_aligned_malloc( nThreads*sizeof(libxsmm_dnn_tensor*), 2097152); libxsmm_output = (libxsmm_dnn_tensor**) libxsmm_aligned_malloc( nThreads*sizeof(libxsmm_dnn_tensor*), 2097152); libxsmm_filter = (libxsmm_dnn_tensor**) libxsmm_aligned_malloc( nThreads*sizeof(libxsmm_dnn_tensor*), 2097152); libxsmm_bias = (libxsmm_dnn_tensor**) libxsmm_aligned_malloc( nThreads*sizeof(libxsmm_dnn_tensor*), 2097152); libxsmm_relumask = (libxsmm_dnn_tensor**) libxsmm_aligned_malloc( nThreads*sizeof(libxsmm_dnn_tensor*), 2097152); #if defined(_OPENMP) # pragma omp parallel #endif { #if defined(_OPENMP) const int _tid = omp_get_thread_num(); #else const int _tid = 0; #endif int tid = _tid / nthreads_per_instance; int member_id = _tid % nthreads_per_instance; if (member_id == 0) { libxsmm_dnn_tensor_datalayout *libxsmm_layout; libxsmm_dnn_err_t l_status; libxsmm_handle[tid] = libxsmm_dnn_create_fullyconnected( fullyconnected_desc, &l_status ); CHKERR_LIBXSMM_DNN( l_status ); /* setup LIBXSMM buffers */ libxsmm_layout = libxsmm_dnn_fullyconnected_create_tensor_datalayout( libxsmm_handle[tid], LIBXSMM_DNN_REGULAR_INPUT, &l_status ); CHKERR_LIBXSMM_DNN( l_status ); libxsmm_input[tid] = libxsmm_dnn_link_tensor( libxsmm_layout, input_libxsmm[tid], &l_status ); CHKERR_LIBXSMM_DNN( l_status ); libxsmm_dnn_destroy_tensor_datalayout( libxsmm_layout ); libxsmm_layout = libxsmm_dnn_fullyconnected_create_tensor_datalayout( libxsmm_handle[tid], LIBXSMM_DNN_REGULAR_OUTPUT, &l_status ); CHKERR_LIBXSMM_DNN( l_status ); libxsmm_output[tid] = libxsmm_dnn_link_tensor( libxsmm_layout, output_libxsmm[tid], &l_status ); CHKERR_LIBXSMM_DNN( l_status ); libxsmm_dnn_destroy_tensor_datalayout( libxsmm_layout ); libxsmm_layout = libxsmm_dnn_fullyconnected_create_tensor_datalayout( libxsmm_handle[tid], LIBXSMM_DNN_REGULAR_FILTER, &l_status ); CHKERR_LIBXSMM_DNN( l_status ); libxsmm_filter[tid] = libxsmm_dnn_link_tensor( libxsmm_layout, filter_libxsmm[tid], &l_status ); CHKERR_LIBXSMM_DNN( l_status ); libxsmm_dnn_destroy_tensor_datalayout( libxsmm_layout ); libxsmm_layout = libxsmm_dnn_fullyconnected_create_tensor_datalayout( libxsmm_handle[tid], LIBXSMM_DNN_REGULAR_CHANNEL_BIAS, &l_status ); CHKERR_LIBXSMM_DNN( l_status ); libxsmm_bias[tid] = libxsmm_dnn_link_tensor( libxsmm_layout, bias_libxsmm[tid], &l_status ); CHKERR_LIBXSMM_DNN( l_status ); libxsmm_dnn_destroy_tensor_datalayout( libxsmm_layout ); libxsmm_layout = libxsmm_dnn_fullyconnected_create_tensor_datalayout( libxsmm_handle[tid], LIBXSMM_DNN_RELU_MASK, &l_status ); CHKERR_LIBXSMM_DNN( l_status ); libxsmm_relumask[tid] = libxsmm_dnn_link_tensor( libxsmm_layout, relumask_libxsmm[tid], &l_status ); CHKERR_LIBXSMM_DNN( l_status ); libxsmm_dnn_destroy_tensor_datalayout( libxsmm_layout ); /* copy in data to LIBXSMM format */ /* we can also use the layout functions and set the data on our own external to the library */ matrix_copy_NC_to_NCNC_bf16_serial( naive_input_bf16, input_libxsmm[tid], 1, nImg, nIFm, bn, bc ); matrix_copy_NC_to_NCNC_bf16_serial( naive_output_bf16, output_libxsmm[tid], 1, nImg, nOFm, bn, bk ); matrix_copy_NC_to_NCNC_bf16_serial( naive_filter_bf16, filter_libxsmm[tid], 1, nIFm, nOFm, bc, bk ); matrix_copy_NC_to_NCNC_bf16_serial( naive_bias_bf16, bias_libxsmm[tid], 1, 1, nOFm, 1, nOFm ); } } /* Sparsify filters to requested level */ memset(filter_libxsmm_sparse, 0, nIFm * nOFm * sizeof(libxsmm_bfloat16)); #if defined(__AVX512VBMI2__) || (defined(__AVX512BW__) && defined(LIBXSMM_INTEL_COMPILER)) int __i = 0, __j = 0, __k = 0; for (__i = 0; __i < nIFm * nOFm; __i+= 32 ) { unsigned int cur_mask_int = random_mask_half_full(sparsity_factor); __mmask32 cur_mask = _cvtu32_mask32(cur_mask_int); __m512i vreg_dense = _mm512_loadu_si512 ((libxsmm_bfloat16*)filter_libxsmm[0]+__i); sparse_idx_libxsmm[__k] = cur_mask_int; _mm512_mask_storeu_epi16 ((libxsmm_bfloat16*)filter_libxsmm_sparse+__i, cur_mask, vreg_dense); _mm512_mask_compressstoreu_epi16((libxsmm_bfloat16*)filter_libxsmm[0]+__j, cur_mask, vreg_dense); __k += 1; __j += 32/sparsity_factor; } #else fprintf(stderr, "ERROR: support for at least " # if defined(LIBXSMM_INTEL_COMPILER) "AVX512BW" # else "AVX512VBMI2" # endif " required for this kernel!\n"); exit(EXIT_FAILURE); #endif /* Copyover the sparse idx tensor after the compressed filter buffer */ if (sparsity_factor > 1) { memcpy((libxsmm_bfloat16*)filter_libxsmm[0] + (nIFm * nOFm)/sparsity_factor, sparse_idx_libxsmm, ((nIFm * nOFm)/32)*sizeof(unsigned int)); } #if defined(_OPENMP) # pragma omp parallel #endif { #if defined(_OPENMP) const int _tid = omp_get_thread_num(); #else const int _tid = 0; #endif int tid = _tid / nthreads_per_instance; int member_id = _tid % nthreads_per_instance; if ((member_id == 0) && (_tid > 0)) { memcpy((libxsmm_bfloat16*)filter_libxsmm[tid], (libxsmm_bfloat16*)filter_libxsmm[0], (nIFm * nOFm)/sparsity_factor*sizeof(libxsmm_bfloat16)); if (sparsity_factor > 1) { memcpy((libxsmm_bfloat16*)filter_libxsmm[tid] + (nIFm * nOFm)/sparsity_factor, sparse_idx_libxsmm, ((nIFm * nOFm)/32)*sizeof(unsigned int)); } } } /* Copyover the sparse filter ot the reference filter for correctness checks */ matrix_copy_KCCK_to_KC_bf16( filter_libxsmm_sparse, naive_filter_bf16, nIFm, nOFm, bc, bk ); libxsmm_convert_bf16_f32( naive_filter_bf16, naive_filter, nIFm*nOFm ); if (LIBXSMM_NEQ(0, check)) { printf("##########################################\n"); printf("# Computing Reference ... #\n"); printf("##########################################\n"); naive_fullyconnected_fused_fp(&naive_param, naive_input, naive_output, naive_filter, naive_bias); printf("##########################################\n"); printf("# Computing Reference ... done #\n"); printf("##########################################\n"); } /* bind buffers and filter to handle */ for (i = 0; i < nThreads/nthreads_per_instance; i++) { CHKERR_LIBXSMM_DNN( libxsmm_dnn_fullyconnected_bind_tensor( libxsmm_handle[i], libxsmm_input[i], LIBXSMM_DNN_REGULAR_INPUT ) ); CHKERR_LIBXSMM_DNN( libxsmm_dnn_fullyconnected_bind_tensor( libxsmm_handle[i], libxsmm_output[i], LIBXSMM_DNN_REGULAR_OUTPUT ) ); CHKERR_LIBXSMM_DNN( libxsmm_dnn_fullyconnected_bind_tensor( libxsmm_handle[i], libxsmm_filter[i], LIBXSMM_DNN_REGULAR_FILTER ) ); CHKERR_LIBXSMM_DNN( libxsmm_dnn_fullyconnected_bind_tensor( libxsmm_handle[i], libxsmm_bias[i], LIBXSMM_DNN_REGULAR_CHANNEL_BIAS ) ); CHKERR_LIBXSMM_DNN( libxsmm_dnn_fullyconnected_bind_tensor( libxsmm_handle[i], libxsmm_relumask[i], LIBXSMM_DNN_RELU_MASK ) ); } /* let's allocate and bind scratch */ scratch_size = libxsmm_dnn_fullyconnected_get_scratch_size( libxsmm_handle[0], &status ); CHKERR_LIBXSMM_DNN( status ); scratch = (char**) libxsmm_aligned_malloc( nThreads*sizeof(char*), 2097152); #if defined(_OPENMP) # pragma omp parallel #endif { #if defined(_OPENMP) const int _tid = omp_get_thread_num(); #else const int _tid = 0; #endif int tid = _tid / nthreads_per_instance; int member_id = _tid % nthreads_per_instance; if (member_id == 0) { scratch[tid] = (char*) libxsmm_aligned_malloc( scratch_size * sizeof(char), 2097152 ); CHKERR_LIBXSMM_DNN( libxsmm_dnn_fullyconnected_bind_scratch( libxsmm_handle[tid], scratch[tid] ) ); /* set scratch to bogus to make sure that libxsmm takes care of zeroing internally */ memset(scratch[tid], 42, scratch_size); } } printf("##########################################\n"); printf("# Correctness - FWD (custom-Storage) #\n"); printf("##########################################\n"); #if defined(_OPENMP) # pragma omp parallel #endif { #if defined(_OPENMP) const int _tid = omp_get_thread_num(); #else const int _tid = 0; #endif int tid = _tid / nthreads_per_instance; int member_id = _tid % nthreads_per_instance; CHKERR_LIBXSMM_DNN( libxsmm_dnn_fullyconnected_execute_st( libxsmm_handle[tid], LIBXSMM_DNN_COMPUTE_KIND_FWD, 0, member_id ) ); } /* copy out data */ matrix_copy_NCNC_to_NC_bf16( output_libxsmm[0], naive_libxsmm_output_bf16, 1, nImg, nOFm, bn, bk ); libxsmm_convert_bf16_f32( naive_libxsmm_output_bf16, naive_libxsmm_output_f32, nImg*nOFm ); /* compare */ libxsmm_matdiff(&norms_fwd, LIBXSMM_DATATYPE_F32, nImg*nOFm, 1, naive_output, naive_libxsmm_output_f32, 0, 0); printf("L1 reference : %.25g\n", norms_fwd.l1_ref); printf("L1 test : %.25g\n", norms_fwd.l1_tst); printf("L2 abs.error : %.24f\n", norms_fwd.l2_abs); printf("L2 rel.error : %.24f\n", norms_fwd.l2_rel); printf("Linf abs.error: %.24f\n", norms_fwd.linf_abs); printf("Linf rel.error: %.24f\n", norms_fwd.linf_rel); printf("Check-norm : %.24f\n", norms_fwd.normf_rel); libxsmm_matdiff_reduce(&diff, &norms_fwd); printf("##########################################\n"); printf("# Running %d warmup iterations #\n", iters); printf("##########################################\n"); #if defined(_OPENMP) # pragma omp parallel private(i) #endif { #if defined(_OPENMP) const int _tid = omp_get_thread_num(); #else const int _tid = 0; #endif int tid = _tid / nthreads_per_instance; int member_id = _tid % nthreads_per_instance; for (i = 0; i < iters; ++i) { libxsmm_dnn_fullyconnected_execute_st( libxsmm_handle[tid], LIBXSMM_DNN_COMPUTE_KIND_FWD, 0, member_id ); } } #if defined(_OPENMP) # pragma omp parallel private(i) #endif { #if defined(_OPENMP) const int _tid = omp_get_thread_num(); #else const int _tid = 0; #endif int tid = _tid / nthreads_per_instance; int member_id = _tid % nthreads_per_instance; unsigned long long chunk_size = (unsigned long long)nuke_size/((unsigned long long)nThreads); char *pt_nuke = (char*)nuke_buffer + (unsigned long long) (((unsigned long long)tid) * (unsigned long long) chunk_size); libxsmm_bfloat16* pt_out = (libxsmm_bfloat16*) output_libxsmm[tid] + member_id * (nImg * nOFm)/nthreads_per_instance; libxsmm_bfloat16* pt_in = (libxsmm_bfloat16*) input_libxsmm[tid] + member_id * (nImg * nIFm)/nthreads_per_instance; libxsmm_bfloat16* pt_wt = (libxsmm_bfloat16*) filter_libxsmm[tid]; char* pt_scratch = (char*) scratch[tid] + member_id * (scratch_size/nthreads_per_instance); int j; int it = 0; unsigned long long __i; unsigned long long _l_start, _l_end; for (it = 0; it < iters; it++) { if (nuke_caches > 0) { #ifdef PRINT_PROGRESS if (tid == 0) { printf("##########################################\n"); printf("# Nuking caches.... \n"); printf("##########################################\n"); } #endif #if USE_NUKE_BUFFER memset((char*)nuke_buffer + (unsigned long long)(((unsigned long long)tid)* chunk_size), (char)tid, (unsigned long long)chunk_size * (unsigned long long)sizeof(char)); for (j = 0; j < 10; j++) { for (__i = 0; __i < chunk_size; __i++) { dummies[tid] += (unsigned long long) pt_nuke[__i]; } } #else for (__i = 0; __i < (nImg*nOFm)/32/nthreads_per_instance; __i++) { _mm_clflushopt((libxsmm_bfloat16*)pt_out + __i * 32); } for (__i = 0; __i < (nIFm*nOFm)/32; __i++) { _mm_clflushopt((libxsmm_bfloat16*)pt_wt + __i * 32); } for (__i = 0; __i < (nImg*nIFm)/32/nthreads_per_instance; __i++) { _mm_clflushopt((libxsmm_bfloat16*)pt_in + __i * 32); } for (__i = 0; __i < scratch_size/64/nthreads_per_instance; __i++) { _mm_clflushopt((char*)pt_scratch+ __i * 64); } #endif } if (warmup_acts > 0) { #ifdef PRINT_PROGRESS if (tid == 0) { printf("##################################################\n"); printf("# Bringing input/output activations in cache... \n"); printf("##################################################\n"); } #endif for (j = 0; j < 10; j++) { for (__i = 0; __i < (nImg*nOFm)/nthreads_per_instance; __i++) { dummies[_tid] += (unsigned long long) pt_out[__i]; pt_out[__i] = (libxsmm_bfloat16) dummies[_tid]; } for (__i = 0; __i < (nImg*nIFm)/nthreads_per_instance; __i++) { dummies[_tid] += (unsigned long long) pt_in[__i]; } for (__i = 0; __i < nIFm*bk; __i++) { dummies[_tid] += (unsigned long long) *((libxsmm_bfloat16*)scratch[tid] + member_id * nIFm * bk + __i); } } } #ifdef PRINT_PROGRESS if (tid == 0) { printf("##########################################\n"); printf("# Performance run,,,, #\n"); printf("##########################################\n"); } #endif #pragma omp barrier _l_start = libxsmm_timer_tick(); libxsmm_dnn_fullyconnected_execute_st( libxsmm_handle[tid], LIBXSMM_DNN_COMPUTE_KIND_FWD, 0, member_id ); _l_end = libxsmm_timer_tick(); l_totals[_tid*iters+it] = libxsmm_timer_duration(_l_start, _l_end); } } gflop = (2.0*(double)nImg*(double)nIFm*(double)nOFm*(double)nThreads*iters/nthreads_per_instance) / (1000*1000*1000); l_total = l_totals[0]; for (i = 1; i< iters; i++) { l_total += l_totals[i]; } printf("GFLOP = %.5g\n", gflop); printf("fp time = %.5g\n", ((double)(l_total))); printf("GFLOPS = %.5g\n", gflop/l_total); m = mean(l_totals, nThreads*iters); s = std(l_totals, nThreads*iters); printf("mean of ALL times is %.5g, std is %.5g which is %.5g%%\n", m, s, s*100.0/m); for (i = 1; i < nThreads; i++) { dummies[0] += dummies[i]; } for (i = 0; i < nThreads; i++) { int _i; l_total = l_totals[i*iters+0]; for (_i = 1; _i < iters; _i++) { l_total += l_totals[i*iters+_i]; } gflop_array[i] = gflop/l_total; } m = mean(gflop_array, nThreads); s = std(gflop_array, nThreads); printf("Mean of ALL GFLOPS is %.5g, std is %.5g which is %.5g%%\n\n", m, s, s*100.0/m); min_gflops = gflop_array[0]; max_gflops = gflop_array[0]; for (i = 1; i < nThreads; i++) { min_gflops = LIBXSMM_MIN(min_gflops, gflop_array[i]); max_gflops = LIBXSMM_MAX(max_gflops, gflop_array[i]); } printf("Among threads total MIN is %.5g and total MAX is %.5g\n", min_gflops, max_gflops); iter_flops = (2.0*(double)nImg*(double)nIFm*(double)nOFm*(double)nThreads/(double)nthreads_per_instance) / (1000*1000*1000); min_gflops = iter_flops / l_totals[0]; max_gflops = iter_flops / l_totals[0]; m = max_gflops; for (i = 1; i < nThreads * iters; i++) { min_gflops = LIBXSMM_MIN(min_gflops, iter_flops / l_totals[i]); max_gflops = LIBXSMM_MAX(max_gflops, iter_flops / l_totals[i]); m += iter_flops / l_totals[i]; } printf("Among threads and iters MIN is %.5g and MAX is %.5g and MEAN is %.5g\n", min_gflops, max_gflops, m/(double)(nThreads*iters)); printf("PERFDUMP,%s,FP,%i,%i,%i,%i,%.5g,%.5g,%f,%f,%f,%f,%f,%f,%f,%llu\n", LIBXSMM_VERSION, nThreads, nImg, nIFm, nOFm, ((double)(l_total/iters)), gflop/l_total, norms_fwd.l1_ref, norms_fwd.l1_tst, norms_fwd.l2_abs, norms_fwd.l2_rel, norms_fwd.linf_abs, norms_fwd.linf_rel, norms_fwd.normf_rel, dummies[0]); /* clean-up */ for (i = 0; i < nThreads/nthreads_per_instance; i++) { CHKERR_LIBXSMM_DNN( libxsmm_dnn_fullyconnected_release_scratch( libxsmm_handle[i] ) ); CHKERR_LIBXSMM_DNN( libxsmm_dnn_fullyconnected_release_tensor( libxsmm_handle[i], LIBXSMM_DNN_REGULAR_INPUT ) ); CHKERR_LIBXSMM_DNN( libxsmm_dnn_fullyconnected_release_tensor( libxsmm_handle[i], LIBXSMM_DNN_REGULAR_OUTPUT ) ); CHKERR_LIBXSMM_DNN( libxsmm_dnn_fullyconnected_release_tensor( libxsmm_handle[i], LIBXSMM_DNN_REGULAR_FILTER ) ); CHKERR_LIBXSMM_DNN( libxsmm_dnn_fullyconnected_release_tensor( libxsmm_handle[i], LIBXSMM_DNN_REGULAR_CHANNEL_BIAS ) ); CHKERR_LIBXSMM_DNN( libxsmm_dnn_fullyconnected_release_tensor( libxsmm_handle[i], LIBXSMM_DNN_RELU_MASK ) ); CHKERR_LIBXSMM_DNN( libxsmm_dnn_destroy_tensor( libxsmm_input[i] ) ); CHKERR_LIBXSMM_DNN( libxsmm_dnn_destroy_tensor( libxsmm_output[i] ) ); CHKERR_LIBXSMM_DNN( libxsmm_dnn_destroy_tensor( libxsmm_filter[i] ) ); CHKERR_LIBXSMM_DNN( libxsmm_dnn_destroy_tensor( libxsmm_bias[i] ) ); CHKERR_LIBXSMM_DNN( libxsmm_dnn_destroy_tensor( libxsmm_relumask[i] ) ); CHKERR_LIBXSMM_DNN( libxsmm_dnn_destroy_fullyconnected( libxsmm_handle[i] ) ); libxsmm_free(input_libxsmm[i]); libxsmm_free(output_libxsmm[i]); libxsmm_free(filter_libxsmm[i]); libxsmm_free(relumask_libxsmm[i]); libxsmm_free(bias_libxsmm[i]); libxsmm_free(scratch[i]); } /* deallocate data */ libxsmm_free(naive_input); libxsmm_free(naive_output); libxsmm_free(naive_filter); libxsmm_free(naive_input_bf16); libxsmm_free(naive_output_bf16); libxsmm_free(naive_filter_bf16); libxsmm_free(naive_libxsmm_output_bf16); libxsmm_free(naive_libxsmm_output_f32); libxsmm_free(naive_bias); libxsmm_free(naive_bias_bf16); libxsmm_free(libxsmm_handle); libxsmm_free(libxsmm_input); libxsmm_free(libxsmm_output); libxsmm_free(libxsmm_filter); libxsmm_free(libxsmm_bias); libxsmm_free(libxsmm_relumask); libxsmm_free(input_libxsmm); libxsmm_free(output_libxsmm); libxsmm_free(filter_libxsmm); libxsmm_free(relumask_libxsmm); libxsmm_free(bias_libxsmm); libxsmm_free(scratch); libxsmm_free(nuke_buffer); libxsmm_free(l_totals); libxsmm_free(gflop_array); { const char *const env_check_scale = getenv("CHECK_SCALE"); const double check_scale = LIBXSMM_ABS(0 == env_check_scale ? 1.0 : atof(env_check_scale)); if (LIBXSMM_NEQ(0, check) && (check < 100.0 * check_scale * diff.normf_rel) && (global_status == LIBXSMM_DNN_SUCCESS)) { fprintf(stderr, "FAILED with an error of %f%%!\n", 100.0 * diff.normf_rel); exit(EXIT_FAILURE); } } /* some empty lines at the end */ printf("\n\n\n"); return global_status; }

declare_reduction_messages.c

// RUN: %clang_cc1 -verify -fopenmp -ferror-limit 100 %s // RUN: %clang_cc1 -verify -fopenmp-simd -ferror-limit 100 %s int temp; // expected-note 6 {{'temp' declared here}} #pragma omp declare reduction // expected-error {{expected '(' after 'declare reduction'}} #pragma omp declare reduction { // expected-error {{expected '(' after 'declare reduction'}} #pragma omp declare reduction( // expected-error {{expected identifier or one of the following operators: '+', '-', '*', '&', '|', '^', '&&', or '||'}} #pragma omp declare reduction(# // expected-error {{expected identifier or one of the following operators: '+', '-', '*', '&', '|', '^', '&&', or '||'}} #pragma omp declare reduction(/ // expected-error {{expected identifier or one of the following operators: '+', '-', '*', '&', '|', '^', '&&', or '||'}} #pragma omp declare reduction(+ // expected-error {{expected ':'}} #pragma omp declare reduction(for // expected-error {{expected identifier or one of the following operators: '+', '-', '*', '&', '|', '^', '&&', or '||'}} #pragma omp declare reduction(if: // expected-error {{expected identifier or one of the following operators: '+', '-', '*', '&', '|', '^', '&&', or '||'}} expected-error {{expected a type}} #pragma omp declare reduction(oper: // expected-error {{expected a type}} #pragma omp declare reduction(oper; // expected-error {{expected ':'}} expected-error {{expected a type}} #pragma omp declare reduction(fun : int // expected-error {{expected ':'}} expected-error {{expected expression}} #pragma omp declare reduction(+ : const int: // expected-error {{reduction type cannot be qualified with 'const', 'volatile' or 'restrict'}} #pragma omp declare reduction(- : volatile int: // expected-error {{reduction type cannot be qualified with 'const', 'volatile' or 'restrict'}} #pragma omp declare reduction(* : int; // expected-error {{expected ','}} expected-error {{expected a type}} #pragma omp declare reduction(& : double char: // expected-error {{cannot combine with previous 'double' declaration specifier}} expected-error {{expected expression}} #pragma omp declare reduction(^ : double, char, : // expected-error {{expected a type}} expected-error {{expected expression}} #pragma omp declare reduction(&& : int, S: // expected-error {{unknown type name 'S'}} expected-error {{expected expression}} #pragma omp declare reduction(|| : int, double : temp += omp_in) // expected-error 2 {{only 'omp_in' or 'omp_out' variables are allowed in combiner expression}} #pragma omp declare reduction(| : char, float : omp_out += temp) // expected-error 2 {{only 'omp_in' or 'omp_out' variables are allowed in combiner expression}} #pragma omp declare reduction(fun : long : omp_out += omp_in) { // expected-error {{expected 'initializer'}} expected-warning {{extra tokens at the end of '#pragma omp declare reduction' are ignored}} #pragma omp declare reduction(fun : unsigned : omp_out += temp)) // expected-error {{expected 'initializer'}} expected-warning {{extra tokens at the end of '#pragma omp declare reduction' are ignored}} expected-error {{only 'omp_in' or 'omp_out' variables are allowed in combiner expression}} #pragma omp declare reduction(fun : long(void) : omp_out += omp_in) // expected-error {{reduction type cannot be a function type}} #pragma omp declare reduction(fun : long[3] : omp_out += omp_in) // expected-error {{reduction type cannot be an array type}} #pragma omp declare reduction(fun23 : long, int, long : omp_out += omp_in) // expected-error {{redefinition of user-defined reduction for type 'long'}} expected-note {{previous definition is here}} #pragma omp declare reduction(fun222 : long : omp_out += omp_in) #pragma omp declare reduction(fun1 : long : omp_out += omp_in) initializer // expected-error {{expected '(' after 'initializer'}} #pragma omp declare reduction(fun2 : long : omp_out += omp_in) initializer { // expected-error {{expected '(' after 'initializer'}} expected-error {{expected expression}} expected-warning {{extra tokens at the end of '#pragma omp declare reduction' are ignored}} #pragma omp declare reduction(fun3 : long : omp_out += omp_in) initializer[ // expected-error {{expected '(' after 'initializer'}} expected-error {{expected expression}} expected-warning {{extra tokens at the end of '#pragma omp declare reduction' are ignored}} #pragma omp declare reduction(fun4 : long : omp_out += omp_in) initializer() // expected-error {{expected expression}} #pragma omp declare reduction(fun5 : long : omp_out += omp_in) initializer(temp) // expected-error {{only 'omp_priv' or 'omp_orig' variables are allowed in initializer expression}} #pragma omp declare reduction(fun6 : long : omp_out += omp_in) initializer(omp_orig // expected-error {{expected ')'}} expected-note {{to match this '('}} #pragma omp declare reduction(fun7 : long : omp_out += omp_in) initializer(omp_priv 12) // expected-error {{expected ')'}} expected-note {{to match this '('}} #pragma omp declare reduction(fun8 : long : omp_out += omp_in) initializer(omp_priv = 23) // expected-note {{previous definition is here}} #pragma omp declare reduction(fun8 : long : omp_out += omp_in) initializer(omp_priv = 23)) // expected-warning {{extra tokens at the end of '#pragma omp declare reduction' are ignored}} expected-error {{redefinition of user-defined reduction for type 'long'}} #pragma omp declare reduction(fun9 : long : omp_out += omp_in) initializer(omp_priv = ) // expected-error {{expected expression}} struct S { int s; }; #pragma omp declare reduction(+: struct S: omp_out.s += omp_in.s) // initializer(omp_priv = { .s = 0 }) int fun(int arg) { struct S s;// expected-note {{'s' defined here}} s.s = 0; #pragma omp parallel for reduction(+ : s) // expected-error {{list item of type 'struct S' is not valid for specified reduction operation: unable to provide default initialization value}} for (arg = 0; arg < 10; ++arg) s.s += arg; #pragma omp declare reduction(red : int : omp_out++) { #pragma omp declare reduction(red : int : omp_out++) // expected-note {{previous definition is here}} #pragma omp declare reduction(red : int : omp_out++) // expected-error {{redefinition of user-defined reduction for type 'int'}} { #pragma omp declare reduction(red : int : omp_out++) } } return arg; }

comms.h

/* //@HEADER // ***************************************************************************** // // XtraPuLP: Xtreme-Scale Graph Partitioning using Label Propagation // Copyright (2016) Sandia Corporation // // Under the terms of Contract DE-AC04-94AL85000 with Sandia Corporation, // the U.S. Government retains certain rights in this software. // // Redistribution and use in source and binary forms, with or without // modification, are permitted provided that the following conditions are // met: // // 1. Redistributions of source code must retain the above copyright // notice, this list of conditions and the following disclaimer. // // 2. 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. // // 3. Neither the name of the Corporation nor the names of the // contributors may be used to endorse or promote products derived from // this software without specific prior written permission. // // THIS SOFTWARE IS PROVIDED BY SANDIA CORPORATION "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 SANDIA CORPORATION OR THE // 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. // // Questions? Contact George M. Slota (gmslota@sandia.gov) // Siva Rajamanickam (srajama@sandia.gov) // Kamesh Madduri (madduri@cse.psu.edu) // // ***************************************************************************** //@HEADER */ #ifndef _COMMS_H_ #define _COMMS_H_ #include <mpi.h> #include <omp.h> #include <stdio.h> #include <stdlib.h> #include <stdint.h> #include <assert.h> #include "xtrapulp.h" #include "util.h" namespace pulp{ extern int procid, nprocs; extern bool verbose, debug, verify; extern MPI_Comm pulp_comm; #define MAX_SEND_SIZE 2147483648 #define THREAD_QUEUE_SIZE 1024 struct mpi_data_t { int32_t* sendcounts; uint64_t* sendcounts_temp; int32_t* recvcounts; uint64_t* recvcounts_temp; int32_t* sdispls; int32_t* rdispls; int32_t* sdispls_cpy; uint64_t* sdispls_temp; uint64_t* sendbuf_vert; int32_t* sendbuf_data; uint64_t* recvbuf_vert; int32_t* recvbuf_data; uint64_t total_recv; uint64_t total_send; uint64_t global_queue_size; }; struct queue_data_t { uint64_t* queue; uint64_t* queue_next; uint64_t* queue_send; uint64_t queue_size; uint64_t next_size; uint64_t send_size; }; struct thread_queue_t { int32_t tid; uint64_t* thread_queue; uint64_t* thread_send; uint64_t thread_queue_size; uint64_t thread_send_size; } ; struct thread_comm_t { int32_t tid; bool* v_to_rank; uint64_t* sendcounts_thread; uint64_t* sendbuf_vert_thread; int32_t* sendbuf_data_thread ; int32_t* sendbuf_rank_thread; uint64_t* thread_starts; uint64_t thread_queue_size; }; void init_queue_data(dist_graph_t* g, queue_data_t* q); void clear_queue_data(queue_data_t* q); void init_comm_data(mpi_data_t* comm); void clear_comm_data(mpi_data_t* comm); void init_thread_queue(thread_queue_t* tq); void clear_thread_queue(thread_queue_t* tq); void init_thread_comm(thread_comm_t* tc); void clear_thread_comm(thread_comm_t* tc); void init_sendbuf_vid_data(mpi_data_t* comm); void clear_recvbuf_vid_data(mpi_data_t* comm); inline void exchange_verts(dist_graph_t* g, mpi_data_t* comm, queue_data_t* q); inline void exchange_vert_data(dist_graph_t* g, mpi_data_t* comm, queue_data_t* q); inline void update_sendcounts_thread(dist_graph_t* g, thread_comm_t* tc, uint64_t vert_index); inline void update_vid_data_queues(dist_graph_t* g, thread_comm_t* tc, mpi_data_t* comm, uint64_t vert_index, int32_t* data); inline void add_vid_to_queue(thread_queue_t* tq, queue_data_t* q, uint64_t vertex_id); inline void empty_queue(thread_queue_t* tq, queue_data_t* q); inline void add_vid_to_send(thread_queue_t* tq, queue_data_t* q, uint64_t vertex_id); inline void empty_send(thread_queue_t* tq, queue_data_t* q); inline void add_vid_data_to_send(thread_comm_t* tc, mpi_data_t* comm, uint64_t vertex_id, int32_t data_val, int32_t send_rank); inline void empty_vid_data(thread_comm_t* tc, mpi_data_t* comm); inline void exchange_verts(dist_graph_t* g, mpi_data_t* comm, queue_data_t* q) { comm->global_queue_size = 0; uint64_t task_queue_size = q->next_size + q->send_size; MPI_Allreduce(&task_queue_size, &comm->global_queue_size, 1, MPI_UINT64_T, MPI_SUM, pulp_comm); uint64_t num_comms = comm->global_queue_size / (uint64_t)MAX_SEND_SIZE + 1; uint64_t sum_recv = 0; for (uint64_t c = 0; c < num_comms; ++c) { uint64_t send_begin = (q->send_size * c) / num_comms; uint64_t send_end = (q->send_size * (c + 1)) / num_comms; if (c == (num_comms-1)) send_end = q->send_size; for (int32_t i = 0; i < nprocs; ++i) { comm->sendcounts[i] = 0; comm->recvcounts[i] = 0; } for (uint64_t i = send_begin; i < send_end; ++i) { uint64_t ghost_index = q->queue_send[i] - g->n_local; uint64_t ghost_task = g->ghost_tasks[ghost_index]; ++comm->sendcounts[ghost_task]; } MPI_Alltoall(comm->sendcounts, 1, MPI_INT32_T, comm->recvcounts, 1, MPI_INT32_T, pulp_comm); comm->sdispls[0] = 0; comm->sdispls_cpy[0] = 0; comm->rdispls[0] = 0; for (int32_t i = 1; i < nprocs; ++i) { comm->sdispls[i] = comm->sdispls[i-1] + comm->sendcounts[i-1]; comm->rdispls[i] = comm->rdispls[i-1] + comm->recvcounts[i-1]; comm->sdispls_cpy[i] = comm->sdispls[i]; } int32_t cur_send = comm->sdispls[nprocs-1] + comm->sendcounts[nprocs-1]; int32_t cur_recv = comm->rdispls[nprocs-1] + comm->recvcounts[nprocs-1]; comm->sendbuf_vert = (uint64_t*)malloc((uint64_t)(cur_send+1)*sizeof(uint64_t)); if (comm->sendbuf_vert == NULL) throw_err("exchange_verts(), unable to allocate comm buffers", procid); for (uint64_t i = send_begin; i < send_end; ++i) { uint64_t ghost_index = q->queue_send[i] - g->n_local; uint64_t ghost_task = g->ghost_tasks[ghost_index]; uint64_t vert = g->ghost_unmap[ghost_index]; comm->sendbuf_vert[comm->sdispls_cpy[ghost_task]++] = vert; } MPI_Alltoallv(comm->sendbuf_vert, comm->sendcounts, comm->sdispls, MPI_UINT64_T, q->queue_next+q->next_size+sum_recv, comm->recvcounts, comm->rdispls, MPI_UINT64_T, pulp_comm); free(comm->sendbuf_vert); sum_recv += cur_recv; } q->queue_size = q->next_size + sum_recv; q->next_size = 0; q->send_size = 0; uint64_t* temp = q->queue; q->queue = q->queue_next; q->queue_next = temp; } inline void exchange_vert_data(dist_graph_t* g, mpi_data_t* comm, queue_data_t* q) { for (int32_t i = 0; i < nprocs; ++i) comm->recvcounts_temp[i] = 0; for (int32_t i = 0; i < nprocs; ++i) comm->sdispls_temp[i] -= comm->sendcounts_temp[i]; MPI_Alltoall(comm->sendcounts_temp, 1, MPI_UINT64_T, comm->recvcounts_temp, 1, MPI_UINT64_T, pulp_comm); comm->total_recv = 0; for (int i = 0; i < nprocs; ++i) comm->total_recv += comm->recvcounts_temp[i]; comm->recvbuf_vert = (uint64_t*)malloc(comm->total_recv*sizeof(uint64_t)); comm->recvbuf_data = (int32_t*)malloc(comm->total_recv*sizeof(uint32_t)); if (comm->recvbuf_vert == NULL || comm->sendbuf_vert == NULL) throw_err("exchange_vert_data() unable to allocate comm buffers", procid); comm->global_queue_size = 0; uint64_t task_queue_size = comm->total_send; MPI_Allreduce(&task_queue_size, &comm->global_queue_size, 1, MPI_UINT64_T, MPI_SUM, pulp_comm); uint64_t num_comms = comm->global_queue_size / (uint64_t)MAX_SEND_SIZE + 1; uint64_t sum_recv = 0; uint64_t sum_send = 0; for (uint64_t c = 0; c < num_comms; ++c) { for (int32_t i = 0; i < nprocs; ++i) { uint64_t send_begin = (comm->sendcounts_temp[i] * c) / num_comms; uint64_t send_end = (comm->sendcounts_temp[i] * (c + 1)) / num_comms; if (c == (num_comms-1)) send_end = comm->sendcounts_temp[i]; comm->sendcounts[i] = (int32_t)(send_end - send_begin); assert(comm->sendcounts[i] >= 0); } MPI_Alltoall(comm->sendcounts, 1, MPI_INT32_T, comm->recvcounts, 1, MPI_INT32_T, pulp_comm); comm->sdispls[0] = 0; comm->sdispls_cpy[0] = 0; comm->rdispls[0] = 0; for (int32_t i = 1; i < nprocs; ++i) { comm->sdispls[i] = comm->sdispls[i-1] + comm->sendcounts[i-1]; comm->rdispls[i] = comm->rdispls[i-1] + comm->recvcounts[i-1]; comm->sdispls_cpy[i] = comm->sdispls[i]; } int32_t cur_send = comm->sdispls[nprocs-1] + comm->sendcounts[nprocs-1]; int32_t cur_recv = comm->rdispls[nprocs-1] + comm->recvcounts[nprocs-1]; uint64_t* buf_v = (uint64_t*)malloc((uint64_t)(cur_send)*sizeof(uint64_t)); int32_t* buf_d = (int32_t*)malloc((int32_t)(cur_send)*sizeof(int32_t)); if (buf_v == NULL || buf_d == NULL) throw_err("exchange_verts(), unable to allocate comm buffers", procid); for (int32_t i = 0; i < nprocs; ++i) { uint64_t send_begin = (comm->sendcounts_temp[i] * c) / num_comms; uint64_t send_end = (comm->sendcounts_temp[i] * (c + 1)) / num_comms; if (c == (num_comms-1)) send_end = comm->sendcounts_temp[i]; for (uint64_t j = send_begin; j < send_end; ++j) { uint64_t vert = comm->sendbuf_vert[comm->sdispls_temp[i]+j]; int32_t data = comm->sendbuf_data[comm->sdispls_temp[i]+j]; buf_v[comm->sdispls_cpy[i]] = vert; buf_d[comm->sdispls_cpy[i]++] = data; } } MPI_Alltoallv(buf_v, comm->sendcounts, comm->sdispls, MPI_UINT64_T, comm->recvbuf_vert+sum_recv, comm->recvcounts, comm->rdispls, MPI_UINT64_T, pulp_comm); MPI_Alltoallv(buf_d, comm->sendcounts, comm->sdispls, MPI_INT32_T, comm->recvbuf_data+sum_recv, comm->recvcounts, comm->rdispls, MPI_INT32_T, pulp_comm); free(buf_v); free(buf_d); sum_recv += cur_recv; sum_send += cur_send; } free(comm->sendbuf_data); free(comm->sendbuf_vert); assert(sum_recv == comm->total_recv); assert(sum_send == comm->total_send); comm->global_queue_size = 0; task_queue_size = comm->total_recv + q->next_size; MPI_Allreduce(&task_queue_size, &comm->global_queue_size, 1, MPI_UINT64_T, MPI_SUM, pulp_comm); q->next_size = 0; q->send_size = 0; } inline void update_sendcounts_thread(dist_graph_t* g, thread_comm_t* tc, uint64_t vert_index) { for (int32_t i = 0; i < nprocs; ++i) tc->v_to_rank[i] = false; uint64_t out_degree = out_degree(g, vert_index); uint64_t* outs = out_vertices(g, vert_index); for (uint64_t j = 0; j < out_degree; ++j) { uint64_t out_index = outs[j]; if (out_index >= g->n_local) { int32_t out_rank = g->ghost_tasks[out_index-g->n_local]; if (!tc->v_to_rank[out_rank]) { tc->v_to_rank[out_rank] = true; ++tc->sendcounts_thread[out_rank]; } } } } inline void update_vid_data_queues(dist_graph_t* g, thread_comm_t* tc, mpi_data_t* comm, uint64_t vert_index, int32_t data) { for (int32_t i = 0; i < nprocs; ++i) tc->v_to_rank[i] = false; uint64_t out_degree = out_degree(g, vert_index); uint64_t* outs = out_vertices(g, vert_index); for (uint64_t j = 0; j < out_degree; ++j) { uint64_t out_index = outs[j]; if (out_index >= g->n_local) { int32_t out_rank = g->ghost_tasks[out_index - g->n_local]; if (!tc->v_to_rank[out_rank]) { tc->v_to_rank[out_rank] = true; add_vid_data_to_send(tc, comm, g->local_unmap[vert_index], data, out_rank); } } } } inline void add_vid_to_queue(thread_queue_t* tq, queue_data_t* q, uint64_t vertex_id) { tq->thread_queue[tq->thread_queue_size++] = vertex_id; if (tq->thread_queue_size == THREAD_QUEUE_SIZE) { uint64_t start_offset; #pragma omp atomic capture start_offset = q->next_size += THREAD_QUEUE_SIZE; start_offset -= THREAD_QUEUE_SIZE; for (uint64_t i = 0; i < THREAD_QUEUE_SIZE; ++i) q->queue_next[start_offset + i] = tq->thread_queue[i]; tq->thread_queue_size = 0; } } inline void empty_queue(thread_queue_t* tq, queue_data_t* q) { uint64_t start_offset; #pragma omp atomic capture start_offset = q->next_size += tq->thread_queue_size; start_offset -= tq->thread_queue_size; for (uint64_t i = 0; i < tq->thread_queue_size; ++i) q->queue_next[start_offset + i] = tq->thread_queue[i]; tq->thread_queue_size = 0; } inline void add_vid_to_send(thread_queue_t* tq, queue_data_t* q, uint64_t vertex_id) { tq->thread_send[tq->thread_send_size++] = vertex_id; if (tq->thread_send_size == THREAD_QUEUE_SIZE) { uint64_t start_offset; #pragma omp atomic capture start_offset = q->send_size += tq->thread_send_size; start_offset -= tq->thread_send_size; for (uint64_t i = 0; i < THREAD_QUEUE_SIZE; ++i) q->queue_send[start_offset + i] = tq->thread_send[i]; tq->thread_send_size = 0; } } inline void empty_send(thread_queue_t* tq, queue_data_t* q) { uint64_t start_offset; #pragma omp atomic capture start_offset = q->send_size += tq->thread_send_size; start_offset -= tq->thread_send_size; for (uint64_t i = 0; i < tq->thread_send_size; ++i) q->queue_send[start_offset + i] = tq->thread_send[i]; tq->thread_send_size = 0; } inline void add_vid_data_to_send(thread_comm_t* tc, mpi_data_t* comm, uint64_t vertex_id, int32_t data_val, int32_t send_rank) { tc->sendbuf_vert_thread[tc->thread_queue_size] = vertex_id; tc->sendbuf_data_thread[tc->thread_queue_size] = data_val; tc->sendbuf_rank_thread[tc->thread_queue_size] = send_rank; ++tc->thread_queue_size; ++tc->sendcounts_thread[send_rank]; if (tc->thread_queue_size == THREAD_QUEUE_SIZE) { for (int32_t i = 0; i < nprocs; ++i) { #pragma omp atomic capture tc->thread_starts[i] = comm->sdispls_temp[i] += tc->sendcounts_thread[i]; tc->thread_starts[i] -= tc->sendcounts_thread[i]; } for (uint64_t i = 0; i < tc->thread_queue_size; ++i) { int32_t cur_rank = tc->sendbuf_rank_thread[i]; comm->sendbuf_vert[tc->thread_starts[cur_rank]] = tc->sendbuf_vert_thread[i]; comm->sendbuf_data[tc->thread_starts[cur_rank]] = tc->sendbuf_data_thread[i]; ++tc->thread_starts[cur_rank]; } for (int32_t i = 0; i < nprocs; ++i) { tc->thread_starts[i] = 0; tc->sendcounts_thread[i] = 0; } tc->thread_queue_size = 0; } } inline void empty_vid_data(thread_comm_t* tc, mpi_data_t* comm) { for (int32_t i = 0; i < nprocs; ++i) { #pragma omp atomic capture tc->thread_starts[i] = comm->sdispls_temp[i] += tc->sendcounts_thread[i]; tc->thread_starts[i] -= tc->sendcounts_thread[i]; } for (uint64_t i = 0; i < tc->thread_queue_size; ++i) { int32_t cur_rank = tc->sendbuf_rank_thread[i]; comm->sendbuf_vert[tc->thread_starts[cur_rank]] = tc->sendbuf_vert_thread[i]; comm->sendbuf_data[tc->thread_starts[cur_rank]] = tc->sendbuf_data_thread[i]; ++tc->thread_starts[cur_rank]; } for (int32_t i = 0; i < nprocs; ++i) { tc->thread_starts[i] = 0; tc->sendcounts_thread[i] = 0; } tc->thread_queue_size = 0; } } #endif

cell_division_gpu.h

// ----------------------------------------------------------------------------- // // Copyright (C) The BioDynaMo Project. // 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. // // See the LICENSE file distributed with this work for details. // See the NOTICE file distributed with this work for additional information // regarding copyright ownership. // // ----------------------------------------------------------------------------- #ifndef SYSTEM_CELL_DIVISION_GPU_SRC_CELL_DIVISION_GPU_H_ #define SYSTEM_CELL_DIVISION_GPU_SRC_CELL_DIVISION_GPU_H_ #include <array> #include "biodynamo.h" #include "core/param/command_line_options.h" #include "core/util/math.h" #include "core/util/timing.h" namespace bdm { // ---------------------------------------------------------------------------- // Starting with 8 cells, we let each cell grow in volume up until a point // a cell must divide. This tests whether the GPU accelerated mechanical // interactions properly handle the creation of new cells. // ----------------------------------------------------------------------------- inline void ExpectArrayNear(const Double3& actual, const Double3& expected, bool* wrong) { for (size_t i = 0; i < actual.size(); i++) { if (std::fabs(expected[i] - actual[i]) > 1e-9) { *wrong = true; std::cout << "Wrong result! Expected " << expected[i] << ", but instead got " << actual[i] << ", which is a difference of " << std::fabs(expected[i] - actual[i]) << ", which is larger than 1e-9" << std::endl; } } } inline void RunTest(bool* wrong, OpComputeTarget mode, uint64_t timesteps, uint64_t cells_per_dim) { std::cout << "Running simulation on "; auto set_param = [&](auto* param) { switch (mode) { case kCpu: std::cout << "CPU (" << omp_get_max_threads() << " threads)\n"; break; case kOpenCl: std::cout << "GPU (OpenCL)\n"; param->compute_target = "opencl"; break; case kCuda: std::cout << "GPU (CUDA)\n"; param->compute_target = "cuda"; break; } }; Simulation simulation("cell_division_gpu", set_param); auto* rm = simulation.GetResourceManager(); rm->ClearAgents(); // We need to give every test the same seed for the RNG, because in the cell // division, random numbers are used. Within a single executable these numbers // vary. Also within the threads this needs to be enforced #pragma omp parallel simulation.GetRandom()->SetSeed(1); auto construct = [](const Double3& position) { auto* cell = new Cell(position); cell->SetDiameter(30); cell->SetAdherence(0.4); cell->SetMass(1.0); cell->AddBehavior(new GrowthDivision(30.05, 5000)); return cell; }; for (size_t x = 0; x < cells_per_dim; x++) { double x_pos = x * 20.0; for (size_t y = 0; y < cells_per_dim; y++) { double y_pos = y * 20.0; for (size_t z = 0; z < cells_per_dim; z++) { auto new_simulation_object = construct({x_pos, y_pos, z * 20.0}); rm->AddAgent(new_simulation_object); } } } { Timing timer("Execution time"); simulation.GetScheduler()->Simulate(timesteps); } // TODO: add verification of results } inline int Simulate(int argc, const char** argv) { auto options = CommandLineOptions(argc, argv); options.AddOption<bool>("verify", "false"); options.AddOption<uint64_t>("cells-per-dim", "64"); options.AddOption<uint64_t>("timesteps", "5"); uint64_t cells_per_dim = options.Get<uint64_t>("cells-per-dim"); uint64_t timesteps = options.Get<uint64_t>("timesteps"); bool wrong = true; bool is_opencl = options.Get<bool>("opencl"); bool is_cuda = options.Get<bool>("cuda"); // TODO(ahmad): after Trello card ("Fix inconsistency in cell state due to // direct updates in Biology Modules") enable multithreading, and adjust // results if necessary // omp_set_num_threads(1); if (!is_cuda && !is_opencl) { // Run CPU version RunTest(&wrong, kCpu, timesteps, cells_per_dim); } #ifdef USE_CUDA if (is_cuda) { // Run GPU (CUDA) version RunTest(&wrong, kCuda, timesteps, cells_per_dim); } #endif // USE_CUDA #ifdef USE_OPENCL if (is_opencl) { // Run GPU (OpenCL) version RunTest(&wrong, kOpenCl, timesteps, cells_per_dim); } #endif // USE_OPENCL return !wrong; } } // namespace bdm #endif // SYSTEM_CELL_DIVISION_GPU_SRC_CELL_DIVISION_GPU_H_

GB_unaryop__ainv_int32_int64.c

//------------------------------------------------------------------------------ // GB_unaryop: hard-coded functions for each built-in unary operator //------------------------------------------------------------------------------ // SuiteSparse:GraphBLAS, Timothy A. Davis, (c) 2017-2019, 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__ainv_int32_int64 // op(A') function: GB_tran__ainv_int32_int64 // C type: int32_t // A type: int64_t // cast: int32_t cij = (int32_t) aij // unaryop: cij = -aij #define GB_ATYPE \ int64_t #define GB_CTYPE \ int32_t // aij = Ax [pA] #define GB_GETA(aij,Ax,pA) \ int64_t aij = Ax [pA] #define GB_CX(p) Cx [p] // unary operator #define GB_OP(z, x) \ z = -x ; // casting #define GB_CASTING(z, x) \ int32_t z = (int32_t) x ; // 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 (x, aij) ; \ GB_OP (GB_CX (pC), x) ; \ } // disable this operator and use the generic case if these conditions hold #define GB_DISABLE \ (GxB_NO_AINV || GxB_NO_INT32 || GxB_NO_INT64) //------------------------------------------------------------------------------ // Cx = op (cast (Ax)): apply a unary operator //------------------------------------------------------------------------------ GrB_Info GB_unop__ainv_int32_int64 ( int32_t *restrict Cx, const int64_t *restrict Ax, int64_t anz, int nthreads ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else #pragma omp parallel for num_threads(nthreads) schedule(static) for (int64_t 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__ainv_int32_int64 ( GrB_Matrix C, const GrB_Matrix A, int64_t *restrict *Rowcounts, GBI_single_iterator Iter, const int64_t *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

cache.c

/* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % CCCC AAA CCCC H H EEEEE % % C A A C H H E % % C AAAAA C HHHHH EEE % % C A A C H H E % % CCCC A A CCCC H H EEEEE % % % % % % MagickCore Pixel Cache Methods % % % % Software Design % % Cristy % % July 1999 % % % % % % Copyright 1999-2018 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/cache-private.h" #include "MagickCore/color-private.h" #include "MagickCore/colorspace-private.h" #include "MagickCore/composite-private.h" #include "MagickCore/distribute-cache-private.h" #include "MagickCore/exception.h" #include "MagickCore/exception-private.h" #include "MagickCore/geometry.h" #include "MagickCore/list.h" #include "MagickCore/log.h" #include "MagickCore/magick.h" #include "MagickCore/memory_.h" #include "MagickCore/memory-private.h" #include "MagickCore/nt-base-private.h" #include "MagickCore/option.h" #include "MagickCore/pixel.h" #include "MagickCore/pixel-accessor.h" #include "MagickCore/policy.h" #include "MagickCore/quantum.h" #include "MagickCore/random_.h" #include "MagickCore/registry.h" #include "MagickCore/resource_.h" #include "MagickCore/semaphore.h" #include "MagickCore/splay-tree.h" #include "MagickCore/string_.h" #include "MagickCore/string-private.h" #include "MagickCore/thread-private.h" #include "MagickCore/utility.h" #include "MagickCore/utility-private.h" #if defined(MAGICKCORE_ZLIB_DELEGATE) #include "zlib.h" #endif /* Define declarations. */ #define CacheTick(offset,extent) QuantumTick((MagickOffsetType) offset,extent) #define IsFileDescriptorLimitExceeded() (GetMagickResource(FileResource) > \ GetMagickResourceLimit(FileResource) ? MagickTrue : MagickFalse) /* Typedef declarations. */ typedef struct _MagickModulo { ssize_t quotient, remainder; } MagickModulo; /* Forward declarations. */ #if defined(__cplusplus) || defined(c_plusplus) extern "C" { #endif static Cache GetImagePixelCache(Image *,const MagickBooleanType,ExceptionInfo *) magick_hot_spot; static const Quantum *GetVirtualPixelCache(const Image *,const VirtualPixelMethod,const ssize_t, const ssize_t,const size_t,const size_t,ExceptionInfo *), *GetVirtualPixelsCache(const Image *); static const void *GetVirtualMetacontentFromCache(const Image *); static MagickBooleanType GetOneAuthenticPixelFromCache(Image *,const ssize_t,const ssize_t,Quantum *, ExceptionInfo *), GetOneVirtualPixelFromCache(const Image *,const VirtualPixelMethod, const ssize_t,const ssize_t,Quantum *,ExceptionInfo *), OpenPixelCache(Image *,const MapMode,ExceptionInfo *), OpenPixelCacheOnDisk(CacheInfo *,const MapMode), ReadPixelCachePixels(CacheInfo *magick_restrict,NexusInfo *magick_restrict, ExceptionInfo *), ReadPixelCacheMetacontent(CacheInfo *magick_restrict, NexusInfo *magick_restrict,ExceptionInfo *), SyncAuthenticPixelsCache(Image *,ExceptionInfo *), WritePixelCachePixels(CacheInfo *magick_restrict,NexusInfo *magick_restrict, ExceptionInfo *), WritePixelCacheMetacontent(CacheInfo *,NexusInfo *magick_restrict, ExceptionInfo *); static Quantum *GetAuthenticPixelsCache(Image *,const ssize_t,const ssize_t,const size_t, const size_t,ExceptionInfo *), *QueueAuthenticPixelsCache(Image *,const ssize_t,const ssize_t,const size_t, const size_t,ExceptionInfo *), *SetPixelCacheNexusPixels(const CacheInfo *,const MapMode, const RectangleInfo *,const MagickBooleanType,NexusInfo *,ExceptionInfo *) magick_hot_spot; #if defined(MAGICKCORE_OPENCL_SUPPORT) static void CopyOpenCLBuffer(CacheInfo *magick_restrict); #endif #if defined(__cplusplus) || defined(c_plusplus) } #endif /* Global declarations. */ static SemaphoreInfo *cache_semaphore = (SemaphoreInfo *) NULL; static ssize_t cache_anonymous_memory = (-1); static time_t cache_epoch = 0; /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + A c q u i r e P i x e l C a c h e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % AcquirePixelCache() acquires a pixel cache. % % The format of the AcquirePixelCache() method is: % % Cache AcquirePixelCache(const size_t number_threads) % % A description of each parameter follows: % % o number_threads: the number of nexus threads. % */ MagickPrivate Cache AcquirePixelCache(const size_t number_threads) { CacheInfo *magick_restrict cache_info; char *value; cache_info=(CacheInfo *) AcquireCriticalMemory(sizeof(*cache_info)); (void) memset(cache_info,0,sizeof(*cache_info)); cache_info->type=UndefinedCache; cache_info->mode=IOMode; cache_info->disk_mode=IOMode; cache_info->colorspace=sRGBColorspace; cache_info->file=(-1); cache_info->id=GetMagickThreadId(); cache_info->number_threads=number_threads; if (GetOpenMPMaximumThreads() > cache_info->number_threads) cache_info->number_threads=GetOpenMPMaximumThreads(); if (GetMagickResourceLimit(ThreadResource) > cache_info->number_threads) cache_info->number_threads=(size_t) GetMagickResourceLimit(ThreadResource); if (cache_info->number_threads == 0) cache_info->number_threads=1; cache_info->nexus_info=AcquirePixelCacheNexus(cache_info->number_threads); if (cache_info->nexus_info == (NexusInfo **) NULL) ThrowFatalException(ResourceLimitFatalError,"MemoryAllocationFailed"); value=GetEnvironmentValue("MAGICK_SYNCHRONIZE"); if (value != (const char *) NULL) { cache_info->synchronize=IsStringTrue(value); value=DestroyString(value); } value=GetPolicyValue("cache:synchronize"); if (value != (const char *) NULL) { cache_info->synchronize=IsStringTrue(value); value=DestroyString(value); } cache_info->semaphore=AcquireSemaphoreInfo(); cache_info->reference_count=1; cache_info->file_semaphore=AcquireSemaphoreInfo(); cache_info->debug=IsEventLogging(); cache_info->signature=MagickCoreSignature; return((Cache ) cache_info); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % A c q u i r e P i x e l C a c h e N e x u s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % AcquirePixelCacheNexus() allocates the NexusInfo structure. % % The format of the AcquirePixelCacheNexus method is: % % NexusInfo **AcquirePixelCacheNexus(const size_t number_threads) % % A description of each parameter follows: % % o number_threads: the number of nexus threads. % */ MagickPrivate NexusInfo **AcquirePixelCacheNexus(const size_t number_threads) { NexusInfo **magick_restrict nexus_info; register ssize_t i; nexus_info=(NexusInfo **) MagickAssumeAligned(AcquireAlignedMemory( number_threads,sizeof(*nexus_info))); if (nexus_info == (NexusInfo **) NULL) ThrowFatalException(ResourceLimitFatalError,"MemoryAllocationFailed"); nexus_info[0]=(NexusInfo *) AcquireQuantumMemory(number_threads, sizeof(**nexus_info)); if (nexus_info[0] == (NexusInfo *) NULL) ThrowFatalException(ResourceLimitFatalError,"MemoryAllocationFailed"); (void) memset(nexus_info[0],0,number_threads*sizeof(**nexus_info)); for (i=0; i < (ssize_t) number_threads; i++) { nexus_info[i]=(&nexus_info[0][i]); nexus_info[i]->signature=MagickCoreSignature; } return(nexus_info); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % A c q u i r e P i x e l C a c h e P i x e l s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % AcquirePixelCachePixels() returns the pixels associated with the specified % image. % % The format of the AcquirePixelCachePixels() method is: % % void *AcquirePixelCachePixels(const Image *image,size_t *length, % ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o length: the pixel cache length. % % o exception: return any errors or warnings in this structure. % */ MagickExport void *AcquirePixelCachePixels(const Image *image,size_t *length, ExceptionInfo *exception) { CacheInfo *magick_restrict cache_info; assert(image != (const Image *) NULL); assert(image->signature == MagickCoreSignature); assert(exception != (ExceptionInfo *) NULL); assert(exception->signature == MagickCoreSignature); assert(image->cache != (Cache) NULL); cache_info=(CacheInfo *) image->cache; assert(cache_info->signature == MagickCoreSignature); *length=0; if ((cache_info->type != MemoryCache) && (cache_info->type != MapCache)) return((void *) NULL); *length=(size_t) cache_info->length; return(cache_info->pixels); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + C a c h e C o m p o n e n t G e n e s i s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % CacheComponentGenesis() instantiates the cache component. % % The format of the CacheComponentGenesis method is: % % MagickBooleanType CacheComponentGenesis(void) % */ MagickPrivate MagickBooleanType CacheComponentGenesis(void) { if (cache_semaphore == (SemaphoreInfo *) NULL) cache_semaphore=AcquireSemaphoreInfo(); return(MagickTrue); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + C a c h e C o m p o n e n t T e r m i n u s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % CacheComponentTerminus() destroys the cache component. % % The format of the CacheComponentTerminus() method is: % % CacheComponentTerminus(void) % */ MagickPrivate void CacheComponentTerminus(void) { if (cache_semaphore == (SemaphoreInfo *) NULL) ActivateSemaphoreInfo(&cache_semaphore); /* no op-- nothing to destroy */ RelinquishSemaphoreInfo(&cache_semaphore); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + C l i p P i x e l C a c h e N e x u s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % ClipPixelCacheNexus() clips the cache nexus as defined by the image clip % mask. The method returns MagickTrue if the pixel region is clipped, % otherwise MagickFalse. % % The format of the ClipPixelCacheNexus() method is: % % MagickBooleanType ClipPixelCacheNexus(Image *image,NexusInfo *nexus_info, % ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o nexus_info: the cache nexus to clip. % % o exception: return any errors or warnings in this structure. % */ static MagickBooleanType ClipPixelCacheNexus(Image *image, NexusInfo *nexus_info,ExceptionInfo *exception) { CacheInfo *magick_restrict cache_info; MagickSizeType number_pixels; NexusInfo **magick_restrict image_nexus; register Quantum *magick_restrict p, *magick_restrict q; register ssize_t n; /* Apply clip mask. */ if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); if ((image->channels & WriteMaskChannel) == 0) return(MagickTrue); cache_info=(CacheInfo *) image->cache; if (cache_info == (Cache) NULL) return(MagickFalse); image_nexus=AcquirePixelCacheNexus(1); p=GetAuthenticPixelCacheNexus(image,nexus_info->region.x,nexus_info->region.y, nexus_info->region.width,nexus_info->region.height,image_nexus[0], exception); q=nexus_info->pixels; number_pixels=(MagickSizeType) nexus_info->region.width* nexus_info->region.height; for (n=0; n < (ssize_t) number_pixels; n++) { double mask_alpha; register ssize_t i; if (p == (Quantum *) NULL) break; mask_alpha=QuantumScale*GetPixelWriteMask(image,p); if (fabs(mask_alpha) >= MagickEpsilon) { for (i=0; i < (ssize_t) image->number_channels; i++) { PixelChannel channel = GetPixelChannelChannel(image,i); PixelTrait traits = GetPixelChannelTraits(image,channel); if ((traits & UpdatePixelTrait) == 0) continue; q[i]=ClampToQuantum(MagickOver_((double) p[i],mask_alpha* GetPixelAlpha(image,p),(double) q[i],(double) GetPixelAlpha(image,q))); } SetPixelAlpha(image,GetPixelAlpha(image,p),q); } p+=GetPixelChannels(image); q+=GetPixelChannels(image); } image_nexus=DestroyPixelCacheNexus(image_nexus,1); if (n < (ssize_t) number_pixels) return(MagickFalse); return(MagickTrue); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + C l o n e P i x e l C a c h e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % ClonePixelCache() clones a pixel cache. % % The format of the ClonePixelCache() method is: % % Cache ClonePixelCache(const Cache cache) % % A description of each parameter follows: % % o cache: the pixel cache. % */ MagickPrivate Cache ClonePixelCache(const Cache cache) { CacheInfo *magick_restrict clone_info; const CacheInfo *magick_restrict cache_info; assert(cache != NULL); cache_info=(const CacheInfo *) cache; assert(cache_info->signature == MagickCoreSignature); if (cache_info->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s", cache_info->filename); clone_info=(CacheInfo *) AcquirePixelCache(cache_info->number_threads); clone_info->virtual_pixel_method=cache_info->virtual_pixel_method; return((Cache ) clone_info); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + C l o n e P i x e l C a c h e M e t h o d s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % ClonePixelCacheMethods() clones the pixel cache methods from one cache to % another. % % The format of the ClonePixelCacheMethods() method is: % % void ClonePixelCacheMethods(Cache clone,const Cache cache) % % A description of each parameter follows: % % o clone: Specifies a pointer to a Cache structure. % % o cache: the pixel cache. % */ MagickPrivate void ClonePixelCacheMethods(Cache clone,const Cache cache) { CacheInfo *magick_restrict cache_info, *magick_restrict source_info; assert(clone != (Cache) NULL); source_info=(CacheInfo *) clone; assert(source_info->signature == MagickCoreSignature); if (source_info->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s", source_info->filename); assert(cache != (Cache) NULL); cache_info=(CacheInfo *) cache; assert(cache_info->signature == MagickCoreSignature); source_info->methods=cache_info->methods; } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + C l o n e P i x e l C a c h e R e p o s i t o r y % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % ClonePixelCacheRepository() clones the source pixel cache to the destination % cache. % % The format of the ClonePixelCacheRepository() method is: % % MagickBooleanType ClonePixelCacheRepository(CacheInfo *cache_info, % CacheInfo *source_info,ExceptionInfo *exception) % % A description of each parameter follows: % % o cache_info: the pixel cache. % % o source_info: the source pixel cache. % % o exception: return any errors or warnings in this structure. % */ static MagickBooleanType ClonePixelCacheOnDisk( CacheInfo *magick_restrict cache_info,CacheInfo *magick_restrict clone_info) { MagickSizeType extent; size_t quantum; ssize_t count; struct stat file_stats; unsigned char *buffer; /* Clone pixel cache on disk with identical morphology. */ if ((OpenPixelCacheOnDisk(cache_info,ReadMode) == MagickFalse) || (OpenPixelCacheOnDisk(clone_info,IOMode) == MagickFalse)) return(MagickFalse); if ((lseek(cache_info->file,0,SEEK_SET) < 0) || (lseek(clone_info->file,0,SEEK_SET) < 0)) return(MagickFalse); quantum=(size_t) MagickMaxBufferExtent; if ((fstat(cache_info->file,&file_stats) == 0) && (file_stats.st_size > 0)) quantum=(size_t) MagickMin(file_stats.st_size,MagickMaxBufferExtent); buffer=(unsigned char *) AcquireQuantumMemory(quantum,sizeof(*buffer)); if (buffer == (unsigned char *) NULL) ThrowFatalException(ResourceLimitFatalError,"MemoryAllocationFailed"); extent=0; while ((count=read(cache_info->file,buffer,quantum)) > 0) { ssize_t number_bytes; number_bytes=write(clone_info->file,buffer,(size_t) count); if (number_bytes != count) break; extent+=number_bytes; } buffer=(unsigned char *) RelinquishMagickMemory(buffer); if (extent != cache_info->length) return(MagickFalse); return(MagickTrue); } static MagickBooleanType ClonePixelCacheRepository( CacheInfo *magick_restrict clone_info,CacheInfo *magick_restrict cache_info, ExceptionInfo *exception) { #define MaxCacheThreads ((size_t) GetMagickResourceLimit(ThreadResource)) #define cache_number_threads(source,destination,chunk,multithreaded) \ num_threads((multithreaded) == 0 ? 1 : \ (((source)->type != MemoryCache) && ((source)->type != MapCache)) || \ (((destination)->type != MemoryCache) && ((destination)->type != MapCache)) ? \ MagickMax(MagickMin(GetMagickResourceLimit(ThreadResource),2),1) : \ MagickMax(MagickMin((ssize_t) GetMagickResourceLimit(ThreadResource),(ssize_t) (chunk)/256),1)) MagickBooleanType optimize, status; NexusInfo **magick_restrict cache_nexus, **magick_restrict clone_nexus; size_t length; ssize_t y; assert(cache_info != (CacheInfo *) NULL); assert(clone_info != (CacheInfo *) NULL); assert(exception != (ExceptionInfo *) NULL); if (cache_info->type == PingCache) return(MagickTrue); length=cache_info->number_channels*sizeof(*cache_info->channel_map); if ((cache_info->storage_class == clone_info->storage_class) && (cache_info->colorspace == clone_info->colorspace) && (cache_info->alpha_trait == clone_info->alpha_trait) && (cache_info->channels == clone_info->channels) && (cache_info->columns == clone_info->columns) && (cache_info->rows == clone_info->rows) && (cache_info->number_channels == clone_info->number_channels) && (memcmp(cache_info->channel_map,clone_info->channel_map,length) == 0) && (cache_info->metacontent_extent == clone_info->metacontent_extent)) { /* Identical pixel cache morphology. */ if (((cache_info->type == MemoryCache) || (cache_info->type == MapCache)) && ((clone_info->type == MemoryCache) || (clone_info->type == MapCache))) { (void) memcpy(clone_info->pixels,cache_info->pixels, cache_info->number_channels*cache_info->columns*cache_info->rows* sizeof(*cache_info->pixels)); if ((cache_info->metacontent_extent != 0) && (clone_info->metacontent_extent != 0)) (void) memcpy(clone_info->metacontent,cache_info->metacontent, cache_info->columns*cache_info->rows* clone_info->metacontent_extent*sizeof(unsigned char)); return(MagickTrue); } if ((cache_info->type == DiskCache) && (clone_info->type == DiskCache)) return(ClonePixelCacheOnDisk(cache_info,clone_info)); } /* Mismatched pixel cache morphology. */ cache_nexus=AcquirePixelCacheNexus(MaxCacheThreads); clone_nexus=AcquirePixelCacheNexus(MaxCacheThreads); length=cache_info->number_channels*sizeof(*cache_info->channel_map); optimize=(cache_info->number_channels == clone_info->number_channels) && (memcmp(cache_info->channel_map,clone_info->channel_map,length) == 0) ? MagickTrue : MagickFalse; length=(size_t) MagickMin(cache_info->number_channels*cache_info->columns, clone_info->number_channels*clone_info->columns); status=MagickTrue; #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(status) \ cache_number_threads(cache_info,clone_info,cache_info->rows,1) #endif for (y=0; y < (ssize_t) cache_info->rows; y++) { const int id = GetOpenMPThreadId(); Quantum *pixels; RectangleInfo region; register ssize_t x; if (status == MagickFalse) continue; if (y >= (ssize_t) clone_info->rows) continue; region.width=cache_info->columns; region.height=1; region.x=0; region.y=y; pixels=SetPixelCacheNexusPixels(cache_info,ReadMode,&region,MagickFalse, cache_nexus[id],exception); if (pixels == (Quantum *) NULL) continue; status=ReadPixelCachePixels(cache_info,cache_nexus[id],exception); if (status == MagickFalse) continue; region.width=clone_info->columns; pixels=SetPixelCacheNexusPixels(clone_info,WriteMode,&region,MagickFalse, clone_nexus[id],exception); if (pixels == (Quantum *) NULL) continue; (void) memset(clone_nexus[id]->pixels,0,(size_t) clone_nexus[id]->length); if (optimize != MagickFalse) (void) memcpy(clone_nexus[id]->pixels,cache_nexus[id]->pixels,length* sizeof(Quantum)); else { register const Quantum *magick_restrict p; register Quantum *magick_restrict q; /* Mismatched pixel channel map. */ p=cache_nexus[id]->pixels; q=clone_nexus[id]->pixels; for (x=0; x < (ssize_t) cache_info->columns; x++) { register ssize_t i; if (x == (ssize_t) clone_info->columns) break; for (i=0; i < (ssize_t) clone_info->number_channels; i++) { PixelChannel channel; PixelTrait traits; channel=clone_info->channel_map[i].channel; traits=cache_info->channel_map[channel].traits; if (traits != UndefinedPixelTrait) *q=*(p+cache_info->channel_map[channel].offset); q++; } p+=cache_info->number_channels; } } status=WritePixelCachePixels(clone_info,clone_nexus[id],exception); } if ((cache_info->metacontent_extent != 0) && (clone_info->metacontent_extent != 0)) { /* Clone metacontent. */ length=(size_t) MagickMin(cache_info->metacontent_extent, clone_info->metacontent_extent); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(status) \ cache_number_threads(cache_info,clone_info,cache_info->rows,1) #endif for (y=0; y < (ssize_t) cache_info->rows; y++) { const int id = GetOpenMPThreadId(); Quantum *pixels; RectangleInfo region; if (status == MagickFalse) continue; if (y >= (ssize_t) clone_info->rows) continue; region.width=cache_info->columns; region.height=1; region.x=0; region.y=y; pixels=SetPixelCacheNexusPixels(cache_info,ReadMode,&region,MagickFalse, cache_nexus[id],exception); if (pixels == (Quantum *) NULL) continue; status=ReadPixelCacheMetacontent(cache_info,cache_nexus[id],exception); if (status == MagickFalse) continue; region.width=clone_info->columns; pixels=SetPixelCacheNexusPixels(clone_info,WriteMode,&region, MagickFalse,clone_nexus[id],exception); if (pixels == (Quantum *) NULL) continue; if ((clone_nexus[id]->metacontent != (void *) NULL) && (cache_nexus[id]->metacontent != (void *) NULL)) (void) memcpy(clone_nexus[id]->metacontent, cache_nexus[id]->metacontent,length*sizeof(unsigned char)); status=WritePixelCacheMetacontent(clone_info,clone_nexus[id],exception); } } cache_nexus=DestroyPixelCacheNexus(cache_nexus,MaxCacheThreads); clone_nexus=DestroyPixelCacheNexus(clone_nexus,MaxCacheThreads); if (cache_info->debug != MagickFalse) { char message[MagickPathExtent]; (void) FormatLocaleString(message,MagickPathExtent,"%s => %s", CommandOptionToMnemonic(MagickCacheOptions,(ssize_t) cache_info->type), CommandOptionToMnemonic(MagickCacheOptions,(ssize_t) clone_info->type)); (void) LogMagickEvent(CacheEvent,GetMagickModule(),"%s",message); } return(status); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + D e s t r o y I m a g e P i x e l C a c h e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % DestroyImagePixelCache() deallocates memory associated with the pixel cache. % % The format of the DestroyImagePixelCache() method is: % % void DestroyImagePixelCache(Image *image) % % A description of each parameter follows: % % o image: the image. % */ static void DestroyImagePixelCache(Image *image) { assert(image != (Image *) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); if (image->cache == (void *) NULL) return; image->cache=DestroyPixelCache(image->cache); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + D e s t r o y I m a g e P i x e l s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % DestroyImagePixels() deallocates memory associated with the pixel cache. % % The format of the DestroyImagePixels() method is: % % void DestroyImagePixels(Image *image) % % A description of each parameter follows: % % o image: the image. % */ MagickExport void DestroyImagePixels(Image *image) { CacheInfo *magick_restrict cache_info; assert(image != (const Image *) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(image->cache != (Cache) NULL); cache_info=(CacheInfo *) image->cache; assert(cache_info->signature == MagickCoreSignature); if (cache_info->methods.destroy_pixel_handler != (DestroyPixelHandler) NULL) { cache_info->methods.destroy_pixel_handler(image); return; } image->cache=DestroyPixelCache(image->cache); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + D e s t r o y P i x e l C a c h e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % DestroyPixelCache() deallocates memory associated with the pixel cache. % % The format of the DestroyPixelCache() method is: % % Cache DestroyPixelCache(Cache cache) % % A description of each parameter follows: % % o cache: the pixel cache. % */ static MagickBooleanType ClosePixelCacheOnDisk(CacheInfo *cache_info) { int status; status=(-1); if (cache_info->file != -1) { status=close(cache_info->file); cache_info->file=(-1); RelinquishMagickResource(FileResource,1); } return(status == -1 ? MagickFalse : MagickTrue); } static inline void RelinquishPixelCachePixels(CacheInfo *cache_info) { switch (cache_info->type) { case MemoryCache: { #if defined(MAGICKCORE_OPENCL_SUPPORT) if (cache_info->opencl != (MagickCLCacheInfo) NULL) { cache_info->opencl=RelinquishMagickCLCacheInfo(cache_info->opencl, MagickTrue); cache_info->pixels=(Quantum *) NULL; break; } #endif if (cache_info->mapped == MagickFalse) cache_info->pixels=(Quantum *) RelinquishAlignedMemory( cache_info->pixels); else (void) UnmapBlob(cache_info->pixels,(size_t) cache_info->length); RelinquishMagickResource(MemoryResource,cache_info->length); break; } case MapCache: { (void) UnmapBlob(cache_info->pixels,(size_t) cache_info->length); cache_info->pixels=(Quantum *) NULL; if ((cache_info->mode != ReadMode) && (cache_info->mode != PersistMode)) (void) RelinquishUniqueFileResource(cache_info->cache_filename); *cache_info->cache_filename='\0'; RelinquishMagickResource(MapResource,cache_info->length); } case DiskCache: { if (cache_info->file != -1) (void) ClosePixelCacheOnDisk(cache_info); if ((cache_info->mode != ReadMode) && (cache_info->mode != PersistMode)) (void) RelinquishUniqueFileResource(cache_info->cache_filename); *cache_info->cache_filename='\0'; RelinquishMagickResource(DiskResource,cache_info->length); break; } case DistributedCache: { *cache_info->cache_filename='\0'; (void) RelinquishDistributePixelCache((DistributeCacheInfo *) cache_info->server_info); break; } default: break; } cache_info->type=UndefinedCache; cache_info->mapped=MagickFalse; cache_info->metacontent=(void *) NULL; } MagickPrivate Cache DestroyPixelCache(Cache cache) { CacheInfo *magick_restrict cache_info; assert(cache != (Cache) NULL); cache_info=(CacheInfo *) cache; assert(cache_info->signature == MagickCoreSignature); if (cache_info->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s", cache_info->filename); LockSemaphoreInfo(cache_info->semaphore); cache_info->reference_count--; if (cache_info->reference_count != 0) { UnlockSemaphoreInfo(cache_info->semaphore); return((Cache) NULL); } UnlockSemaphoreInfo(cache_info->semaphore); if (cache_info->debug != MagickFalse) { char message[MagickPathExtent]; (void) FormatLocaleString(message,MagickPathExtent,"destroy %s", cache_info->filename); (void) LogMagickEvent(CacheEvent,GetMagickModule(),"%s",message); } RelinquishPixelCachePixels(cache_info); if (cache_info->server_info != (DistributeCacheInfo *) NULL) cache_info->server_info=DestroyDistributeCacheInfo((DistributeCacheInfo *) cache_info->server_info); if (cache_info->nexus_info != (NexusInfo **) NULL) cache_info->nexus_info=DestroyPixelCacheNexus(cache_info->nexus_info, cache_info->number_threads); if (cache_info->random_info != (RandomInfo *) NULL) cache_info->random_info=DestroyRandomInfo(cache_info->random_info); if (cache_info->file_semaphore != (SemaphoreInfo *) NULL) RelinquishSemaphoreInfo(&cache_info->file_semaphore); if (cache_info->semaphore != (SemaphoreInfo *) NULL) RelinquishSemaphoreInfo(&cache_info->semaphore); cache_info->signature=(~MagickCoreSignature); cache_info=(CacheInfo *) RelinquishMagickMemory(cache_info); cache=(Cache) NULL; return(cache); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + D e s t r o y P i x e l C a c h e N e x u s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % DestroyPixelCacheNexus() destroys a pixel cache nexus. % % The format of the DestroyPixelCacheNexus() method is: % % NexusInfo **DestroyPixelCacheNexus(NexusInfo *nexus_info, % const size_t number_threads) % % A description of each parameter follows: % % o nexus_info: the nexus to destroy. % % o number_threads: the number of nexus threads. % */ static inline void RelinquishCacheNexusPixels(NexusInfo *nexus_info) { if (nexus_info->mapped == MagickFalse) (void) RelinquishAlignedMemory(nexus_info->cache); else (void) UnmapBlob(nexus_info->cache,(size_t) nexus_info->length); nexus_info->cache=(Quantum *) NULL; nexus_info->pixels=(Quantum *) NULL; nexus_info->metacontent=(void *) NULL; nexus_info->length=0; nexus_info->mapped=MagickFalse; } MagickPrivate NexusInfo **DestroyPixelCacheNexus(NexusInfo **nexus_info, const size_t number_threads) { register ssize_t i; assert(nexus_info != (NexusInfo **) NULL); for (i=0; i < (ssize_t) number_threads; i++) { if (nexus_info[i]->cache != (Quantum *) NULL) RelinquishCacheNexusPixels(nexus_info[i]); nexus_info[i]->signature=(~MagickCoreSignature); } nexus_info[0]=(NexusInfo *) RelinquishMagickMemory(nexus_info[0]); nexus_info=(NexusInfo **) RelinquishAlignedMemory(nexus_info); return(nexus_info); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % G e t A u t h e n t i c M e t a c o n t e n t % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetAuthenticMetacontent() returns the authentic metacontent corresponding % with the last call to QueueAuthenticPixels() or GetVirtualPixels(). NULL is % returned if the associated pixels are not available. % % The format of the GetAuthenticMetacontent() method is: % % void *GetAuthenticMetacontent(const Image *image) % % A description of each parameter follows: % % o image: the image. % */ MagickExport void *GetAuthenticMetacontent(const Image *image) { CacheInfo *magick_restrict cache_info; const int id = GetOpenMPThreadId(); assert(image != (const Image *) NULL); assert(image->signature == MagickCoreSignature); assert(image->cache != (Cache) NULL); cache_info=(CacheInfo *) image->cache; assert(cache_info->signature == MagickCoreSignature); if (cache_info->methods.get_authentic_metacontent_from_handler != (GetAuthenticMetacontentFromHandler) NULL) { void *metacontent; metacontent=cache_info->methods. get_authentic_metacontent_from_handler(image); return(metacontent); } assert(id < (int) cache_info->number_threads); return(cache_info->nexus_info[id]->metacontent); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + G e t A u t h e n t i c M e t a c o n t e n t F r o m C a c h e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetAuthenticMetacontentFromCache() returns the meta-content corresponding % with the last call to QueueAuthenticPixelsCache() or % GetAuthenticPixelsCache(). % % The format of the GetAuthenticMetacontentFromCache() method is: % % void *GetAuthenticMetacontentFromCache(const Image *image) % % A description of each parameter follows: % % o image: the image. % */ static void *GetAuthenticMetacontentFromCache(const Image *image) { CacheInfo *magick_restrict cache_info; const int id = GetOpenMPThreadId(); assert(image != (const Image *) NULL); assert(image->signature == MagickCoreSignature); assert(image->cache != (Cache) NULL); cache_info=(CacheInfo *) image->cache; assert(cache_info->signature == MagickCoreSignature); assert(id < (int) cache_info->number_threads); return(cache_info->nexus_info[id]->metacontent); } #if defined(MAGICKCORE_OPENCL_SUPPORT) /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + G e t A u t h e n t i c O p e n C L B u f f e r % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetAuthenticOpenCLBuffer() returns an OpenCL buffer used to execute OpenCL % operations. % % The format of the GetAuthenticOpenCLBuffer() method is: % % cl_mem GetAuthenticOpenCLBuffer(const Image *image, % MagickCLDevice device,ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o device: the device to use. % % o exception: return any errors or warnings in this structure. % */ MagickPrivate cl_mem GetAuthenticOpenCLBuffer(const Image *image, MagickCLDevice device,ExceptionInfo *exception) { CacheInfo *magick_restrict cache_info; assert(image != (const Image *) NULL); assert(device != (const MagickCLDevice) NULL); cache_info=(CacheInfo *) image->cache; if ((cache_info->type == UndefinedCache) || (cache_info->reference_count > 1)) { SyncImagePixelCache((Image *) image,exception); cache_info=(CacheInfo *) image->cache; } if ((cache_info->type != MemoryCache) || (cache_info->mapped != MagickFalse)) return((cl_mem) NULL); LockSemaphoreInfo(cache_info->semaphore); if ((cache_info->opencl != (MagickCLCacheInfo) NULL) && (cache_info->opencl->device->context != device->context)) cache_info->opencl=CopyMagickCLCacheInfo(cache_info->opencl); if (cache_info->opencl == (MagickCLCacheInfo) NULL) { assert(cache_info->pixels != (Quantum *) NULL); cache_info->opencl=AcquireMagickCLCacheInfo(device,cache_info->pixels, cache_info->length); } if (cache_info->opencl != (MagickCLCacheInfo) NULL) RetainOpenCLMemObject(cache_info->opencl->buffer); UnlockSemaphoreInfo(cache_info->semaphore); if (cache_info->opencl == (MagickCLCacheInfo) NULL) return((cl_mem) NULL); assert(cache_info->opencl->pixels == cache_info->pixels); return(cache_info->opencl->buffer); } #endif /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + G e t A u t h e n t i c P i x e l C a c h e N e x u s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetAuthenticPixelCacheNexus() gets authentic pixels from the in-memory or % disk pixel cache as defined by the geometry parameters. A pointer to the % pixels is returned if the pixels are transferred, otherwise a NULL is % returned. % % The format of the GetAuthenticPixelCacheNexus() method is: % % Quantum *GetAuthenticPixelCacheNexus(Image *image,const ssize_t x, % const ssize_t y,const size_t columns,const size_t rows, % NexusInfo *nexus_info,ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o x,y,columns,rows: These values define the perimeter of a region of % pixels. % % o nexus_info: the cache nexus to return. % % o exception: return any errors or warnings in this structure. % */ MagickPrivate Quantum *GetAuthenticPixelCacheNexus(Image *image,const ssize_t x, const ssize_t y,const size_t columns,const size_t rows,NexusInfo *nexus_info, ExceptionInfo *exception) { CacheInfo *magick_restrict cache_info; Quantum *magick_restrict pixels; /* Transfer pixels from the cache. */ assert(image != (Image *) NULL); assert(image->signature == MagickCoreSignature); pixels=QueueAuthenticPixelCacheNexus(image,x,y,columns,rows,MagickTrue, nexus_info,exception); if (pixels == (Quantum *) NULL) return((Quantum *) NULL); cache_info=(CacheInfo *) image->cache; assert(cache_info->signature == MagickCoreSignature); if (nexus_info->authentic_pixel_cache != MagickFalse) return(pixels); if (ReadPixelCachePixels(cache_info,nexus_info,exception) == MagickFalse) return((Quantum *) NULL); if (cache_info->metacontent_extent != 0) if (ReadPixelCacheMetacontent(cache_info,nexus_info,exception) == MagickFalse) return((Quantum *) NULL); return(pixels); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + G e t A u t h e n t i c P i x e l s F r o m C a c h e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetAuthenticPixelsFromCache() returns the pixels associated with the last % call to the QueueAuthenticPixelsCache() or GetAuthenticPixelsCache() methods. % % The format of the GetAuthenticPixelsFromCache() method is: % % Quantum *GetAuthenticPixelsFromCache(const Image image) % % A description of each parameter follows: % % o image: the image. % */ static Quantum *GetAuthenticPixelsFromCache(const Image *image) { CacheInfo *magick_restrict cache_info; const int id = GetOpenMPThreadId(); assert(image != (const Image *) NULL); assert(image->signature == MagickCoreSignature); assert(image->cache != (Cache) NULL); cache_info=(CacheInfo *) image->cache; assert(cache_info->signature == MagickCoreSignature); assert(id < (int) cache_info->number_threads); return(cache_info->nexus_info[id]->pixels); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % G e t A u t h e n t i c P i x e l Q u e u e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetAuthenticPixelQueue() returns the authentic pixels associated % corresponding with the last call to QueueAuthenticPixels() or % GetAuthenticPixels(). % % The format of the GetAuthenticPixelQueue() method is: % % Quantum *GetAuthenticPixelQueue(const Image image) % % A description of each parameter follows: % % o image: the image. % */ MagickExport Quantum *GetAuthenticPixelQueue(const Image *image) { CacheInfo *magick_restrict cache_info; const int id = GetOpenMPThreadId(); assert(image != (const Image *) NULL); assert(image->signature == MagickCoreSignature); assert(image->cache != (Cache) NULL); cache_info=(CacheInfo *) image->cache; assert(cache_info->signature == MagickCoreSignature); if (cache_info->methods.get_authentic_pixels_from_handler != (GetAuthenticPixelsFromHandler) NULL) return(cache_info->methods.get_authentic_pixels_from_handler(image)); assert(id < (int) cache_info->number_threads); return(cache_info->nexus_info[id]->pixels); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % G e t A u t h e n t i c P i x e l s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetAuthenticPixels() obtains a pixel region for read/write access. If the % region is successfully accessed, a pointer to a Quantum array % representing the region is returned, otherwise NULL is returned. % % The returned pointer may point to a temporary working copy of the pixels % or it may point to the original pixels in memory. Performance is maximized % if the selected region is part of one row, or one or more full rows, since % then there is opportunity to access the pixels in-place (without a copy) % if the image is in memory, or in a memory-mapped file. The returned pointer % must *never* be deallocated by the user. % % Pixels accessed via the returned pointer represent a simple array of type % Quantum. If the image has corresponding metacontent,call % GetAuthenticMetacontent() after invoking GetAuthenticPixels() to obtain the % meta-content corresponding to the region. Once the Quantum array has % been updated, the changes must be saved back to the underlying image using % SyncAuthenticPixels() or they may be lost. % % The format of the GetAuthenticPixels() method is: % % Quantum *GetAuthenticPixels(Image *image,const ssize_t x, % const ssize_t y,const size_t columns,const size_t rows, % ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o x,y,columns,rows: These values define the perimeter of a region of % pixels. % % o exception: return any errors or warnings in this structure. % */ MagickExport Quantum *GetAuthenticPixels(Image *image,const ssize_t x, const ssize_t y,const size_t columns,const size_t rows, ExceptionInfo *exception) { CacheInfo *magick_restrict cache_info; const int id = GetOpenMPThreadId(); Quantum *pixels; assert(image != (Image *) NULL); assert(image->signature == MagickCoreSignature); assert(image->cache != (Cache) NULL); cache_info=(CacheInfo *) image->cache; assert(cache_info->signature == MagickCoreSignature); if (cache_info->methods.get_authentic_pixels_handler != (GetAuthenticPixelsHandler) NULL) { pixels=cache_info->methods.get_authentic_pixels_handler(image,x,y,columns, rows,exception); return(pixels); } assert(id < (int) cache_info->number_threads); pixels=GetAuthenticPixelCacheNexus(image,x,y,columns,rows, cache_info->nexus_info[id],exception); return(pixels); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + G e t A u t h e n t i c P i x e l s C a c h e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetAuthenticPixelsCache() gets pixels from the in-memory or disk pixel cache % as defined by the geometry parameters. A pointer to the pixels is returned % if the pixels are transferred, otherwise a NULL is returned. % % The format of the GetAuthenticPixelsCache() method is: % % Quantum *GetAuthenticPixelsCache(Image *image,const ssize_t x, % const ssize_t y,const size_t columns,const size_t rows, % ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o x,y,columns,rows: These values define the perimeter of a region of % pixels. % % o exception: return any errors or warnings in this structure. % */ static Quantum *GetAuthenticPixelsCache(Image *image,const ssize_t x, const ssize_t y,const size_t columns,const size_t rows, ExceptionInfo *exception) { CacheInfo *magick_restrict cache_info; const int id = GetOpenMPThreadId(); Quantum *magick_restrict pixels; assert(image != (const Image *) NULL); assert(image->signature == MagickCoreSignature); assert(image->cache != (Cache) NULL); cache_info=(CacheInfo *) image->cache; if (cache_info == (Cache) NULL) return((Quantum *) NULL); assert(cache_info->signature == MagickCoreSignature); assert(id < (int) cache_info->number_threads); pixels=GetAuthenticPixelCacheNexus(image,x,y,columns,rows, cache_info->nexus_info[id],exception); return(pixels); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + G e t I m a g e E x t e n t % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetImageExtent() returns the extent of the pixels associated corresponding % with the last call to QueueAuthenticPixels() or GetAuthenticPixels(). % % The format of the GetImageExtent() method is: % % MagickSizeType GetImageExtent(const Image *image) % % A description of each parameter follows: % % o image: the image. % */ MagickExport MagickSizeType GetImageExtent(const Image *image) { CacheInfo *magick_restrict cache_info; const int id = GetOpenMPThreadId(); assert(image != (Image *) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(image->cache != (Cache) NULL); cache_info=(CacheInfo *) image->cache; assert(cache_info->signature == MagickCoreSignature); assert(id < (int) cache_info->number_threads); return(GetPixelCacheNexusExtent(cache_info,cache_info->nexus_info[id])); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + G e t I m a g e P i x e l C a c h e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetImagePixelCache() ensures that there is only a single reference to the % pixel cache to be modified, updating the provided cache pointer to point to % a clone of the original pixel cache if necessary. % % The format of the GetImagePixelCache method is: % % Cache GetImagePixelCache(Image *image,const MagickBooleanType clone, % ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o clone: any value other than MagickFalse clones the cache pixels. % % o exception: return any errors or warnings in this structure. % */ static inline MagickBooleanType ValidatePixelCacheMorphology( const Image *magick_restrict image) { const CacheInfo *magick_restrict cache_info; const PixelChannelMap *magick_restrict p, *magick_restrict q; /* Does the image match the pixel cache morphology? */ cache_info=(CacheInfo *) image->cache; p=image->channel_map; q=cache_info->channel_map; if ((image->storage_class != cache_info->storage_class) || (image->colorspace != cache_info->colorspace) || (image->alpha_trait != cache_info->alpha_trait) || (image->channels != cache_info->channels) || (image->columns != cache_info->columns) || (image->rows != cache_info->rows) || (image->number_channels != cache_info->number_channels) || (memcmp(p,q,image->number_channels*sizeof(*p)) != 0) || (image->metacontent_extent != cache_info->metacontent_extent) || (cache_info->nexus_info == (NexusInfo **) NULL)) return(MagickFalse); return(MagickTrue); } static Cache GetImagePixelCache(Image *image,const MagickBooleanType clone, ExceptionInfo *exception) { CacheInfo *magick_restrict cache_info; MagickBooleanType destroy, status; static MagickSizeType cache_timelimit = MagickResourceInfinity, cpu_throttle = MagickResourceInfinity, cycles = 0; status=MagickTrue; if (cpu_throttle == MagickResourceInfinity) cpu_throttle=GetMagickResourceLimit(ThrottleResource); if ((cpu_throttle != 0) && ((cycles++ % 32) == 0)) MagickDelay(cpu_throttle); if (cache_epoch == 0) { /* Set the expire time in seconds. */ cache_timelimit=GetMagickResourceLimit(TimeResource); cache_epoch=time((time_t *) NULL); } if ((cache_timelimit != MagickResourceInfinity) && ((MagickSizeType) (time((time_t *) NULL)-cache_epoch) >= cache_timelimit)) { #if defined(ECANCELED) errno=ECANCELED; #endif cache_info=(CacheInfo *) image->cache; if (cache_info->file != -1) (void) ClosePixelCacheOnDisk(cache_info); ThrowFatalException(ResourceLimitFatalError,"TimeLimitExceeded"); } LockSemaphoreInfo(image->semaphore); assert(image->cache != (Cache) NULL); cache_info=(CacheInfo *) image->cache; #if defined(MAGICKCORE_OPENCL_SUPPORT) CopyOpenCLBuffer(cache_info); #endif destroy=MagickFalse; if ((cache_info->reference_count > 1) || (cache_info->mode == ReadMode)) { LockSemaphoreInfo(cache_info->semaphore); if ((cache_info->reference_count > 1) || (cache_info->mode == ReadMode)) { CacheInfo *clone_info; Image clone_image; /* Clone pixel cache. */ clone_image=(*image); clone_image.semaphore=AcquireSemaphoreInfo(); clone_image.reference_count=1; clone_image.cache=ClonePixelCache(cache_info); clone_info=(CacheInfo *) clone_image.cache; status=OpenPixelCache(&clone_image,IOMode,exception); if (status == MagickFalse) clone_info=(CacheInfo *) DestroyPixelCache(clone_info); else { if (clone != MagickFalse) status=ClonePixelCacheRepository(clone_info,cache_info, exception); if (status == MagickFalse) clone_info=(CacheInfo *) DestroyPixelCache(clone_info); else { destroy=MagickTrue; image->cache=clone_info; } } RelinquishSemaphoreInfo(&clone_image.semaphore); } UnlockSemaphoreInfo(cache_info->semaphore); } if (destroy != MagickFalse) cache_info=(CacheInfo *) DestroyPixelCache(cache_info); if (status != MagickFalse) { /* Ensure the image matches the pixel cache morphology. */ image->type=UndefinedType; if (ValidatePixelCacheMorphology(image) == MagickFalse) { status=OpenPixelCache(image,IOMode,exception); cache_info=(CacheInfo *) image->cache; if (cache_info->file != -1) (void) ClosePixelCacheOnDisk(cache_info); } } UnlockSemaphoreInfo(image->semaphore); if (status == MagickFalse) return((Cache) NULL); return(image->cache); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + G e t I m a g e P i x e l C a c h e T y p e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetImagePixelCacheType() returns the pixel cache type: UndefinedCache, % DiskCache, MemoryCache, MapCache, or PingCache. % % The format of the GetImagePixelCacheType() method is: % % CacheType GetImagePixelCacheType(const Image *image) % % A description of each parameter follows: % % o image: the image. % */ MagickExport CacheType GetImagePixelCacheType(const Image *image) { CacheInfo *magick_restrict cache_info; assert(image != (Image *) NULL); assert(image->signature == MagickCoreSignature); assert(image->cache != (Cache) NULL); cache_info=(CacheInfo *) image->cache; assert(cache_info->signature == MagickCoreSignature); return(cache_info->type); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % G e t O n e A u t h e n t i c P i x e l % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetOneAuthenticPixel() returns a single pixel at the specified (x,y) % location. The image background color is returned if an error occurs. % % The format of the GetOneAuthenticPixel() method is: % % MagickBooleanType GetOneAuthenticPixel(const Image image,const ssize_t x, % const ssize_t y,Quantum *pixel,ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o x,y: These values define the location of the pixel to return. % % o pixel: return a pixel at the specified (x,y) location. % % o exception: return any errors or warnings in this structure. % */ static inline MagickBooleanType CopyPixel(const Image *image, const Quantum *source,Quantum *destination) { register ssize_t i; if (source == (const Quantum *) NULL) { destination[RedPixelChannel]=ClampToQuantum(image->background_color.red); destination[GreenPixelChannel]=ClampToQuantum( image->background_color.green); destination[BluePixelChannel]=ClampToQuantum( image->background_color.blue); destination[BlackPixelChannel]=ClampToQuantum( image->background_color.black); destination[AlphaPixelChannel]=ClampToQuantum( image->background_color.alpha); return(MagickFalse); } for (i=0; i < (ssize_t) GetPixelChannels(image); i++) { PixelChannel channel = GetPixelChannelChannel(image,i); destination[channel]=source[i]; } return(MagickTrue); } MagickExport MagickBooleanType GetOneAuthenticPixel(Image *image, const ssize_t x,const ssize_t y,Quantum *pixel,ExceptionInfo *exception) { CacheInfo *magick_restrict cache_info; register Quantum *magick_restrict q; assert(image != (Image *) NULL); assert(image->signature == MagickCoreSignature); assert(image->cache != (Cache) NULL); cache_info=(CacheInfo *) image->cache; assert(cache_info->signature == MagickCoreSignature); (void) memset(pixel,0,MaxPixelChannels*sizeof(*pixel)); if (cache_info->methods.get_one_authentic_pixel_from_handler != (GetOneAuthenticPixelFromHandler) NULL) return(cache_info->methods.get_one_authentic_pixel_from_handler(image,x,y,pixel,exception)); q=GetAuthenticPixelsCache(image,x,y,1UL,1UL,exception); return(CopyPixel(image,q,pixel)); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + G e t O n e A u t h e n t i c P i x e l F r o m C a c h e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetOneAuthenticPixelFromCache() returns a single pixel at the specified (x,y) % location. The image background color is returned if an error occurs. % % The format of the GetOneAuthenticPixelFromCache() method is: % % MagickBooleanType GetOneAuthenticPixelFromCache(const Image image, % const ssize_t x,const ssize_t y,Quantum *pixel, % ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o x,y: These values define the location of the pixel to return. % % o pixel: return a pixel at the specified (x,y) location. % % o exception: return any errors or warnings in this structure. % */ static MagickBooleanType GetOneAuthenticPixelFromCache(Image *image, const ssize_t x,const ssize_t y,Quantum *pixel,ExceptionInfo *exception) { CacheInfo *magick_restrict cache_info; const int id = GetOpenMPThreadId(); register Quantum *magick_restrict q; assert(image != (const Image *) NULL); assert(image->signature == MagickCoreSignature); assert(image->cache != (Cache) NULL); cache_info=(CacheInfo *) image->cache; assert(cache_info->signature == MagickCoreSignature); assert(id < (int) cache_info->number_threads); (void) memset(pixel,0,MaxPixelChannels*sizeof(*pixel)); q=GetAuthenticPixelCacheNexus(image,x,y,1UL,1UL,cache_info->nexus_info[id], exception); return(CopyPixel(image,q,pixel)); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % G e t O n e V i r t u a l P i x e l % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetOneVirtualPixel() returns a single virtual pixel at the specified % (x,y) location. The image background color is returned if an error occurs. % If you plan to modify the pixel, use GetOneAuthenticPixel() instead. % % The format of the GetOneVirtualPixel() method is: % % MagickBooleanType GetOneVirtualPixel(const Image image,const ssize_t x, % const ssize_t y,Quantum *pixel,ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o x,y: These values define the location of the pixel to return. % % o pixel: return a pixel at the specified (x,y) location. % % o exception: return any errors or warnings in this structure. % */ MagickExport MagickBooleanType GetOneVirtualPixel(const Image *image, const ssize_t x,const ssize_t y,Quantum *pixel,ExceptionInfo *exception) { CacheInfo *magick_restrict cache_info; const int id = GetOpenMPThreadId(); const Quantum *p; assert(image != (const Image *) NULL); assert(image->signature == MagickCoreSignature); assert(image->cache != (Cache) NULL); cache_info=(CacheInfo *) image->cache; assert(cache_info->signature == MagickCoreSignature); (void) memset(pixel,0,MaxPixelChannels*sizeof(*pixel)); if (cache_info->methods.get_one_virtual_pixel_from_handler != (GetOneVirtualPixelFromHandler) NULL) return(cache_info->methods.get_one_virtual_pixel_from_handler(image, GetPixelCacheVirtualMethod(image),x,y,pixel,exception)); assert(id < (int) cache_info->number_threads); p=GetVirtualPixelCacheNexus(image,GetPixelCacheVirtualMethod(image),x,y, 1UL,1UL,cache_info->nexus_info[id],exception); return(CopyPixel(image,p,pixel)); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + G e t O n e V i r t u a l P i x e l F r o m C a c h e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetOneVirtualPixelFromCache() returns a single virtual pixel at the % specified (x,y) location. The image background color is returned if an % error occurs. % % The format of the GetOneVirtualPixelFromCache() method is: % % MagickBooleanType GetOneVirtualPixelFromCache(const Image image, % const VirtualPixelMethod method,const ssize_t x,const ssize_t y, % Quantum *pixel,ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o virtual_pixel_method: the virtual pixel method. % % o x,y: These values define the location of the pixel to return. % % o pixel: return a pixel at the specified (x,y) location. % % o exception: return any errors or warnings in this structure. % */ static MagickBooleanType GetOneVirtualPixelFromCache(const Image *image, const VirtualPixelMethod virtual_pixel_method,const ssize_t x,const ssize_t y, Quantum *pixel,ExceptionInfo *exception) { CacheInfo *magick_restrict cache_info; const int id = GetOpenMPThreadId(); const Quantum *p; assert(image != (const Image *) NULL); assert(image->signature == MagickCoreSignature); assert(image->cache != (Cache) NULL); cache_info=(CacheInfo *) image->cache; assert(cache_info->signature == MagickCoreSignature); assert(id < (int) cache_info->number_threads); (void) memset(pixel,0,MaxPixelChannels*sizeof(*pixel)); p=GetVirtualPixelCacheNexus(image,virtual_pixel_method,x,y,1UL,1UL, cache_info->nexus_info[id],exception); return(CopyPixel(image,p,pixel)); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % G e t O n e V i r t u a l P i x e l I n f o % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetOneVirtualPixelInfo() returns a single pixel at the specified (x,y) % location. The image background color is returned if an error occurs. If % you plan to modify the pixel, use GetOneAuthenticPixel() instead. % % The format of the GetOneVirtualPixelInfo() method is: % % MagickBooleanType GetOneVirtualPixelInfo(const Image image, % const VirtualPixelMethod virtual_pixel_method,const ssize_t x, % const ssize_t y,PixelInfo *pixel,ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o virtual_pixel_method: the virtual pixel method. % % o x,y: these values define the location of the pixel to return. % % o pixel: return a pixel at the specified (x,y) location. % % o exception: return any errors or warnings in this structure. % */ MagickExport MagickBooleanType GetOneVirtualPixelInfo(const Image *image, const VirtualPixelMethod virtual_pixel_method,const ssize_t x,const ssize_t y, PixelInfo *pixel,ExceptionInfo *exception) { CacheInfo *magick_restrict cache_info; const int id = GetOpenMPThreadId(); register const Quantum *magick_restrict p; assert(image != (const Image *) NULL); assert(image->signature == MagickCoreSignature); assert(image->cache != (Cache) NULL); cache_info=(CacheInfo *) image->cache; assert(cache_info->signature == MagickCoreSignature); assert(id < (int) cache_info->number_threads); GetPixelInfo(image,pixel); p=GetVirtualPixelCacheNexus(image,virtual_pixel_method,x,y,1UL,1UL, cache_info->nexus_info[id],exception); if (p == (const Quantum *) NULL) return(MagickFalse); GetPixelInfoPixel(image,p,pixel); return(MagickTrue); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + G e t P i x e l C a c h e C o l o r s p a c e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetPixelCacheColorspace() returns the class type of the pixel cache. % % The format of the GetPixelCacheColorspace() method is: % % Colorspace GetPixelCacheColorspace(Cache cache) % % A description of each parameter follows: % % o cache: the pixel cache. % */ MagickPrivate ColorspaceType GetPixelCacheColorspace(const Cache cache) { CacheInfo *magick_restrict cache_info; assert(cache != (Cache) NULL); cache_info=(CacheInfo *) cache; assert(cache_info->signature == MagickCoreSignature); if (cache_info->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s", cache_info->filename); return(cache_info->colorspace); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + G e t P i x e l C a c h e F i l e n a m e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetPixelCacheFilename() returns the filename associated with the pixel % cache. % % The format of the GetPixelCacheFilename() method is: % % const char *GetPixelCacheFilename(const Image *image) % % A description of each parameter follows: % % o image: the image. % */ MagickExport const char *GetPixelCacheFilename(const Image *image) { CacheInfo *magick_restrict cache_info; assert(image != (const Image *) NULL); assert(image->signature == MagickCoreSignature); assert(image->cache != (Cache) NULL); cache_info=(CacheInfo *) image->cache; assert(cache_info->signature == MagickCoreSignature); return(cache_info->cache_filename); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + G e t P i x e l C a c h e M e t h o d s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetPixelCacheMethods() initializes the CacheMethods structure. % % The format of the GetPixelCacheMethods() method is: % % void GetPixelCacheMethods(CacheMethods *cache_methods) % % A description of each parameter follows: % % o cache_methods: Specifies a pointer to a CacheMethods structure. % */ MagickPrivate void GetPixelCacheMethods(CacheMethods *cache_methods) { assert(cache_methods != (CacheMethods *) NULL); (void) memset(cache_methods,0,sizeof(*cache_methods)); cache_methods->get_virtual_pixel_handler=GetVirtualPixelCache; cache_methods->get_virtual_pixels_handler=GetVirtualPixelsCache; cache_methods->get_virtual_metacontent_from_handler= GetVirtualMetacontentFromCache; cache_methods->get_one_virtual_pixel_from_handler=GetOneVirtualPixelFromCache; cache_methods->get_authentic_pixels_handler=GetAuthenticPixelsCache; cache_methods->get_authentic_metacontent_from_handler= GetAuthenticMetacontentFromCache; cache_methods->get_authentic_pixels_from_handler=GetAuthenticPixelsFromCache; cache_methods->get_one_authentic_pixel_from_handler= GetOneAuthenticPixelFromCache; cache_methods->queue_authentic_pixels_handler=QueueAuthenticPixelsCache; cache_methods->sync_authentic_pixels_handler=SyncAuthenticPixelsCache; cache_methods->destroy_pixel_handler=DestroyImagePixelCache; } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + G e t P i x e l C a c h e N e x u s E x t e n t % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetPixelCacheNexusExtent() returns the extent of the pixels associated % corresponding with the last call to SetPixelCacheNexusPixels() or % GetPixelCacheNexusPixels(). % % The format of the GetPixelCacheNexusExtent() method is: % % MagickSizeType GetPixelCacheNexusExtent(const Cache cache, % NexusInfo *nexus_info) % % A description of each parameter follows: % % o nexus_info: the nexus info. % */ MagickPrivate MagickSizeType GetPixelCacheNexusExtent(const Cache cache, NexusInfo *magick_restrict nexus_info) { CacheInfo *magick_restrict cache_info; MagickSizeType extent; assert(cache != NULL); cache_info=(CacheInfo *) cache; assert(cache_info->signature == MagickCoreSignature); extent=(MagickSizeType) nexus_info->region.width*nexus_info->region.height; if (extent == 0) return((MagickSizeType) cache_info->columns*cache_info->rows); return(extent); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + G e t P i x e l C a c h e P i x e l s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetPixelCachePixels() returns the pixels associated with the specified image. % % The format of the GetPixelCachePixels() method is: % % void *GetPixelCachePixels(Image *image,MagickSizeType *length, % ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o length: the pixel cache length. % % o exception: return any errors or warnings in this structure. % */ MagickExport void *GetPixelCachePixels(Image *image,MagickSizeType *length, ExceptionInfo *exception) { CacheInfo *magick_restrict cache_info; assert(image != (const Image *) NULL); assert(image->signature == MagickCoreSignature); assert(image->cache != (Cache) NULL); assert(length != (MagickSizeType *) NULL); assert(exception != (ExceptionInfo *) NULL); assert(exception->signature == MagickCoreSignature); cache_info=(CacheInfo *) image->cache; assert(cache_info->signature == MagickCoreSignature); *length=cache_info->length; if ((cache_info->type != MemoryCache) && (cache_info->type != MapCache)) return((void *) NULL); return((void *) cache_info->pixels); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + G e t P i x e l C a c h e S t o r a g e C l a s s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetPixelCacheStorageClass() returns the class type of the pixel cache. % % The format of the GetPixelCacheStorageClass() method is: % % ClassType GetPixelCacheStorageClass(Cache cache) % % A description of each parameter follows: % % o type: GetPixelCacheStorageClass returns DirectClass or PseudoClass. % % o cache: the pixel cache. % */ MagickPrivate ClassType GetPixelCacheStorageClass(const Cache cache) { CacheInfo *magick_restrict cache_info; assert(cache != (Cache) NULL); cache_info=(CacheInfo *) cache; assert(cache_info->signature == MagickCoreSignature); if (cache_info->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s", cache_info->filename); return(cache_info->storage_class); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + G e t P i x e l C a c h e T i l e S i z e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetPixelCacheTileSize() returns the pixel cache tile size. % % The format of the GetPixelCacheTileSize() method is: % % void GetPixelCacheTileSize(const Image *image,size_t *width, % size_t *height) % % A description of each parameter follows: % % o image: the image. % % o width: the optimized cache tile width in pixels. % % o height: the optimized cache tile height in pixels. % */ MagickPrivate void GetPixelCacheTileSize(const Image *image,size_t *width, size_t *height) { CacheInfo *magick_restrict cache_info; assert(image != (Image *) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); cache_info=(CacheInfo *) image->cache; assert(cache_info->signature == MagickCoreSignature); *width=2048UL/(cache_info->number_channels*sizeof(Quantum)); if (GetImagePixelCacheType(image) == DiskCache) *width=8192UL/(cache_info->number_channels*sizeof(Quantum)); *height=(*width); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + G e t P i x e l C a c h e V i r t u a l M e t h o d % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetPixelCacheVirtualMethod() gets the "virtual pixels" method for the % pixel cache. A virtual pixel is any pixel access that is outside the % boundaries of the image cache. % % The format of the GetPixelCacheVirtualMethod() method is: % % VirtualPixelMethod GetPixelCacheVirtualMethod(const Image *image) % % A description of each parameter follows: % % o image: the image. % */ MagickPrivate VirtualPixelMethod GetPixelCacheVirtualMethod(const Image *image) { CacheInfo *magick_restrict cache_info; assert(image != (Image *) NULL); assert(image->signature == MagickCoreSignature); assert(image->cache != (Cache) NULL); cache_info=(CacheInfo *) image->cache; assert(cache_info->signature == MagickCoreSignature); return(cache_info->virtual_pixel_method); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + G e t V i r t u a l M e t a c o n t e n t F r o m C a c h e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetVirtualMetacontentFromCache() returns the meta-content corresponding with % the last call to QueueAuthenticPixelsCache() or GetVirtualPixelCache(). % % The format of the GetVirtualMetacontentFromCache() method is: % % void *GetVirtualMetacontentFromCache(const Image *image) % % A description of each parameter follows: % % o image: the image. % */ static const void *GetVirtualMetacontentFromCache(const Image *image) { CacheInfo *magick_restrict cache_info; const int id = GetOpenMPThreadId(); const void *magick_restrict metacontent; assert(image != (const Image *) NULL); assert(image->signature == MagickCoreSignature); assert(image->cache != (Cache) NULL); cache_info=(CacheInfo *) image->cache; assert(cache_info->signature == MagickCoreSignature); assert(id < (int) cache_info->number_threads); metacontent=GetVirtualMetacontentFromNexus(cache_info, cache_info->nexus_info[id]); return(metacontent); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + G e t V i r t u a l M e t a c o n t e n t F r o m N e x u s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetVirtualMetacontentFromNexus() returns the meta-content for the specified % cache nexus. % % The format of the GetVirtualMetacontentFromNexus() method is: % % const void *GetVirtualMetacontentFromNexus(const Cache cache, % NexusInfo *nexus_info) % % A description of each parameter follows: % % o cache: the pixel cache. % % o nexus_info: the cache nexus to return the meta-content. % */ MagickPrivate const void *GetVirtualMetacontentFromNexus(const Cache cache, NexusInfo *magick_restrict nexus_info) { CacheInfo *magick_restrict cache_info; assert(cache != (Cache) NULL); cache_info=(CacheInfo *) cache; assert(cache_info->signature == MagickCoreSignature); if (cache_info->storage_class == UndefinedClass) return((void *) NULL); return(nexus_info->metacontent); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % G e t V i r t u a l M e t a c o n t e n t % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetVirtualMetacontent() returns the virtual metacontent corresponding with % the last call to QueueAuthenticPixels() or GetVirtualPixels(). NULL is % returned if the meta-content are not available. % % The format of the GetVirtualMetacontent() method is: % % const void *GetVirtualMetacontent(const Image *image) % % A description of each parameter follows: % % o image: the image. % */ MagickExport const void *GetVirtualMetacontent(const Image *image) { CacheInfo *magick_restrict cache_info; const int id = GetOpenMPThreadId(); const void *magick_restrict metacontent; assert(image != (const Image *) NULL); assert(image->signature == MagickCoreSignature); assert(image->cache != (Cache) NULL); cache_info=(CacheInfo *) image->cache; assert(cache_info->signature == MagickCoreSignature); metacontent=cache_info->methods.get_virtual_metacontent_from_handler(image); if (metacontent != (void *) NULL) return(metacontent); assert(id < (int) cache_info->number_threads); metacontent=GetVirtualMetacontentFromNexus(cache_info, cache_info->nexus_info[id]); return(metacontent); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + G e t V i r t u a l P i x e l C a c h e N e x u s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetVirtualPixelCacheNexus() gets virtual pixels from the in-memory or disk % pixel cache as defined by the geometry parameters. A pointer to the pixels % is returned if the pixels are transferred, otherwise a NULL is returned. % % The format of the GetVirtualPixelCacheNexus() method is: % % Quantum *GetVirtualPixelCacheNexus(const Image *image, % const VirtualPixelMethod method,const ssize_t x,const ssize_t y, % const size_t columns,const size_t rows,NexusInfo *nexus_info, % ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o virtual_pixel_method: the virtual pixel method. % % o x,y,columns,rows: These values define the perimeter of a region of % pixels. % % o nexus_info: the cache nexus to acquire. % % o exception: return any errors or warnings in this structure. % */ static ssize_t DitherMatrix[64] = { 0, 48, 12, 60, 3, 51, 15, 63, 32, 16, 44, 28, 35, 19, 47, 31, 8, 56, 4, 52, 11, 59, 7, 55, 40, 24, 36, 20, 43, 27, 39, 23, 2, 50, 14, 62, 1, 49, 13, 61, 34, 18, 46, 30, 33, 17, 45, 29, 10, 58, 6, 54, 9, 57, 5, 53, 42, 26, 38, 22, 41, 25, 37, 21 }; static inline ssize_t DitherX(const ssize_t x,const size_t columns) { ssize_t index; index=x+DitherMatrix[x & 0x07]-32L; if (index < 0L) return(0L); if (index >= (ssize_t) columns) return((ssize_t) columns-1L); return(index); } static inline ssize_t DitherY(const ssize_t y,const size_t rows) { ssize_t index; index=y+DitherMatrix[y & 0x07]-32L; if (index < 0L) return(0L); if (index >= (ssize_t) rows) return((ssize_t) rows-1L); return(index); } 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 ssize_t RandomX(RandomInfo *random_info,const size_t columns) { return((ssize_t) (columns*GetPseudoRandomValue(random_info))); } static inline ssize_t RandomY(RandomInfo *random_info,const size_t rows) { return((ssize_t) (rows*GetPseudoRandomValue(random_info))); } static inline MagickModulo VirtualPixelModulo(const ssize_t offset, const size_t extent) { MagickModulo modulo; /* Compute the remainder of dividing offset by extent. It returns not only the quotient (tile the offset falls in) but also the positive remainer within that tile such that 0 <= remainder < extent. This method is essentially a ldiv() using a floored modulo division rather than the normal default truncated modulo division. */ modulo.quotient=offset/(ssize_t) extent; if (offset < 0L) modulo.quotient--; modulo.remainder=(ssize_t) (offset-(MagickOffsetType) modulo.quotient* (ssize_t) extent); return(modulo); } MagickPrivate const Quantum *GetVirtualPixelCacheNexus(const Image *image, const VirtualPixelMethod virtual_pixel_method,const ssize_t x,const ssize_t y, const size_t columns,const size_t rows,NexusInfo *nexus_info, ExceptionInfo *exception) { CacheInfo *magick_restrict cache_info; MagickOffsetType offset; MagickSizeType length, number_pixels; NexusInfo **magick_restrict virtual_nexus; Quantum *magick_restrict pixels, virtual_pixel[MaxPixelChannels]; RectangleInfo region; register const Quantum *magick_restrict p; register const void *magick_restrict r; register Quantum *magick_restrict q; register ssize_t i, u; register unsigned char *magick_restrict s; ssize_t v; void *magick_restrict virtual_metacontent; /* Acquire pixels. */ assert(image != (const Image *) NULL); assert(image->signature == MagickCoreSignature); assert(image->cache != (Cache) NULL); cache_info=(CacheInfo *) image->cache; assert(cache_info->signature == MagickCoreSignature); if (cache_info->type == UndefinedCache) return((const Quantum *) NULL); #if defined(MAGICKCORE_OPENCL_SUPPORT) CopyOpenCLBuffer(cache_info); #endif region.x=x; region.y=y; region.width=columns; region.height=rows; pixels=SetPixelCacheNexusPixels(cache_info,ReadMode,&region, ((image->channels & WriteMaskChannel) != 0) || ((image->channels & CompositeMaskChannel) != 0) ? MagickTrue : MagickFalse, nexus_info,exception); if (pixels == (Quantum *) NULL) return((const Quantum *) NULL); q=pixels; offset=(MagickOffsetType) nexus_info->region.y*cache_info->columns+ nexus_info->region.x; length=(MagickSizeType) (nexus_info->region.height-1L)*cache_info->columns+ nexus_info->region.width-1L; number_pixels=(MagickSizeType) cache_info->columns*cache_info->rows; if ((offset >= 0) && (((MagickSizeType) offset+length) < number_pixels)) if ((x >= 0) && ((ssize_t) (x+columns) <= (ssize_t) cache_info->columns) && (y >= 0) && ((ssize_t) (y+rows) <= (ssize_t) cache_info->rows)) { MagickBooleanType status; /* Pixel request is inside cache extents. */ if (nexus_info->authentic_pixel_cache != MagickFalse) return(q); status=ReadPixelCachePixels(cache_info,nexus_info,exception); if (status == MagickFalse) return((const Quantum *) NULL); if (cache_info->metacontent_extent != 0) { status=ReadPixelCacheMetacontent(cache_info,nexus_info,exception); if (status == MagickFalse) return((const Quantum *) NULL); } return(q); } /* Pixel request is outside cache extents. */ s=(unsigned char *) nexus_info->metacontent; virtual_nexus=AcquirePixelCacheNexus(1); (void) memset(virtual_pixel,0,cache_info->number_channels* sizeof(*virtual_pixel)); virtual_metacontent=(void *) NULL; switch (virtual_pixel_method) { case BackgroundVirtualPixelMethod: case BlackVirtualPixelMethod: case GrayVirtualPixelMethod: case TransparentVirtualPixelMethod: case MaskVirtualPixelMethod: case WhiteVirtualPixelMethod: case EdgeVirtualPixelMethod: case CheckerTileVirtualPixelMethod: case HorizontalTileVirtualPixelMethod: case VerticalTileVirtualPixelMethod: { if (cache_info->metacontent_extent != 0) { /* Acquire a metacontent buffer. */ virtual_metacontent=(void *) AcquireQuantumMemory(1, cache_info->metacontent_extent); if (virtual_metacontent == (void *) NULL) { virtual_nexus=DestroyPixelCacheNexus(virtual_nexus,1); (void) ThrowMagickException(exception,GetMagickModule(), CacheError,"UnableToGetCacheNexus","`%s'",image->filename); return((const Quantum *) NULL); } (void) memset(virtual_metacontent,0,cache_info->metacontent_extent); } switch (virtual_pixel_method) { case BlackVirtualPixelMethod: { for (i=0; i < (ssize_t) cache_info->number_channels; i++) SetPixelChannel(image,(PixelChannel) i,(Quantum) 0,virtual_pixel); SetPixelAlpha(image,OpaqueAlpha,virtual_pixel); break; } case GrayVirtualPixelMethod: { for (i=0; i < (ssize_t) cache_info->number_channels; i++) SetPixelChannel(image,(PixelChannel) i,QuantumRange/2, virtual_pixel); SetPixelAlpha(image,OpaqueAlpha,virtual_pixel); break; } case TransparentVirtualPixelMethod: { for (i=0; i < (ssize_t) cache_info->number_channels; i++) SetPixelChannel(image,(PixelChannel) i,(Quantum) 0,virtual_pixel); SetPixelAlpha(image,TransparentAlpha,virtual_pixel); break; } case MaskVirtualPixelMethod: case WhiteVirtualPixelMethod: { for (i=0; i < (ssize_t) cache_info->number_channels; i++) SetPixelChannel(image,(PixelChannel) i,QuantumRange,virtual_pixel); SetPixelAlpha(image,OpaqueAlpha,virtual_pixel); break; } default: { SetPixelRed(image,ClampToQuantum(image->background_color.red), virtual_pixel); SetPixelGreen(image,ClampToQuantum(image->background_color.green), virtual_pixel); SetPixelBlue(image,ClampToQuantum(image->background_color.blue), virtual_pixel); SetPixelBlack(image,ClampToQuantum(image->background_color.black), virtual_pixel); SetPixelAlpha(image,ClampToQuantum(image->background_color.alpha), virtual_pixel); break; } } break; } default: break; } for (v=0; v < (ssize_t) rows; v++) { ssize_t y_offset; y_offset=y+v; if ((virtual_pixel_method == EdgeVirtualPixelMethod) || (virtual_pixel_method == UndefinedVirtualPixelMethod)) y_offset=EdgeY(y_offset,cache_info->rows); for (u=0; u < (ssize_t) columns; u+=length) { ssize_t x_offset; x_offset=x+u; length=(MagickSizeType) MagickMin(cache_info->columns-x_offset,columns-u); if (((x_offset < 0) || (x_offset >= (ssize_t) cache_info->columns)) || ((y_offset < 0) || (y_offset >= (ssize_t) cache_info->rows)) || (length == 0)) { MagickModulo x_modulo, y_modulo; /* Transfer a single pixel. */ length=(MagickSizeType) 1; switch (virtual_pixel_method) { case EdgeVirtualPixelMethod: default: { p=GetVirtualPixelCacheNexus(image,virtual_pixel_method, EdgeX(x_offset,cache_info->columns), EdgeY(y_offset,cache_info->rows),1UL,1UL,*virtual_nexus, exception); r=GetVirtualMetacontentFromNexus(cache_info,*virtual_nexus); break; } case RandomVirtualPixelMethod: { if (cache_info->random_info == (RandomInfo *) NULL) cache_info->random_info=AcquireRandomInfo(); p=GetVirtualPixelCacheNexus(image,virtual_pixel_method, RandomX(cache_info->random_info,cache_info->columns), RandomY(cache_info->random_info,cache_info->rows),1UL,1UL, *virtual_nexus,exception); r=GetVirtualMetacontentFromNexus(cache_info,*virtual_nexus); break; } case DitherVirtualPixelMethod: { p=GetVirtualPixelCacheNexus(image,virtual_pixel_method, DitherX(x_offset,cache_info->columns), DitherY(y_offset,cache_info->rows),1UL,1UL,*virtual_nexus, exception); r=GetVirtualMetacontentFromNexus(cache_info,*virtual_nexus); break; } case TileVirtualPixelMethod: { x_modulo=VirtualPixelModulo(x_offset,cache_info->columns); y_modulo=VirtualPixelModulo(y_offset,cache_info->rows); p=GetVirtualPixelCacheNexus(image,virtual_pixel_method, x_modulo.remainder,y_modulo.remainder,1UL,1UL,*virtual_nexus, exception); r=GetVirtualMetacontentFromNexus(cache_info,*virtual_nexus); break; } case MirrorVirtualPixelMethod: { x_modulo=VirtualPixelModulo(x_offset,cache_info->columns); if ((x_modulo.quotient & 0x01) == 1L) x_modulo.remainder=(ssize_t) cache_info->columns- x_modulo.remainder-1L; y_modulo=VirtualPixelModulo(y_offset,cache_info->rows); if ((y_modulo.quotient & 0x01) == 1L) y_modulo.remainder=(ssize_t) cache_info->rows- y_modulo.remainder-1L; p=GetVirtualPixelCacheNexus(image,virtual_pixel_method, x_modulo.remainder,y_modulo.remainder,1UL,1UL,*virtual_nexus, exception); r=GetVirtualMetacontentFromNexus(cache_info,*virtual_nexus); break; } case HorizontalTileEdgeVirtualPixelMethod: { x_modulo=VirtualPixelModulo(x_offset,cache_info->columns); p=GetVirtualPixelCacheNexus(image,virtual_pixel_method, x_modulo.remainder,EdgeY(y_offset,cache_info->rows),1UL,1UL, *virtual_nexus,exception); r=GetVirtualMetacontentFromNexus(cache_info,*virtual_nexus); break; } case VerticalTileEdgeVirtualPixelMethod: { y_modulo=VirtualPixelModulo(y_offset,cache_info->rows); p=GetVirtualPixelCacheNexus(image,virtual_pixel_method, EdgeX(x_offset,cache_info->columns),y_modulo.remainder,1UL,1UL, *virtual_nexus,exception); r=GetVirtualMetacontentFromNexus(cache_info,*virtual_nexus); break; } case BackgroundVirtualPixelMethod: case BlackVirtualPixelMethod: case GrayVirtualPixelMethod: case TransparentVirtualPixelMethod: case MaskVirtualPixelMethod: case WhiteVirtualPixelMethod: { p=virtual_pixel; r=virtual_metacontent; break; } case CheckerTileVirtualPixelMethod: { x_modulo=VirtualPixelModulo(x_offset,cache_info->columns); y_modulo=VirtualPixelModulo(y_offset,cache_info->rows); if (((x_modulo.quotient ^ y_modulo.quotient) & 0x01) != 0L) { p=virtual_pixel; r=virtual_metacontent; break; } p=GetVirtualPixelCacheNexus(image,virtual_pixel_method, x_modulo.remainder,y_modulo.remainder,1UL,1UL,*virtual_nexus, exception); r=GetVirtualMetacontentFromNexus(cache_info,*virtual_nexus); break; } case HorizontalTileVirtualPixelMethod: { if ((y_offset < 0) || (y_offset >= (ssize_t) cache_info->rows)) { p=virtual_pixel; r=virtual_metacontent; break; } x_modulo=VirtualPixelModulo(x_offset,cache_info->columns); y_modulo=VirtualPixelModulo(y_offset,cache_info->rows); p=GetVirtualPixelCacheNexus(image,virtual_pixel_method, x_modulo.remainder,y_modulo.remainder,1UL,1UL,*virtual_nexus, exception); r=GetVirtualMetacontentFromNexus(cache_info,*virtual_nexus); break; } case VerticalTileVirtualPixelMethod: { if ((x_offset < 0) || (x_offset >= (ssize_t) cache_info->columns)) { p=virtual_pixel; r=virtual_metacontent; break; } x_modulo=VirtualPixelModulo(x_offset,cache_info->columns); y_modulo=VirtualPixelModulo(y_offset,cache_info->rows); p=GetVirtualPixelCacheNexus(image,virtual_pixel_method, x_modulo.remainder,y_modulo.remainder,1UL,1UL,*virtual_nexus, exception); r=GetVirtualMetacontentFromNexus(cache_info,*virtual_nexus); break; } } if (p == (const Quantum *) NULL) break; (void) memcpy(q,p,(size_t) length*cache_info->number_channels* sizeof(*p)); q+=cache_info->number_channels; if ((s != (void *) NULL) && (r != (const void *) NULL)) { (void) memcpy(s,r,(size_t) cache_info->metacontent_extent); s+=cache_info->metacontent_extent; } continue; } /* Transfer a run of pixels. */ p=GetVirtualPixelCacheNexus(image,virtual_pixel_method,x_offset,y_offset, (size_t) length,1UL,*virtual_nexus,exception); if (p == (const Quantum *) NULL) break; r=GetVirtualMetacontentFromNexus(cache_info,*virtual_nexus); (void) memcpy(q,p,(size_t) length*cache_info->number_channels*sizeof(*p)); q+=length*cache_info->number_channels; if ((r != (void *) NULL) && (s != (const void *) NULL)) { (void) memcpy(s,r,(size_t) length); s+=length*cache_info->metacontent_extent; } } if (u < (ssize_t) columns) break; } /* Free resources. */ if (virtual_metacontent != (void *) NULL) virtual_metacontent=(void *) RelinquishMagickMemory(virtual_metacontent); virtual_nexus=DestroyPixelCacheNexus(virtual_nexus,1); if (v < (ssize_t) rows) return((const Quantum *) NULL); return(pixels); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + G e t V i r t u a l P i x e l C a c h e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetVirtualPixelCache() get virtual pixels from the in-memory or disk pixel % cache as defined by the geometry parameters. A pointer to the pixels % is returned if the pixels are transferred, otherwise a NULL is returned. % % The format of the GetVirtualPixelCache() method is: % % const Quantum *GetVirtualPixelCache(const Image *image, % const VirtualPixelMethod virtual_pixel_method,const ssize_t x, % const ssize_t y,const size_t columns,const size_t rows, % ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o virtual_pixel_method: the virtual pixel method. % % o x,y,columns,rows: These values define the perimeter of a region of % pixels. % % o exception: return any errors or warnings in this structure. % */ static const Quantum *GetVirtualPixelCache(const Image *image, const VirtualPixelMethod virtual_pixel_method,const ssize_t x,const ssize_t y, const size_t columns,const size_t rows,ExceptionInfo *exception) { CacheInfo *magick_restrict cache_info; const int id = GetOpenMPThreadId(); const Quantum *magick_restrict p; assert(image != (const Image *) NULL); assert(image->signature == MagickCoreSignature); assert(image->cache != (Cache) NULL); cache_info=(CacheInfo *) image->cache; assert(cache_info->signature == MagickCoreSignature); assert(id < (int) cache_info->number_threads); p=GetVirtualPixelCacheNexus(image,virtual_pixel_method,x,y,columns,rows, cache_info->nexus_info[id],exception); return(p); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % G e t V i r t u a l P i x e l Q u e u e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetVirtualPixelQueue() returns the virtual pixels associated corresponding % with the last call to QueueAuthenticPixels() or GetVirtualPixels(). % % The format of the GetVirtualPixelQueue() method is: % % const Quantum *GetVirtualPixelQueue(const Image image) % % A description of each parameter follows: % % o image: the image. % */ MagickExport const Quantum *GetVirtualPixelQueue(const Image *image) { CacheInfo *magick_restrict cache_info; const int id = GetOpenMPThreadId(); assert(image != (const Image *) NULL); assert(image->signature == MagickCoreSignature); assert(image->cache != (Cache) NULL); cache_info=(CacheInfo *) image->cache; assert(cache_info->signature == MagickCoreSignature); if (cache_info->methods.get_virtual_pixels_handler != (GetVirtualPixelsHandler) NULL) return(cache_info->methods.get_virtual_pixels_handler(image)); assert(id < (int) cache_info->number_threads); return(GetVirtualPixelsNexus(cache_info,cache_info->nexus_info[id])); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % G e t V i r t u a l P i x e l s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetVirtualPixels() returns an immutable pixel region. If the % region is successfully accessed, a pointer to it is returned, otherwise % NULL is returned. The returned pointer may point to a temporary working % copy of the pixels or it may point to the original pixels in memory. % Performance is maximized if the selected region is part of one row, or one % or more full rows, since there is opportunity to access the pixels in-place % (without a copy) if the image is in memory, or in a memory-mapped file. The % returned pointer must *never* be deallocated by the user. % % Pixels accessed via the returned pointer represent a simple array of type % Quantum. If the image type is CMYK or the storage class is PseudoClass, % call GetAuthenticMetacontent() after invoking GetAuthenticPixels() to % access the meta-content (of type void) corresponding to the the % region. % % If you plan to modify the pixels, use GetAuthenticPixels() instead. % % Note, the GetVirtualPixels() and GetAuthenticPixels() methods are not thread- % safe. In a threaded environment, use GetCacheViewVirtualPixels() or % GetCacheViewAuthenticPixels() instead. % % The format of the GetVirtualPixels() method is: % % const Quantum *GetVirtualPixels(const Image *image,const ssize_t x, % const ssize_t y,const size_t columns,const size_t rows, % ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o x,y,columns,rows: These values define the perimeter of a region of % pixels. % % o exception: return any errors or warnings in this structure. % */ MagickExport const Quantum *GetVirtualPixels(const Image *image, const ssize_t x,const ssize_t y,const size_t columns,const size_t rows, ExceptionInfo *exception) { CacheInfo *magick_restrict cache_info; const int id = GetOpenMPThreadId(); const Quantum *magick_restrict p; assert(image != (const Image *) NULL); assert(image->signature == MagickCoreSignature); assert(image->cache != (Cache) NULL); cache_info=(CacheInfo *) image->cache; assert(cache_info->signature == MagickCoreSignature); if (cache_info->methods.get_virtual_pixel_handler != (GetVirtualPixelHandler) NULL) return(cache_info->methods.get_virtual_pixel_handler(image, GetPixelCacheVirtualMethod(image),x,y,columns,rows,exception)); assert(id < (int) cache_info->number_threads); p=GetVirtualPixelCacheNexus(image,GetPixelCacheVirtualMethod(image),x,y, columns,rows,cache_info->nexus_info[id],exception); return(p); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + G e t V i r t u a l P i x e l s F r o m C a c h e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetVirtualPixelsCache() returns the pixels associated corresponding with the % last call to QueueAuthenticPixelsCache() or GetVirtualPixelCache(). % % The format of the GetVirtualPixelsCache() method is: % % Quantum *GetVirtualPixelsCache(const Image *image) % % A description of each parameter follows: % % o image: the image. % */ static const Quantum *GetVirtualPixelsCache(const Image *image) { CacheInfo *magick_restrict cache_info; const int id = GetOpenMPThreadId(); assert(image != (const Image *) NULL); assert(image->signature == MagickCoreSignature); assert(image->cache != (Cache) NULL); cache_info=(CacheInfo *) image->cache; assert(cache_info->signature == MagickCoreSignature); assert(id < (int) cache_info->number_threads); return(GetVirtualPixelsNexus(image->cache,cache_info->nexus_info[id])); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + G e t V i r t u a l P i x e l s N e x u s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetVirtualPixelsNexus() returns the pixels associated with the specified % cache nexus. % % The format of the GetVirtualPixelsNexus() method is: % % const Quantum *GetVirtualPixelsNexus(const Cache cache, % NexusInfo *nexus_info) % % A description of each parameter follows: % % o cache: the pixel cache. % % o nexus_info: the cache nexus to return the colormap pixels. % */ MagickPrivate const Quantum *GetVirtualPixelsNexus(const Cache cache, NexusInfo *magick_restrict nexus_info) { CacheInfo *magick_restrict cache_info; assert(cache != (Cache) NULL); cache_info=(CacheInfo *) cache; assert(cache_info->signature == MagickCoreSignature); if (cache_info->storage_class == UndefinedClass) return((Quantum *) NULL); return((const Quantum *) nexus_info->pixels); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + M a s k P i x e l C a c h e N e x u s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % MaskPixelCacheNexus() masks the cache nexus as defined by the image mask. % The method returns MagickTrue if the pixel region is masked, otherwise % MagickFalse. % % The format of the MaskPixelCacheNexus() method is: % % MagickBooleanType MaskPixelCacheNexus(Image *image, % NexusInfo *nexus_info,ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o nexus_info: the cache nexus to clip. % % o exception: return any errors or warnings in this structure. % */ static inline Quantum ApplyPixelCompositeMask(const Quantum p, const MagickRealType alpha,const Quantum q,const MagickRealType beta) { double mask_alpha; if (fabs(alpha-OpaqueAlpha) < MagickEpsilon) return(p); mask_alpha=1.0-QuantumScale*QuantumScale*alpha*beta; mask_alpha=PerceptibleReciprocal(mask_alpha); return(ClampToQuantum(mask_alpha*MagickOver_((double) p,alpha,(double) q,beta))); } static MagickBooleanType MaskPixelCacheNexus(Image *image,NexusInfo *nexus_info, ExceptionInfo *exception) { CacheInfo *magick_restrict cache_info; MagickSizeType number_pixels; NexusInfo **magick_restrict image_nexus; register Quantum *magick_restrict p, *magick_restrict q; register ssize_t n; /* Apply clip mask. */ if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); if ((image->channels & CompositeMaskChannel) == 0) return(MagickTrue); cache_info=(CacheInfo *) image->cache; if (cache_info == (Cache) NULL) return(MagickFalse); image_nexus=AcquirePixelCacheNexus(1); p=GetAuthenticPixelCacheNexus(image,nexus_info->region.x,nexus_info->region.y, nexus_info->region.width,nexus_info->region.height,image_nexus[0], exception); q=nexus_info->pixels; number_pixels=(MagickSizeType) nexus_info->region.width* nexus_info->region.height; for (n=0; n < (ssize_t) number_pixels; n++) { double mask_alpha; register ssize_t i; if (p == (Quantum *) NULL) break; mask_alpha=(double) GetPixelCompositeMask(image,p); for (i=0; i < (ssize_t) image->number_channels; i++) { PixelChannel channel = GetPixelChannelChannel(image,i); PixelTrait traits = GetPixelChannelTraits(image,channel); if ((traits & UpdatePixelTrait) == 0) continue; q[i]=ApplyPixelCompositeMask(p[i],mask_alpha,q[i], (MagickRealType) GetPixelAlpha(image,q)); } p+=GetPixelChannels(image); q+=GetPixelChannels(image); } image_nexus=DestroyPixelCacheNexus(image_nexus,1); if (n < (ssize_t) number_pixels) return(MagickFalse); return(MagickTrue); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + O p e n P i x e l C a c h e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % OpenPixelCache() allocates the pixel cache. This includes defining the cache % dimensions, allocating space for the image pixels and optionally the % metacontent, and memory mapping the cache if it is disk based. The cache % nexus array is initialized as well. % % The format of the OpenPixelCache() method is: % % MagickBooleanType OpenPixelCache(Image *image,const MapMode mode, % ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o mode: ReadMode, WriteMode, or IOMode. % % o exception: return any errors or warnings in this structure. % */ static MagickBooleanType OpenPixelCacheOnDisk(CacheInfo *cache_info, const MapMode mode) { int file; /* Open pixel cache on disk. */ if ((cache_info->file != -1) && (cache_info->disk_mode == mode)) return(MagickTrue); /* cache already open and in the proper mode */ if (*cache_info->cache_filename == '\0') file=AcquireUniqueFileResource(cache_info->cache_filename); else switch (mode) { case ReadMode: { file=open_utf8(cache_info->cache_filename,O_RDONLY | O_BINARY,0); break; } case WriteMode: { file=open_utf8(cache_info->cache_filename,O_WRONLY | O_CREAT | O_BINARY | O_EXCL,S_MODE); if (file == -1) file=open_utf8(cache_info->cache_filename,O_WRONLY | O_BINARY,S_MODE); break; } case IOMode: default: { file=open_utf8(cache_info->cache_filename,O_RDWR | O_CREAT | O_BINARY | O_EXCL,S_MODE); if (file == -1) file=open_utf8(cache_info->cache_filename,O_RDWR | O_BINARY,S_MODE); break; } } if (file == -1) return(MagickFalse); (void) AcquireMagickResource(FileResource,1); if (cache_info->file != -1) (void) ClosePixelCacheOnDisk(cache_info); cache_info->file=file; cache_info->disk_mode=mode; return(MagickTrue); } static inline MagickOffsetType WritePixelCacheRegion( const CacheInfo *magick_restrict cache_info,const MagickOffsetType offset, const MagickSizeType length,const unsigned char *magick_restrict buffer) { register MagickOffsetType i; ssize_t count; #if !defined(MAGICKCORE_HAVE_PWRITE) if (lseek(cache_info->file,offset,SEEK_SET) < 0) return((MagickOffsetType) -1); #endif count=0; for (i=0; i < (MagickOffsetType) length; i+=count) { #if !defined(MAGICKCORE_HAVE_PWRITE) count=write(cache_info->file,buffer+i,(size_t) MagickMin(length-i,(size_t) SSIZE_MAX)); #else count=pwrite(cache_info->file,buffer+i,(size_t) MagickMin(length-i,(size_t) SSIZE_MAX),(off_t) (offset+i)); #endif if (count <= 0) { count=0; if (errno != EINTR) break; } } return(i); } static MagickBooleanType SetPixelCacheExtent(Image *image,MagickSizeType length) { CacheInfo *magick_restrict cache_info; MagickOffsetType count, extent, offset; cache_info=(CacheInfo *) image->cache; if (image->debug != MagickFalse) { char format[MagickPathExtent], message[MagickPathExtent]; (void) FormatMagickSize(length,MagickFalse,"B",MagickPathExtent,format); (void) FormatLocaleString(message,MagickPathExtent, "extend %s (%s[%d], disk, %s)",cache_info->filename, cache_info->cache_filename,cache_info->file,format); (void) LogMagickEvent(CacheEvent,GetMagickModule(),"%s",message); } if (length != (MagickSizeType) ((MagickOffsetType) length)) return(MagickFalse); offset=(MagickOffsetType) lseek(cache_info->file,0,SEEK_END); if (offset < 0) return(MagickFalse); if ((MagickSizeType) offset >= length) count=(MagickOffsetType) 1; else { extent=(MagickOffsetType) length-1; count=WritePixelCacheRegion(cache_info,extent,1,(const unsigned char *) ""); if (count != 1) return(MagickFalse); #if defined(MAGICKCORE_HAVE_POSIX_FALLOCATE) if (cache_info->synchronize != MagickFalse) (void) posix_fallocate(cache_info->file,offset+1,extent-offset); #endif } offset=(MagickOffsetType) lseek(cache_info->file,0,SEEK_SET); if (offset < 0) return(MagickFalse); return(MagickTrue); } static MagickBooleanType OpenPixelCache(Image *image,const MapMode mode, ExceptionInfo *exception) { CacheInfo *magick_restrict cache_info, source_info; char format[MagickPathExtent], message[MagickPathExtent]; const char *hosts, *type; MagickBooleanType status; MagickSizeType length, number_pixels; size_t columns, packet_size; assert(image != (const Image *) NULL); assert(image->signature == MagickCoreSignature); assert(image->cache != (Cache) NULL); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); if (cache_anonymous_memory < 0) { char *value; /* Does the security policy require anonymous mapping for pixel cache? */ cache_anonymous_memory=0; value=GetPolicyValue("pixel-cache-memory"); if (value == (char *) NULL) value=GetPolicyValue("cache:memory-map"); if (LocaleCompare(value,"anonymous") == 0) { #if defined(MAGICKCORE_HAVE_MMAP) && defined(MAP_ANONYMOUS) cache_anonymous_memory=1; #else (void) ThrowMagickException(exception,GetMagickModule(), MissingDelegateError,"DelegateLibrarySupportNotBuiltIn", "'%s' (policy requires anonymous memory mapping)",image->filename); #endif } value=DestroyString(value); } if ((image->columns == 0) || (image->rows == 0)) ThrowBinaryException(CacheError,"NoPixelsDefinedInCache",image->filename); cache_info=(CacheInfo *) image->cache; assert(cache_info->signature == MagickCoreSignature); if ((AcquireMagickResource(WidthResource,image->columns) == MagickFalse) || (AcquireMagickResource(HeightResource,image->rows) == MagickFalse)) ThrowBinaryException(ImageError,"WidthOrHeightExceedsLimit", image->filename); length=GetImageListLength(image); if (AcquireMagickResource(ListLengthResource,length) == MagickFalse) ThrowBinaryException(ResourceLimitError,"ListLengthExceedsLimit", image->filename); source_info=(*cache_info); source_info.file=(-1); (void) FormatLocaleString(cache_info->filename,MagickPathExtent,"%s[%.20g]", image->filename,(double) image->scene); cache_info->storage_class=image->storage_class; cache_info->colorspace=image->colorspace; cache_info->alpha_trait=image->alpha_trait; cache_info->channels=image->channels; cache_info->rows=image->rows; cache_info->columns=image->columns; InitializePixelChannelMap(image); cache_info->number_channels=GetPixelChannels(image); (void) memcpy(cache_info->channel_map,image->channel_map,MaxPixelChannels* sizeof(*image->channel_map)); cache_info->metacontent_extent=image->metacontent_extent; cache_info->mode=mode; number_pixels=(MagickSizeType) cache_info->columns*cache_info->rows; packet_size=cache_info->number_channels*sizeof(Quantum); if (image->metacontent_extent != 0) packet_size+=cache_info->metacontent_extent; length=number_pixels*packet_size; columns=(size_t) (length/cache_info->rows/packet_size); if ((cache_info->columns != columns) || ((ssize_t) cache_info->columns < 0) || ((ssize_t) cache_info->rows < 0)) ThrowBinaryException(ResourceLimitError,"PixelCacheAllocationFailed", image->filename); cache_info->length=length; if (image->ping != MagickFalse) { cache_info->storage_class=image->storage_class; cache_info->colorspace=image->colorspace; cache_info->type=PingCache; return(MagickTrue); } status=AcquireMagickResource(AreaResource,(MagickSizeType) cache_info->columns*cache_info->rows); if (cache_info->mode == PersistMode) status=MagickFalse; length=number_pixels*(cache_info->number_channels*sizeof(Quantum)+ cache_info->metacontent_extent); if ((status != MagickFalse) && (length == (MagickSizeType) ((size_t) length)) && ((cache_info->type == UndefinedCache) || (cache_info->type == MemoryCache))) { status=AcquireMagickResource(MemoryResource,cache_info->length); if (status != MagickFalse) { status=MagickTrue; if (cache_anonymous_memory <= 0) { cache_info->mapped=MagickFalse; cache_info->pixels=(Quantum *) MagickAssumeAligned( AcquireAlignedMemory(1,(size_t) cache_info->length)); } else { cache_info->mapped=MagickTrue; cache_info->pixels=(Quantum *) MapBlob(-1,IOMode,0,(size_t) cache_info->length); } if (cache_info->pixels == (Quantum *) NULL) cache_info->pixels=source_info.pixels; else { /* Create memory pixel cache. */ cache_info->type=MemoryCache; cache_info->metacontent=(void *) NULL; if (cache_info->metacontent_extent != 0) cache_info->metacontent=(void *) (cache_info->pixels+ number_pixels*cache_info->number_channels); if ((source_info.storage_class != UndefinedClass) && (mode != ReadMode)) { status=ClonePixelCacheRepository(cache_info,&source_info, exception); RelinquishPixelCachePixels(&source_info); } if (image->debug != MagickFalse) { (void) FormatMagickSize(cache_info->length,MagickTrue,"B", MagickPathExtent,format); type=CommandOptionToMnemonic(MagickCacheOptions,(ssize_t) cache_info->type); (void) FormatLocaleString(message,MagickPathExtent, "open %s (%s %s, %.20gx%.20gx%.20g %s)", cache_info->filename,cache_info->mapped != MagickFalse ? "Anonymous" : "Heap",type,(double) cache_info->columns, (double) cache_info->rows,(double) cache_info->number_channels,format); (void) LogMagickEvent(CacheEvent,GetMagickModule(),"%s", message); } return(status == 0 ? MagickFalse : MagickTrue); } } } status=AcquireMagickResource(DiskResource,cache_info->length); hosts=(const char *) GetImageRegistry(StringRegistryType,"cache:hosts", exception); if ((status == MagickFalse) && (hosts != (const char *) NULL)) { DistributeCacheInfo *server_info; /* Distribute the pixel cache to a remote server. */ server_info=AcquireDistributeCacheInfo(exception); if (server_info != (DistributeCacheInfo *) NULL) { status=OpenDistributePixelCache(server_info,image); if (status == MagickFalse) { ThrowFileException(exception,CacheError,"UnableToOpenPixelCache", GetDistributeCacheHostname(server_info)); server_info=DestroyDistributeCacheInfo(server_info); } else { /* Create a distributed pixel cache. */ status=MagickTrue; cache_info->type=DistributedCache; cache_info->server_info=server_info; (void) FormatLocaleString(cache_info->cache_filename, MagickPathExtent,"%s:%d",GetDistributeCacheHostname( (DistributeCacheInfo *) cache_info->server_info), GetDistributeCachePort((DistributeCacheInfo *) cache_info->server_info)); if ((source_info.storage_class != UndefinedClass) && (mode != ReadMode)) { status=ClonePixelCacheRepository(cache_info,&source_info, exception); RelinquishPixelCachePixels(&source_info); } if (image->debug != MagickFalse) { (void) FormatMagickSize(cache_info->length,MagickFalse,"B", MagickPathExtent,format); type=CommandOptionToMnemonic(MagickCacheOptions,(ssize_t) cache_info->type); (void) FormatLocaleString(message,MagickPathExtent, "open %s (%s[%d], %s, %.20gx%.20gx%.20g %s)", cache_info->filename,cache_info->cache_filename, GetDistributeCacheFile((DistributeCacheInfo *) cache_info->server_info),type,(double) cache_info->columns, (double) cache_info->rows,(double) cache_info->number_channels,format); (void) LogMagickEvent(CacheEvent,GetMagickModule(),"%s", message); } return(status == 0 ? MagickFalse : MagickTrue); } } cache_info->type=UndefinedCache; (void) ThrowMagickException(exception,GetMagickModule(),CacheError, "CacheResourcesExhausted","`%s'",image->filename); return(MagickFalse); } /* Create pixel cache on disk. */ if (status == MagickFalse) { cache_info->type=UndefinedCache; (void) ThrowMagickException(exception,GetMagickModule(),CacheError, "CacheResourcesExhausted","`%s'",image->filename); return(MagickFalse); } if ((source_info.storage_class != UndefinedClass) && (mode != ReadMode) && (cache_info->mode != PersistMode)) { (void) ClosePixelCacheOnDisk(cache_info); *cache_info->cache_filename='\0'; } if (OpenPixelCacheOnDisk(cache_info,mode) == MagickFalse) { ThrowFileException(exception,CacheError,"UnableToOpenPixelCache", image->filename); return(MagickFalse); } status=SetPixelCacheExtent(image,(MagickSizeType) cache_info->offset+ cache_info->length); if (status == MagickFalse) { ThrowFileException(exception,CacheError,"UnableToExtendCache", image->filename); return(MagickFalse); } length=number_pixels*(cache_info->number_channels*sizeof(Quantum)+ cache_info->metacontent_extent); if (length != (MagickSizeType) ((size_t) length)) cache_info->type=DiskCache; else { status=AcquireMagickResource(MapResource,cache_info->length); if (status == MagickFalse) cache_info->type=DiskCache; else if ((cache_info->type != MapCache) && (cache_info->type != MemoryCache)) { cache_info->type=DiskCache; RelinquishMagickResource(MapResource,cache_info->length); } else { cache_info->pixels=(Quantum *) MapBlob(cache_info->file,mode, cache_info->offset,(size_t) cache_info->length); if (cache_info->pixels == (Quantum *) NULL) { cache_info->type=DiskCache; cache_info->pixels=source_info.pixels; RelinquishMagickResource(MapResource,cache_info->length); } else { /* Create file-backed memory-mapped pixel cache. */ (void) ClosePixelCacheOnDisk(cache_info); cache_info->type=MapCache; cache_info->mapped=MagickTrue; cache_info->metacontent=(void *) NULL; if (cache_info->metacontent_extent != 0) cache_info->metacontent=(void *) (cache_info->pixels+ number_pixels*cache_info->number_channels); if ((source_info.storage_class != UndefinedClass) && (mode != ReadMode)) { status=ClonePixelCacheRepository(cache_info,&source_info, exception); RelinquishPixelCachePixels(&source_info); } if (image->debug != MagickFalse) { (void) FormatMagickSize(cache_info->length,MagickTrue,"B", MagickPathExtent,format); type=CommandOptionToMnemonic(MagickCacheOptions,(ssize_t) cache_info->type); (void) FormatLocaleString(message,MagickPathExtent, "open %s (%s[%d], %s, %.20gx%.20gx%.20g %s)", cache_info->filename,cache_info->cache_filename, cache_info->file,type,(double) cache_info->columns, (double) cache_info->rows,(double) cache_info->number_channels,format); (void) LogMagickEvent(CacheEvent,GetMagickModule(),"%s", message); } return(status == 0 ? MagickFalse : MagickTrue); } } } status=MagickTrue; if ((source_info.storage_class != UndefinedClass) && (mode != ReadMode)) { status=ClonePixelCacheRepository(cache_info,&source_info,exception); RelinquishPixelCachePixels(&source_info); } if (image->debug != MagickFalse) { (void) FormatMagickSize(cache_info->length,MagickFalse,"B", MagickPathExtent,format); type=CommandOptionToMnemonic(MagickCacheOptions,(ssize_t) cache_info->type); (void) FormatLocaleString(message,MagickPathExtent, "open %s (%s[%d], %s, %.20gx%.20gx%.20g %s)",cache_info->filename, cache_info->cache_filename,cache_info->file,type,(double) cache_info->columns,(double) cache_info->rows,(double) cache_info->number_channels,format); (void) LogMagickEvent(CacheEvent,GetMagickModule(),"%s",message); } return(status == 0 ? MagickFalse : MagickTrue); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + P e r s i s t P i x e l C a c h e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % PersistPixelCache() attaches to or initializes a persistent pixel cache. A % persistent pixel cache is one that resides on disk and is not destroyed % when the program exits. % % The format of the PersistPixelCache() method is: % % MagickBooleanType PersistPixelCache(Image *image,const char *filename, % const MagickBooleanType attach,MagickOffsetType *offset, % ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o filename: the persistent pixel cache filename. % % o attach: A value other than zero initializes the persistent pixel cache. % % o initialize: A value other than zero initializes the persistent pixel % cache. % % o offset: the offset in the persistent cache to store pixels. % % o exception: return any errors or warnings in this structure. % */ MagickExport MagickBooleanType PersistPixelCache(Image *image, const char *filename,const MagickBooleanType attach,MagickOffsetType *offset, ExceptionInfo *exception) { CacheInfo *magick_restrict cache_info, *magick_restrict clone_info; MagickBooleanType status; ssize_t page_size; assert(image != (Image *) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(image->cache != (void *) NULL); assert(filename != (const char *) NULL); assert(offset != (MagickOffsetType *) NULL); page_size=GetMagickPageSize(); cache_info=(CacheInfo *) image->cache; assert(cache_info->signature == MagickCoreSignature); #if defined(MAGICKCORE_OPENCL_SUPPORT) CopyOpenCLBuffer(cache_info); #endif if (attach != MagickFalse) { /* Attach existing persistent pixel cache. */ if (image->debug != MagickFalse) (void) LogMagickEvent(CacheEvent,GetMagickModule(), "attach persistent cache"); (void) CopyMagickString(cache_info->cache_filename,filename, MagickPathExtent); cache_info->type=DiskCache; cache_info->offset=(*offset); if (OpenPixelCache(image,ReadMode,exception) == MagickFalse) return(MagickFalse); *offset+=cache_info->length+page_size-(cache_info->length % page_size); return(SyncImagePixelCache(image,exception)); } /* Clone persistent pixel cache. */ status=AcquireMagickResource(DiskResource,cache_info->length); if (status == MagickFalse) { (void) ThrowMagickException(exception,GetMagickModule(),CacheError, "CacheResourcesExhausted","`%s'",image->filename); return(MagickFalse); } clone_info=(CacheInfo *) ClonePixelCache(cache_info); clone_info->type=DiskCache; (void) CopyMagickString(clone_info->cache_filename,filename,MagickPathExtent); clone_info->file=(-1); clone_info->storage_class=cache_info->storage_class; clone_info->colorspace=cache_info->colorspace; clone_info->alpha_trait=cache_info->alpha_trait; clone_info->channels=cache_info->channels; clone_info->columns=cache_info->columns; clone_info->rows=cache_info->rows; clone_info->number_channels=cache_info->number_channels; clone_info->metacontent_extent=cache_info->metacontent_extent; clone_info->mode=PersistMode; clone_info->length=cache_info->length; (void) memcpy(clone_info->channel_map,cache_info->channel_map, MaxPixelChannels*sizeof(*cache_info->channel_map)); clone_info->offset=(*offset); status=ClonePixelCacheRepository(clone_info,cache_info,exception); *offset+=cache_info->length+page_size-(cache_info->length % page_size); clone_info=(CacheInfo *) DestroyPixelCache(clone_info); return(status); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + Q u e u e A u t h e n t i c P i x e l C a c h e N e x u s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % QueueAuthenticPixelCacheNexus() allocates an region to store image pixels as % defined by the region rectangle and returns a pointer to the region. This % region is subsequently transferred from the pixel cache with % SyncAuthenticPixelsCache(). A pointer to the pixels is returned if the % pixels are transferred, otherwise a NULL is returned. % % The format of the QueueAuthenticPixelCacheNexus() method is: % % Quantum *QueueAuthenticPixelCacheNexus(Image *image,const ssize_t x, % const ssize_t y,const size_t columns,const size_t rows, % const MagickBooleanType clone,NexusInfo *nexus_info, % ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o x,y,columns,rows: These values define the perimeter of a region of % pixels. % % o nexus_info: the cache nexus to set. % % o clone: clone the pixel cache. % % o exception: return any errors or warnings in this structure. % */ MagickPrivate Quantum *QueueAuthenticPixelCacheNexus(Image *image, const ssize_t x,const ssize_t y,const size_t columns,const size_t rows, const MagickBooleanType clone,NexusInfo *nexus_info,ExceptionInfo *exception) { CacheInfo *magick_restrict cache_info; MagickOffsetType offset; MagickSizeType number_pixels; Quantum *magick_restrict pixels; RectangleInfo region; /* Validate pixel cache geometry. */ assert(image != (const Image *) NULL); assert(image->signature == MagickCoreSignature); assert(image->cache != (Cache) NULL); cache_info=(CacheInfo *) GetImagePixelCache(image,clone,exception); if (cache_info == (Cache) NULL) return((Quantum *) NULL); assert(cache_info->signature == MagickCoreSignature); if ((cache_info->columns == 0) || (cache_info->rows == 0) || (x < 0) || (y < 0) || (x >= (ssize_t) cache_info->columns) || (y >= (ssize_t) cache_info->rows)) { (void) ThrowMagickException(exception,GetMagickModule(),CacheError, "PixelsAreNotAuthentic","`%s'",image->filename); return((Quantum *) NULL); } offset=(MagickOffsetType) y*cache_info->columns+x; if (offset < 0) return((Quantum *) NULL); number_pixels=(MagickSizeType) cache_info->columns*cache_info->rows; offset+=(MagickOffsetType) (rows-1)*cache_info->columns+columns-1; if ((MagickSizeType) offset >= number_pixels) return((Quantum *) NULL); /* Return pixel cache. */ region.x=x; region.y=y; region.width=columns; region.height=rows; pixels=SetPixelCacheNexusPixels(cache_info,WriteMode,&region, ((image->channels & WriteMaskChannel) != 0) || ((image->channels & CompositeMaskChannel) != 0) ? MagickTrue : MagickFalse, nexus_info,exception); return(pixels); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + Q u e u e A u t h e n t i c P i x e l s C a c h e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % QueueAuthenticPixelsCache() allocates an region to store image pixels as % defined by the region rectangle and returns a pointer to the region. This % region is subsequently transferred from the pixel cache with % SyncAuthenticPixelsCache(). A pointer to the pixels is returned if the % pixels are transferred, otherwise a NULL is returned. % % The format of the QueueAuthenticPixelsCache() method is: % % Quantum *QueueAuthenticPixelsCache(Image *image,const ssize_t x, % const ssize_t y,const size_t columns,const size_t rows, % ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o x,y,columns,rows: These values define the perimeter of a region of % pixels. % % o exception: return any errors or warnings in this structure. % */ static Quantum *QueueAuthenticPixelsCache(Image *image,const ssize_t x, const ssize_t y,const size_t columns,const size_t rows, ExceptionInfo *exception) { CacheInfo *magick_restrict cache_info; const int id = GetOpenMPThreadId(); Quantum *magick_restrict pixels; assert(image != (const Image *) NULL); assert(image->signature == MagickCoreSignature); assert(image->cache != (Cache) NULL); cache_info=(CacheInfo *) image->cache; assert(cache_info->signature == MagickCoreSignature); assert(id < (int) cache_info->number_threads); pixels=QueueAuthenticPixelCacheNexus(image,x,y,columns,rows,MagickFalse, cache_info->nexus_info[id],exception); return(pixels); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % Q u e u e A u t h e n t i c P i x e l s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % QueueAuthenticPixels() queues a mutable pixel region. If the region is % successfully initialized a pointer to a Quantum array representing the % region is returned, otherwise NULL is returned. The returned pointer may % point to a temporary working buffer for the pixels or it may point to the % final location of the pixels in memory. % % Write-only access means that any existing pixel values corresponding to % the region are ignored. This is useful if the initial image is being % created from scratch, or if the existing pixel values are to be % completely replaced without need to refer to their pre-existing values. % The application is free to read and write the pixel buffer returned by % QueueAuthenticPixels() any way it pleases. QueueAuthenticPixels() does not % initialize the pixel array values. Initializing pixel array values is the % application's responsibility. % % Performance is maximized if the selected region is part of one row, or % one or more full rows, since then there is opportunity to access the % pixels in-place (without a copy) if the image is in memory, or in a % memory-mapped file. The returned pointer must *never* be deallocated % by the user. % % Pixels accessed via the returned pointer represent a simple array of type % Quantum. If the image type is CMYK or the storage class is PseudoClass, % call GetAuthenticMetacontent() after invoking GetAuthenticPixels() to % obtain the meta-content (of type void) corresponding to the region. % Once the Quantum (and/or Quantum) array has been updated, the % changes must be saved back to the underlying image using % SyncAuthenticPixels() or they may be lost. % % The format of the QueueAuthenticPixels() method is: % % Quantum *QueueAuthenticPixels(Image *image,const ssize_t x, % const ssize_t y,const size_t columns,const size_t rows, % ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o x,y,columns,rows: These values define the perimeter of a region of % pixels. % % o exception: return any errors or warnings in this structure. % */ MagickExport Quantum *QueueAuthenticPixels(Image *image,const ssize_t x, const ssize_t y,const size_t columns,const size_t rows, ExceptionInfo *exception) { CacheInfo *magick_restrict cache_info; const int id = GetOpenMPThreadId(); Quantum *magick_restrict pixels; assert(image != (Image *) NULL); assert(image->signature == MagickCoreSignature); assert(image->cache != (Cache) NULL); cache_info=(CacheInfo *) image->cache; assert(cache_info->signature == MagickCoreSignature); if (cache_info->methods.queue_authentic_pixels_handler != (QueueAuthenticPixelsHandler) NULL) { pixels=cache_info->methods.queue_authentic_pixels_handler(image,x,y, columns,rows,exception); return(pixels); } assert(id < (int) cache_info->number_threads); pixels=QueueAuthenticPixelCacheNexus(image,x,y,columns,rows,MagickFalse, cache_info->nexus_info[id],exception); return(pixels); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + R e a d P i x e l C a c h e M e t a c o n t e n t % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % ReadPixelCacheMetacontent() reads metacontent from the specified region of % the pixel cache. % % The format of the ReadPixelCacheMetacontent() method is: % % MagickBooleanType ReadPixelCacheMetacontent(CacheInfo *cache_info, % NexusInfo *nexus_info,ExceptionInfo *exception) % % A description of each parameter follows: % % o cache_info: the pixel cache. % % o nexus_info: the cache nexus to read the metacontent. % % o exception: return any errors or warnings in this structure. % */ static inline MagickOffsetType ReadPixelCacheRegion( const CacheInfo *magick_restrict cache_info,const MagickOffsetType offset, const MagickSizeType length,unsigned char *magick_restrict buffer) { register MagickOffsetType i; ssize_t count; #if !defined(MAGICKCORE_HAVE_PREAD) if (lseek(cache_info->file,offset,SEEK_SET) < 0) return((MagickOffsetType) -1); #endif count=0; for (i=0; i < (MagickOffsetType) length; i+=count) { #if !defined(MAGICKCORE_HAVE_PREAD) count=read(cache_info->file,buffer+i,(size_t) MagickMin(length-i,(size_t) SSIZE_MAX)); #else count=pread(cache_info->file,buffer+i,(size_t) MagickMin(length-i,(size_t) SSIZE_MAX),(off_t) (offset+i)); #endif if (count <= 0) { count=0; if (errno != EINTR) break; } } return(i); } static MagickBooleanType ReadPixelCacheMetacontent( CacheInfo *magick_restrict cache_info,NexusInfo *magick_restrict nexus_info, ExceptionInfo *exception) { MagickOffsetType count, offset; MagickSizeType extent, length; register ssize_t y; register unsigned char *magick_restrict q; size_t rows; if (cache_info->metacontent_extent == 0) return(MagickFalse); if (nexus_info->authentic_pixel_cache != MagickFalse) return(MagickTrue); offset=(MagickOffsetType) nexus_info->region.y*cache_info->columns+ nexus_info->region.x; length=(MagickSizeType) nexus_info->region.width* cache_info->metacontent_extent; extent=length*nexus_info->region.height; rows=nexus_info->region.height; y=0; q=(unsigned char *) nexus_info->metacontent; switch (cache_info->type) { case MemoryCache: case MapCache: { register unsigned char *magick_restrict p; /* Read meta-content from memory. */ if ((cache_info->columns == nexus_info->region.width) && (extent == (MagickSizeType) ((size_t) extent))) { length=extent; rows=1UL; } p=(unsigned char *) cache_info->metacontent+offset* cache_info->metacontent_extent; for (y=0; y < (ssize_t) rows; y++) { (void) memcpy(q,p,(size_t) length); p+=cache_info->metacontent_extent*cache_info->columns; q+=cache_info->metacontent_extent*nexus_info->region.width; } break; } case DiskCache: { /* Read meta content from disk. */ LockSemaphoreInfo(cache_info->file_semaphore); if (OpenPixelCacheOnDisk(cache_info,IOMode) == MagickFalse) { ThrowFileException(exception,FileOpenError,"UnableToOpenFile", cache_info->cache_filename); UnlockSemaphoreInfo(cache_info->file_semaphore); return(MagickFalse); } if ((cache_info->columns == nexus_info->region.width) && (extent <= MagickMaxBufferExtent)) { length=extent; rows=1UL; } extent=(MagickSizeType) cache_info->columns*cache_info->rows; for (y=0; y < (ssize_t) rows; y++) { count=ReadPixelCacheRegion(cache_info,cache_info->offset+extent* cache_info->number_channels*sizeof(Quantum)+offset* cache_info->metacontent_extent,length,(unsigned char *) q); if (count != (MagickOffsetType) length) break; offset+=cache_info->columns; q+=cache_info->metacontent_extent*nexus_info->region.width; } if (IsFileDescriptorLimitExceeded() != MagickFalse) (void) ClosePixelCacheOnDisk(cache_info); UnlockSemaphoreInfo(cache_info->file_semaphore); break; } case DistributedCache: { RectangleInfo region; /* Read metacontent from distributed cache. */ LockSemaphoreInfo(cache_info->file_semaphore); region=nexus_info->region; if ((cache_info->columns != nexus_info->region.width) || (extent > MagickMaxBufferExtent)) region.height=1UL; else { length=extent; rows=1UL; } for (y=0; y < (ssize_t) rows; y++) { count=ReadDistributePixelCacheMetacontent((DistributeCacheInfo *) cache_info->server_info,&region,length,(unsigned char *) q); if (count != (MagickOffsetType) length) break; q+=cache_info->metacontent_extent*nexus_info->region.width; region.y++; } UnlockSemaphoreInfo(cache_info->file_semaphore); break; } default: break; } if (y < (ssize_t) rows) { ThrowFileException(exception,CacheError,"UnableToReadPixelCache", cache_info->cache_filename); return(MagickFalse); } if ((cache_info->debug != MagickFalse) && (CacheTick(nexus_info->region.y,cache_info->rows) != MagickFalse)) (void) LogMagickEvent(CacheEvent,GetMagickModule(), "%s[%.20gx%.20g%+.20g%+.20g]",cache_info->filename,(double) nexus_info->region.width,(double) nexus_info->region.height,(double) nexus_info->region.x,(double) nexus_info->region.y); return(MagickTrue); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + R e a d P i x e l C a c h e P i x e l s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % ReadPixelCachePixels() reads pixels from the specified region of the pixel % cache. % % The format of the ReadPixelCachePixels() method is: % % MagickBooleanType ReadPixelCachePixels(CacheInfo *cache_info, % NexusInfo *nexus_info,ExceptionInfo *exception) % % A description of each parameter follows: % % o cache_info: the pixel cache. % % o nexus_info: the cache nexus to read the pixels. % % o exception: return any errors or warnings in this structure. % */ static MagickBooleanType ReadPixelCachePixels( CacheInfo *magick_restrict cache_info,NexusInfo *magick_restrict nexus_info, ExceptionInfo *exception) { MagickOffsetType count, offset; MagickSizeType extent, length; register Quantum *magick_restrict q; register ssize_t y; size_t number_channels, rows; if (nexus_info->authentic_pixel_cache != MagickFalse) return(MagickTrue); offset=(MagickOffsetType) nexus_info->region.y*cache_info->columns; if ((ssize_t) (offset/cache_info->columns) != nexus_info->region.y) return(MagickFalse); offset+=nexus_info->region.x; number_channels=cache_info->number_channels; length=(MagickSizeType) number_channels*nexus_info->region.width* sizeof(Quantum); if ((length/number_channels/sizeof(Quantum)) != nexus_info->region.width) return(MagickFalse); rows=nexus_info->region.height; extent=length*rows; if ((extent == 0) || ((extent/length) != rows)) return(MagickFalse); y=0; q=nexus_info->pixels; switch (cache_info->type) { case MemoryCache: case MapCache: { register Quantum *magick_restrict p; /* Read pixels from memory. */ if ((cache_info->columns == nexus_info->region.width) && (extent == (MagickSizeType) ((size_t) extent))) { length=extent; rows=1UL; } p=cache_info->pixels+offset*cache_info->number_channels; for (y=0; y < (ssize_t) rows; y++) { (void) memcpy(q,p,(size_t) length); p+=cache_info->number_channels*cache_info->columns; q+=cache_info->number_channels*nexus_info->region.width; } break; } case DiskCache: { /* Read pixels from disk. */ LockSemaphoreInfo(cache_info->file_semaphore); if (OpenPixelCacheOnDisk(cache_info,IOMode) == MagickFalse) { ThrowFileException(exception,FileOpenError,"UnableToOpenFile", cache_info->cache_filename); UnlockSemaphoreInfo(cache_info->file_semaphore); return(MagickFalse); } if ((cache_info->columns == nexus_info->region.width) && (extent <= MagickMaxBufferExtent)) { length=extent; rows=1UL; } for (y=0; y < (ssize_t) rows; y++) { count=ReadPixelCacheRegion(cache_info,cache_info->offset+offset* cache_info->number_channels*sizeof(*q),length,(unsigned char *) q); if (count != (MagickOffsetType) length) break; offset+=cache_info->columns; q+=cache_info->number_channels*nexus_info->region.width; } if (IsFileDescriptorLimitExceeded() != MagickFalse) (void) ClosePixelCacheOnDisk(cache_info); UnlockSemaphoreInfo(cache_info->file_semaphore); break; } case DistributedCache: { RectangleInfo region; /* Read pixels from distributed cache. */ LockSemaphoreInfo(cache_info->file_semaphore); region=nexus_info->region; if ((cache_info->columns != nexus_info->region.width) || (extent > MagickMaxBufferExtent)) region.height=1UL; else { length=extent; rows=1UL; } for (y=0; y < (ssize_t) rows; y++) { count=ReadDistributePixelCachePixels((DistributeCacheInfo *) cache_info->server_info,&region,length,(unsigned char *) q); if (count != (MagickOffsetType) length) break; q+=cache_info->number_channels*nexus_info->region.width; region.y++; } UnlockSemaphoreInfo(cache_info->file_semaphore); break; } default: break; } if (y < (ssize_t) rows) { ThrowFileException(exception,CacheError,"UnableToReadPixelCache", cache_info->cache_filename); return(MagickFalse); } if ((cache_info->debug != MagickFalse) && (CacheTick(nexus_info->region.y,cache_info->rows) != MagickFalse)) (void) LogMagickEvent(CacheEvent,GetMagickModule(), "%s[%.20gx%.20g%+.20g%+.20g]",cache_info->filename,(double) nexus_info->region.width,(double) nexus_info->region.height,(double) nexus_info->region.x,(double) nexus_info->region.y); return(MagickTrue); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + R e f e r e n c e P i x e l C a c h e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % ReferencePixelCache() increments the reference count associated with the % pixel cache returning a pointer to the cache. % % The format of the ReferencePixelCache method is: % % Cache ReferencePixelCache(Cache cache_info) % % A description of each parameter follows: % % o cache_info: the pixel cache. % */ MagickPrivate Cache ReferencePixelCache(Cache cache) { CacheInfo *magick_restrict cache_info; assert(cache != (Cache *) NULL); cache_info=(CacheInfo *) cache; assert(cache_info->signature == MagickCoreSignature); LockSemaphoreInfo(cache_info->semaphore); cache_info->reference_count++; UnlockSemaphoreInfo(cache_info->semaphore); return(cache_info); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + R e s e t P i x e l C a c h e C h a n n e l s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % ResetPixelCacheChannels() resets the pixel cache channels. % % The format of the ResetPixelCacheChannels method is: % % void ResetPixelCacheChannels(Image *) % % A description of each parameter follows: % % o image: the image. % */ MagickPrivate void ResetPixelCacheChannels(Image *image) { CacheInfo *magick_restrict cache_info; assert(image != (const Image *) NULL); assert(image->signature == MagickCoreSignature); assert(image->cache != (Cache) NULL); cache_info=(CacheInfo *) image->cache; assert(cache_info->signature == MagickCoreSignature); cache_info->number_channels=GetPixelChannels(image); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + R e s e t C a c h e A n o n y m o u s M e m o r y % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % ResetCacheAnonymousMemory() resets the anonymous_memory value. % % The format of the ResetCacheAnonymousMemory method is: % % void ResetCacheAnonymousMemory(void) % */ MagickPrivate void ResetCacheAnonymousMemory(void) { cache_anonymous_memory=0; } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + R e s e t P i x e l C a c h e E p o c h % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % ResetPixelCacheEpoch() resets the pixel cache epoch. % % The format of the ResetPixelCacheEpoch method is: % % void ResetPixelCacheEpoch(void) % */ MagickPrivate void ResetPixelCacheEpoch(void) { cache_epoch=0; } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + S e t P i x e l C a c h e M e t h o d s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % SetPixelCacheMethods() sets the image pixel methods to the specified ones. % % The format of the SetPixelCacheMethods() method is: % % SetPixelCacheMethods(Cache *,CacheMethods *cache_methods) % % A description of each parameter follows: % % o cache: the pixel cache. % % o cache_methods: Specifies a pointer to a CacheMethods structure. % */ MagickPrivate void SetPixelCacheMethods(Cache cache,CacheMethods *cache_methods) { CacheInfo *magick_restrict cache_info; GetOneAuthenticPixelFromHandler get_one_authentic_pixel_from_handler; GetOneVirtualPixelFromHandler get_one_virtual_pixel_from_handler; /* Set cache pixel methods. */ assert(cache != (Cache) NULL); assert(cache_methods != (CacheMethods *) NULL); cache_info=(CacheInfo *) cache; assert(cache_info->signature == MagickCoreSignature); if (cache_info->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s", cache_info->filename); if (cache_methods->get_virtual_pixel_handler != (GetVirtualPixelHandler) NULL) cache_info->methods.get_virtual_pixel_handler= cache_methods->get_virtual_pixel_handler; if (cache_methods->destroy_pixel_handler != (DestroyPixelHandler) NULL) cache_info->methods.destroy_pixel_handler= cache_methods->destroy_pixel_handler; if (cache_methods->get_virtual_metacontent_from_handler != (GetVirtualMetacontentFromHandler) NULL) cache_info->methods.get_virtual_metacontent_from_handler= cache_methods->get_virtual_metacontent_from_handler; if (cache_methods->get_authentic_pixels_handler != (GetAuthenticPixelsHandler) NULL) cache_info->methods.get_authentic_pixels_handler= cache_methods->get_authentic_pixels_handler; if (cache_methods->queue_authentic_pixels_handler != (QueueAuthenticPixelsHandler) NULL) cache_info->methods.queue_authentic_pixels_handler= cache_methods->queue_authentic_pixels_handler; if (cache_methods->sync_authentic_pixels_handler != (SyncAuthenticPixelsHandler) NULL) cache_info->methods.sync_authentic_pixels_handler= cache_methods->sync_authentic_pixels_handler; if (cache_methods->get_authentic_pixels_from_handler != (GetAuthenticPixelsFromHandler) NULL) cache_info->methods.get_authentic_pixels_from_handler= cache_methods->get_authentic_pixels_from_handler; if (cache_methods->get_authentic_metacontent_from_handler != (GetAuthenticMetacontentFromHandler) NULL) cache_info->methods.get_authentic_metacontent_from_handler= cache_methods->get_authentic_metacontent_from_handler; get_one_virtual_pixel_from_handler= cache_info->methods.get_one_virtual_pixel_from_handler; if (get_one_virtual_pixel_from_handler != (GetOneVirtualPixelFromHandler) NULL) cache_info->methods.get_one_virtual_pixel_from_handler= cache_methods->get_one_virtual_pixel_from_handler; get_one_authentic_pixel_from_handler= cache_methods->get_one_authentic_pixel_from_handler; if (get_one_authentic_pixel_from_handler != (GetOneAuthenticPixelFromHandler) NULL) cache_info->methods.get_one_authentic_pixel_from_handler= cache_methods->get_one_authentic_pixel_from_handler; } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + S e t P i x e l C a c h e N e x u s P i x e l s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % SetPixelCacheNexusPixels() defines the region of the cache for the % specified cache nexus. % % The format of the SetPixelCacheNexusPixels() method is: % % Quantum SetPixelCacheNexusPixels(const CacheInfo *cache_info, % const MapMode mode,const RectangleInfo *region, % const MagickBooleanType buffered,NexusInfo *nexus_info, % ExceptionInfo *exception) % % A description of each parameter follows: % % o cache_info: the pixel cache. % % o mode: ReadMode, WriteMode, or IOMode. % % o region: A pointer to the RectangleInfo structure that defines the % region of this particular cache nexus. % % o buffered: if true, nexus pixels are buffered. % % o nexus_info: the cache nexus to set. % % o exception: return any errors or warnings in this structure. % */ static inline MagickBooleanType AcquireCacheNexusPixels( const CacheInfo *magick_restrict cache_info,NexusInfo *nexus_info, ExceptionInfo *exception) { if (nexus_info->length != (MagickSizeType) ((size_t) nexus_info->length)) return(MagickFalse); if (cache_anonymous_memory <= 0) { nexus_info->mapped=MagickFalse; nexus_info->cache=(Quantum *) MagickAssumeAligned(AcquireAlignedMemory(1, (size_t) nexus_info->length)); if (nexus_info->cache != (Quantum *) NULL) (void) memset(nexus_info->cache,0,(size_t) nexus_info->length); } else { nexus_info->mapped=MagickTrue; nexus_info->cache=(Quantum *) MapBlob(-1,IOMode,0,(size_t) nexus_info->length); } if (nexus_info->cache == (Quantum *) NULL) { (void) ThrowMagickException(exception,GetMagickModule(), ResourceLimitError,"MemoryAllocationFailed","`%s'", cache_info->filename); return(MagickFalse); } return(MagickTrue); } static inline MagickBooleanType IsPixelCacheAuthentic( const CacheInfo *magick_restrict cache_info, const NexusInfo *magick_restrict nexus_info) { MagickBooleanType status; MagickOffsetType offset; /* Does nexus pixels point directly to in-core cache pixels or is it buffered? */ if (cache_info->type == PingCache) return(MagickTrue); offset=(MagickOffsetType) nexus_info->region.y*cache_info->columns+ nexus_info->region.x; status=nexus_info->pixels == (cache_info->pixels+offset* cache_info->number_channels) ? MagickTrue : MagickFalse; return(status); } static inline void PrefetchPixelCacheNexusPixels(const NexusInfo *nexus_info, const MapMode mode) { if (mode == ReadMode) { MagickCachePrefetch((unsigned char *) nexus_info->pixels,0,1); return; } MagickCachePrefetch((unsigned char *) nexus_info->pixels,1,1); } static Quantum *SetPixelCacheNexusPixels(const CacheInfo *cache_info, const MapMode mode,const RectangleInfo *region, const MagickBooleanType buffered,NexusInfo *nexus_info, ExceptionInfo *exception) { MagickBooleanType status; MagickSizeType length, number_pixels; assert(cache_info != (const CacheInfo *) NULL); assert(cache_info->signature == MagickCoreSignature); if (cache_info->type == UndefinedCache) return((Quantum *) NULL); if ((region->width == 0) || (region->height == 0)) return((Quantum *) NULL); nexus_info->region=(*region); number_pixels=(MagickSizeType) nexus_info->region.width* nexus_info->region.height; if (number_pixels == 0) return((Quantum *) NULL); if (((cache_info->type == MemoryCache) || (cache_info->type == MapCache)) && (buffered == MagickFalse)) { ssize_t x, y; x=nexus_info->region.x+(ssize_t) nexus_info->region.width-1; y=nexus_info->region.y+(ssize_t) nexus_info->region.height-1; if (((nexus_info->region.x >= 0) && (nexus_info->region.y >= 0) && (y < (ssize_t) cache_info->rows)) && (((nexus_info->region.x == 0) && (nexus_info->region.width == cache_info->columns)) || ((nexus_info->region.height == 1) && (x < (ssize_t) cache_info->columns)))) { MagickOffsetType offset; /* Pixels are accessed directly from memory. */ offset=(MagickOffsetType) nexus_info->region.y*cache_info->columns+ nexus_info->region.x; nexus_info->pixels=cache_info->pixels+cache_info->number_channels* offset; nexus_info->metacontent=(void *) NULL; if (cache_info->metacontent_extent != 0) nexus_info->metacontent=(unsigned char *) cache_info->metacontent+ offset*cache_info->metacontent_extent; PrefetchPixelCacheNexusPixels(nexus_info,mode); nexus_info->authentic_pixel_cache=IsPixelCacheAuthentic(cache_info, nexus_info); return(nexus_info->pixels); } } /* Pixels are stored in a staging region until they are synced to the cache. */ length=number_pixels*cache_info->number_channels*sizeof(Quantum); if (cache_info->metacontent_extent != 0) length+=number_pixels*cache_info->metacontent_extent; if (nexus_info->cache == (Quantum *) NULL) { nexus_info->length=length; status=AcquireCacheNexusPixels(cache_info,nexus_info,exception); if (status == MagickFalse) { nexus_info->length=0; return((Quantum *) NULL); } } else if (nexus_info->length < length) { RelinquishCacheNexusPixels(nexus_info); nexus_info->length=length; status=AcquireCacheNexusPixels(cache_info,nexus_info,exception); if (status == MagickFalse) { nexus_info->length=0; return((Quantum *) NULL); } } nexus_info->pixels=nexus_info->cache; nexus_info->metacontent=(void *) NULL; if (cache_info->metacontent_extent != 0) nexus_info->metacontent=(void *) (nexus_info->pixels+number_pixels* cache_info->number_channels); PrefetchPixelCacheNexusPixels(nexus_info,mode); nexus_info->authentic_pixel_cache=IsPixelCacheAuthentic(cache_info, nexus_info); return(nexus_info->pixels); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % S e t P i x e l C a c h e V i r t u a l M e t h o d % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % SetPixelCacheVirtualMethod() sets the "virtual pixels" method for the % pixel cache 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 SetPixelCacheVirtualMethod() method is: % % VirtualPixelMethod SetPixelCacheVirtualMethod(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. % */ static MagickBooleanType SetCacheAlphaChannel(Image *image,const Quantum alpha, ExceptionInfo *exception) { CacheInfo *magick_restrict cache_info; CacheView *magick_restrict 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); assert(image->cache != (Cache) NULL); cache_info=(CacheInfo *) image->cache; assert(cache_info->signature == MagickCoreSignature); image->alpha_trait=BlendPixelTrait; status=MagickTrue; image_view=AcquireVirtualCacheView(image,exception); /* must be virtual */ #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); } status=SyncCacheViewAuthenticPixels(image_view,exception); } image_view=DestroyCacheView(image_view); return(status); } MagickPrivate VirtualPixelMethod SetPixelCacheVirtualMethod(Image *image, const VirtualPixelMethod virtual_pixel_method,ExceptionInfo *exception) { CacheInfo *magick_restrict cache_info; VirtualPixelMethod method; assert(image != (Image *) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(image->cache != (Cache) NULL); cache_info=(CacheInfo *) image->cache; assert(cache_info->signature == MagickCoreSignature); method=cache_info->virtual_pixel_method; cache_info->virtual_pixel_method=virtual_pixel_method; if ((image->columns != 0) && (image->rows != 0)) switch (virtual_pixel_method) { case BackgroundVirtualPixelMethod: { if ((image->background_color.alpha_trait != UndefinedPixelTrait) && (image->alpha_trait == UndefinedPixelTrait)) (void) SetCacheAlphaChannel(image,OpaqueAlpha,exception); if ((IsPixelInfoGray(&image->background_color) == MagickFalse) && (IsGrayColorspace(image->colorspace) != MagickFalse)) (void) SetImageColorspace(image,sRGBColorspace,exception); break; } case TransparentVirtualPixelMethod: { if (image->alpha_trait == UndefinedPixelTrait) (void) SetCacheAlphaChannel(image,OpaqueAlpha,exception); break; } default: break; } return(method); } #if defined(MAGICKCORE_OPENCL_SUPPORT) /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + S y n c A u t h e n t i c O p e n C L B u f f e r % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % SyncAuthenticOpenCLBuffer() makes sure that all the OpenCL operations have % been completed and updates the host memory. % % The format of the SyncAuthenticOpenCLBuffer() method is: % % void SyncAuthenticOpenCLBuffer(const Image *image) % % A description of each parameter follows: % % o image: the image. % */ static void CopyOpenCLBuffer(CacheInfo *magick_restrict cache_info) { assert(cache_info != (CacheInfo *) NULL); assert(cache_info->signature == MagickCoreSignature); if ((cache_info->type != MemoryCache) || (cache_info->opencl == (MagickCLCacheInfo) NULL)) return; /* Ensure single threaded access to OpenCL environment. */ LockSemaphoreInfo(cache_info->semaphore); cache_info->opencl=CopyMagickCLCacheInfo(cache_info->opencl); UnlockSemaphoreInfo(cache_info->semaphore); } MagickPrivate void SyncAuthenticOpenCLBuffer(const Image *image) { CacheInfo *magick_restrict cache_info; assert(image != (const Image *) NULL); cache_info=(CacheInfo *) image->cache; CopyOpenCLBuffer(cache_info); } #endif /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + S y n c A u t h e n t i c P i x e l C a c h e N e x u s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % SyncAuthenticPixelCacheNexus() saves the authentic image pixels to the % in-memory or disk cache. The method returns MagickTrue if the pixel region % is synced, otherwise MagickFalse. % % The format of the SyncAuthenticPixelCacheNexus() method is: % % MagickBooleanType SyncAuthenticPixelCacheNexus(Image *image, % NexusInfo *nexus_info,ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o nexus_info: the cache nexus to sync. % % o exception: return any errors or warnings in this structure. % */ MagickPrivate MagickBooleanType SyncAuthenticPixelCacheNexus(Image *image, NexusInfo *magick_restrict nexus_info,ExceptionInfo *exception) { CacheInfo *magick_restrict cache_info; MagickBooleanType status; /* Transfer pixels to the cache. */ assert(image != (Image *) NULL); assert(image->signature == MagickCoreSignature); if (image->cache == (Cache) NULL) ThrowBinaryException(CacheError,"PixelCacheIsNotOpen",image->filename); cache_info=(CacheInfo *) image->cache; assert(cache_info->signature == MagickCoreSignature); if (cache_info->type == UndefinedCache) return(MagickFalse); if (image->mask_trait != UpdatePixelTrait) { if (((image->channels & WriteMaskChannel) != 0) && (ClipPixelCacheNexus(image,nexus_info,exception) == MagickFalse)) return(MagickFalse); if (((image->channels & CompositeMaskChannel) != 0) && (MaskPixelCacheNexus(image,nexus_info,exception) == MagickFalse)) return(MagickFalse); } if (nexus_info->authentic_pixel_cache != MagickFalse) { image->taint=MagickTrue; return(MagickTrue); } assert(cache_info->signature == MagickCoreSignature); status=WritePixelCachePixels(cache_info,nexus_info,exception); if ((cache_info->metacontent_extent != 0) && (WritePixelCacheMetacontent(cache_info,nexus_info,exception) == MagickFalse)) return(MagickFalse); if (status != MagickFalse) image->taint=MagickTrue; return(status); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + S y n c A u t h e n t i c P i x e l C a c h e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % SyncAuthenticPixelsCache() saves the authentic image pixels to the in-memory % or disk cache. The method returns MagickTrue if the pixel region is synced, % otherwise MagickFalse. % % The format of the SyncAuthenticPixelsCache() method is: % % MagickBooleanType SyncAuthenticPixelsCache(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 MagickBooleanType SyncAuthenticPixelsCache(Image *image, ExceptionInfo *exception) { CacheInfo *magick_restrict cache_info; const int id = GetOpenMPThreadId(); MagickBooleanType status; assert(image != (Image *) NULL); assert(image->signature == MagickCoreSignature); assert(image->cache != (Cache) NULL); cache_info=(CacheInfo *) image->cache; assert(cache_info->signature == MagickCoreSignature); assert(id < (int) cache_info->number_threads); status=SyncAuthenticPixelCacheNexus(image,cache_info->nexus_info[id], exception); return(status); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % S y n c A u t h e n t i c P i x e l s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % SyncAuthenticPixels() saves the image pixels to the in-memory or disk cache. % The method returns MagickTrue if the pixel region is flushed, otherwise % MagickFalse. % % The format of the SyncAuthenticPixels() method is: % % MagickBooleanType SyncAuthenticPixels(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 SyncAuthenticPixels(Image *image, ExceptionInfo *exception) { CacheInfo *magick_restrict cache_info; const int id = GetOpenMPThreadId(); MagickBooleanType status; assert(image != (Image *) NULL); assert(image->signature == MagickCoreSignature); assert(image->cache != (Cache) NULL); cache_info=(CacheInfo *) image->cache; assert(cache_info->signature == MagickCoreSignature); if (cache_info->methods.sync_authentic_pixels_handler != (SyncAuthenticPixelsHandler) NULL) { status=cache_info->methods.sync_authentic_pixels_handler(image, exception); return(status); } assert(id < (int) cache_info->number_threads); status=SyncAuthenticPixelCacheNexus(image,cache_info->nexus_info[id], exception); return(status); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + S y n c I m a g e P i x e l C a c h e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % SyncImagePixelCache() saves the image pixels to the in-memory or disk cache. % The method returns MagickTrue if the pixel region is flushed, otherwise % MagickFalse. % % The format of the SyncImagePixelCache() method is: % % MagickBooleanType SyncImagePixelCache(Image *image, % ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o exception: return any errors or warnings in this structure. % */ MagickPrivate MagickBooleanType SyncImagePixelCache(Image *image, ExceptionInfo *exception) { CacheInfo *magick_restrict cache_info; assert(image != (Image *) NULL); assert(exception != (ExceptionInfo *) NULL); cache_info=(CacheInfo *) GetImagePixelCache(image,MagickTrue,exception); return(cache_info == (CacheInfo *) NULL ? MagickFalse : MagickTrue); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + W r i t e P i x e l C a c h e M e t a c o n t e n t % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % WritePixelCacheMetacontent() writes the meta-content to the specified region % of the pixel cache. % % The format of the WritePixelCacheMetacontent() method is: % % MagickBooleanType WritePixelCacheMetacontent(CacheInfo *cache_info, % NexusInfo *nexus_info,ExceptionInfo *exception) % % A description of each parameter follows: % % o cache_info: the pixel cache. % % o nexus_info: the cache nexus to write the meta-content. % % o exception: return any errors or warnings in this structure. % */ static MagickBooleanType WritePixelCacheMetacontent(CacheInfo *cache_info, NexusInfo *magick_restrict nexus_info,ExceptionInfo *exception) { MagickOffsetType count, offset; MagickSizeType extent, length; register const unsigned char *magick_restrict p; register ssize_t y; size_t rows; if (cache_info->metacontent_extent == 0) return(MagickFalse); if (nexus_info->authentic_pixel_cache != MagickFalse) return(MagickTrue); offset=(MagickOffsetType) nexus_info->region.y*cache_info->columns+ nexus_info->region.x; length=(MagickSizeType) nexus_info->region.width* cache_info->metacontent_extent; extent=(MagickSizeType) length*nexus_info->region.height; rows=nexus_info->region.height; y=0; p=(unsigned char *) nexus_info->metacontent; switch (cache_info->type) { case MemoryCache: case MapCache: { register unsigned char *magick_restrict q; /* Write associated pixels to memory. */ if ((cache_info->columns == nexus_info->region.width) && (extent == (MagickSizeType) ((size_t) extent))) { length=extent; rows=1UL; } q=(unsigned char *) cache_info->metacontent+offset* cache_info->metacontent_extent; for (y=0; y < (ssize_t) rows; y++) { (void) memcpy(q,p,(size_t) length); p+=nexus_info->region.width*cache_info->metacontent_extent; q+=cache_info->columns*cache_info->metacontent_extent; } break; } case DiskCache: { /* Write associated pixels to disk. */ LockSemaphoreInfo(cache_info->file_semaphore); if (OpenPixelCacheOnDisk(cache_info,IOMode) == MagickFalse) { ThrowFileException(exception,FileOpenError,"UnableToOpenFile", cache_info->cache_filename); UnlockSemaphoreInfo(cache_info->file_semaphore); return(MagickFalse); } if ((cache_info->columns == nexus_info->region.width) && (extent <= MagickMaxBufferExtent)) { length=extent; rows=1UL; } extent=(MagickSizeType) cache_info->columns*cache_info->rows; for (y=0; y < (ssize_t) rows; y++) { count=WritePixelCacheRegion(cache_info,cache_info->offset+extent* cache_info->number_channels*sizeof(Quantum)+offset* cache_info->metacontent_extent,length,(const unsigned char *) p); if (count != (MagickOffsetType) length) break; p+=cache_info->metacontent_extent*nexus_info->region.width; offset+=cache_info->columns; } if (IsFileDescriptorLimitExceeded() != MagickFalse) (void) ClosePixelCacheOnDisk(cache_info); UnlockSemaphoreInfo(cache_info->file_semaphore); break; } case DistributedCache: { RectangleInfo region; /* Write metacontent to distributed cache. */ LockSemaphoreInfo(cache_info->file_semaphore); region=nexus_info->region; if ((cache_info->columns != nexus_info->region.width) || (extent > MagickMaxBufferExtent)) region.height=1UL; else { length=extent; rows=1UL; } for (y=0; y < (ssize_t) rows; y++) { count=WriteDistributePixelCacheMetacontent((DistributeCacheInfo *) cache_info->server_info,&region,length,(const unsigned char *) p); if (count != (MagickOffsetType) length) break; p+=cache_info->metacontent_extent*nexus_info->region.width; region.y++; } UnlockSemaphoreInfo(cache_info->file_semaphore); break; } default: break; } if (y < (ssize_t) rows) { ThrowFileException(exception,CacheError,"UnableToWritePixelCache", cache_info->cache_filename); return(MagickFalse); } if ((cache_info->debug != MagickFalse) && (CacheTick(nexus_info->region.y,cache_info->rows) != MagickFalse)) (void) LogMagickEvent(CacheEvent,GetMagickModule(), "%s[%.20gx%.20g%+.20g%+.20g]",cache_info->filename,(double) nexus_info->region.width,(double) nexus_info->region.height,(double) nexus_info->region.x,(double) nexus_info->region.y); return(MagickTrue); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + W r i t e C a c h e P i x e l s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % WritePixelCachePixels() writes image pixels to the specified region of the % pixel cache. % % The format of the WritePixelCachePixels() method is: % % MagickBooleanType WritePixelCachePixels(CacheInfo *cache_info, % NexusInfo *nexus_info,ExceptionInfo *exception) % % A description of each parameter follows: % % o cache_info: the pixel cache. % % o nexus_info: the cache nexus to write the pixels. % % o exception: return any errors or warnings in this structure. % */ static MagickBooleanType WritePixelCachePixels( CacheInfo *magick_restrict cache_info,NexusInfo *magick_restrict nexus_info, ExceptionInfo *exception) { MagickOffsetType count, offset; MagickSizeType extent, length; register const Quantum *magick_restrict p; register ssize_t y; size_t rows; if (nexus_info->authentic_pixel_cache != MagickFalse) return(MagickTrue); offset=(MagickOffsetType) nexus_info->region.y*cache_info->columns+ nexus_info->region.x; length=(MagickSizeType) cache_info->number_channels*nexus_info->region.width* sizeof(Quantum); extent=length*nexus_info->region.height; rows=nexus_info->region.height; y=0; p=nexus_info->pixels; switch (cache_info->type) { case MemoryCache: case MapCache: { register Quantum *magick_restrict q; /* Write pixels to memory. */ if ((cache_info->columns == nexus_info->region.width) && (extent == (MagickSizeType) ((size_t) extent))) { length=extent; rows=1UL; } q=cache_info->pixels+offset*cache_info->number_channels; for (y=0; y < (ssize_t) rows; y++) { (void) memcpy(q,p,(size_t) length); p+=cache_info->number_channels*nexus_info->region.width; q+=cache_info->number_channels*cache_info->columns; } break; } case DiskCache: { /* Write pixels to disk. */ LockSemaphoreInfo(cache_info->file_semaphore); if (OpenPixelCacheOnDisk(cache_info,IOMode) == MagickFalse) { ThrowFileException(exception,FileOpenError,"UnableToOpenFile", cache_info->cache_filename); UnlockSemaphoreInfo(cache_info->file_semaphore); return(MagickFalse); } if ((cache_info->columns == nexus_info->region.width) && (extent <= MagickMaxBufferExtent)) { length=extent; rows=1UL; } for (y=0; y < (ssize_t) rows; y++) { count=WritePixelCacheRegion(cache_info,cache_info->offset+offset* cache_info->number_channels*sizeof(*p),length,(const unsigned char *) p); if (count != (MagickOffsetType) length) break; p+=cache_info->number_channels*nexus_info->region.width; offset+=cache_info->columns; } if (IsFileDescriptorLimitExceeded() != MagickFalse) (void) ClosePixelCacheOnDisk(cache_info); UnlockSemaphoreInfo(cache_info->file_semaphore); break; } case DistributedCache: { RectangleInfo region; /* Write pixels to distributed cache. */ LockSemaphoreInfo(cache_info->file_semaphore); region=nexus_info->region; if ((cache_info->columns != nexus_info->region.width) || (extent > MagickMaxBufferExtent)) region.height=1UL; else { length=extent; rows=1UL; } for (y=0; y < (ssize_t) rows; y++) { count=WriteDistributePixelCachePixels((DistributeCacheInfo *) cache_info->server_info,&region,length,(const unsigned char *) p); if (count != (MagickOffsetType) length) break; p+=cache_info->number_channels*nexus_info->region.width; region.y++; } UnlockSemaphoreInfo(cache_info->file_semaphore); break; } default: break; } if (y < (ssize_t) rows) { ThrowFileException(exception,CacheError,"UnableToWritePixelCache", cache_info->cache_filename); return(MagickFalse); } if ((cache_info->debug != MagickFalse) && (CacheTick(nexus_info->region.y,cache_info->rows) != MagickFalse)) (void) LogMagickEvent(CacheEvent,GetMagickModule(), "%s[%.20gx%.20g%+.20g%+.20g]",cache_info->filename,(double) nexus_info->region.width,(double) nexus_info->region.height,(double) nexus_info->region.x,(double) nexus_info->region.y); return(MagickTrue); }

task_multiple_producer_omp.c

/* -*- Mode: C; c-basic-offset:4 ; indent-tabs-mode:nil ; -*- */ /* * See LICENSE.txt in top-level directory. */ #include <assert.h> #include <omp.h> #include <stdio.h> #include <stdlib.h> #include <unistd.h> #define NUM_TASKS 5000000 #define NUM_REPS 1 #define USLEEP usleep(100); /* Pragma omp task directive evaluation * Output: avg time */ void sscal(float value, float *a) { *a = *a * value; } int main(int argc, char *argv[]) { int i, r, nthreads; double *time, avg_time = 0.0; char *str, *endptr; float *a; #pragma omp parallel { #pragma omp master { nthreads = omp_get_num_threads(); } } if (argc > 1) { str = argv[1]; } int ntasks = argc > 1 ? strtoll(str, &endptr, 10) : NUM_TASKS; if (ntasks < nthreads) { ntasks = nthreads; } int rep = (argc > 2) ? atoi(argv[2]) : NUM_REPS; time = malloc(sizeof(double) * (rep + 1)); a = malloc(sizeof(float) * ntasks); for (i = 0; i < ntasks; i++) { a[i] = i + 100.0f; } for (r = 0; r < rep; r++) { time[r] = omp_get_wtime(); #pragma omp parallel { time[1] = omp_get_wtime(); #pragma omp for for (i = 0; i < ntasks; i++) { #pragma omp task firstprivate(i) { sscal(0.9f, &a[i]); } } time[1] = (omp_get_wtime() - time[1]); } time[r] = omp_get_wtime() - time[r]; avg_time += time[r]; } for (i = 0; i < ntasks; i++) { if (a[i] != (i + 100.0f) * 0.9f) { printf("error: a[%d]=%.2f expected %.2f\n", i, a[i], (i + 100.0f) * 0.9f); } } avg_time /= rep; printf("nthreads: %d\nntasks: %d\nTime(s):%f\nCreation Time: %f\n", nthreads, ntasks, avg_time, time[1]); return EXIT_SUCCESS; }

flowinfo_ipv4_dst.c

/* * Copyright 2014-2017 Nippon Telegraph and Telephone Corporation. * * 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. */ /** * @file flowinfo_ipv4_dst.c * @brief Optimized flow database for dataplane, for ipv4_dst */ #include <stdlib.h> #include "openflow.h" #include "lagopus_apis.h" #include "lagopus/flowdb.h" #include "pktbuf.h" #include "packet.h" #include "lagopus/flowinfo.h" #define OXM_FIELD_TYPE(field) ((field) >> 1) #define IPV4_DST_BITLEN (32) static lagopus_result_t add_flow_ipv4_dst_mask(struct flowinfo *, struct flow *); static lagopus_result_t del_flow_ipv4_dst_mask(struct flowinfo *, struct flow *); static struct flow * match_flow_ipv4_dst_mask(struct flowinfo *, struct lagopus_packet *, int32_t *); static struct flow * find_flow_ipv4_dst_mask(struct flowinfo *, struct flow *); static void destroy_flowinfo_ipv4_dst_mask(struct flowinfo *); static lagopus_result_t add_flow_ipv4_dst(struct flowinfo *, struct flow *); static lagopus_result_t del_flow_ipv4_dst(struct flowinfo *, struct flow *); static struct flow * match_flow_ipv4_dst(struct flowinfo *, struct lagopus_packet *, int32_t *); static struct flow * find_flow_ipv4_dst(struct flowinfo *, struct flow *); static void destroy_flowinfo_ipv4_dst(struct flowinfo *); static lagopus_result_t get_match_ipv4_dst(const struct match_list *match_list, uint32_t *ipv4_dst, uint32_t *mask) { const struct match *match; TAILQ_FOREACH(match, match_list, entry) { if (match->oxm_field == (OFPXMT_OFB_IPV4_DST << 1) + 1) { OS_MEMCPY(ipv4_dst, match->oxm_value, sizeof(*ipv4_dst)); OS_MEMCPY(mask, &match->oxm_value[4], sizeof(*mask)); break; } if (OXM_FIELD_TYPE(match->oxm_field) == OFPXMT_OFB_IPV4_DST) { OS_MEMCPY(ipv4_dst, match->oxm_value, sizeof(*ipv4_dst)); *mask = 0xffffffff; break; } } if (match == NULL) { return LAGOPUS_RESULT_NOT_FOUND; } return LAGOPUS_RESULT_OK; } struct flowinfo * new_flowinfo_ipv4_dst_mask(void) { struct flowinfo *self; self = calloc(1, sizeof(struct flowinfo)); if (self != NULL) { self->nflow = 0; self->nnext = 0; self->next = malloc(1); self->misc = new_flowinfo_ipv4_src_mask(); self->add_func = add_flow_ipv4_dst_mask; self->del_func = del_flow_ipv4_dst_mask; self->match_func = match_flow_ipv4_dst_mask; self->find_func = find_flow_ipv4_dst_mask; self->destroy_func = destroy_flowinfo_ipv4_dst_mask; } return self; } static void destroy_flowinfo_ipv4_dst_mask(struct flowinfo *self) { struct flowinfo *flowinfo; unsigned int i; for (i = 0; i < self->nnext; i++) { flowinfo = self->next[i]; flowinfo->destroy_func(flowinfo); } free(self->next); free(self); } static void freeup_flowinfo(void *val) { struct flowinfo *flowinfo; flowinfo = val; flowinfo->destroy_func(flowinfo); } struct flowinfo * new_flowinfo_ipv4_dst(void) { struct flowinfo *self; self = calloc(1, sizeof(struct flowinfo)); if (self != NULL) { lagopus_hashmap_create(&self->hashmap, LAGOPUS_HASHMAP_TYPE_ONE_WORD, freeup_flowinfo); /* misc is not used */ self->add_func = add_flow_ipv4_dst; self->del_func = del_flow_ipv4_dst; self->match_func = match_flow_ipv4_dst; self->find_func = find_flow_ipv4_dst; self->destroy_func = destroy_flowinfo_ipv4_dst; } return self; } static void destroy_flowinfo_ipv4_dst(struct flowinfo *self) { lagopus_hashmap_destroy(&self->hashmap, true); free(self); } static lagopus_result_t add_flow_ipv4_dst_mask(struct flowinfo *self, struct flow *flow) { struct flowinfo *flowinfo; uint32_t ipv4_dst, mask; lagopus_result_t rv; unsigned int i; rv = get_match_ipv4_dst(&flow->match_list, &ipv4_dst, &mask); if (rv == LAGOPUS_RESULT_OK) { rv = LAGOPUS_RESULT_NOT_FOUND; for (i = 0; i < self->nnext; i++) { if (self->next[i]->userdata == mask) { flowinfo = self->next[i]; rv = LAGOPUS_RESULT_OK; break; } } if (rv == LAGOPUS_RESULT_NOT_FOUND) { /* new node. */ flowinfo = new_flowinfo_ipv4_dst(); flowinfo->userdata = mask; self->next = realloc(self->next, (unsigned long)(self->nnext + 1) * sizeof(struct flowinfo *)); self->next[self->nnext] = flowinfo; self->nnext++; } rv = flowinfo->add_func(flowinfo, flow); } else { rv = self->misc->add_func(self->misc, flow); } if (rv == LAGOPUS_RESULT_OK) { self->nflow++; } return rv; } static lagopus_result_t del_flow_ipv4_dst_mask(struct flowinfo *self, struct flow *flow) { struct flowinfo *flowinfo; uint32_t ipv4_dst, mask; lagopus_result_t rv; unsigned int i; rv = get_match_ipv4_dst(&flow->match_list, &ipv4_dst, &mask); if (rv == LAGOPUS_RESULT_OK) { rv = LAGOPUS_RESULT_NOT_FOUND; for (i = 0; i < self->nnext; i++) { if (self->next[i]->userdata == mask) { flowinfo = self->next[i]; rv = LAGOPUS_RESULT_OK; break; } } if (rv == LAGOPUS_RESULT_NOT_FOUND) { return LAGOPUS_RESULT_NOT_FOUND; } rv = flowinfo->del_func(flowinfo, flow); if (flowinfo->nflow == 0) { flowinfo->destroy_func(flowinfo); self->nnext--; memmove(&self->next[i], &self->next[i + 1], (self->nnext - i) * sizeof(struct flowinfo **)); } } else { rv = self->misc->del_func(self->misc, flow); } if (rv == LAGOPUS_RESULT_OK) { self->nflow--; } return rv; } static struct flow * match_flow_ipv4_dst_mask(struct flowinfo *self, struct lagopus_packet *pkt, int32_t *pri) { struct flowinfo *flowinfo; struct flow *flow[self->nnext], *matched, *alt_flow; struct flow mismatched = { .priority = 0, .flags = 0, .idle_timeout = 0, .hard_timeout = 0, .match_list = {NULL, NULL}, .instruction_list = {NULL, NULL}, .field_bits = 0 }; unsigned int i; matched = &mismatched; //#pragma omp parallel for for (i = 0; i < self->nnext; i++) { flowinfo = self->next[i]; flow[i] = flowinfo->match_func(flowinfo, pkt, pri); } for (i = 0; i < self->nnext; i++) { if (flow[i] != NULL && flow[i]->priority > matched->priority) { matched = flow[i]; } } alt_flow = self->misc->match_func(self->misc, pkt, pri); if (alt_flow != NULL) { matched = alt_flow; } if (matched == &mismatched) { matched = NULL; } return matched; } static struct flow * find_flow_ipv4_dst_mask(struct flowinfo *self, struct flow *flow) { struct flowinfo *flowinfo; uint32_t ipv4_dst, mask; lagopus_result_t rv; unsigned int i; rv = get_match_ipv4_dst(&flow->match_list, &ipv4_dst, &mask); if (rv == LAGOPUS_RESULT_OK) { rv = LAGOPUS_RESULT_NOT_FOUND; for (i = 0; i < self->nnext; i++) { if (self->next[i]->userdata == mask) { flowinfo = self->next[i]; rv = LAGOPUS_RESULT_OK; break; } } if (rv == LAGOPUS_RESULT_NOT_FOUND) { return NULL; } } else { flowinfo = self->misc; } return flowinfo->find_func(flowinfo, flow); } static lagopus_result_t add_flow_ipv4_dst(struct flowinfo *self, struct flow *flow) { struct flowinfo *flowinfo; uint32_t ipv4_dst, mask; lagopus_result_t rv; rv = get_match_ipv4_dst(&flow->match_list, &ipv4_dst, &mask); if (rv == LAGOPUS_RESULT_OK) { rv = lagopus_hashmap_find_no_lock(&self->hashmap, (void *)ipv4_dst, (void *)&flowinfo); if (rv != LAGOPUS_RESULT_OK) { void *val; flowinfo = new_flowinfo_ipv4(); val = flowinfo; lagopus_hashmap_add_no_lock(&self->hashmap, (void *)ipv4_dst, (void *)&val, false); } rv = flowinfo->add_func(flowinfo, flow); if (rv == LAGOPUS_RESULT_OK) { self->nflow++; } } return rv; } static lagopus_result_t del_flow_ipv4_dst(struct flowinfo *self, struct flow *flow) { uint32_t ipv4_dst, mask; lagopus_result_t rv; rv = get_match_ipv4_dst(&flow->match_list, &ipv4_dst, &mask); if (rv == LAGOPUS_RESULT_OK) { struct flowinfo *flowinfo; rv = lagopus_hashmap_find_no_lock(&self->hashmap, (void *)ipv4_dst, (void *)&flowinfo); if (rv == LAGOPUS_RESULT_OK) { flowinfo->del_func(flowinfo, flow); } if (rv == LAGOPUS_RESULT_OK) { self->nflow--; } } return rv; } static struct flow * match_flow_ipv4_dst(struct flowinfo *self, struct lagopus_packet *pkt, int32_t *pri) { struct flowinfo *flowinfo; uint32_t ipv4_dst; struct flow *flow; lagopus_result_t rv; flow = NULL; ipv4_dst = (pkt->ipv4->ip_dst.s_addr & (uint32_t)self->userdata); rv = lagopus_hashmap_find_no_lock(&self->hashmap, (void *)ipv4_dst, (void *)&flowinfo); if (rv == LAGOPUS_RESULT_OK) { flow = flowinfo->match_func(flowinfo, pkt, pri); } return flow; } static struct flow * find_flow_ipv4_dst(struct flowinfo *self, struct flow *flow) { struct flowinfo *flowinfo; uint32_t ipv4_dst, mask; lagopus_result_t rv; rv = get_match_ipv4_dst(&flow->match_list, &ipv4_dst, &mask); if (rv == LAGOPUS_RESULT_OK) { rv = lagopus_hashmap_find_no_lock(&self->hashmap, (void *)ipv4_dst, (void *)&flowinfo); if (rv != LAGOPUS_RESULT_OK) { return NULL; } return flowinfo->find_func(flowinfo, flow); } else { return self->misc->find_func(self->misc, flow); } }

Functions.h

// // smarties // Copyright (c) 2018 CSE-Lab, ETH Zurich, Switzerland. All rights reserved. // Distributed under the terms of the MIT license. // // Created by Guido Novati (novatig@ethz.ch). // #ifndef smarties_Function_h #define smarties_Function_h #include "../../Utils/FunctionUtilities.h" #include "../../Utils/Warnings.h" #include <memory> #ifndef PRELU_FAC #define PRELU_FAC 0.1 #endif //List of non-linearities for neural networks //- eval return f(in), also present as array in / array out //- evalDiff returns f'(x) //- initFactor: some prefer fan in fan out, some only fan-in dependency //If adding a new function, edit function readFunction at end of file namespace smarties { struct Function { //weights are initialized with uniform distrib [-weightsInitFactor, weightsInitFactor] virtual Real initFactor(const Uint inps, const Uint outs) const = 0; virtual void eval(const nnReal*const in, nnReal*const out, const Uint N) const = 0; // f(in) virtual nnReal eval(const nnReal in) const = 0; virtual nnReal inverse(const nnReal in) const = 0; // f(in) virtual nnReal evalDiff(const nnReal in, const nnReal out) const = 0; // f'(in) virtual std::string name() const = 0; virtual ~Function() {} }; struct Linear : public Function { std::string name() const override { return "Linear";} Real initFactor(const Uint inps, const Uint outs) const override { return std::sqrt(1./inps); } static Real _initFactor(const Uint inps, const Uint outs) { return std::sqrt(1./inps); } void eval(const nnReal*const in, nnReal*const out, const Uint N) const override { memcpy(out, in, N*sizeof(nnReal)); } static void _eval(const nnReal*const in, nnReal*const out, const Uint N) { memcpy(out, in, N*sizeof(nnReal)); } template <typename T> static T _eval(const T in) { return in; } template <typename T> static T _evalDiff(const T in, const T out) { return 1; } nnReal eval(const nnReal in) const override { return in; } nnReal inverse(const nnReal in) const override { return in; } nnReal evalDiff(const nnReal in, const nnReal out) const override { return 1; } }; struct Tanh : public Function { std::string name() const override { return "Tanh"; } Real initFactor(const Uint inps, const Uint outs) const override { return std::sqrt(6./(inps + outs)); } static Real _initFactor(const Uint inps, const Uint outs) { return std::sqrt(6./(inps + outs)); } template <typename T> static T _eval(const T in) { if(in > 0) { const T e2x = std::exp(-2*in); return (1-e2x)/(1+e2x); } else { const T e2x = std::exp( 2*in); return (e2x-1)/(1+e2x); } } template <typename T> static T _evalDiff(const T in, const T out) { return 1 - out*out; } static void _eval(const nnReal*const in, nnReal*const out, const Uint N) { for(Uint i=0; i<N; ++i) out[i] = _eval(in[i]); } void eval(const nnReal*const in, nnReal*const out, const Uint N) const override { for(Uint i=0; i<N; ++i) out[i] = _eval(in[i]); } nnReal eval(const nnReal in) const override { return _eval(in); } nnReal inverse(const nnReal in) const override { assert(std::fabs(in)<1); return std::log((1+in)/(1-in)) / 2; } nnReal evalDiff(const nnReal in, const nnReal out) const override { return _evalDiff(in, out); } }; struct Sigm : public Function { std::string name() const override { return "Sigm";} Real initFactor(const Uint inps, const Uint outs) const override { return std::sqrt(6./(inps + outs)); } static Real _initFactor(const Uint inps, const Uint outs) { return std::sqrt(6./(inps + outs)); } template <typename T> static T _eval(const T in) { if(in > 0) return 1/(1+Utilities::safeExp(-in)); else { const T ex = Utilities::safeExp(in); return ex/(1+ex); } } template <typename T> static T _inv(const T in) { assert(in > 0 && in < 1); return - std::log(1/in - 1); } template <typename T> static T _evalDiff(const T in) { const T expx = Utilities::safeExp(in); return expx / std::pow(expx+1, 2); } template <typename T> static T _evalDiff(const T in, const T out) { return out*(1-out); } static void _eval(const nnReal*const in, nnReal*const out, const Uint N) { for(Uint i=0; i<N; ++i) out[i] = _eval(in[i]); } void eval(const nnReal*const in, nnReal*const out, const Uint N) const override { for(Uint i=0; i<N; ++i) out[i] = _eval(in[i]); } nnReal eval(const nnReal in) const override { return _eval(in); } nnReal inverse(const nnReal in) const override { return _inv(in); } nnReal evalDiff(const nnReal in, const nnReal out) const override { return _evalDiff(in, out); } }; struct HardSign : public Function { std::string name() const override { return "HardSign";} Real initFactor(const Uint inps, const Uint outs) const override { return std::sqrt(6./(inps + outs)); } static Real _initFactor(const Uint inps, const Uint outs) { return std::sqrt(6./(inps + outs)); } template <typename T> static T _eval(const T in) { return in/std::sqrt(1+in*in); } template <typename T> static T _evalDiff(const T in, const T out) { const T denom = std::sqrt(1+in*in); return 1/(denom*denom*denom); } static void _eval(const nnReal*const in, nnReal*const out, const Uint N) { #pragma omp simd aligned(in,out : VEC_WIDTH) for (Uint i=0; i<N; ++i) out[i] = in[i]/std::sqrt(1+in[i]*in[i]); } void eval(const nnReal*const in, nnReal*const out, const Uint N) const override { return _eval(in, out, N); } nnReal eval(const nnReal in) const override { return _eval(in); } nnReal inverse(const nnReal in) const override { assert(in > 0 && in < 1); return in/std::sqrt(1 -in*in); } nnReal evalDiff(const nnReal in, const nnReal out) const override { return _evalDiff(in, out); } }; struct HardSigmoid : public Function { std::string name() const override { return "HardSigmoid";} Real initFactor(const Uint inps, const Uint outs) const override { return std::sqrt(6./(inps + outs)); } static Real _initFactor(const Uint inps, const Uint outs) { return std::sqrt(6./(inps + outs)); } template <typename T> static T _eval(const T x) { return 0.5 * (1 + x/std::sqrt(1+x*x)); } template <typename T> static T _evalDiff(const T x, const T y) { const T denom = std::sqrt(1+x*x); return 0.5/(denom*denom*denom); } template <typename T> static T _evalDiff(const T x) { const T denom = std::sqrt(1+x*x); return 0.5/(denom*denom*denom); } template <typename T> static T _inv(const T y) { assert(y > 0 && y < 1); const Real map = 2 * y - 1; return map/std::sqrt(1 -map*map); } static void _eval(const nnReal*const in, nnReal*const out, const Uint N) { #pragma omp simd aligned(in,out : VEC_WIDTH) for (Uint i=0; i<N; ++i) out[i] = _eval(in[i]); } void eval(const nnReal*const in, nnReal*const out, const Uint N) const override { return _eval(in, out, N); } nnReal eval(const nnReal in) const override { return _eval(in); } nnReal inverse(const nnReal y) const override { return _inv(y); } nnReal evalDiff(const nnReal in, const nnReal out) const override { return _evalDiff(in, out); } }; struct SoftSign : public Function { std::string name() const override { return "SoftSign";} Real initFactor(const Uint inps, const Uint outs) const override { return std::sqrt(6.0/(inps + outs)); } static Real _initFactor(const Uint inps, const Uint outs) { return std::sqrt(6.0/(inps + outs)); } template <typename T> static T _eval(const T in) { return in/(1 + std::fabs(in)); } template <typename T> static T _evalDiff(const T in, const T out) { const T denom = 1 + std::fabs(in); return 1/(denom*denom); } static void _eval(const nnReal*const in, nnReal*const out, const Uint N) { #pragma omp simd aligned(in,out : VEC_WIDTH) for (Uint i=0;i<N; ++i) out[i] = _eval(in[i]); } void eval(const nnReal*const in, nnReal*const out, const Uint N) const override { return _eval(in, out, N); } nnReal eval(const nnReal in) const override { return _eval(in); } nnReal inverse(const nnReal in) const override { assert(in > 0 && in < 1); return in / (1 - std::fabs(in)); } nnReal evalDiff(const nnReal in, const nnReal out) const override { return _evalDiff(in, out); } }; struct SoftRBF : public Function { std::string name() const override { return "SoftRBF";} Real initFactor(const Uint inps, const Uint outs) const override { return std::sqrt(6.0/(inps + outs)); } static Real _initFactor(const Uint inps, const Uint outs) { return std::sqrt(6.0/(inps + outs)); } template <typename T> static T _eval(const T in) { return 1/(1 + in * in); } template <typename T> static T _evalDiff(const T in, const T out) { const T denom = 1 + in * in; return - 2 * in / (denom * denom); } static void _eval(const nnReal*const in, nnReal*const out, const Uint N) { #pragma omp simd aligned(in,out : VEC_WIDTH) for (Uint i=0;i<N; ++i) out[i] = _eval(in[i]); } void eval(const nnReal*const in, nnReal*const out, const Uint N) const override { return _eval(in, out, N); } nnReal eval(const nnReal in) const override { return _eval(in); } nnReal inverse(const nnReal in) const override { die("Not supported"); return in / (1 - std::fabs(in)); } nnReal evalDiff(const nnReal in, const nnReal out) const override { return _evalDiff(in, out); } }; struct Relu : public Function { std::string name() const override { return "Relu";} Real initFactor(const Uint inps, const Uint outs) const override { return std::sqrt(2./inps); } static Real _initFactor(const Uint inps, const Uint outs) { return std::sqrt(2./inps); } template <typename T> static T _eval(const T in) { return in>0 ? in : 0; } template <typename T> static T _evalDiff(const T in, const T out) { return in>0 ? 1 : 0; } static void _eval(const nnReal*const in, nnReal*const out, const Uint N) { #pragma omp simd aligned(in,out : VEC_WIDTH) for (Uint i=0;i<N; ++i) out[i] = in[i]>0 ? in[i] : 0; } void eval(const nnReal*const in, nnReal*const out, const Uint N) const override { return _eval(in, out, N); } nnReal eval(const nnReal in) const override { return _eval(in); } nnReal inverse(const nnReal in) const override { assert(in>=0); return in; } nnReal evalDiff(const nnReal in, const nnReal out) const override { return _evalDiff(in, out); } }; struct LRelu : public Function { std::string name() const override { return "LRelu";} Real initFactor(const Uint inps, const Uint outs) const override { return std::sqrt(1.0/inps); } static Real _initFactor(const Uint inps, const Uint outs) { return std::sqrt(1.0/inps); } template <typename T> static T _eval(const T in) { return in>0 ? in : PRELU_FAC*in; } template <typename T> static T _evalDiff(const T in, const T out) { return in>0 ? 1 : PRELU_FAC; } static void _eval(const nnReal*const in, nnReal*const out, const Uint N) { #pragma omp simd aligned(in,out : VEC_WIDTH) for (Uint i=0;i<N; ++i) out[i] = in[i]>0 ? in[i] : PRELU_FAC*in[i]; } void eval(const nnReal*const in, nnReal*const out, const Uint N) const override { return _eval(in, out, N); } nnReal eval(const nnReal in) const override { return _eval(in); } nnReal inverse(const nnReal in) const override { if(in >= 0) return in; else return in / PRELU_FAC; } nnReal evalDiff(const nnReal in, const nnReal out) const override { return _evalDiff(in, out); } }; struct ExpPlus : public Function { std::string name() const override { return "ExpPlus";} Real initFactor(const Uint inps, const Uint outs) const override { return std::sqrt(2./inps); } static Real _initFactor(const Uint inps, const Uint outs) { return std::sqrt(2./inps); } template <typename T> static T _inv(const T in) { return std::log(Utilities::safeExp(in) - 1); } // Used here, std::exp is trigger happy with nans, therefore we clip it // between exp(-32) and exp(16). template <typename T> static T _eval(const T in) { return std::log(1 + Utilities::safeExp(in)); } template <typename T> static T _evalDiff(const T in) { return 1/(1 + Utilities::safeExp(-in)); } template <typename T> static T _evalDiff(const T in, const T out) { return 1/(1 + Utilities::safeExp(-in)); } static void _eval(const nnReal*const in, nnReal*const out, const Uint N) { for(Uint i=0; i<N; ++i) out[i] = _eval(in[i]); } void eval(const nnReal*const in, nnReal*const out, const Uint N) const override { return _eval(in, out, N); } nnReal eval(const nnReal in) const override { return _eval(in); } nnReal inverse(const nnReal in) const override { return _inv(in); } nnReal evalDiff(const nnReal in, const nnReal out) const override { return _evalDiff(in, out); } }; struct SoftPlus : public Function { std::string name() const override { return "SoftPlus";} Real initFactor(const Uint inps, const Uint outs) const override { return std::sqrt(2./inps); } static Real _initFactor(const Uint inps, const Uint outs) { return std::sqrt(2./inps); } template <typename T> static T _eval(const T in) { return (in + std::sqrt(1+in*in)) / 2; } template <typename T> static T _evalDiff(const T in) { return (1 + in/std::sqrt(1+in*in)) / 2; } template <typename T> static T _evalDiff(const T in, const T out) { return (1 + in/std::sqrt(1+in*in)) / 2; } template <typename T> static T _inv(const T in) { assert(in > 0); return (in*in - (T)0.25)/in; } static void _eval(const nnReal*const in, nnReal*const out, const Uint N) { #pragma omp simd aligned(in,out : VEC_WIDTH) for (Uint i=0;i<N; ++i) out[i] = (in[i] + std::sqrt(1+in[i]*in[i])) / 2; } void eval(const nnReal*const in, nnReal*const out, const Uint N) const override { return _eval(in, out, N); } nnReal eval(const nnReal in) const override { return _eval(in); } nnReal inverse(const nnReal in) const override { return _inv(in); } nnReal evalDiff(const nnReal in, const nnReal out) const override { return _evalDiff(in, out); } }; struct Exp : public Function { std::string name() const override { return "Exp";} Real initFactor(const Uint inps, const Uint outs) const override { return std::sqrt(2./inps); } static Real _initFactor(const Uint inps, const Uint outs) { return std::sqrt(2./inps); } template <typename T> static T _inv(const T in) { return std::log(in); } template <typename T> static T _eval(const T in) { return Utilities::nnSafeExp(in); } template <typename T> static T _evalDiff(const T in) { return Utilities::nnSafeExp(in); } template <typename T> static T _evalDiff(const T in, const T out) { return out; } static void _eval(const nnReal*const in, nnReal*const out, const Uint N) { for(Uint i=0; i<N; ++i) out[i] = Utilities::nnSafeExp(in[i]); } void eval(const nnReal*const in, nnReal*const out, const Uint N) const override { return _eval(in, out, N); } nnReal eval(const nnReal in) const override { return _eval(in); } nnReal inverse(const nnReal in) const override { assert(in > 0); return std::log(in); } nnReal evalDiff(const nnReal in, const nnReal out) const override { return _evalDiff(in, out); } }; inline std::unique_ptr<Function> makeFunction(const std::string name, const bool bOutput=false) { if (bOutput || name == "Linear") return std::make_unique<Linear>(); else if (name == "Tanh") return std::make_unique<Tanh>(); else if (name == "Sigm") return std::make_unique<Sigm>(); else if (name == "HardSign") return std::make_unique<HardSign>(); else if (name == "SoftSign") return std::make_unique<SoftSign>(); else if (name == "Relu") return std::make_unique<Relu>(); else if (name == "LRelu") return std::make_unique<LRelu>(); else if (name == "ExpPlus") return std::make_unique<ExpPlus>(); else if (name == "SoftPlus") return std::make_unique<SoftPlus>(); else if (name == "Exp") return std::make_unique<Exp>(); else die("Activation function not recognized"); return std::make_unique<Linear>(); } } // end namespace smarties #endif // smarties_Quadratic_term_h

parser.c

/* C++ Parser. Copyright (C) 2000, 2001, 2002, 2003, 2004, 2005 Free Software Foundation, Inc. Written by Mark Mitchell <mark@codesourcery.com>. This file is part of GCC. GCC 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, or (at your option) any later version. GCC 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 GCC; see the file COPYING. If not, write to the Free Software Foundation, 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA. */ #include "config.h" #include "system.h" #include "coretypes.h" #include "tm.h" #include "dyn-string.h" #include "varray.h" #include "cpplib.h" #include "tree.h" #include "cp-tree.h" #include "c-pragma.h" #include "decl.h" #include "flags.h" #include "diagnostic.h" #include "toplev.h" #include "output.h" #include "target.h" #include "cgraph.h" #include "c-common.h" /* The lexer. */ /* The cp_lexer_* routines mediate between the lexer proper (in libcpp and c-lex.c) and the C++ parser. */ /* A token's value and its associated deferred access checks and qualifying scope. */ struct tree_check GTY(()) { /* The value associated with the token. */ tree value; /* The checks that have been associated with value. */ VEC (deferred_access_check, gc)* checks; /* The token's qualifying scope (used when it is a CPP_NESTED_NAME_SPECIFIER). */ tree qualifying_scope; }; /* A C++ token. */ typedef struct cp_token GTY (()) { /* The kind of token. */ ENUM_BITFIELD (cpp_ttype) type : 8; /* If this token is a keyword, this value indicates which keyword. Otherwise, this value is RID_MAX. */ ENUM_BITFIELD (rid) keyword : 8; /* Token flags. */ unsigned char flags; /* Identifier for the pragma. */ ENUM_BITFIELD (pragma_kind) pragma_kind : 6; /* True if this token is from a system header. */ BOOL_BITFIELD in_system_header : 1; /* True if this token is from a context where it is implicitly extern "C" */ BOOL_BITFIELD implicit_extern_c : 1; /* True for a CPP_NAME token that is not a keyword (i.e., for which KEYWORD is RID_MAX) iff this name was looked up and found to be ambiguous. An error has already been reported. */ BOOL_BITFIELD ambiguous_p : 1; /* The input file stack index at which this token was found. */ unsigned input_file_stack_index : INPUT_FILE_STACK_BITS; /* The value associated with this token, if any. */ union cp_token_value { /* Used for CPP_NESTED_NAME_SPECIFIER and CPP_TEMPLATE_ID. */ struct tree_check* GTY((tag ("1"))) tree_check_value; /* Use for all other tokens. */ tree GTY((tag ("0"))) value; } GTY((desc ("(%1.type == CPP_TEMPLATE_ID) || (%1.type == CPP_NESTED_NAME_SPECIFIER)"))) u; /* The location at which this token was found. */ location_t location; } cp_token; /* We use a stack of token pointer for saving token sets. */ typedef struct cp_token *cp_token_position; DEF_VEC_P (cp_token_position); DEF_VEC_ALLOC_P (cp_token_position,heap); static const cp_token eof_token = { CPP_EOF, RID_MAX, 0, PRAGMA_NONE, 0, 0, false, 0, { NULL }, #if USE_MAPPED_LOCATION 0 #else {0, 0} #endif }; /* The cp_lexer structure represents the C++ lexer. It is responsible for managing the token stream from the preprocessor and supplying it to the parser. Tokens are never added to the cp_lexer after it is created. */ typedef struct cp_lexer GTY (()) { /* The memory allocated for the buffer. NULL if this lexer does not own the token buffer. */ cp_token * GTY ((length ("%h.buffer_length"))) buffer; /* If the lexer owns the buffer, this is the number of tokens in the buffer. */ size_t buffer_length; /* A pointer just past the last available token. The tokens in this lexer are [buffer, last_token). */ cp_token_position GTY ((skip)) last_token; /* The next available token. If NEXT_TOKEN is &eof_token, then there are no more available tokens. */ cp_token_position GTY ((skip)) next_token; /* A stack indicating positions at which cp_lexer_save_tokens was called. The top entry is the most recent position at which we began saving tokens. If the stack is non-empty, we are saving tokens. */ VEC(cp_token_position,heap) *GTY ((skip)) saved_tokens; /* The next lexer in a linked list of lexers. */ struct cp_lexer *next; /* True if we should output debugging information. */ bool debugging_p; /* True if we're in the context of parsing a pragma, and should not increment past the end-of-line marker. */ bool in_pragma; } cp_lexer; /* cp_token_cache is a range of tokens. There is no need to represent allocate heap memory for it, since tokens are never removed from the lexer's array. There is also no need for the GC to walk through a cp_token_cache, since everything in here is referenced through a lexer. */ typedef struct cp_token_cache GTY(()) { /* The beginning of the token range. */ cp_token * GTY((skip)) first; /* Points immediately after the last token in the range. */ cp_token * GTY ((skip)) last; } cp_token_cache; /* Prototypes. */ static cp_lexer *cp_lexer_new_main (void); static cp_lexer *cp_lexer_new_from_tokens (cp_token_cache *tokens); static void cp_lexer_destroy (cp_lexer *); static int cp_lexer_saving_tokens (const cp_lexer *); static cp_token_position cp_lexer_token_position (cp_lexer *, bool); static cp_token *cp_lexer_token_at (cp_lexer *, cp_token_position); static void cp_lexer_get_preprocessor_token (cp_lexer *, cp_token *); static inline cp_token *cp_lexer_peek_token (cp_lexer *); static cp_token *cp_lexer_peek_nth_token (cp_lexer *, size_t); static inline bool cp_lexer_next_token_is (cp_lexer *, enum cpp_ttype); static bool cp_lexer_next_token_is_not (cp_lexer *, enum cpp_ttype); static bool cp_lexer_next_token_is_keyword (cp_lexer *, enum rid); static cp_token *cp_lexer_consume_token (cp_lexer *); static void cp_lexer_purge_token (cp_lexer *); static void cp_lexer_purge_tokens_after (cp_lexer *, cp_token_position); static void cp_lexer_save_tokens (cp_lexer *); static void cp_lexer_commit_tokens (cp_lexer *); static void cp_lexer_rollback_tokens (cp_lexer *); #ifdef ENABLE_CHECKING static void cp_lexer_print_token (FILE *, cp_token *); static inline bool cp_lexer_debugging_p (cp_lexer *); static void cp_lexer_start_debugging (cp_lexer *) ATTRIBUTE_UNUSED; static void cp_lexer_stop_debugging (cp_lexer *) ATTRIBUTE_UNUSED; #else /* If we define cp_lexer_debug_stream to NULL it will provoke warnings about passing NULL to functions that require non-NULL arguments (fputs, fprintf). It will never be used, so all we need is a value of the right type that's guaranteed not to be NULL. */ #define cp_lexer_debug_stream stdout #define cp_lexer_print_token(str, tok) (void) 0 #define cp_lexer_debugging_p(lexer) 0 #endif /* ENABLE_CHECKING */ static cp_token_cache *cp_token_cache_new (cp_token *, cp_token *); static void cp_parser_initial_pragma (cp_token *); /* Manifest constants. */ #define CP_LEXER_BUFFER_SIZE ((256 * 1024) / sizeof (cp_token)) #define CP_SAVED_TOKEN_STACK 5 /* A token type for keywords, as opposed to ordinary identifiers. */ #define CPP_KEYWORD ((enum cpp_ttype) (N_TTYPES + 1)) /* A token type for template-ids. If a template-id is processed while parsing tentatively, it is replaced with a CPP_TEMPLATE_ID token; the value of the CPP_TEMPLATE_ID is whatever was returned by cp_parser_template_id. */ #define CPP_TEMPLATE_ID ((enum cpp_ttype) (CPP_KEYWORD + 1)) /* A token type for nested-name-specifiers. If a nested-name-specifier is processed while parsing tentatively, it is replaced with a CPP_NESTED_NAME_SPECIFIER token; the value of the CPP_NESTED_NAME_SPECIFIER is whatever was returned by cp_parser_nested_name_specifier_opt. */ #define CPP_NESTED_NAME_SPECIFIER ((enum cpp_ttype) (CPP_TEMPLATE_ID + 1)) /* A token type for tokens that are not tokens at all; these are used to represent slots in the array where there used to be a token that has now been deleted. */ #define CPP_PURGED ((enum cpp_ttype) (CPP_NESTED_NAME_SPECIFIER + 1)) /* The number of token types, including C++-specific ones. */ #define N_CP_TTYPES ((int) (CPP_PURGED + 1)) /* Variables. */ #ifdef ENABLE_CHECKING /* The stream to which debugging output should be written. */ static FILE *cp_lexer_debug_stream; #endif /* ENABLE_CHECKING */ /* Create a new main C++ lexer, the lexer that gets tokens from the preprocessor. */ static cp_lexer * cp_lexer_new_main (void) { cp_token first_token; cp_lexer *lexer; cp_token *pos; size_t alloc; size_t space; cp_token *buffer; /* It's possible that parsing the first pragma will load a PCH file, which is a GC collection point. So we have to do that before allocating any memory. */ cp_parser_initial_pragma (&first_token); /* Tell c_lex_with_flags not to merge string constants. */ c_lex_return_raw_strings = true; c_common_no_more_pch (); /* Allocate the memory. */ lexer = GGC_CNEW (cp_lexer); #ifdef ENABLE_CHECKING /* Initially we are not debugging. */ lexer->debugging_p = false; #endif /* ENABLE_CHECKING */ lexer->saved_tokens = VEC_alloc (cp_token_position, heap, CP_SAVED_TOKEN_STACK); /* Create the buffer. */ alloc = CP_LEXER_BUFFER_SIZE; buffer = GGC_NEWVEC (cp_token, alloc); /* Put the first token in the buffer. */ space = alloc; pos = buffer; *pos = first_token; /* Get the remaining tokens from the preprocessor. */ while (pos->type != CPP_EOF) { pos++; if (!--space) { space = alloc; alloc *= 2; buffer = GGC_RESIZEVEC (cp_token, buffer, alloc); pos = buffer + space; } cp_lexer_get_preprocessor_token (lexer, pos); } lexer->buffer = buffer; lexer->buffer_length = alloc - space; lexer->last_token = pos; lexer->next_token = lexer->buffer_length ? buffer : (cp_token *)&eof_token; /* Subsequent preprocessor diagnostics should use compiler diagnostic functions to get the compiler source location. */ cpp_get_options (parse_in)->client_diagnostic = true; cpp_get_callbacks (parse_in)->error = cp_cpp_error; gcc_assert (lexer->next_token->type != CPP_PURGED); return lexer; } /* Create a new lexer whose token stream is primed with the tokens in CACHE. When these tokens are exhausted, no new tokens will be read. */ static cp_lexer * cp_lexer_new_from_tokens (cp_token_cache *cache) { cp_token *first = cache->first; cp_token *last = cache->last; cp_lexer *lexer = GGC_CNEW (cp_lexer); /* We do not own the buffer. */ lexer->buffer = NULL; lexer->buffer_length = 0; lexer->next_token = first == last ? (cp_token *)&eof_token : first; lexer->last_token = last; lexer->saved_tokens = VEC_alloc (cp_token_position, heap, CP_SAVED_TOKEN_STACK); #ifdef ENABLE_CHECKING /* Initially we are not debugging. */ lexer->debugging_p = false; #endif gcc_assert (lexer->next_token->type != CPP_PURGED); return lexer; } /* Frees all resources associated with LEXER. */ static void cp_lexer_destroy (cp_lexer *lexer) { if (lexer->buffer) ggc_free (lexer->buffer); VEC_free (cp_token_position, heap, lexer->saved_tokens); ggc_free (lexer); } /* Returns nonzero if debugging information should be output. */ #ifdef ENABLE_CHECKING static inline bool cp_lexer_debugging_p (cp_lexer *lexer) { return lexer->debugging_p; } #endif /* ENABLE_CHECKING */ static inline cp_token_position cp_lexer_token_position (cp_lexer *lexer, bool previous_p) { gcc_assert (!previous_p || lexer->next_token != &eof_token); return lexer->next_token - previous_p; } static inline cp_token * cp_lexer_token_at (cp_lexer *lexer ATTRIBUTE_UNUSED, cp_token_position pos) { return pos; } /* nonzero if we are presently saving tokens. */ static inline int cp_lexer_saving_tokens (const cp_lexer* lexer) { return VEC_length (cp_token_position, lexer->saved_tokens) != 0; } /* Store the next token from the preprocessor in *TOKEN. Return true if we reach EOF. */ static void cp_lexer_get_preprocessor_token (cp_lexer *lexer ATTRIBUTE_UNUSED , cp_token *token) { static int is_extern_c = 0; /* Get a new token from the preprocessor. */ token->type = c_lex_with_flags (&token->u.value, &token->location, &token->flags); token->input_file_stack_index = input_file_stack_tick; token->keyword = RID_MAX; token->pragma_kind = PRAGMA_NONE; token->in_system_header = in_system_header; /* On some systems, some header files are surrounded by an implicit extern "C" block. Set a flag in the token if it comes from such a header. */ is_extern_c += pending_lang_change; pending_lang_change = 0; token->implicit_extern_c = is_extern_c > 0; /* Check to see if this token is a keyword. */ if (token->type == CPP_NAME) { if (C_IS_RESERVED_WORD (token->u.value)) { /* Mark this token as a keyword. */ token->type = CPP_KEYWORD; /* Record which keyword. */ token->keyword = C_RID_CODE (token->u.value); /* Update the value. Some keywords are mapped to particular entities, rather than simply having the value of the corresponding IDENTIFIER_NODE. For example, `__const' is mapped to `const'. */ token->u.value = ridpointers[token->keyword]; } else { token->ambiguous_p = false; token->keyword = RID_MAX; } } /* Handle Objective-C++ keywords. */ else if (token->type == CPP_AT_NAME) { token->type = CPP_KEYWORD; switch (C_RID_CODE (token->u.value)) { /* Map 'class' to '@class', 'private' to '@private', etc. */ case RID_CLASS: token->keyword = RID_AT_CLASS; break; case RID_PRIVATE: token->keyword = RID_AT_PRIVATE; break; case RID_PROTECTED: token->keyword = RID_AT_PROTECTED; break; case RID_PUBLIC: token->keyword = RID_AT_PUBLIC; break; case RID_THROW: token->keyword = RID_AT_THROW; break; case RID_TRY: token->keyword = RID_AT_TRY; break; case RID_CATCH: token->keyword = RID_AT_CATCH; break; default: token->keyword = C_RID_CODE (token->u.value); } } else if (token->type == CPP_PRAGMA) { /* We smuggled the cpp_token->u.pragma value in an INTEGER_CST. */ token->pragma_kind = TREE_INT_CST_LOW (token->u.value); token->u.value = NULL_TREE; } } /* Update the globals input_location and in_system_header and the input file stack from TOKEN. */ static inline void cp_lexer_set_source_position_from_token (cp_token *token) { if (token->type != CPP_EOF) { input_location = token->location; in_system_header = token->in_system_header; restore_input_file_stack (token->input_file_stack_index); } } /* Return a pointer to the next token in the token stream, but do not consume it. */ static inline cp_token * cp_lexer_peek_token (cp_lexer *lexer) { if (cp_lexer_debugging_p (lexer)) { fputs ("cp_lexer: peeking at token: ", cp_lexer_debug_stream); cp_lexer_print_token (cp_lexer_debug_stream, lexer->next_token); putc ('\n', cp_lexer_debug_stream); } return lexer->next_token; } /* Return true if the next token has the indicated TYPE. */ static inline bool cp_lexer_next_token_is (cp_lexer* lexer, enum cpp_ttype type) { return cp_lexer_peek_token (lexer)->type == type; } /* Return true if the next token does not have the indicated TYPE. */ static inline bool cp_lexer_next_token_is_not (cp_lexer* lexer, enum cpp_ttype type) { return !cp_lexer_next_token_is (lexer, type); } /* Return true if the next token is the indicated KEYWORD. */ static inline bool cp_lexer_next_token_is_keyword (cp_lexer* lexer, enum rid keyword) { return cp_lexer_peek_token (lexer)->keyword == keyword; } /* Return true if the next token is a keyword for a decl-specifier. */ static bool cp_lexer_next_token_is_decl_specifier_keyword (cp_lexer *lexer) { cp_token *token; token = cp_lexer_peek_token (lexer); switch (token->keyword) { /* Storage classes. */ case RID_AUTO: case RID_REGISTER: case RID_STATIC: case RID_EXTERN: case RID_MUTABLE: case RID_THREAD: /* Elaborated type specifiers. */ case RID_ENUM: case RID_CLASS: case RID_STRUCT: case RID_UNION: case RID_TYPENAME: /* Simple type specifiers. */ case RID_CHAR: case RID_WCHAR: case RID_BOOL: case RID_SHORT: case RID_INT: case RID_LONG: case RID_SIGNED: case RID_UNSIGNED: case RID_FLOAT: case RID_DOUBLE: case RID_VOID: /* GNU extensions. */ case RID_ATTRIBUTE: case RID_TYPEOF: return true; default: return false; } } /* Return a pointer to the Nth token in the token stream. If N is 1, then this is precisely equivalent to cp_lexer_peek_token (except that it is not inline). One would like to disallow that case, but there is one case (cp_parser_nth_token_starts_template_id) where the caller passes a variable for N and it might be 1. */ static cp_token * cp_lexer_peek_nth_token (cp_lexer* lexer, size_t n) { cp_token *token; /* N is 1-based, not zero-based. */ gcc_assert (n > 0); if (cp_lexer_debugging_p (lexer)) fprintf (cp_lexer_debug_stream, "cp_lexer: peeking ahead %ld at token: ", (long)n); --n; token = lexer->next_token; gcc_assert (!n || token != &eof_token); while (n != 0) { ++token; if (token == lexer->last_token) { token = (cp_token *)&eof_token; break; } if (token->type != CPP_PURGED) --n; } if (cp_lexer_debugging_p (lexer)) { cp_lexer_print_token (cp_lexer_debug_stream, token); putc ('\n', cp_lexer_debug_stream); } return token; } /* Return the next token, and advance the lexer's next_token pointer to point to the next non-purged token. */ static cp_token * cp_lexer_consume_token (cp_lexer* lexer) { cp_token *token = lexer->next_token; gcc_assert (token != &eof_token); gcc_assert (!lexer->in_pragma || token->type != CPP_PRAGMA_EOL); do { lexer->next_token++; if (lexer->next_token == lexer->last_token) { lexer->next_token = (cp_token *)&eof_token; break; } } while (lexer->next_token->type == CPP_PURGED); cp_lexer_set_source_position_from_token (token); /* Provide debugging output. */ if (cp_lexer_debugging_p (lexer)) { fputs ("cp_lexer: consuming token: ", cp_lexer_debug_stream); cp_lexer_print_token (cp_lexer_debug_stream, token); putc ('\n', cp_lexer_debug_stream); } return token; } /* Permanently remove the next token from the token stream, and advance the next_token pointer to refer to the next non-purged token. */ static void cp_lexer_purge_token (cp_lexer *lexer) { cp_token *tok = lexer->next_token; gcc_assert (tok != &eof_token); tok->type = CPP_PURGED; tok->location = UNKNOWN_LOCATION; tok->u.value = NULL_TREE; tok->keyword = RID_MAX; do { tok++; if (tok == lexer->last_token) { tok = (cp_token *)&eof_token; break; } } while (tok->type == CPP_PURGED); lexer->next_token = tok; } /* Permanently remove all tokens after TOK, up to, but not including, the token that will be returned next by cp_lexer_peek_token. */ static void cp_lexer_purge_tokens_after (cp_lexer *lexer, cp_token *tok) { cp_token *peek = lexer->next_token; if (peek == &eof_token) peek = lexer->last_token; gcc_assert (tok < peek); for ( tok += 1; tok != peek; tok += 1) { tok->type = CPP_PURGED; tok->location = UNKNOWN_LOCATION; tok->u.value = NULL_TREE; tok->keyword = RID_MAX; } } /* Begin saving tokens. All tokens consumed after this point will be preserved. */ static void cp_lexer_save_tokens (cp_lexer* lexer) { /* Provide debugging output. */ if (cp_lexer_debugging_p (lexer)) fprintf (cp_lexer_debug_stream, "cp_lexer: saving tokens\n"); VEC_safe_push (cp_token_position, heap, lexer->saved_tokens, lexer->next_token); } /* Commit to the portion of the token stream most recently saved. */ static void cp_lexer_commit_tokens (cp_lexer* lexer) { /* Provide debugging output. */ if (cp_lexer_debugging_p (lexer)) fprintf (cp_lexer_debug_stream, "cp_lexer: committing tokens\n"); VEC_pop (cp_token_position, lexer->saved_tokens); } /* Return all tokens saved since the last call to cp_lexer_save_tokens to the token stream. Stop saving tokens. */ static void cp_lexer_rollback_tokens (cp_lexer* lexer) { /* Provide debugging output. */ if (cp_lexer_debugging_p (lexer)) fprintf (cp_lexer_debug_stream, "cp_lexer: restoring tokens\n"); lexer->next_token = VEC_pop (cp_token_position, lexer->saved_tokens); } /* Print a representation of the TOKEN on the STREAM. */ #ifdef ENABLE_CHECKING static void cp_lexer_print_token (FILE * stream, cp_token *token) { /* We don't use cpp_type2name here because the parser defines a few tokens of its own. */ static const char *const token_names[] = { /* cpplib-defined token types */ #define OP(e, s) #e, #define TK(e, s) #e, TTYPE_TABLE #undef OP #undef TK /* C++ parser token types - see "Manifest constants", above. */ "KEYWORD", "TEMPLATE_ID", "NESTED_NAME_SPECIFIER", "PURGED" }; /* If we have a name for the token, print it out. Otherwise, we simply give the numeric code. */ gcc_assert (token->type < ARRAY_SIZE(token_names)); fputs (token_names[token->type], stream); /* For some tokens, print the associated data. */ switch (token->type) { case CPP_KEYWORD: /* Some keywords have a value that is not an IDENTIFIER_NODE. For example, `struct' is mapped to an INTEGER_CST. */ if (TREE_CODE (token->u.value) != IDENTIFIER_NODE) break; /* else fall through */ case CPP_NAME: fputs (IDENTIFIER_POINTER (token->u.value), stream); break; case CPP_STRING: case CPP_WSTRING: fprintf (stream, " \"%s\"", TREE_STRING_POINTER (token->u.value)); break; default: break; } } /* Start emitting debugging information. */ static void cp_lexer_start_debugging (cp_lexer* lexer) { lexer->debugging_p = true; } /* Stop emitting debugging information. */ static void cp_lexer_stop_debugging (cp_lexer* lexer) { lexer->debugging_p = false; } #endif /* ENABLE_CHECKING */ /* Create a new cp_token_cache, representing a range of tokens. */ static cp_token_cache * cp_token_cache_new (cp_token *first, cp_token *last) { cp_token_cache *cache = GGC_NEW (cp_token_cache); cache->first = first; cache->last = last; return cache; } /* Decl-specifiers. */ /* Set *DECL_SPECS to represent an empty decl-specifier-seq. */ static void clear_decl_specs (cp_decl_specifier_seq *decl_specs) { memset (decl_specs, 0, sizeof (cp_decl_specifier_seq)); } /* Declarators. */ /* Nothing other than the parser should be creating declarators; declarators are a semi-syntactic representation of C++ entities. Other parts of the front end that need to create entities (like VAR_DECLs or FUNCTION_DECLs) should do that directly. */ static cp_declarator *make_call_declarator (cp_declarator *, cp_parameter_declarator *, cp_cv_quals, tree); static cp_declarator *make_array_declarator (cp_declarator *, tree); static cp_declarator *make_pointer_declarator (cp_cv_quals, cp_declarator *); static cp_declarator *make_reference_declarator (cp_cv_quals, cp_declarator *); static cp_parameter_declarator *make_parameter_declarator (cp_decl_specifier_seq *, cp_declarator *, tree); static cp_declarator *make_ptrmem_declarator (cp_cv_quals, tree, cp_declarator *); /* An erroneous declarator. */ static cp_declarator *cp_error_declarator; /* The obstack on which declarators and related data structures are allocated. */ static struct obstack declarator_obstack; /* Alloc BYTES from the declarator memory pool. */ static inline void * alloc_declarator (size_t bytes) { return obstack_alloc (&declarator_obstack, bytes); } /* Allocate a declarator of the indicated KIND. Clear fields that are common to all declarators. */ static cp_declarator * make_declarator (cp_declarator_kind kind) { cp_declarator *declarator; declarator = (cp_declarator *) alloc_declarator (sizeof (cp_declarator)); declarator->kind = kind; declarator->attributes = NULL_TREE; declarator->declarator = NULL; return declarator; } /* Make a declarator for a generalized identifier. If QUALIFYING_SCOPE is non-NULL, the identifier is QUALIFYING_SCOPE::UNQUALIFIED_NAME; otherwise, it is just UNQUALIFIED_NAME. SFK indicates the kind of special function this is, if any. */ static cp_declarator * make_id_declarator (tree qualifying_scope, tree unqualified_name, special_function_kind sfk) { cp_declarator *declarator; /* It is valid to write: class C { void f(); }; typedef C D; void D::f(); The standard is not clear about whether `typedef const C D' is legal; as of 2002-09-15 the committee is considering that question. EDG 3.0 allows that syntax. Therefore, we do as well. */ if (qualifying_scope && TYPE_P (qualifying_scope)) qualifying_scope = TYPE_MAIN_VARIANT (qualifying_scope); gcc_assert (TREE_CODE (unqualified_name) == IDENTIFIER_NODE || TREE_CODE (unqualified_name) == BIT_NOT_EXPR || TREE_CODE (unqualified_name) == TEMPLATE_ID_EXPR); declarator = make_declarator (cdk_id); declarator->u.id.qualifying_scope = qualifying_scope; declarator->u.id.unqualified_name = unqualified_name; declarator->u.id.sfk = sfk; return declarator; } /* Make a declarator for a pointer to TARGET. CV_QUALIFIERS is a list of modifiers such as const or volatile to apply to the pointer type, represented as identifiers. */ cp_declarator * make_pointer_declarator (cp_cv_quals cv_qualifiers, cp_declarator *target) { cp_declarator *declarator; declarator = make_declarator (cdk_pointer); declarator->declarator = target; declarator->u.pointer.qualifiers = cv_qualifiers; declarator->u.pointer.class_type = NULL_TREE; return declarator; } /* Like make_pointer_declarator -- but for references. */ cp_declarator * make_reference_declarator (cp_cv_quals cv_qualifiers, cp_declarator *target) { cp_declarator *declarator; declarator = make_declarator (cdk_reference); declarator->declarator = target; declarator->u.pointer.qualifiers = cv_qualifiers; declarator->u.pointer.class_type = NULL_TREE; return declarator; } /* Like make_pointer_declarator -- but for a pointer to a non-static member of CLASS_TYPE. */ cp_declarator * make_ptrmem_declarator (cp_cv_quals cv_qualifiers, tree class_type, cp_declarator *pointee) { cp_declarator *declarator; declarator = make_declarator (cdk_ptrmem); declarator->declarator = pointee; declarator->u.pointer.qualifiers = cv_qualifiers; declarator->u.pointer.class_type = class_type; return declarator; } /* Make a declarator for the function given by TARGET, with the indicated PARMS. The CV_QUALIFIERS aply to the function, as in "const"-qualified member function. The EXCEPTION_SPECIFICATION indicates what exceptions can be thrown. */ cp_declarator * make_call_declarator (cp_declarator *target, cp_parameter_declarator *parms, cp_cv_quals cv_qualifiers, tree exception_specification) { cp_declarator *declarator; declarator = make_declarator (cdk_function); declarator->declarator = target; declarator->u.function.parameters = parms; declarator->u.function.qualifiers = cv_qualifiers; declarator->u.function.exception_specification = exception_specification; return declarator; } /* Make a declarator for an array of BOUNDS elements, each of which is defined by ELEMENT. */ cp_declarator * make_array_declarator (cp_declarator *element, tree bounds) { cp_declarator *declarator; declarator = make_declarator (cdk_array); declarator->declarator = element; declarator->u.array.bounds = bounds; return declarator; } cp_parameter_declarator *no_parameters; /* Create a parameter declarator with the indicated DECL_SPECIFIERS, DECLARATOR and DEFAULT_ARGUMENT. */ cp_parameter_declarator * make_parameter_declarator (cp_decl_specifier_seq *decl_specifiers, cp_declarator *declarator, tree default_argument) { cp_parameter_declarator *parameter; parameter = ((cp_parameter_declarator *) alloc_declarator (sizeof (cp_parameter_declarator))); parameter->next = NULL; if (decl_specifiers) parameter->decl_specifiers = *decl_specifiers; else clear_decl_specs (&parameter->decl_specifiers); parameter->declarator = declarator; parameter->default_argument = default_argument; parameter->ellipsis_p = false; return parameter; } /* Returns true iff DECLARATOR is a declaration for a function. */ static bool function_declarator_p (const cp_declarator *declarator) { while (declarator) { if (declarator->kind == cdk_function && declarator->declarator->kind == cdk_id) return true; if (declarator->kind == cdk_id || declarator->kind == cdk_error) return false; declarator = declarator->declarator; } return false; } /* The parser. */ /* Overview -------- A cp_parser parses the token stream as specified by the C++ grammar. Its job is purely parsing, not semantic analysis. For example, the parser breaks the token stream into declarators, expressions, statements, and other similar syntactic constructs. It does not check that the types of the expressions on either side of an assignment-statement are compatible, or that a function is not declared with a parameter of type `void'. The parser invokes routines elsewhere in the compiler to perform semantic analysis and to build up the abstract syntax tree for the code processed. The parser (and the template instantiation code, which is, in a way, a close relative of parsing) are the only parts of the compiler that should be calling push_scope and pop_scope, or related functions. The parser (and template instantiation code) keeps track of what scope is presently active; everything else should simply honor that. (The code that generates static initializers may also need to set the scope, in order to check access control correctly when emitting the initializers.) Methodology ----------- The parser is of the standard recursive-descent variety. Upcoming tokens in the token stream are examined in order to determine which production to use when parsing a non-terminal. Some C++ constructs require arbitrary look ahead to disambiguate. For example, it is impossible, in the general case, to tell whether a statement is an expression or declaration without scanning the entire statement. Therefore, the parser is capable of "parsing tentatively." When the parser is not sure what construct comes next, it enters this mode. Then, while we attempt to parse the construct, the parser queues up error messages, rather than issuing them immediately, and saves the tokens it consumes. If the construct is parsed successfully, the parser "commits", i.e., it issues any queued error messages and the tokens that were being preserved are permanently discarded. If, however, the construct is not parsed successfully, the parser rolls back its state completely so that it can resume parsing using a different alternative. Future Improvements ------------------- The performance of the parser could probably be improved substantially. We could often eliminate the need to parse tentatively by looking ahead a little bit. In some places, this approach might not entirely eliminate the need to parse tentatively, but it might still speed up the average case. */ /* Flags that are passed to some parsing functions. These values can be bitwise-ored together. */ typedef enum cp_parser_flags { /* No flags. */ CP_PARSER_FLAGS_NONE = 0x0, /* The construct is optional. If it is not present, then no error should be issued. */ CP_PARSER_FLAGS_OPTIONAL = 0x1, /* When parsing a type-specifier, do not allow user-defined types. */ CP_PARSER_FLAGS_NO_USER_DEFINED_TYPES = 0x2 } cp_parser_flags; /* The different kinds of declarators we want to parse. */ typedef enum cp_parser_declarator_kind { /* We want an abstract declarator. */ CP_PARSER_DECLARATOR_ABSTRACT, /* We want a named declarator. */ CP_PARSER_DECLARATOR_NAMED, /* We don't mind, but the name must be an unqualified-id. */ CP_PARSER_DECLARATOR_EITHER } cp_parser_declarator_kind; /* The precedence values used to parse binary expressions. The minimum value of PREC must be 1, because zero is reserved to quickly discriminate binary operators from other tokens. */ enum cp_parser_prec { PREC_NOT_OPERATOR, PREC_LOGICAL_OR_EXPRESSION, PREC_LOGICAL_AND_EXPRESSION, PREC_INCLUSIVE_OR_EXPRESSION, PREC_EXCLUSIVE_OR_EXPRESSION, PREC_AND_EXPRESSION, PREC_EQUALITY_EXPRESSION, PREC_RELATIONAL_EXPRESSION, PREC_SHIFT_EXPRESSION, PREC_ADDITIVE_EXPRESSION, PREC_MULTIPLICATIVE_EXPRESSION, PREC_PM_EXPRESSION, NUM_PREC_VALUES = PREC_PM_EXPRESSION }; /* A mapping from a token type to a corresponding tree node type, with a precedence value. */ typedef struct cp_parser_binary_operations_map_node { /* The token type. */ enum cpp_ttype token_type; /* The corresponding tree code. */ enum tree_code tree_type; /* The precedence of this operator. */ enum cp_parser_prec prec; } cp_parser_binary_operations_map_node; /* The status of a tentative parse. */ typedef enum cp_parser_status_kind { /* No errors have occurred. */ CP_PARSER_STATUS_KIND_NO_ERROR, /* An error has occurred. */ CP_PARSER_STATUS_KIND_ERROR, /* We are committed to this tentative parse, whether or not an error has occurred. */ CP_PARSER_STATUS_KIND_COMMITTED } cp_parser_status_kind; typedef struct cp_parser_expression_stack_entry { tree lhs; enum tree_code tree_type; int prec; } cp_parser_expression_stack_entry; /* The stack for storing partial expressions. We only need NUM_PREC_VALUES entries because precedence levels on the stack are monotonically increasing. */ typedef struct cp_parser_expression_stack_entry cp_parser_expression_stack[NUM_PREC_VALUES]; /* Context that is saved and restored when parsing tentatively. */ typedef struct cp_parser_context GTY (()) { /* If this is a tentative parsing context, the status of the tentative parse. */ enum cp_parser_status_kind status; /* If non-NULL, we have just seen a `x->' or `x.' expression. Names that are looked up in this context must be looked up both in the scope given by OBJECT_TYPE (the type of `x' or `*x') and also in the context of the containing expression. */ tree object_type; /* The next parsing context in the stack. */ struct cp_parser_context *next; } cp_parser_context; /* Prototypes. */ /* Constructors and destructors. */ static cp_parser_context *cp_parser_context_new (cp_parser_context *); /* Class variables. */ static GTY((deletable)) cp_parser_context* cp_parser_context_free_list; /* The operator-precedence table used by cp_parser_binary_expression. Transformed into an associative array (binops_by_token) by cp_parser_new. */ static const cp_parser_binary_operations_map_node binops[] = { { CPP_DEREF_STAR, MEMBER_REF, PREC_PM_EXPRESSION }, { CPP_DOT_STAR, DOTSTAR_EXPR, PREC_PM_EXPRESSION }, { CPP_MULT, MULT_EXPR, PREC_MULTIPLICATIVE_EXPRESSION }, { CPP_DIV, TRUNC_DIV_EXPR, PREC_MULTIPLICATIVE_EXPRESSION }, { CPP_MOD, TRUNC_MOD_EXPR, PREC_MULTIPLICATIVE_EXPRESSION }, { CPP_PLUS, PLUS_EXPR, PREC_ADDITIVE_EXPRESSION }, { CPP_MINUS, MINUS_EXPR, PREC_ADDITIVE_EXPRESSION }, { CPP_LSHIFT, LSHIFT_EXPR, PREC_SHIFT_EXPRESSION }, { CPP_RSHIFT, RSHIFT_EXPR, PREC_SHIFT_EXPRESSION }, { CPP_LESS, LT_EXPR, PREC_RELATIONAL_EXPRESSION }, { CPP_GREATER, GT_EXPR, PREC_RELATIONAL_EXPRESSION }, { CPP_LESS_EQ, LE_EXPR, PREC_RELATIONAL_EXPRESSION }, { CPP_GREATER_EQ, GE_EXPR, PREC_RELATIONAL_EXPRESSION }, { CPP_EQ_EQ, EQ_EXPR, PREC_EQUALITY_EXPRESSION }, { CPP_NOT_EQ, NE_EXPR, PREC_EQUALITY_EXPRESSION }, { CPP_AND, BIT_AND_EXPR, PREC_AND_EXPRESSION }, { CPP_XOR, BIT_XOR_EXPR, PREC_EXCLUSIVE_OR_EXPRESSION }, { CPP_OR, BIT_IOR_EXPR, PREC_INCLUSIVE_OR_EXPRESSION }, { CPP_AND_AND, TRUTH_ANDIF_EXPR, PREC_LOGICAL_AND_EXPRESSION }, { CPP_OR_OR, TRUTH_ORIF_EXPR, PREC_LOGICAL_OR_EXPRESSION } }; /* The same as binops, but initialized by cp_parser_new so that binops_by_token[N].token_type == N. Used in cp_parser_binary_expression for speed. */ static cp_parser_binary_operations_map_node binops_by_token[N_CP_TTYPES]; /* Constructors and destructors. */ /* Construct a new context. The context below this one on the stack is given by NEXT. */ static cp_parser_context * cp_parser_context_new (cp_parser_context* next) { cp_parser_context *context; /* Allocate the storage. */ if (cp_parser_context_free_list != NULL) { /* Pull the first entry from the free list. */ context = cp_parser_context_free_list; cp_parser_context_free_list = context->next; memset (context, 0, sizeof (*context)); } else context = GGC_CNEW (cp_parser_context); /* No errors have occurred yet in this context. */ context->status = CP_PARSER_STATUS_KIND_NO_ERROR; /* If this is not the bottomost context, copy information that we need from the previous context. */ if (next) { /* If, in the NEXT context, we are parsing an `x->' or `x.' expression, then we are parsing one in this context, too. */ context->object_type = next->object_type; /* Thread the stack. */ context->next = next; } return context; } /* The cp_parser structure represents the C++ parser. */ typedef struct cp_parser GTY(()) { /* The lexer from which we are obtaining tokens. */ cp_lexer *lexer; /* The scope in which names should be looked up. If NULL_TREE, then we look up names in the scope that is currently open in the source program. If non-NULL, this is either a TYPE or NAMESPACE_DECL for the scope in which we should look. It can also be ERROR_MARK, when we've parsed a bogus scope. This value is not cleared automatically after a name is looked up, so we must be careful to clear it before starting a new look up sequence. (If it is not cleared, then `X::Y' followed by `Z' will look up `Z' in the scope of `X', rather than the current scope.) Unfortunately, it is difficult to tell when name lookup is complete, because we sometimes peek at a token, look it up, and then decide not to consume it. */ tree scope; /* OBJECT_SCOPE and QUALIFYING_SCOPE give the scopes in which the last lookup took place. OBJECT_SCOPE is used if an expression like "x->y" or "x.y" was used; it gives the type of "*x" or "x", respectively. QUALIFYING_SCOPE is used for an expression of the form "X::Y"; it refers to X. */ tree object_scope; tree qualifying_scope; /* A stack of parsing contexts. All but the bottom entry on the stack will be tentative contexts. We parse tentatively in order to determine which construct is in use in some situations. For example, in order to determine whether a statement is an expression-statement or a declaration-statement we parse it tentatively as a declaration-statement. If that fails, we then reparse the same token stream as an expression-statement. */ cp_parser_context *context; /* True if we are parsing GNU C++. If this flag is not set, then GNU extensions are not recognized. */ bool allow_gnu_extensions_p; /* TRUE if the `>' token should be interpreted as the greater-than operator. FALSE if it is the end of a template-id or template-parameter-list. */ bool greater_than_is_operator_p; /* TRUE if default arguments are allowed within a parameter list that starts at this point. FALSE if only a gnu extension makes them permissible. */ bool default_arg_ok_p; /* TRUE if we are parsing an integral constant-expression. See [expr.const] for a precise definition. */ bool integral_constant_expression_p; /* TRUE if we are parsing an integral constant-expression -- but a non-constant expression should be permitted as well. This flag is used when parsing an array bound so that GNU variable-length arrays are tolerated. */ bool allow_non_integral_constant_expression_p; /* TRUE if ALLOW_NON_CONSTANT_EXPRESSION_P is TRUE and something has been seen that makes the expression non-constant. */ bool non_integral_constant_expression_p; /* TRUE if local variable names and `this' are forbidden in the current context. */ bool local_variables_forbidden_p; /* TRUE if the declaration we are parsing is part of a linkage-specification of the form `extern string-literal declaration'. */ bool in_unbraced_linkage_specification_p; /* TRUE if we are presently parsing a declarator, after the direct-declarator. */ bool in_declarator_p; /* TRUE if we are presently parsing a template-argument-list. */ bool in_template_argument_list_p; /* Set to IN_ITERATION_STMT if parsing an iteration-statement, to IN_OMP_BLOCK if parsing OpenMP structured block and IN_OMP_FOR if parsing OpenMP loop. If parsing a switch statement, this is bitwise ORed with IN_SWITCH_STMT, unless parsing an iteration-statement, OpenMP block or loop within that switch. */ #define IN_SWITCH_STMT 1 #define IN_ITERATION_STMT 2 #define IN_OMP_BLOCK 4 #define IN_OMP_FOR 8 unsigned char in_statement; /* TRUE if we are presently parsing the body of a switch statement. Note that this doesn't quite overlap with in_statement above. The difference relates to giving the right sets of error messages: "case not in switch" vs "break statement used with OpenMP...". */ bool in_switch_statement_p; /* TRUE if we are parsing a type-id in an expression context. In such a situation, both "type (expr)" and "type (type)" are valid alternatives. */ bool in_type_id_in_expr_p; /* TRUE if we are currently in a header file where declarations are implicitly extern "C". */ bool implicit_extern_c; /* TRUE if strings in expressions should be translated to the execution character set. */ bool translate_strings_p; /* TRUE if we are presently parsing the body of a function, but not a local class. */ bool in_function_body; /* If non-NULL, then we are parsing a construct where new type definitions are not permitted. The string stored here will be issued as an error message if a type is defined. */ const char *type_definition_forbidden_message; /* A list of lists. The outer list is a stack, used for member functions of local classes. At each level there are two sub-list, one on TREE_VALUE and one on TREE_PURPOSE. Each of those sub-lists has a FUNCTION_DECL or TEMPLATE_DECL on their TREE_VALUE's. The functions are chained in reverse declaration order. The TREE_PURPOSE sublist contains those functions with default arguments that need post processing, and the TREE_VALUE sublist contains those functions with definitions that need post processing. These lists can only be processed once the outermost class being defined is complete. */ tree unparsed_functions_queues; /* The number of classes whose definitions are currently in progress. */ unsigned num_classes_being_defined; /* The number of template parameter lists that apply directly to the current declaration. */ unsigned num_template_parameter_lists; } cp_parser; /* Prototypes. */ /* Constructors and destructors. */ static cp_parser *cp_parser_new (void); /* Routines to parse various constructs. Those that return `tree' will return the error_mark_node (rather than NULL_TREE) if a parse error occurs, unless otherwise noted. Sometimes, they will return an ordinary node if error-recovery was attempted, even though a parse error occurred. So, to check whether or not a parse error occurred, you should always use cp_parser_error_occurred. If the construct is optional (indicated either by an `_opt' in the name of the function that does the parsing or via a FLAGS parameter), then NULL_TREE is returned if the construct is not present. */ /* Lexical conventions [gram.lex] */ static tree cp_parser_identifier (cp_parser *); static tree cp_parser_string_literal (cp_parser *, bool, bool); /* Basic concepts [gram.basic] */ static bool cp_parser_translation_unit (cp_parser *); /* Expressions [gram.expr] */ static tree cp_parser_primary_expression (cp_parser *, bool, bool, bool, cp_id_kind *); static tree cp_parser_id_expression (cp_parser *, bool, bool, bool *, bool, bool); static tree cp_parser_unqualified_id (cp_parser *, bool, bool, bool, bool); static tree cp_parser_nested_name_specifier_opt (cp_parser *, bool, bool, bool, bool); static tree cp_parser_nested_name_specifier (cp_parser *, bool, bool, bool, bool); static tree cp_parser_class_or_namespace_name (cp_parser *, bool, bool, bool, bool, bool); static tree cp_parser_postfix_expression (cp_parser *, bool, bool); static tree cp_parser_postfix_open_square_expression (cp_parser *, tree, bool); static tree cp_parser_postfix_dot_deref_expression (cp_parser *, enum cpp_ttype, tree, bool, cp_id_kind *); static tree cp_parser_parenthesized_expression_list (cp_parser *, bool, bool, bool *); static void cp_parser_pseudo_destructor_name (cp_parser *, tree *, tree *); static tree cp_parser_unary_expression (cp_parser *, bool, bool); static enum tree_code cp_parser_unary_operator (cp_token *); static tree cp_parser_new_expression (cp_parser *); static tree cp_parser_new_placement (cp_parser *); static tree cp_parser_new_type_id (cp_parser *, tree *); static cp_declarator *cp_parser_new_declarator_opt (cp_parser *); static cp_declarator *cp_parser_direct_new_declarator (cp_parser *); static tree cp_parser_new_initializer (cp_parser *); static tree cp_parser_delete_expression (cp_parser *); static tree cp_parser_cast_expression (cp_parser *, bool, bool); static tree cp_parser_binary_expression (cp_parser *, bool); static tree cp_parser_question_colon_clause (cp_parser *, tree); static tree cp_parser_assignment_expression (cp_parser *, bool); static enum tree_code cp_parser_assignment_operator_opt (cp_parser *); static tree cp_parser_expression (cp_parser *, bool); static tree cp_parser_constant_expression (cp_parser *, bool, bool *); static tree cp_parser_builtin_offsetof (cp_parser *); /* Statements [gram.stmt.stmt] */ static void cp_parser_statement (cp_parser *, tree, bool); static void cp_parser_label_for_labeled_statement (cp_parser *); static tree cp_parser_expression_statement (cp_parser *, tree); static tree cp_parser_compound_statement (cp_parser *, tree, bool); static void cp_parser_statement_seq_opt (cp_parser *, tree); static tree cp_parser_selection_statement (cp_parser *); static tree cp_parser_condition (cp_parser *); static tree cp_parser_iteration_statement (cp_parser *); static void cp_parser_for_init_statement (cp_parser *); static tree cp_parser_jump_statement (cp_parser *); static void cp_parser_declaration_statement (cp_parser *); static tree cp_parser_implicitly_scoped_statement (cp_parser *); static void cp_parser_already_scoped_statement (cp_parser *); /* Declarations [gram.dcl.dcl] */ static void cp_parser_declaration_seq_opt (cp_parser *); static void cp_parser_declaration (cp_parser *); static void cp_parser_block_declaration (cp_parser *, bool); static void cp_parser_simple_declaration (cp_parser *, bool); static void cp_parser_decl_specifier_seq (cp_parser *, cp_parser_flags, cp_decl_specifier_seq *, int *); static tree cp_parser_storage_class_specifier_opt (cp_parser *); static tree cp_parser_function_specifier_opt (cp_parser *, cp_decl_specifier_seq *); static tree cp_parser_type_specifier (cp_parser *, cp_parser_flags, cp_decl_specifier_seq *, bool, int *, bool *); static tree cp_parser_simple_type_specifier (cp_parser *, cp_decl_specifier_seq *, cp_parser_flags); static tree cp_parser_type_name (cp_parser *); static tree cp_parser_elaborated_type_specifier (cp_parser *, bool, bool); static tree cp_parser_enum_specifier (cp_parser *); static void cp_parser_enumerator_list (cp_parser *, tree); static void cp_parser_enumerator_definition (cp_parser *, tree); static tree cp_parser_namespace_name (cp_parser *); static void cp_parser_namespace_definition (cp_parser *); static void cp_parser_namespace_body (cp_parser *); static tree cp_parser_qualified_namespace_specifier (cp_parser *); static void cp_parser_namespace_alias_definition (cp_parser *); static bool cp_parser_using_declaration (cp_parser *, bool); static void cp_parser_using_directive (cp_parser *); static void cp_parser_asm_definition (cp_parser *); static void cp_parser_linkage_specification (cp_parser *); /* Declarators [gram.dcl.decl] */ static tree cp_parser_init_declarator (cp_parser *, cp_decl_specifier_seq *, VEC (deferred_access_check,gc)*, bool, bool, int, bool *); static cp_declarator *cp_parser_declarator (cp_parser *, cp_parser_declarator_kind, int *, bool *, bool); static cp_declarator *cp_parser_direct_declarator (cp_parser *, cp_parser_declarator_kind, int *, bool); static enum tree_code cp_parser_ptr_operator (cp_parser *, tree *, cp_cv_quals *); static cp_cv_quals cp_parser_cv_qualifier_seq_opt (cp_parser *); static tree cp_parser_declarator_id (cp_parser *, bool); static tree cp_parser_type_id (cp_parser *); static void cp_parser_type_specifier_seq (cp_parser *, bool, cp_decl_specifier_seq *); static cp_parameter_declarator *cp_parser_parameter_declaration_clause (cp_parser *); static cp_parameter_declarator *cp_parser_parameter_declaration_list (cp_parser *, bool *); static cp_parameter_declarator *cp_parser_parameter_declaration (cp_parser *, bool, bool *); static void cp_parser_function_body (cp_parser *); static tree cp_parser_initializer (cp_parser *, bool *, bool *); static tree cp_parser_initializer_clause (cp_parser *, bool *); static VEC(constructor_elt,gc) *cp_parser_initializer_list (cp_parser *, bool *); static bool cp_parser_ctor_initializer_opt_and_function_body (cp_parser *); /* Classes [gram.class] */ static tree cp_parser_class_name (cp_parser *, bool, bool, enum tag_types, bool, bool, bool); static tree cp_parser_class_specifier (cp_parser *); static tree cp_parser_class_head (cp_parser *, bool *, tree *, tree *); static enum tag_types cp_parser_class_key (cp_parser *); static void cp_parser_member_specification_opt (cp_parser *); static void cp_parser_member_declaration (cp_parser *); static tree cp_parser_pure_specifier (cp_parser *); static tree cp_parser_constant_initializer (cp_parser *); /* Derived classes [gram.class.derived] */ static tree cp_parser_base_clause (cp_parser *); static tree cp_parser_base_specifier (cp_parser *); /* Special member functions [gram.special] */ static tree cp_parser_conversion_function_id (cp_parser *); static tree cp_parser_conversion_type_id (cp_parser *); static cp_declarator *cp_parser_conversion_declarator_opt (cp_parser *); static bool cp_parser_ctor_initializer_opt (cp_parser *); static void cp_parser_mem_initializer_list (cp_parser *); static tree cp_parser_mem_initializer (cp_parser *); static tree cp_parser_mem_initializer_id (cp_parser *); /* Overloading [gram.over] */ static tree cp_parser_operator_function_id (cp_parser *); static tree cp_parser_operator (cp_parser *); /* Templates [gram.temp] */ static void cp_parser_template_declaration (cp_parser *, bool); static tree cp_parser_template_parameter_list (cp_parser *); static tree cp_parser_template_parameter (cp_parser *, bool *); static tree cp_parser_type_parameter (cp_parser *); static tree cp_parser_template_id (cp_parser *, bool, bool, bool); static tree cp_parser_template_name (cp_parser *, bool, bool, bool, bool *); static tree cp_parser_template_argument_list (cp_parser *); static tree cp_parser_template_argument (cp_parser *); static void cp_parser_explicit_instantiation (cp_parser *); static void cp_parser_explicit_specialization (cp_parser *); /* Exception handling [gram.exception] */ static tree cp_parser_try_block (cp_parser *); static bool cp_parser_function_try_block (cp_parser *); static void cp_parser_handler_seq (cp_parser *); static void cp_parser_handler (cp_parser *); static tree cp_parser_exception_declaration (cp_parser *); static tree cp_parser_throw_expression (cp_parser *); static tree cp_parser_exception_specification_opt (cp_parser *); static tree cp_parser_type_id_list (cp_parser *); /* GNU Extensions */ static tree cp_parser_asm_specification_opt (cp_parser *); static tree cp_parser_asm_operand_list (cp_parser *); static tree cp_parser_asm_clobber_list (cp_parser *); static tree cp_parser_attributes_opt (cp_parser *); static tree cp_parser_attribute_list (cp_parser *); static bool cp_parser_extension_opt (cp_parser *, int *); static void cp_parser_label_declaration (cp_parser *); enum pragma_context { pragma_external, pragma_stmt, pragma_compound }; static bool cp_parser_pragma (cp_parser *, enum pragma_context); /* Objective-C++ Productions */ static tree cp_parser_objc_message_receiver (cp_parser *); static tree cp_parser_objc_message_args (cp_parser *); static tree cp_parser_objc_message_expression (cp_parser *); static tree cp_parser_objc_encode_expression (cp_parser *); static tree cp_parser_objc_defs_expression (cp_parser *); static tree cp_parser_objc_protocol_expression (cp_parser *); static tree cp_parser_objc_selector_expression (cp_parser *); static tree cp_parser_objc_expression (cp_parser *); static bool cp_parser_objc_selector_p (enum cpp_ttype); static tree cp_parser_objc_selector (cp_parser *); static tree cp_parser_objc_protocol_refs_opt (cp_parser *); static void cp_parser_objc_declaration (cp_parser *); static tree cp_parser_objc_statement (cp_parser *); /* Utility Routines */ static tree cp_parser_lookup_name (cp_parser *, tree, enum tag_types, bool, bool, bool, tree *); static tree cp_parser_lookup_name_simple (cp_parser *, tree); static tree cp_parser_maybe_treat_template_as_class (tree, bool); static bool cp_parser_check_declarator_template_parameters (cp_parser *, cp_declarator *); static bool cp_parser_check_template_parameters (cp_parser *, unsigned); static tree cp_parser_simple_cast_expression (cp_parser *); static tree cp_parser_global_scope_opt (cp_parser *, bool); static bool cp_parser_constructor_declarator_p (cp_parser *, bool); static tree cp_parser_function_definition_from_specifiers_and_declarator (cp_parser *, cp_decl_specifier_seq *, tree, const cp_declarator *); static tree cp_parser_function_definition_after_declarator (cp_parser *, bool); static void cp_parser_template_declaration_after_export (cp_parser *, bool); static void cp_parser_perform_template_parameter_access_checks (VEC (deferred_access_check,gc)*); static tree cp_parser_single_declaration (cp_parser *, VEC (deferred_access_check,gc)*, bool, bool *); static tree cp_parser_functional_cast (cp_parser *, tree); static tree cp_parser_save_member_function_body (cp_parser *, cp_decl_specifier_seq *, cp_declarator *, tree); static tree cp_parser_enclosed_template_argument_list (cp_parser *); static void cp_parser_save_default_args (cp_parser *, tree); static void cp_parser_late_parsing_for_member (cp_parser *, tree); static void cp_parser_late_parsing_default_args (cp_parser *, tree); static tree cp_parser_sizeof_operand (cp_parser *, enum rid); static bool cp_parser_declares_only_class_p (cp_parser *); static void cp_parser_set_storage_class (cp_parser *, cp_decl_specifier_seq *, enum rid); static void cp_parser_set_decl_spec_type (cp_decl_specifier_seq *, tree, bool); static bool cp_parser_friend_p (const cp_decl_specifier_seq *); static cp_token *cp_parser_require (cp_parser *, enum cpp_ttype, const char *); static cp_token *cp_parser_require_keyword (cp_parser *, enum rid, const char *); static bool cp_parser_token_starts_function_definition_p (cp_token *); static bool cp_parser_next_token_starts_class_definition_p (cp_parser *); static bool cp_parser_next_token_ends_template_argument_p (cp_parser *); static bool cp_parser_nth_token_starts_template_argument_list_p (cp_parser *, size_t); static enum tag_types cp_parser_token_is_class_key (cp_token *); static void cp_parser_check_class_key (enum tag_types, tree type); static void cp_parser_check_access_in_redeclaration (tree type); static bool cp_parser_optional_template_keyword (cp_parser *); static void cp_parser_pre_parsed_nested_name_specifier (cp_parser *); static void cp_parser_cache_group (cp_parser *, enum cpp_ttype, unsigned); static void cp_parser_parse_tentatively (cp_parser *); static void cp_parser_commit_to_tentative_parse (cp_parser *); static void cp_parser_abort_tentative_parse (cp_parser *); static bool cp_parser_parse_definitely (cp_parser *); static inline bool cp_parser_parsing_tentatively (cp_parser *); static bool cp_parser_uncommitted_to_tentative_parse_p (cp_parser *); static void cp_parser_error (cp_parser *, const char *); static void cp_parser_name_lookup_error (cp_parser *, tree, tree, const char *); static bool cp_parser_simulate_error (cp_parser *); static bool cp_parser_check_type_definition (cp_parser *); static void cp_parser_check_for_definition_in_return_type (cp_declarator *, tree); static void cp_parser_check_for_invalid_template_id (cp_parser *, tree); static bool cp_parser_non_integral_constant_expression (cp_parser *, const char *); static void cp_parser_diagnose_invalid_type_name (cp_parser *, tree, tree); static bool cp_parser_parse_and_diagnose_invalid_type_name (cp_parser *); static int cp_parser_skip_to_closing_parenthesis (cp_parser *, bool, bool, bool); static void cp_parser_skip_to_end_of_statement (cp_parser *); static void cp_parser_consume_semicolon_at_end_of_statement (cp_parser *); static void cp_parser_skip_to_end_of_block_or_statement (cp_parser *); static void cp_parser_skip_to_closing_brace (cp_parser *); static void cp_parser_skip_to_end_of_template_parameter_list (cp_parser *); static void cp_parser_skip_to_pragma_eol (cp_parser*, cp_token *); static bool cp_parser_error_occurred (cp_parser *); static bool cp_parser_allow_gnu_extensions_p (cp_parser *); static bool cp_parser_is_string_literal (cp_token *); static bool cp_parser_is_keyword (cp_token *, enum rid); static tree cp_parser_make_typename_type (cp_parser *, tree, tree); /* Returns nonzero if we are parsing tentatively. */ static inline bool cp_parser_parsing_tentatively (cp_parser* parser) { return parser->context->next != NULL; } /* Returns nonzero if TOKEN is a string literal. */ static bool cp_parser_is_string_literal (cp_token* token) { return (token->type == CPP_STRING || token->type == CPP_WSTRING); } /* Returns nonzero if TOKEN is the indicated KEYWORD. */ static bool cp_parser_is_keyword (cp_token* token, enum rid keyword) { return token->keyword == keyword; } /* If not parsing tentatively, issue a diagnostic of the form FILE:LINE: MESSAGE before TOKEN where TOKEN is the next token in the input stream. MESSAGE (specified by the caller) is usually of the form "expected OTHER-TOKEN". */ static void cp_parser_error (cp_parser* parser, const char* message) { if (!cp_parser_simulate_error (parser)) { cp_token *token = cp_lexer_peek_token (parser->lexer); /* This diagnostic makes more sense if it is tagged to the line of the token we just peeked at. */ cp_lexer_set_source_position_from_token (token); if (token->type == CPP_PRAGMA) { error ("%<#pragma%> is not allowed here"); cp_parser_skip_to_pragma_eol (parser, token); return; } c_parse_error (message, /* Because c_parser_error does not understand CPP_KEYWORD, keywords are treated like identifiers. */ (token->type == CPP_KEYWORD ? CPP_NAME : token->type), token->u.value); } } /* Issue an error about name-lookup failing. NAME is the IDENTIFIER_NODE DECL is the result of the lookup (as returned from cp_parser_lookup_name). DESIRED is the thing that we hoped to find. */ static void cp_parser_name_lookup_error (cp_parser* parser, tree name, tree decl, const char* desired) { /* If name lookup completely failed, tell the user that NAME was not declared. */ if (decl == error_mark_node) { if (parser->scope && parser->scope != global_namespace) error ("%<%D::%D%> has not been declared", parser->scope, name); else if (parser->scope == global_namespace) error ("%<::%D%> has not been declared", name); else if (parser->object_scope && !CLASS_TYPE_P (parser->object_scope)) error ("request for member %qD in non-class type %qT", name, parser->object_scope); else if (parser->object_scope) error ("%<%T::%D%> has not been declared", parser->object_scope, name); else error ("%qD has not been declared", name); } else if (parser->scope && parser->scope != global_namespace) error ("%<%D::%D%> %s", parser->scope, name, desired); else if (parser->scope == global_namespace) error ("%<::%D%> %s", name, desired); else error ("%qD %s", name, desired); } /* If we are parsing tentatively, remember that an error has occurred during this tentative parse. Returns true if the error was simulated; false if a message should be issued by the caller. */ static bool cp_parser_simulate_error (cp_parser* parser) { if (cp_parser_uncommitted_to_tentative_parse_p (parser)) { parser->context->status = CP_PARSER_STATUS_KIND_ERROR; return true; } return false; } /* Check for repeated decl-specifiers. */ static void cp_parser_check_decl_spec (cp_decl_specifier_seq *decl_specs) { cp_decl_spec ds; for (ds = ds_first; ds != ds_last; ++ds) { unsigned count = decl_specs->specs[(int)ds]; if (count < 2) continue; /* The "long" specifier is a special case because of "long long". */ if (ds == ds_long) { if (count > 2) error ("%<long long long%> is too long for GCC"); else if (pedantic && !in_system_header && warn_long_long) pedwarn ("ISO C++ does not support %<long long%>"); } else if (count > 1) { static const char *const decl_spec_names[] = { "signed", "unsigned", "short", "long", "const", "volatile", "restrict", "inline", "virtual", "explicit", "friend", "typedef", "__complex", "__thread" }; error ("duplicate %qs", decl_spec_names[(int)ds]); } } } /* This function is called when a type is defined. If type definitions are forbidden at this point, an error message is issued. */ static bool cp_parser_check_type_definition (cp_parser* parser) { /* If types are forbidden here, issue a message. */ if (parser->type_definition_forbidden_message) { /* Use `%s' to print the string in case there are any escape characters in the message. */ error ("%s", parser->type_definition_forbidden_message); return false; } return true; } /* This function is called when the DECLARATOR is processed. The TYPE was a type defined in the decl-specifiers. If it is invalid to define a type in the decl-specifiers for DECLARATOR, an error is issued. */ static void cp_parser_check_for_definition_in_return_type (cp_declarator *declarator, tree type) { /* [dcl.fct] forbids type definitions in return types. Unfortunately, it's not easy to know whether or not we are processing a return type until after the fact. */ while (declarator && (declarator->kind == cdk_pointer || declarator->kind == cdk_reference || declarator->kind == cdk_ptrmem)) declarator = declarator->declarator; if (declarator && declarator->kind == cdk_function) { error ("new types may not be defined in a return type"); inform ("(perhaps a semicolon is missing after the definition of %qT)", type); } } /* A type-specifier (TYPE) has been parsed which cannot be followed by "<" in any valid C++ program. If the next token is indeed "<", issue a message warning the user about what appears to be an invalid attempt to form a template-id. */ static void cp_parser_check_for_invalid_template_id (cp_parser* parser, tree type) { cp_token_position start = 0; if (cp_lexer_next_token_is (parser->lexer, CPP_LESS)) { if (TYPE_P (type)) error ("%qT is not a template", type); else if (TREE_CODE (type) == IDENTIFIER_NODE) error ("%qE is not a template", type); else error ("invalid template-id"); /* Remember the location of the invalid "<". */ if (cp_parser_uncommitted_to_tentative_parse_p (parser)) start = cp_lexer_token_position (parser->lexer, true); /* Consume the "<". */ cp_lexer_consume_token (parser->lexer); /* Parse the template arguments. */ cp_parser_enclosed_template_argument_list (parser); /* Permanently remove the invalid template arguments so that this error message is not issued again. */ if (start) cp_lexer_purge_tokens_after (parser->lexer, start); } } /* If parsing an integral constant-expression, issue an error message about the fact that THING appeared and return true. Otherwise, return false. In either case, set PARSER->NON_INTEGRAL_CONSTANT_EXPRESSION_P. */ static bool cp_parser_non_integral_constant_expression (cp_parser *parser, const char *thing) { parser->non_integral_constant_expression_p = true; if (parser->integral_constant_expression_p) { if (!parser->allow_non_integral_constant_expression_p) { error ("%s cannot appear in a constant-expression", thing); return true; } } return false; } /* Emit a diagnostic for an invalid type name. SCOPE is the qualifying scope (or NULL, if none) for ID. This function commits to the current active tentative parse, if any. (Otherwise, the problematic construct might be encountered again later, resulting in duplicate error messages.) */ static void cp_parser_diagnose_invalid_type_name (cp_parser *parser, tree scope, tree id) { tree decl, old_scope; /* Try to lookup the identifier. */ old_scope = parser->scope; parser->scope = scope; decl = cp_parser_lookup_name_simple (parser, id); parser->scope = old_scope; /* If the lookup found a template-name, it means that the user forgot to specify an argument list. Emit a useful error message. */ if (TREE_CODE (decl) == TEMPLATE_DECL) error ("invalid use of template-name %qE without an argument list", decl); else if (TREE_CODE (id) == BIT_NOT_EXPR) error ("invalid use of destructor %qD as a type", id); else if (TREE_CODE (decl) == TYPE_DECL) /* Something like 'unsigned A a;' */ error ("invalid combination of multiple type-specifiers"); else if (!parser->scope) { /* Issue an error message. */ error ("%qE does not name a type", id); /* If we're in a template class, it's possible that the user was referring to a type from a base class. For example: template <typename T> struct A { typedef T X; }; template <typename T> struct B : public A<T> { X x; }; The user should have said "typename A<T>::X". */ if (processing_template_decl && current_class_type && TYPE_BINFO (current_class_type)) { tree b; for (b = TREE_CHAIN (TYPE_BINFO (current_class_type)); b; b = TREE_CHAIN (b)) { tree base_type = BINFO_TYPE (b); if (CLASS_TYPE_P (base_type) && dependent_type_p (base_type)) { tree field; /* Go from a particular instantiation of the template (which will have an empty TYPE_FIELDs), to the main version. */ base_type = CLASSTYPE_PRIMARY_TEMPLATE_TYPE (base_type); for (field = TYPE_FIELDS (base_type); field; field = TREE_CHAIN (field)) if (TREE_CODE (field) == TYPE_DECL && DECL_NAME (field) == id) { inform ("(perhaps %<typename %T::%E%> was intended)", BINFO_TYPE (b), id); break; } if (field) break; } } } } /* Here we diagnose qualified-ids where the scope is actually correct, but the identifier does not resolve to a valid type name. */ else if (parser->scope != error_mark_node) { if (TREE_CODE (parser->scope) == NAMESPACE_DECL) error ("%qE in namespace %qE does not name a type", id, parser->scope); else if (TYPE_P (parser->scope)) error ("%qE in class %qT does not name a type", id, parser->scope); else gcc_unreachable (); } cp_parser_commit_to_tentative_parse (parser); } /* Check for a common situation where a type-name should be present, but is not, and issue a sensible error message. Returns true if an invalid type-name was detected. The situation handled by this function are variable declarations of the form `ID a', where `ID' is an id-expression and `a' is a plain identifier. Usually, `ID' should name a type, but if we got here it means that it does not. We try to emit the best possible error message depending on how exactly the id-expression looks like. */ static bool cp_parser_parse_and_diagnose_invalid_type_name (cp_parser *parser) { tree id; cp_parser_parse_tentatively (parser); id = cp_parser_id_expression (parser, /*template_keyword_p=*/false, /*check_dependency_p=*/true, /*template_p=*/NULL, /*declarator_p=*/true, /*optional_p=*/false); /* After the id-expression, there should be a plain identifier, otherwise this is not a simple variable declaration. Also, if the scope is dependent, we cannot do much. */ if (!cp_lexer_next_token_is (parser->lexer, CPP_NAME) || (parser->scope && TYPE_P (parser->scope) && dependent_type_p (parser->scope)) || TREE_CODE (id) == TYPE_DECL) { cp_parser_abort_tentative_parse (parser); return false; } if (!cp_parser_parse_definitely (parser)) return false; /* Emit a diagnostic for the invalid type. */ cp_parser_diagnose_invalid_type_name (parser, parser->scope, id); /* Skip to the end of the declaration; there's no point in trying to process it. */ cp_parser_skip_to_end_of_block_or_statement (parser); return true; } /* Consume tokens up to, and including, the next non-nested closing `)'. Returns 1 iff we found a closing `)'. RECOVERING is true, if we are doing error recovery. Returns -1 if OR_COMMA is true and we found an unnested comma. */ static int cp_parser_skip_to_closing_parenthesis (cp_parser *parser, bool recovering, bool or_comma, bool consume_paren) { unsigned paren_depth = 0; unsigned brace_depth = 0; if (recovering && !or_comma && cp_parser_uncommitted_to_tentative_parse_p (parser)) return 0; while (true) { cp_token * token = cp_lexer_peek_token (parser->lexer); switch (token->type) { case CPP_EOF: case CPP_PRAGMA_EOL: /* If we've run out of tokens, then there is no closing `)'. */ return 0; case CPP_SEMICOLON: /* This matches the processing in skip_to_end_of_statement. */ if (!brace_depth) return 0; break; case CPP_OPEN_BRACE: ++brace_depth; break; case CPP_CLOSE_BRACE: if (!brace_depth--) return 0; break; case CPP_COMMA: if (recovering && or_comma && !brace_depth && !paren_depth) return -1; break; case CPP_OPEN_PAREN: if (!brace_depth) ++paren_depth; break; case CPP_CLOSE_PAREN: if (!brace_depth && !paren_depth--) { if (consume_paren) cp_lexer_consume_token (parser->lexer); return 1; } break; default: break; } /* Consume the token. */ cp_lexer_consume_token (parser->lexer); } } /* Consume tokens until we reach the end of the current statement. Normally, that will be just before consuming a `;'. However, if a non-nested `}' comes first, then we stop before consuming that. */ static void cp_parser_skip_to_end_of_statement (cp_parser* parser) { unsigned nesting_depth = 0; while (true) { cp_token *token = cp_lexer_peek_token (parser->lexer); switch (token->type) { case CPP_EOF: case CPP_PRAGMA_EOL: /* If we've run out of tokens, stop. */ return; case CPP_SEMICOLON: /* If the next token is a `;', we have reached the end of the statement. */ if (!nesting_depth) return; break; case CPP_CLOSE_BRACE: /* If this is a non-nested '}', stop before consuming it. That way, when confronted with something like: { 3 + } we stop before consuming the closing '}', even though we have not yet reached a `;'. */ if (nesting_depth == 0) return; /* If it is the closing '}' for a block that we have scanned, stop -- but only after consuming the token. That way given: void f g () { ... } typedef int I; we will stop after the body of the erroneously declared function, but before consuming the following `typedef' declaration. */ if (--nesting_depth == 0) { cp_lexer_consume_token (parser->lexer); return; } case CPP_OPEN_BRACE: ++nesting_depth; break; default: break; } /* Consume the token. */ cp_lexer_consume_token (parser->lexer); } } /* This function is called at the end of a statement or declaration. If the next token is a semicolon, it is consumed; otherwise, error recovery is attempted. */ static void cp_parser_consume_semicolon_at_end_of_statement (cp_parser *parser) { /* Look for the trailing `;'. */ if (!cp_parser_require (parser, CPP_SEMICOLON, "`;'")) { /* If there is additional (erroneous) input, skip to the end of the statement. */ cp_parser_skip_to_end_of_statement (parser); /* If the next token is now a `;', consume it. */ if (cp_lexer_next_token_is (parser->lexer, CPP_SEMICOLON)) cp_lexer_consume_token (parser->lexer); } } /* Skip tokens until we have consumed an entire block, or until we have consumed a non-nested `;'. */ static void cp_parser_skip_to_end_of_block_or_statement (cp_parser* parser) { int nesting_depth = 0; while (nesting_depth >= 0) { cp_token *token = cp_lexer_peek_token (parser->lexer); switch (token->type) { case CPP_EOF: case CPP_PRAGMA_EOL: /* If we've run out of tokens, stop. */ return; case CPP_SEMICOLON: /* Stop if this is an unnested ';'. */ if (!nesting_depth) nesting_depth = -1; break; case CPP_CLOSE_BRACE: /* Stop if this is an unnested '}', or closes the outermost nesting level. */ nesting_depth--; if (!nesting_depth) nesting_depth = -1; break; case CPP_OPEN_BRACE: /* Nest. */ nesting_depth++; break; default: break; } /* Consume the token. */ cp_lexer_consume_token (parser->lexer); } } /* Skip tokens until a non-nested closing curly brace is the next token. */ static void cp_parser_skip_to_closing_brace (cp_parser *parser) { unsigned nesting_depth = 0; while (true) { cp_token *token = cp_lexer_peek_token (parser->lexer); switch (token->type) { case CPP_EOF: case CPP_PRAGMA_EOL: /* If we've run out of tokens, stop. */ return; case CPP_CLOSE_BRACE: /* If the next token is a non-nested `}', then we have reached the end of the current block. */ if (nesting_depth-- == 0) return; break; case CPP_OPEN_BRACE: /* If it the next token is a `{', then we are entering a new block. Consume the entire block. */ ++nesting_depth; break; default: break; } /* Consume the token. */ cp_lexer_consume_token (parser->lexer); } } /* Consume tokens until we reach the end of the pragma. The PRAGMA_TOK parameter is the PRAGMA token, allowing us to purge the entire pragma sequence. */ static void cp_parser_skip_to_pragma_eol (cp_parser* parser, cp_token *pragma_tok) { cp_token *token; parser->lexer->in_pragma = false; do token = cp_lexer_consume_token (parser->lexer); while (token->type != CPP_PRAGMA_EOL && token->type != CPP_EOF); /* Ensure that the pragma is not parsed again. */ cp_lexer_purge_tokens_after (parser->lexer, pragma_tok); } /* Require pragma end of line, resyncing with it as necessary. The arguments are as for cp_parser_skip_to_pragma_eol. */ static void cp_parser_require_pragma_eol (cp_parser *parser, cp_token *pragma_tok) { parser->lexer->in_pragma = false; if (!cp_parser_require (parser, CPP_PRAGMA_EOL, "end of line")) cp_parser_skip_to_pragma_eol (parser, pragma_tok); } /* This is a simple wrapper around make_typename_type. When the id is an unresolved identifier node, we can provide a superior diagnostic using cp_parser_diagnose_invalid_type_name. */ static tree cp_parser_make_typename_type (cp_parser *parser, tree scope, tree id) { tree result; if (TREE_CODE (id) == IDENTIFIER_NODE) { result = make_typename_type (scope, id, typename_type, /*complain=*/tf_none); if (result == error_mark_node) cp_parser_diagnose_invalid_type_name (parser, scope, id); return result; } return make_typename_type (scope, id, typename_type, tf_error); } /* Create a new C++ parser. */ static cp_parser * cp_parser_new (void) { cp_parser *parser; cp_lexer *lexer; unsigned i; /* cp_lexer_new_main is called before calling ggc_alloc because cp_lexer_new_main might load a PCH file. */ lexer = cp_lexer_new_main (); /* Initialize the binops_by_token so that we can get the tree directly from the token. */ for (i = 0; i < sizeof (binops) / sizeof (binops[0]); i++) binops_by_token[binops[i].token_type] = binops[i]; parser = GGC_CNEW (cp_parser); parser->lexer = lexer; parser->context = cp_parser_context_new (NULL); /* For now, we always accept GNU extensions. */ parser->allow_gnu_extensions_p = 1; /* The `>' token is a greater-than operator, not the end of a template-id. */ parser->greater_than_is_operator_p = true; parser->default_arg_ok_p = true; /* We are not parsing a constant-expression. */ parser->integral_constant_expression_p = false; parser->allow_non_integral_constant_expression_p = false; parser->non_integral_constant_expression_p = false; /* Local variable names are not forbidden. */ parser->local_variables_forbidden_p = false; /* We are not processing an `extern "C"' declaration. */ parser->in_unbraced_linkage_specification_p = false; /* We are not processing a declarator. */ parser->in_declarator_p = false; /* We are not processing a template-argument-list. */ parser->in_template_argument_list_p = false; /* We are not in an iteration statement. */ parser->in_statement = 0; /* We are not in a switch statement. */ parser->in_switch_statement_p = false; /* We are not parsing a type-id inside an expression. */ parser->in_type_id_in_expr_p = false; /* Declarations aren't implicitly extern "C". */ parser->implicit_extern_c = false; /* String literals should be translated to the execution character set. */ parser->translate_strings_p = true; /* We are not parsing a function body. */ parser->in_function_body = false; /* The unparsed function queue is empty. */ parser->unparsed_functions_queues = build_tree_list (NULL_TREE, NULL_TREE); /* There are no classes being defined. */ parser->num_classes_being_defined = 0; /* No template parameters apply. */ parser->num_template_parameter_lists = 0; return parser; } /* Create a cp_lexer structure which will emit the tokens in CACHE and push it onto the parser's lexer stack. This is used for delayed parsing of in-class method bodies and default arguments, and should not be confused with tentative parsing. */ static void cp_parser_push_lexer_for_tokens (cp_parser *parser, cp_token_cache *cache) { cp_lexer *lexer = cp_lexer_new_from_tokens (cache); lexer->next = parser->lexer; parser->lexer = lexer; /* Move the current source position to that of the first token in the new lexer. */ cp_lexer_set_source_position_from_token (lexer->next_token); } /* Pop the top lexer off the parser stack. This is never used for the "main" lexer, only for those pushed by cp_parser_push_lexer_for_tokens. */ static void cp_parser_pop_lexer (cp_parser *parser) { cp_lexer *lexer = parser->lexer; parser->lexer = lexer->next; cp_lexer_destroy (lexer); /* Put the current source position back where it was before this lexer was pushed. */ cp_lexer_set_source_position_from_token (parser->lexer->next_token); } /* Lexical conventions [gram.lex] */ /* Parse an identifier. Returns an IDENTIFIER_NODE representing the identifier. */ static tree cp_parser_identifier (cp_parser* parser) { cp_token *token; /* Look for the identifier. */ token = cp_parser_require (parser, CPP_NAME, "identifier"); /* Return the value. */ return token ? token->u.value : error_mark_node; } /* Parse a sequence of adjacent string constants. Returns a TREE_STRING representing the combined, nul-terminated string constant. If TRANSLATE is true, translate the string to the execution character set. If WIDE_OK is true, a wide string is invalid here. C++98 [lex.string] says that if a narrow string literal token is adjacent to a wide string literal token, the behavior is undefined. However, C99 6.4.5p4 says that this results in a wide string literal. We follow C99 here, for consistency with the C front end. This code is largely lifted from lex_string() in c-lex.c. FUTURE: ObjC++ will need to handle @-strings here. */ static tree cp_parser_string_literal (cp_parser *parser, bool translate, bool wide_ok) { tree value; bool wide = false; size_t count; struct obstack str_ob; cpp_string str, istr, *strs; cp_token *tok; tok = cp_lexer_peek_token (parser->lexer); if (!cp_parser_is_string_literal (tok)) { cp_parser_error (parser, "expected string-literal"); return error_mark_node; } /* Try to avoid the overhead of creating and destroying an obstack for the common case of just one string. */ if (!cp_parser_is_string_literal (cp_lexer_peek_nth_token (parser->lexer, 2))) { cp_lexer_consume_token (parser->lexer); str.text = (const unsigned char *)TREE_STRING_POINTER (tok->u.value); str.len = TREE_STRING_LENGTH (tok->u.value); count = 1; if (tok->type == CPP_WSTRING) wide = true; strs = &str; } else { gcc_obstack_init (&str_ob); count = 0; do { cp_lexer_consume_token (parser->lexer); count++; str.text = (unsigned char *)TREE_STRING_POINTER (tok->u.value); str.len = TREE_STRING_LENGTH (tok->u.value); if (tok->type == CPP_WSTRING) wide = true; obstack_grow (&str_ob, &str, sizeof (cpp_string)); tok = cp_lexer_peek_token (parser->lexer); } while (cp_parser_is_string_literal (tok)); strs = (cpp_string *) obstack_finish (&str_ob); } if (wide && !wide_ok) { cp_parser_error (parser, "a wide string is invalid in this context"); wide = false; } if ((translate ? cpp_interpret_string : cpp_interpret_string_notranslate) (parse_in, strs, count, &istr, wide)) { value = build_string (istr.len, (char *)istr.text); free ((void *)istr.text); TREE_TYPE (value) = wide ? wchar_array_type_node : char_array_type_node; value = fix_string_type (value); } else /* cpp_interpret_string has issued an error. */ value = error_mark_node; if (count > 1) obstack_free (&str_ob, 0); return value; } /* Basic concepts [gram.basic] */ /* Parse a translation-unit. translation-unit: declaration-seq [opt] Returns TRUE if all went well. */ static bool cp_parser_translation_unit (cp_parser* parser) { /* The address of the first non-permanent object on the declarator obstack. */ static void *declarator_obstack_base; bool success; /* Create the declarator obstack, if necessary. */ if (!cp_error_declarator) { gcc_obstack_init (&declarator_obstack); /* Create the error declarator. */ cp_error_declarator = make_declarator (cdk_error); /* Create the empty parameter list. */ no_parameters = make_parameter_declarator (NULL, NULL, NULL_TREE); /* Remember where the base of the declarator obstack lies. */ declarator_obstack_base = obstack_next_free (&declarator_obstack); } cp_parser_declaration_seq_opt (parser); /* If there are no tokens left then all went well. */ if (cp_lexer_next_token_is (parser->lexer, CPP_EOF)) { /* Get rid of the token array; we don't need it any more. */ cp_lexer_destroy (parser->lexer); parser->lexer = NULL; /* This file might have been a context that's implicitly extern "C". If so, pop the lang context. (Only relevant for PCH.) */ if (parser->implicit_extern_c) { pop_lang_context (); parser->implicit_extern_c = false; } /* Finish up. */ finish_translation_unit (); success = true; } else { cp_parser_error (parser, "expected declaration"); success = false; } /* Make sure the declarator obstack was fully cleaned up. */ gcc_assert (obstack_next_free (&declarator_obstack) == declarator_obstack_base); /* All went well. */ return success; } /* Expressions [gram.expr] */ /* Parse a primary-expression. primary-expression: literal this ( expression ) id-expression GNU Extensions: primary-expression: ( compound-statement ) __builtin_va_arg ( assignment-expression , type-id ) __builtin_offsetof ( type-id , offsetof-expression ) Objective-C++ Extension: primary-expression: objc-expression literal: __null ADDRESS_P is true iff this expression was immediately preceded by "&" and therefore might denote a pointer-to-member. CAST_P is true iff this expression is the target of a cast. TEMPLATE_ARG_P is true iff this expression is a template argument. Returns a representation of the expression. Upon return, *IDK indicates what kind of id-expression (if any) was present. */ static tree cp_parser_primary_expression (cp_parser *parser, bool address_p, bool cast_p, bool template_arg_p, cp_id_kind *idk) { cp_token *token; /* Assume the primary expression is not an id-expression. */ *idk = CP_ID_KIND_NONE; /* Peek at the next token. */ token = cp_lexer_peek_token (parser->lexer); switch (token->type) { /* literal: integer-literal character-literal floating-literal string-literal boolean-literal */ case CPP_CHAR: case CPP_WCHAR: case CPP_NUMBER: token = cp_lexer_consume_token (parser->lexer); /* Floating-point literals are only allowed in an integral constant expression if they are cast to an integral or enumeration type. */ if (TREE_CODE (token->u.value) == REAL_CST && parser->integral_constant_expression_p && pedantic) { /* CAST_P will be set even in invalid code like "int(2.7 + ...)". Therefore, we have to check that the next token is sure to end the cast. */ if (cast_p) { cp_token *next_token; next_token = cp_lexer_peek_token (parser->lexer); if (/* The comma at the end of an enumerator-definition. */ next_token->type != CPP_COMMA /* The curly brace at the end of an enum-specifier. */ && next_token->type != CPP_CLOSE_BRACE /* The end of a statement. */ && next_token->type != CPP_SEMICOLON /* The end of the cast-expression. */ && next_token->type != CPP_CLOSE_PAREN /* The end of an array bound. */ && next_token->type != CPP_CLOSE_SQUARE /* The closing ">" in a template-argument-list. */ && (next_token->type != CPP_GREATER || parser->greater_than_is_operator_p)) cast_p = false; } /* If we are within a cast, then the constraint that the cast is to an integral or enumeration type will be checked at that point. If we are not within a cast, then this code is invalid. */ if (!cast_p) cp_parser_non_integral_constant_expression (parser, "floating-point literal"); } return token->u.value; case CPP_STRING: case CPP_WSTRING: /* ??? Should wide strings be allowed when parser->translate_strings_p is false (i.e. in attributes)? If not, we can kill the third argument to cp_parser_string_literal. */ return cp_parser_string_literal (parser, parser->translate_strings_p, true); case CPP_OPEN_PAREN: { tree expr; bool saved_greater_than_is_operator_p; /* Consume the `('. */ cp_lexer_consume_token (parser->lexer); /* Within a parenthesized expression, a `>' token is always the greater-than operator. */ saved_greater_than_is_operator_p = parser->greater_than_is_operator_p; parser->greater_than_is_operator_p = true; /* If we see `( { ' then we are looking at the beginning of a GNU statement-expression. */ if (cp_parser_allow_gnu_extensions_p (parser) && cp_lexer_next_token_is (parser->lexer, CPP_OPEN_BRACE)) { /* Statement-expressions are not allowed by the standard. */ if (pedantic) pedwarn ("ISO C++ forbids braced-groups within expressions"); /* And they're not allowed outside of a function-body; you cannot, for example, write: int i = ({ int j = 3; j + 1; }); at class or namespace scope. */ if (!parser->in_function_body) error ("statement-expressions are allowed only inside functions"); /* Start the statement-expression. */ expr = begin_stmt_expr (); /* Parse the compound-statement. */ cp_parser_compound_statement (parser, expr, false); /* Finish up. */ expr = finish_stmt_expr (expr, false); } else { /* Parse the parenthesized expression. */ expr = cp_parser_expression (parser, cast_p); /* Let the front end know that this expression was enclosed in parentheses. This matters in case, for example, the expression is of the form `A::B', since `&A::B' might be a pointer-to-member, but `&(A::B)' is not. */ finish_parenthesized_expr (expr); } /* The `>' token might be the end of a template-id or template-parameter-list now. */ parser->greater_than_is_operator_p = saved_greater_than_is_operator_p; /* Consume the `)'. */ if (!cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'")) cp_parser_skip_to_end_of_statement (parser); return expr; } case CPP_KEYWORD: switch (token->keyword) { /* These two are the boolean literals. */ case RID_TRUE: cp_lexer_consume_token (parser->lexer); return boolean_true_node; case RID_FALSE: cp_lexer_consume_token (parser->lexer); return boolean_false_node; /* The `__null' literal. */ case RID_NULL: cp_lexer_consume_token (parser->lexer); return null_node; /* Recognize the `this' keyword. */ case RID_THIS: cp_lexer_consume_token (parser->lexer); if (parser->local_variables_forbidden_p) { error ("%<this%> may not be used in this context"); return error_mark_node; } /* Pointers cannot appear in constant-expressions. */ if (cp_parser_non_integral_constant_expression (parser, "`this'")) return error_mark_node; return finish_this_expr (); /* The `operator' keyword can be the beginning of an id-expression. */ case RID_OPERATOR: goto id_expression; case RID_FUNCTION_NAME: case RID_PRETTY_FUNCTION_NAME: case RID_C99_FUNCTION_NAME: /* The symbols __FUNCTION__, __PRETTY_FUNCTION__, and __func__ are the names of variables -- but they are treated specially. Therefore, they are handled here, rather than relying on the generic id-expression logic below. Grammatically, these names are id-expressions. Consume the token. */ token = cp_lexer_consume_token (parser->lexer); /* Look up the name. */ return finish_fname (token->u.value); case RID_VA_ARG: { tree expression; tree type; /* The `__builtin_va_arg' construct is used to handle `va_arg'. Consume the `__builtin_va_arg' token. */ cp_lexer_consume_token (parser->lexer); /* Look for the opening `('. */ cp_parser_require (parser, CPP_OPEN_PAREN, "`('"); /* Now, parse the assignment-expression. */ expression = cp_parser_assignment_expression (parser, /*cast_p=*/false); /* Look for the `,'. */ cp_parser_require (parser, CPP_COMMA, "`,'"); /* Parse the type-id. */ type = cp_parser_type_id (parser); /* Look for the closing `)'. */ cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'"); /* Using `va_arg' in a constant-expression is not allowed. */ if (cp_parser_non_integral_constant_expression (parser, "`va_arg'")) return error_mark_node; return build_x_va_arg (expression, type); } case RID_OFFSETOF: return cp_parser_builtin_offsetof (parser); /* Objective-C++ expressions. */ case RID_AT_ENCODE: case RID_AT_PROTOCOL: case RID_AT_SELECTOR: return cp_parser_objc_expression (parser); default: cp_parser_error (parser, "expected primary-expression"); return error_mark_node; } /* An id-expression can start with either an identifier, a `::' as the beginning of a qualified-id, or the "operator" keyword. */ case CPP_NAME: case CPP_SCOPE: case CPP_TEMPLATE_ID: case CPP_NESTED_NAME_SPECIFIER: { tree id_expression; tree decl; const char *error_msg; bool template_p; bool done; id_expression: /* Parse the id-expression. */ id_expression = cp_parser_id_expression (parser, /*template_keyword_p=*/false, /*check_dependency_p=*/true, &template_p, /*declarator_p=*/false, /*optional_p=*/false); if (id_expression == error_mark_node) return error_mark_node; token = cp_lexer_peek_token (parser->lexer); done = (token->type != CPP_OPEN_SQUARE && token->type != CPP_OPEN_PAREN && token->type != CPP_DOT && token->type != CPP_DEREF && token->type != CPP_PLUS_PLUS && token->type != CPP_MINUS_MINUS); /* If we have a template-id, then no further lookup is required. If the template-id was for a template-class, we will sometimes have a TYPE_DECL at this point. */ if (TREE_CODE (id_expression) == TEMPLATE_ID_EXPR || TREE_CODE (id_expression) == TYPE_DECL) decl = id_expression; /* Look up the name. */ else { tree ambiguous_decls; decl = cp_parser_lookup_name (parser, id_expression, none_type, template_p, /*is_namespace=*/false, /*check_dependency=*/true, &ambiguous_decls); /* If the lookup was ambiguous, an error will already have been issued. */ if (ambiguous_decls) return error_mark_node; /* In Objective-C++, an instance variable (ivar) may be preferred to whatever cp_parser_lookup_name() found. */ decl = objc_lookup_ivar (decl, id_expression); /* If name lookup gives us a SCOPE_REF, then the qualifying scope was dependent. */ if (TREE_CODE (decl) == SCOPE_REF) { /* At this point, we do not know if DECL is a valid integral constant expression. We assume that it is in fact such an expression, so that code like: template <int N> struct A { int a[B<N>::i]; }; is accepted. At template-instantiation time, we will check that B<N>::i is actually a constant. */ return decl; } /* Check to see if DECL is a local variable in a context where that is forbidden. */ if (parser->local_variables_forbidden_p && local_variable_p (decl)) { /* It might be that we only found DECL because we are trying to be generous with pre-ISO scoping rules. For example, consider: int i; void g() { for (int i = 0; i < 10; ++i) {} extern void f(int j = i); } Here, name look up will originally find the out of scope `i'. We need to issue a warning message, but then use the global `i'. */ decl = check_for_out_of_scope_variable (decl); if (local_variable_p (decl)) { error ("local variable %qD may not appear in this context", decl); return error_mark_node; } } } decl = (finish_id_expression (id_expression, decl, parser->scope, idk, parser->integral_constant_expression_p, parser->allow_non_integral_constant_expression_p, &parser->non_integral_constant_expression_p, template_p, done, address_p, template_arg_p, &error_msg)); if (error_msg) cp_parser_error (parser, error_msg); return decl; } /* Anything else is an error. */ default: /* ...unless we have an Objective-C++ message or string literal, that is. */ if (c_dialect_objc () && (token->type == CPP_OPEN_SQUARE || token->type == CPP_OBJC_STRING)) return cp_parser_objc_expression (parser); cp_parser_error (parser, "expected primary-expression"); return error_mark_node; } } /* Parse an id-expression. id-expression: unqualified-id qualified-id qualified-id: :: [opt] nested-name-specifier template [opt] unqualified-id :: identifier :: operator-function-id :: template-id Return a representation of the unqualified portion of the identifier. Sets PARSER->SCOPE to the qualifying scope if there is a `::' or nested-name-specifier. Often, if the id-expression was a qualified-id, the caller will want to make a SCOPE_REF to represent the qualified-id. This function does not do this in order to avoid wastefully creating SCOPE_REFs when they are not required. If TEMPLATE_KEYWORD_P is true, then we have just seen the `template' keyword. If CHECK_DEPENDENCY_P is false, then names are looked up inside uninstantiated templates. If *TEMPLATE_P is non-NULL, it is set to true iff the `template' keyword is used to explicitly indicate that the entity named is a template. If DECLARATOR_P is true, the id-expression is appearing as part of a declarator, rather than as part of an expression. */ static tree cp_parser_id_expression (cp_parser *parser, bool template_keyword_p, bool check_dependency_p, bool *template_p, bool declarator_p, bool optional_p) { bool global_scope_p; bool nested_name_specifier_p; /* Assume the `template' keyword was not used. */ if (template_p) *template_p = template_keyword_p; /* Look for the optional `::' operator. */ global_scope_p = (cp_parser_global_scope_opt (parser, /*current_scope_valid_p=*/false) != NULL_TREE); /* Look for the optional nested-name-specifier. */ nested_name_specifier_p = (cp_parser_nested_name_specifier_opt (parser, /*typename_keyword_p=*/false, check_dependency_p, /*type_p=*/false, declarator_p) != NULL_TREE); /* If there is a nested-name-specifier, then we are looking at the first qualified-id production. */ if (nested_name_specifier_p) { tree saved_scope; tree saved_object_scope; tree saved_qualifying_scope; tree unqualified_id; bool is_template; /* See if the next token is the `template' keyword. */ if (!template_p) template_p = &is_template; *template_p = cp_parser_optional_template_keyword (parser); /* Name lookup we do during the processing of the unqualified-id might obliterate SCOPE. */ saved_scope = parser->scope; saved_object_scope = parser->object_scope; saved_qualifying_scope = parser->qualifying_scope; /* Process the final unqualified-id. */ unqualified_id = cp_parser_unqualified_id (parser, *template_p, check_dependency_p, declarator_p, /*optional_p=*/false); /* Restore the SAVED_SCOPE for our caller. */ parser->scope = saved_scope; parser->object_scope = saved_object_scope; parser->qualifying_scope = saved_qualifying_scope; return unqualified_id; } /* Otherwise, if we are in global scope, then we are looking at one of the other qualified-id productions. */ else if (global_scope_p) { cp_token *token; tree id; /* Peek at the next token. */ token = cp_lexer_peek_token (parser->lexer); /* If it's an identifier, and the next token is not a "<", then we can avoid the template-id case. This is an optimization for this common case. */ if (token->type == CPP_NAME && !cp_parser_nth_token_starts_template_argument_list_p (parser, 2)) return cp_parser_identifier (parser); cp_parser_parse_tentatively (parser); /* Try a template-id. */ id = cp_parser_template_id (parser, /*template_keyword_p=*/false, /*check_dependency_p=*/true, declarator_p); /* If that worked, we're done. */ if (cp_parser_parse_definitely (parser)) return id; /* Peek at the next token. (Changes in the token buffer may have invalidated the pointer obtained above.) */ token = cp_lexer_peek_token (parser->lexer); switch (token->type) { case CPP_NAME: return cp_parser_identifier (parser); case CPP_KEYWORD: if (token->keyword == RID_OPERATOR) return cp_parser_operator_function_id (parser); /* Fall through. */ default: cp_parser_error (parser, "expected id-expression"); return error_mark_node; } } else return cp_parser_unqualified_id (parser, template_keyword_p, /*check_dependency_p=*/true, declarator_p, optional_p); } /* Parse an unqualified-id. unqualified-id: identifier operator-function-id conversion-function-id ~ class-name template-id If TEMPLATE_KEYWORD_P is TRUE, we have just seen the `template' keyword, in a construct like `A::template ...'. Returns a representation of unqualified-id. For the `identifier' production, an IDENTIFIER_NODE is returned. For the `~ class-name' production a BIT_NOT_EXPR is returned; the operand of the BIT_NOT_EXPR is an IDENTIFIER_NODE for the class-name. For the other productions, see the documentation accompanying the corresponding parsing functions. If CHECK_DEPENDENCY_P is false, names are looked up in uninstantiated templates. If DECLARATOR_P is true, the unqualified-id is appearing as part of a declarator, rather than as part of an expression. */ static tree cp_parser_unqualified_id (cp_parser* parser, bool template_keyword_p, bool check_dependency_p, bool declarator_p, bool optional_p) { cp_token *token; /* Peek at the next token. */ token = cp_lexer_peek_token (parser->lexer); switch (token->type) { case CPP_NAME: { tree id; /* We don't know yet whether or not this will be a template-id. */ cp_parser_parse_tentatively (parser); /* Try a template-id. */ id = cp_parser_template_id (parser, template_keyword_p, check_dependency_p, declarator_p); /* If it worked, we're done. */ if (cp_parser_parse_definitely (parser)) return id; /* Otherwise, it's an ordinary identifier. */ return cp_parser_identifier (parser); } case CPP_TEMPLATE_ID: return cp_parser_template_id (parser, template_keyword_p, check_dependency_p, declarator_p); case CPP_COMPL: { tree type_decl; tree qualifying_scope; tree object_scope; tree scope; bool done; /* Consume the `~' token. */ cp_lexer_consume_token (parser->lexer); /* Parse the class-name. The standard, as written, seems to say that: template <typename T> struct S { ~S (); }; template <typename T> S<T>::~S() {} is invalid, since `~' must be followed by a class-name, but `S<T>' is dependent, and so not known to be a class. That's not right; we need to look in uninstantiated templates. A further complication arises from: template <typename T> void f(T t) { t.T::~T(); } Here, it is not possible to look up `T' in the scope of `T' itself. We must look in both the current scope, and the scope of the containing complete expression. Yet another issue is: struct S { int S; ~S(); }; S::~S() {} The standard does not seem to say that the `S' in `~S' should refer to the type `S' and not the data member `S::S'. */ /* DR 244 says that we look up the name after the "~" in the same scope as we looked up the qualifying name. That idea isn't fully worked out; it's more complicated than that. */ scope = parser->scope; object_scope = parser->object_scope; qualifying_scope = parser->qualifying_scope; /* Check for invalid scopes. */ if (scope == error_mark_node) { if (cp_lexer_next_token_is (parser->lexer, CPP_NAME)) cp_lexer_consume_token (parser->lexer); return error_mark_node; } if (scope && TREE_CODE (scope) == NAMESPACE_DECL) { if (!cp_parser_uncommitted_to_tentative_parse_p (parser)) error ("scope %qT before %<~%> is not a class-name", scope); cp_parser_simulate_error (parser); if (cp_lexer_next_token_is (parser->lexer, CPP_NAME)) cp_lexer_consume_token (parser->lexer); return error_mark_node; } gcc_assert (!scope || TYPE_P (scope)); /* If the name is of the form "X::~X" it's OK. */ token = cp_lexer_peek_token (parser->lexer); if (scope && token->type == CPP_NAME && (cp_lexer_peek_nth_token (parser->lexer, 2)->type == CPP_OPEN_PAREN) && constructor_name_p (token->u.value, scope)) { cp_lexer_consume_token (parser->lexer); return build_nt (BIT_NOT_EXPR, scope); } /* If there was an explicit qualification (S::~T), first look in the scope given by the qualification (i.e., S). */ done = false; type_decl = NULL_TREE; if (scope) { cp_parser_parse_tentatively (parser); type_decl = cp_parser_class_name (parser, /*typename_keyword_p=*/false, /*template_keyword_p=*/false, none_type, /*check_dependency=*/false, /*class_head_p=*/false, declarator_p); if (cp_parser_parse_definitely (parser)) done = true; } /* In "N::S::~S", look in "N" as well. */ if (!done && scope && qualifying_scope) { cp_parser_parse_tentatively (parser); parser->scope = qualifying_scope; parser->object_scope = NULL_TREE; parser->qualifying_scope = NULL_TREE; type_decl = cp_parser_class_name (parser, /*typename_keyword_p=*/false, /*template_keyword_p=*/false, none_type, /*check_dependency=*/false, /*class_head_p=*/false, declarator_p); if (cp_parser_parse_definitely (parser)) done = true; } /* In "p->S::~T", look in the scope given by "*p" as well. */ else if (!done && object_scope) { cp_parser_parse_tentatively (parser); parser->scope = object_scope; parser->object_scope = NULL_TREE; parser->qualifying_scope = NULL_TREE; type_decl = cp_parser_class_name (parser, /*typename_keyword_p=*/false, /*template_keyword_p=*/false, none_type, /*check_dependency=*/false, /*class_head_p=*/false, declarator_p); if (cp_parser_parse_definitely (parser)) done = true; } /* Look in the surrounding context. */ if (!done) { parser->scope = NULL_TREE; parser->object_scope = NULL_TREE; parser->qualifying_scope = NULL_TREE; type_decl = cp_parser_class_name (parser, /*typename_keyword_p=*/false, /*template_keyword_p=*/false, none_type, /*check_dependency=*/false, /*class_head_p=*/false, declarator_p); } /* If an error occurred, assume that the name of the destructor is the same as the name of the qualifying class. That allows us to keep parsing after running into ill-formed destructor names. */ if (type_decl == error_mark_node && scope) return build_nt (BIT_NOT_EXPR, scope); else if (type_decl == error_mark_node) return error_mark_node; /* Check that destructor name and scope match. */ if (declarator_p && scope && !check_dtor_name (scope, type_decl)) { if (!cp_parser_uncommitted_to_tentative_parse_p (parser)) error ("declaration of %<~%T%> as member of %qT", type_decl, scope); cp_parser_simulate_error (parser); return error_mark_node; } /* [class.dtor] A typedef-name that names a class shall not be used as the identifier in the declarator for a destructor declaration. */ if (declarator_p && !DECL_IMPLICIT_TYPEDEF_P (type_decl) && !DECL_SELF_REFERENCE_P (type_decl) && !cp_parser_uncommitted_to_tentative_parse_p (parser)) error ("typedef-name %qD used as destructor declarator", type_decl); return build_nt (BIT_NOT_EXPR, TREE_TYPE (type_decl)); } case CPP_KEYWORD: if (token->keyword == RID_OPERATOR) { tree id; /* This could be a template-id, so we try that first. */ cp_parser_parse_tentatively (parser); /* Try a template-id. */ id = cp_parser_template_id (parser, template_keyword_p, /*check_dependency_p=*/true, declarator_p); /* If that worked, we're done. */ if (cp_parser_parse_definitely (parser)) return id; /* We still don't know whether we're looking at an operator-function-id or a conversion-function-id. */ cp_parser_parse_tentatively (parser); /* Try an operator-function-id. */ id = cp_parser_operator_function_id (parser); /* If that didn't work, try a conversion-function-id. */ if (!cp_parser_parse_definitely (parser)) id = cp_parser_conversion_function_id (parser); return id; } /* Fall through. */ default: if (optional_p) return NULL_TREE; cp_parser_error (parser, "expected unqualified-id"); return error_mark_node; } } /* Parse an (optional) nested-name-specifier. nested-name-specifier: class-or-namespace-name :: nested-name-specifier [opt] class-or-namespace-name :: template nested-name-specifier [opt] PARSER->SCOPE should be set appropriately before this function is called. TYPENAME_KEYWORD_P is TRUE if the `typename' keyword is in effect. TYPE_P is TRUE if we non-type bindings should be ignored in name lookups. Sets PARSER->SCOPE to the class (TYPE) or namespace (NAMESPACE_DECL) specified by the nested-name-specifier, or leaves it unchanged if there is no nested-name-specifier. Returns the new scope iff there is a nested-name-specifier, or NULL_TREE otherwise. If IS_DECLARATION is TRUE, the nested-name-specifier is known to be part of a declaration and/or decl-specifier. */ static tree cp_parser_nested_name_specifier_opt (cp_parser *parser, bool typename_keyword_p, bool check_dependency_p, bool type_p, bool is_declaration) { bool success = false; cp_token_position start = 0; cp_token *token; /* Remember where the nested-name-specifier starts. */ if (cp_parser_uncommitted_to_tentative_parse_p (parser)) { start = cp_lexer_token_position (parser->lexer, false); push_deferring_access_checks (dk_deferred); } while (true) { tree new_scope; tree old_scope; tree saved_qualifying_scope; bool template_keyword_p; /* Spot cases that cannot be the beginning of a nested-name-specifier. */ token = cp_lexer_peek_token (parser->lexer); /* If the next token is CPP_NESTED_NAME_SPECIFIER, just process the already parsed nested-name-specifier. */ if (token->type == CPP_NESTED_NAME_SPECIFIER) { /* Grab the nested-name-specifier and continue the loop. */ cp_parser_pre_parsed_nested_name_specifier (parser); /* If we originally encountered this nested-name-specifier with IS_DECLARATION set to false, we will not have resolved TYPENAME_TYPEs, so we must do so here. */ if (is_declaration && TREE_CODE (parser->scope) == TYPENAME_TYPE) { new_scope = resolve_typename_type (parser->scope, /*only_current_p=*/false); if (new_scope != error_mark_node) parser->scope = new_scope; } success = true; continue; } /* Spot cases that cannot be the beginning of a nested-name-specifier. On the second and subsequent times through the loop, we look for the `template' keyword. */ if (success && token->keyword == RID_TEMPLATE) ; /* A template-id can start a nested-name-specifier. */ else if (token->type == CPP_TEMPLATE_ID) ; else { /* If the next token is not an identifier, then it is definitely not a class-or-namespace-name. */ if (token->type != CPP_NAME) break; /* If the following token is neither a `<' (to begin a template-id), nor a `::', then we are not looking at a nested-name-specifier. */ token = cp_lexer_peek_nth_token (parser->lexer, 2); if (token->type != CPP_SCOPE && !cp_parser_nth_token_starts_template_argument_list_p (parser, 2)) break; } /* The nested-name-specifier is optional, so we parse tentatively. */ cp_parser_parse_tentatively (parser); /* Look for the optional `template' keyword, if this isn't the first time through the loop. */ if (success) template_keyword_p = cp_parser_optional_template_keyword (parser); else template_keyword_p = false; /* Save the old scope since the name lookup we are about to do might destroy it. */ old_scope = parser->scope; saved_qualifying_scope = parser->qualifying_scope; /* In a declarator-id like "X<T>::I::Y<T>" we must be able to look up names in "X<T>::I" in order to determine that "Y" is a template. So, if we have a typename at this point, we make an effort to look through it. */ if (is_declaration && !typename_keyword_p && parser->scope && TREE_CODE (parser->scope) == TYPENAME_TYPE) parser->scope = resolve_typename_type (parser->scope, /*only_current_p=*/false); /* Parse the qualifying entity. */ new_scope = cp_parser_class_or_namespace_name (parser, typename_keyword_p, template_keyword_p, check_dependency_p, type_p, is_declaration); /* Look for the `::' token. */ cp_parser_require (parser, CPP_SCOPE, "`::'"); /* If we found what we wanted, we keep going; otherwise, we're done. */ if (!cp_parser_parse_definitely (parser)) { bool error_p = false; /* Restore the OLD_SCOPE since it was valid before the failed attempt at finding the last class-or-namespace-name. */ parser->scope = old_scope; parser->qualifying_scope = saved_qualifying_scope; if (cp_parser_uncommitted_to_tentative_parse_p (parser)) break; /* If the next token is an identifier, and the one after that is a `::', then any valid interpretation would have found a class-or-namespace-name. */ while (cp_lexer_next_token_is (parser->lexer, CPP_NAME) && (cp_lexer_peek_nth_token (parser->lexer, 2)->type == CPP_SCOPE) && (cp_lexer_peek_nth_token (parser->lexer, 3)->type != CPP_COMPL)) { token = cp_lexer_consume_token (parser->lexer); if (!error_p) { if (!token->ambiguous_p) { tree decl; tree ambiguous_decls; decl = cp_parser_lookup_name (parser, token->u.value, none_type, /*is_template=*/false, /*is_namespace=*/false, /*check_dependency=*/true, &ambiguous_decls); if (TREE_CODE (decl) == TEMPLATE_DECL) error ("%qD used without template parameters", decl); else if (ambiguous_decls) { error ("reference to %qD is ambiguous", token->u.value); print_candidates (ambiguous_decls); decl = error_mark_node; } else cp_parser_name_lookup_error (parser, token->u.value, decl, "is not a class or namespace"); } parser->scope = error_mark_node; error_p = true; /* Treat this as a successful nested-name-specifier due to: [basic.lookup.qual] If the name found is not a class-name (clause _class_) or namespace-name (_namespace.def_), the program is ill-formed. */ success = true; } cp_lexer_consume_token (parser->lexer); } break; } /* We've found one valid nested-name-specifier. */ success = true; /* Name lookup always gives us a DECL. */ if (TREE_CODE (new_scope) == TYPE_DECL) new_scope = TREE_TYPE (new_scope); /* Uses of "template" must be followed by actual templates. */ if (template_keyword_p && !(CLASS_TYPE_P (new_scope) && ((CLASSTYPE_USE_TEMPLATE (new_scope) && PRIMARY_TEMPLATE_P (CLASSTYPE_TI_TEMPLATE (new_scope))) || CLASSTYPE_IS_TEMPLATE (new_scope))) && !(TREE_CODE (new_scope) == TYPENAME_TYPE && (TREE_CODE (TYPENAME_TYPE_FULLNAME (new_scope)) == TEMPLATE_ID_EXPR))) pedwarn (TYPE_P (new_scope) ? "%qT is not a template" : "%qD is not a template", new_scope); /* If it is a class scope, try to complete it; we are about to be looking up names inside the class. */ if (TYPE_P (new_scope) /* Since checking types for dependency can be expensive, avoid doing it if the type is already complete. */ && !COMPLETE_TYPE_P (new_scope) /* Do not try to complete dependent types. */ && !dependent_type_p (new_scope)) new_scope = complete_type (new_scope); /* Make sure we look in the right scope the next time through the loop. */ parser->scope = new_scope; } /* If parsing tentatively, replace the sequence of tokens that makes up the nested-name-specifier with a CPP_NESTED_NAME_SPECIFIER token. That way, should we re-parse the token stream, we will not have to repeat the effort required to do the parse, nor will we issue duplicate error messages. */ if (success && start) { cp_token *token; token = cp_lexer_token_at (parser->lexer, start); /* Reset the contents of the START token. */ token->type = CPP_NESTED_NAME_SPECIFIER; /* Retrieve any deferred checks. Do not pop this access checks yet so the memory will not be reclaimed during token replacing below. */ token->u.tree_check_value = GGC_CNEW (struct tree_check); token->u.tree_check_value->value = parser->scope; token->u.tree_check_value->checks = get_deferred_access_checks (); token->u.tree_check_value->qualifying_scope = parser->qualifying_scope; token->keyword = RID_MAX; /* Purge all subsequent tokens. */ cp_lexer_purge_tokens_after (parser->lexer, start); } if (start) pop_to_parent_deferring_access_checks (); return success ? parser->scope : NULL_TREE; } /* Parse a nested-name-specifier. See cp_parser_nested_name_specifier_opt for details. This function behaves identically, except that it will an issue an error if no nested-name-specifier is present. */ static tree cp_parser_nested_name_specifier (cp_parser *parser, bool typename_keyword_p, bool check_dependency_p, bool type_p, bool is_declaration) { tree scope; /* Look for the nested-name-specifier. */ scope = cp_parser_nested_name_specifier_opt (parser, typename_keyword_p, check_dependency_p, type_p, is_declaration); /* If it was not present, issue an error message. */ if (!scope) { cp_parser_error (parser, "expected nested-name-specifier"); parser->scope = NULL_TREE; } return scope; } /* Parse a class-or-namespace-name. class-or-namespace-name: class-name namespace-name TYPENAME_KEYWORD_P is TRUE iff the `typename' keyword is in effect. TEMPLATE_KEYWORD_P is TRUE iff the `template' keyword is in effect. CHECK_DEPENDENCY_P is FALSE iff dependent names should be looked up. TYPE_P is TRUE iff the next name should be taken as a class-name, even the same name is declared to be another entity in the same scope. Returns the class (TYPE_DECL) or namespace (NAMESPACE_DECL) specified by the class-or-namespace-name. If neither is found the ERROR_MARK_NODE is returned. */ static tree cp_parser_class_or_namespace_name (cp_parser *parser, bool typename_keyword_p, bool template_keyword_p, bool check_dependency_p, bool type_p, bool is_declaration) { tree saved_scope; tree saved_qualifying_scope; tree saved_object_scope; tree scope; bool only_class_p; /* Before we try to parse the class-name, we must save away the current PARSER->SCOPE since cp_parser_class_name will destroy it. */ saved_scope = parser->scope; saved_qualifying_scope = parser->qualifying_scope; saved_object_scope = parser->object_scope; /* Try for a class-name first. If the SAVED_SCOPE is a type, then there is no need to look for a namespace-name. */ only_class_p = template_keyword_p || (saved_scope && TYPE_P (saved_scope)); if (!only_class_p) cp_parser_parse_tentatively (parser); scope = cp_parser_class_name (parser, typename_keyword_p, template_keyword_p, type_p ? class_type : none_type, check_dependency_p, /*class_head_p=*/false, is_declaration); /* If that didn't work, try for a namespace-name. */ if (!only_class_p && !cp_parser_parse_definitely (parser)) { /* Restore the saved scope. */ parser->scope = saved_scope; parser->qualifying_scope = saved_qualifying_scope; parser->object_scope = saved_object_scope; /* If we are not looking at an identifier followed by the scope resolution operator, then this is not part of a nested-name-specifier. (Note that this function is only used to parse the components of a nested-name-specifier.) */ if (cp_lexer_next_token_is_not (parser->lexer, CPP_NAME) || cp_lexer_peek_nth_token (parser->lexer, 2)->type != CPP_SCOPE) return error_mark_node; scope = cp_parser_namespace_name (parser); } return scope; } /* Parse a postfix-expression. postfix-expression: primary-expression postfix-expression [ expression ] postfix-expression ( expression-list [opt] ) simple-type-specifier ( expression-list [opt] ) typename :: [opt] nested-name-specifier identifier ( expression-list [opt] ) typename :: [opt] nested-name-specifier template [opt] template-id ( expression-list [opt] ) postfix-expression . template [opt] id-expression postfix-expression -> template [opt] id-expression postfix-expression . pseudo-destructor-name postfix-expression -> pseudo-destructor-name postfix-expression ++ postfix-expression -- dynamic_cast < type-id > ( expression ) static_cast < type-id > ( expression ) reinterpret_cast < type-id > ( expression ) const_cast < type-id > ( expression ) typeid ( expression ) typeid ( type-id ) GNU Extension: postfix-expression: ( type-id ) { initializer-list , [opt] } This extension is a GNU version of the C99 compound-literal construct. (The C99 grammar uses `type-name' instead of `type-id', but they are essentially the same concept.) If ADDRESS_P is true, the postfix expression is the operand of the `&' operator. CAST_P is true if this expression is the target of a cast. Returns a representation of the expression. */ static tree cp_parser_postfix_expression (cp_parser *parser, bool address_p, bool cast_p) { cp_token *token; enum rid keyword; cp_id_kind idk = CP_ID_KIND_NONE; tree postfix_expression = NULL_TREE; /* Peek at the next token. */ token = cp_lexer_peek_token (parser->lexer); /* Some of the productions are determined by keywords. */ keyword = token->keyword; switch (keyword) { case RID_DYNCAST: case RID_STATCAST: case RID_REINTCAST: case RID_CONSTCAST: { tree type; tree expression; const char *saved_message; /* All of these can be handled in the same way from the point of view of parsing. Begin by consuming the token identifying the cast. */ cp_lexer_consume_token (parser->lexer); /* New types cannot be defined in the cast. */ saved_message = parser->type_definition_forbidden_message; parser->type_definition_forbidden_message = "types may not be defined in casts"; /* Look for the opening `<'. */ cp_parser_require (parser, CPP_LESS, "`<'"); /* Parse the type to which we are casting. */ type = cp_parser_type_id (parser); /* Look for the closing `>'. */ cp_parser_require (parser, CPP_GREATER, "`>'"); /* Restore the old message. */ parser->type_definition_forbidden_message = saved_message; /* And the expression which is being cast. */ cp_parser_require (parser, CPP_OPEN_PAREN, "`('"); expression = cp_parser_expression (parser, /*cast_p=*/true); cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'"); /* Only type conversions to integral or enumeration types can be used in constant-expressions. */ if (!cast_valid_in_integral_constant_expression_p (type) && (cp_parser_non_integral_constant_expression (parser, "a cast to a type other than an integral or " "enumeration type"))) return error_mark_node; switch (keyword) { case RID_DYNCAST: postfix_expression = build_dynamic_cast (type, expression); break; case RID_STATCAST: postfix_expression = build_static_cast (type, expression); break; case RID_REINTCAST: postfix_expression = build_reinterpret_cast (type, expression); break; case RID_CONSTCAST: postfix_expression = build_const_cast (type, expression); break; default: gcc_unreachable (); } } break; case RID_TYPEID: { tree type; const char *saved_message; bool saved_in_type_id_in_expr_p; /* Consume the `typeid' token. */ cp_lexer_consume_token (parser->lexer); /* Look for the `(' token. */ cp_parser_require (parser, CPP_OPEN_PAREN, "`('"); /* Types cannot be defined in a `typeid' expression. */ saved_message = parser->type_definition_forbidden_message; parser->type_definition_forbidden_message = "types may not be defined in a `typeid\' expression"; /* We can't be sure yet whether we're looking at a type-id or an expression. */ cp_parser_parse_tentatively (parser); /* Try a type-id first. */ saved_in_type_id_in_expr_p = parser->in_type_id_in_expr_p; parser->in_type_id_in_expr_p = true; type = cp_parser_type_id (parser); parser->in_type_id_in_expr_p = saved_in_type_id_in_expr_p; /* Look for the `)' token. Otherwise, we can't be sure that we're not looking at an expression: consider `typeid (int (3))', for example. */ cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'"); /* If all went well, simply lookup the type-id. */ if (cp_parser_parse_definitely (parser)) postfix_expression = get_typeid (type); /* Otherwise, fall back to the expression variant. */ else { tree expression; /* Look for an expression. */ expression = cp_parser_expression (parser, /*cast_p=*/false); /* Compute its typeid. */ postfix_expression = build_typeid (expression); /* Look for the `)' token. */ cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'"); } /* Restore the saved message. */ parser->type_definition_forbidden_message = saved_message; /* `typeid' may not appear in an integral constant expression. */ if (cp_parser_non_integral_constant_expression(parser, "`typeid' operator")) return error_mark_node; } break; case RID_TYPENAME: { tree type; /* The syntax permitted here is the same permitted for an elaborated-type-specifier. */ type = cp_parser_elaborated_type_specifier (parser, /*is_friend=*/false, /*is_declaration=*/false); postfix_expression = cp_parser_functional_cast (parser, type); } break; default: { tree type; /* If the next thing is a simple-type-specifier, we may be looking at a functional cast. We could also be looking at an id-expression. So, we try the functional cast, and if that doesn't work we fall back to the primary-expression. */ cp_parser_parse_tentatively (parser); /* Look for the simple-type-specifier. */ type = cp_parser_simple_type_specifier (parser, /*decl_specs=*/NULL, CP_PARSER_FLAGS_NONE); /* Parse the cast itself. */ if (!cp_parser_error_occurred (parser)) postfix_expression = cp_parser_functional_cast (parser, type); /* If that worked, we're done. */ if (cp_parser_parse_definitely (parser)) break; /* If the functional-cast didn't work out, try a compound-literal. */ if (cp_parser_allow_gnu_extensions_p (parser) && cp_lexer_next_token_is (parser->lexer, CPP_OPEN_PAREN)) { VEC(constructor_elt,gc) *initializer_list = NULL; bool saved_in_type_id_in_expr_p; cp_parser_parse_tentatively (parser); /* Consume the `('. */ cp_lexer_consume_token (parser->lexer); /* Parse the type. */ saved_in_type_id_in_expr_p = parser->in_type_id_in_expr_p; parser->in_type_id_in_expr_p = true; type = cp_parser_type_id (parser); parser->in_type_id_in_expr_p = saved_in_type_id_in_expr_p; /* Look for the `)'. */ cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'"); /* Look for the `{'. */ cp_parser_require (parser, CPP_OPEN_BRACE, "`{'"); /* If things aren't going well, there's no need to keep going. */ if (!cp_parser_error_occurred (parser)) { bool non_constant_p; /* Parse the initializer-list. */ initializer_list = cp_parser_initializer_list (parser, &non_constant_p); /* Allow a trailing `,'. */ if (cp_lexer_next_token_is (parser->lexer, CPP_COMMA)) cp_lexer_consume_token (parser->lexer); /* Look for the final `}'. */ cp_parser_require (parser, CPP_CLOSE_BRACE, "`}'"); } /* If that worked, we're definitely looking at a compound-literal expression. */ if (cp_parser_parse_definitely (parser)) { /* Warn the user that a compound literal is not allowed in standard C++. */ if (pedantic) pedwarn ("ISO C++ forbids compound-literals"); /* For simplicitly, we disallow compound literals in constant-expressions for simpliicitly. We could allow compound literals of integer type, whose initializer was a constant, in constant expressions. Permitting that usage, as a further extension, would not change the meaning of any currently accepted programs. (Of course, as compound literals are not part of ISO C++, the standard has nothing to say.) */ if (cp_parser_non_integral_constant_expression (parser, "non-constant compound literals")) { postfix_expression = error_mark_node; break; } /* Form the representation of the compound-literal. */ postfix_expression = finish_compound_literal (type, initializer_list); break; } } /* It must be a primary-expression. */ postfix_expression = cp_parser_primary_expression (parser, address_p, cast_p, /*template_arg_p=*/false, &idk); } break; } /* Keep looping until the postfix-expression is complete. */ while (true) { if (idk == CP_ID_KIND_UNQUALIFIED && TREE_CODE (postfix_expression) == IDENTIFIER_NODE && cp_lexer_next_token_is_not (parser->lexer, CPP_OPEN_PAREN)) /* It is not a Koenig lookup function call. */ postfix_expression = unqualified_name_lookup_error (postfix_expression); /* Peek at the next token. */ token = cp_lexer_peek_token (parser->lexer); switch (token->type) { case CPP_OPEN_SQUARE: postfix_expression = cp_parser_postfix_open_square_expression (parser, postfix_expression, false); idk = CP_ID_KIND_NONE; break; case CPP_OPEN_PAREN: /* postfix-expression ( expression-list [opt] ) */ { bool koenig_p; bool is_builtin_constant_p; bool saved_integral_constant_expression_p = false; bool saved_non_integral_constant_expression_p = false; tree args; is_builtin_constant_p = DECL_IS_BUILTIN_CONSTANT_P (postfix_expression); if (is_builtin_constant_p) { /* The whole point of __builtin_constant_p is to allow non-constant expressions to appear as arguments. */ saved_integral_constant_expression_p = parser->integral_constant_expression_p; saved_non_integral_constant_expression_p = parser->non_integral_constant_expression_p; parser->integral_constant_expression_p = false; } args = (cp_parser_parenthesized_expression_list (parser, /*is_attribute_list=*/false, /*cast_p=*/false, /*non_constant_p=*/NULL)); if (is_builtin_constant_p) { parser->integral_constant_expression_p = saved_integral_constant_expression_p; parser->non_integral_constant_expression_p = saved_non_integral_constant_expression_p; } if (args == error_mark_node) { postfix_expression = error_mark_node; break; } /* Function calls are not permitted in constant-expressions. */ if (! builtin_valid_in_constant_expr_p (postfix_expression) && cp_parser_non_integral_constant_expression (parser, "a function call")) { postfix_expression = error_mark_node; break; } koenig_p = false; if (idk == CP_ID_KIND_UNQUALIFIED) { if (TREE_CODE (postfix_expression) == IDENTIFIER_NODE) { if (args) { koenig_p = true; postfix_expression = perform_koenig_lookup (postfix_expression, args); } else postfix_expression = unqualified_fn_lookup_error (postfix_expression); } /* We do not perform argument-dependent lookup if normal lookup finds a non-function, in accordance with the expected resolution of DR 218. */ else if (args && is_overloaded_fn (postfix_expression)) { tree fn = get_first_fn (postfix_expression); if (TREE_CODE (fn) == TEMPLATE_ID_EXPR) fn = OVL_CURRENT (TREE_OPERAND (fn, 0)); /* Only do argument dependent lookup if regular lookup does not find a set of member functions. [basic.lookup.koenig]/2a */ if (!DECL_FUNCTION_MEMBER_P (fn)) { koenig_p = true; postfix_expression = perform_koenig_lookup (postfix_expression, args); } } } if (TREE_CODE (postfix_expression) == COMPONENT_REF) { tree instance = TREE_OPERAND (postfix_expression, 0); tree fn = TREE_OPERAND (postfix_expression, 1); if (processing_template_decl && (type_dependent_expression_p (instance) || (!BASELINK_P (fn) && TREE_CODE (fn) != FIELD_DECL) || type_dependent_expression_p (fn) || any_type_dependent_arguments_p (args))) { postfix_expression = build_min_nt (CALL_EXPR, postfix_expression, args, NULL_TREE); break; } if (BASELINK_P (fn)) postfix_expression = (build_new_method_call (instance, fn, args, NULL_TREE, (idk == CP_ID_KIND_QUALIFIED ? LOOKUP_NONVIRTUAL : LOOKUP_NORMAL), /*fn_p=*/NULL)); else postfix_expression = finish_call_expr (postfix_expression, args, /*disallow_virtual=*/false, /*koenig_p=*/false); } else if (TREE_CODE (postfix_expression) == OFFSET_REF || TREE_CODE (postfix_expression) == MEMBER_REF || TREE_CODE (postfix_expression) == DOTSTAR_EXPR) postfix_expression = (build_offset_ref_call_from_tree (postfix_expression, args)); else if (idk == CP_ID_KIND_QUALIFIED) /* A call to a static class member, or a namespace-scope function. */ postfix_expression = finish_call_expr (postfix_expression, args, /*disallow_virtual=*/true, koenig_p); else /* All other function calls. */ postfix_expression = finish_call_expr (postfix_expression, args, /*disallow_virtual=*/false, koenig_p); /* The POSTFIX_EXPRESSION is certainly no longer an id. */ idk = CP_ID_KIND_NONE; } break; case CPP_DOT: case CPP_DEREF: /* postfix-expression . template [opt] id-expression postfix-expression . pseudo-destructor-name postfix-expression -> template [opt] id-expression postfix-expression -> pseudo-destructor-name */ /* Consume the `.' or `->' operator. */ cp_lexer_consume_token (parser->lexer); postfix_expression = cp_parser_postfix_dot_deref_expression (parser, token->type, postfix_expression, false, &idk); break; case CPP_PLUS_PLUS: /* postfix-expression ++ */ /* Consume the `++' token. */ cp_lexer_consume_token (parser->lexer); /* Generate a representation for the complete expression. */ postfix_expression = finish_increment_expr (postfix_expression, POSTINCREMENT_EXPR); /* Increments may not appear in constant-expressions. */ if (cp_parser_non_integral_constant_expression (parser, "an increment")) postfix_expression = error_mark_node; idk = CP_ID_KIND_NONE; break; case CPP_MINUS_MINUS: /* postfix-expression -- */ /* Consume the `--' token. */ cp_lexer_consume_token (parser->lexer); /* Generate a representation for the complete expression. */ postfix_expression = finish_increment_expr (postfix_expression, POSTDECREMENT_EXPR); /* Decrements may not appear in constant-expressions. */ if (cp_parser_non_integral_constant_expression (parser, "a decrement")) postfix_expression = error_mark_node; idk = CP_ID_KIND_NONE; break; default: return postfix_expression; } } /* We should never get here. */ gcc_unreachable (); return error_mark_node; } /* A subroutine of cp_parser_postfix_expression that also gets hijacked by cp_parser_builtin_offsetof. We're looking for postfix-expression [ expression ] FOR_OFFSETOF is set if we're being called in that context, which changes how we deal with integer constant expressions. */ static tree cp_parser_postfix_open_square_expression (cp_parser *parser, tree postfix_expression, bool for_offsetof) { tree index; /* Consume the `[' token. */ cp_lexer_consume_token (parser->lexer); /* Parse the index expression. */ /* ??? For offsetof, there is a question of what to allow here. If offsetof is not being used in an integral constant expression context, then we *could* get the right answer by computing the value at runtime. If we are in an integral constant expression context, then we might could accept any constant expression; hard to say without analysis. Rather than open the barn door too wide right away, allow only integer constant expressions here. */ if (for_offsetof) index = cp_parser_constant_expression (parser, false, NULL); else index = cp_parser_expression (parser, /*cast_p=*/false); /* Look for the closing `]'. */ cp_parser_require (parser, CPP_CLOSE_SQUARE, "`]'"); /* Build the ARRAY_REF. */ postfix_expression = grok_array_decl (postfix_expression, index); /* When not doing offsetof, array references are not permitted in constant-expressions. */ if (!for_offsetof && (cp_parser_non_integral_constant_expression (parser, "an array reference"))) postfix_expression = error_mark_node; return postfix_expression; } /* A subroutine of cp_parser_postfix_expression that also gets hijacked by cp_parser_builtin_offsetof. We're looking for postfix-expression . template [opt] id-expression postfix-expression . pseudo-destructor-name postfix-expression -> template [opt] id-expression postfix-expression -> pseudo-destructor-name FOR_OFFSETOF is set if we're being called in that context. That sorta limits what of the above we'll actually accept, but nevermind. TOKEN_TYPE is the "." or "->" token, which will already have been removed from the stream. */ static tree cp_parser_postfix_dot_deref_expression (cp_parser *parser, enum cpp_ttype token_type, tree postfix_expression, bool for_offsetof, cp_id_kind *idk) { tree name; bool dependent_p; bool pseudo_destructor_p; tree scope = NULL_TREE; /* If this is a `->' operator, dereference the pointer. */ if (token_type == CPP_DEREF) postfix_expression = build_x_arrow (postfix_expression); /* Check to see whether or not the expression is type-dependent. */ dependent_p = type_dependent_expression_p (postfix_expression); /* The identifier following the `->' or `.' is not qualified. */ parser->scope = NULL_TREE; parser->qualifying_scope = NULL_TREE; parser->object_scope = NULL_TREE; *idk = CP_ID_KIND_NONE; /* Enter the scope corresponding to the type of the object given by the POSTFIX_EXPRESSION. */ if (!dependent_p && TREE_TYPE (postfix_expression) != NULL_TREE) { scope = TREE_TYPE (postfix_expression); /* According to the standard, no expression should ever have reference type. Unfortunately, we do not currently match the standard in this respect in that our internal representation of an expression may have reference type even when the standard says it does not. Therefore, we have to manually obtain the underlying type here. */ scope = non_reference (scope); /* The type of the POSTFIX_EXPRESSION must be complete. */ if (scope == unknown_type_node) { error ("%qE does not have class type", postfix_expression); scope = NULL_TREE; } else scope = complete_type_or_else (scope, NULL_TREE); /* Let the name lookup machinery know that we are processing a class member access expression. */ parser->context->object_type = scope; /* If something went wrong, we want to be able to discern that case, as opposed to the case where there was no SCOPE due to the type of expression being dependent. */ if (!scope) scope = error_mark_node; /* If the SCOPE was erroneous, make the various semantic analysis functions exit quickly -- and without issuing additional error messages. */ if (scope == error_mark_node) postfix_expression = error_mark_node; } /* Assume this expression is not a pseudo-destructor access. */ pseudo_destructor_p = false; /* If the SCOPE is a scalar type, then, if this is a valid program, we must be looking at a pseudo-destructor-name. */ if (scope && SCALAR_TYPE_P (scope)) { tree s; tree type; cp_parser_parse_tentatively (parser); /* Parse the pseudo-destructor-name. */ s = NULL_TREE; cp_parser_pseudo_destructor_name (parser, &s, &type); if (cp_parser_parse_definitely (parser)) { pseudo_destructor_p = true; postfix_expression = finish_pseudo_destructor_expr (postfix_expression, s, TREE_TYPE (type)); } } if (!pseudo_destructor_p) { /* If the SCOPE is not a scalar type, we are looking at an ordinary class member access expression, rather than a pseudo-destructor-name. */ bool template_p; /* Parse the id-expression. */ name = (cp_parser_id_expression (parser, cp_parser_optional_template_keyword (parser), /*check_dependency_p=*/true, &template_p, /*declarator_p=*/false, /*optional_p=*/false)); /* In general, build a SCOPE_REF if the member name is qualified. However, if the name was not dependent and has already been resolved; there is no need to build the SCOPE_REF. For example; struct X { void f(); }; template <typename T> void f(T* t) { t->X::f(); } Even though "t" is dependent, "X::f" is not and has been resolved to a BASELINK; there is no need to include scope information. */ /* But we do need to remember that there was an explicit scope for virtual function calls. */ if (parser->scope) *idk = CP_ID_KIND_QUALIFIED; /* If the name is a template-id that names a type, we will get a TYPE_DECL here. That is invalid code. */ if (TREE_CODE (name) == TYPE_DECL) { error ("invalid use of %qD", name); postfix_expression = error_mark_node; } else { if (name != error_mark_node && !BASELINK_P (name) && parser->scope) { name = build_qualified_name (/*type=*/NULL_TREE, parser->scope, name, template_p); parser->scope = NULL_TREE; parser->qualifying_scope = NULL_TREE; parser->object_scope = NULL_TREE; } if (scope && name && BASELINK_P (name)) adjust_result_of_qualified_name_lookup (name, BINFO_TYPE (BASELINK_ACCESS_BINFO (name)), scope); postfix_expression = finish_class_member_access_expr (postfix_expression, name, template_p); } } /* We no longer need to look up names in the scope of the object on the left-hand side of the `.' or `->' operator. */ parser->context->object_type = NULL_TREE; /* Outside of offsetof, these operators may not appear in constant-expressions. */ if (!for_offsetof && (cp_parser_non_integral_constant_expression (parser, token_type == CPP_DEREF ? "'->'" : "`.'"))) postfix_expression = error_mark_node; return postfix_expression; } /* Parse a parenthesized expression-list. expression-list: assignment-expression expression-list, assignment-expression attribute-list: expression-list identifier identifier, expression-list CAST_P is true if this expression is the target of a cast. Returns a TREE_LIST. The TREE_VALUE of each node is a representation of an assignment-expression. Note that a TREE_LIST is returned even if there is only a single expression in the list. error_mark_node is returned if the ( and or ) are missing. NULL_TREE is returned on no expressions. The parentheses are eaten. IS_ATTRIBUTE_LIST is true if this is really an attribute list being parsed. If NON_CONSTANT_P is non-NULL, *NON_CONSTANT_P indicates whether or not all of the expressions in the list were constant. */ static tree cp_parser_parenthesized_expression_list (cp_parser* parser, bool is_attribute_list, bool cast_p, bool *non_constant_p) { tree expression_list = NULL_TREE; bool fold_expr_p = is_attribute_list; tree identifier = NULL_TREE; /* Assume all the expressions will be constant. */ if (non_constant_p) *non_constant_p = false; if (!cp_parser_require (parser, CPP_OPEN_PAREN, "`('")) return error_mark_node; /* Consume expressions until there are no more. */ if (cp_lexer_next_token_is_not (parser->lexer, CPP_CLOSE_PAREN)) while (true) { tree expr; /* At the beginning of attribute lists, check to see if the next token is an identifier. */ if (is_attribute_list && cp_lexer_peek_token (parser->lexer)->type == CPP_NAME) { cp_token *token; /* Consume the identifier. */ token = cp_lexer_consume_token (parser->lexer); /* Save the identifier. */ identifier = token->u.value; } else { /* Parse the next assignment-expression. */ if (non_constant_p) { bool expr_non_constant_p; expr = (cp_parser_constant_expression (parser, /*allow_non_constant_p=*/true, &expr_non_constant_p)); if (expr_non_constant_p) *non_constant_p = true; } else expr = cp_parser_assignment_expression (parser, cast_p); if (fold_expr_p) expr = fold_non_dependent_expr (expr); /* Add it to the list. We add error_mark_node expressions to the list, so that we can still tell if the correct form for a parenthesized expression-list is found. That gives better errors. */ expression_list = tree_cons (NULL_TREE, expr, expression_list); if (expr == error_mark_node) goto skip_comma; } /* After the first item, attribute lists look the same as expression lists. */ is_attribute_list = false; get_comma:; /* If the next token isn't a `,', then we are done. */ if (cp_lexer_next_token_is_not (parser->lexer, CPP_COMMA)) break; /* Otherwise, consume the `,' and keep going. */ cp_lexer_consume_token (parser->lexer); } if (!cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'")) { int ending; skip_comma:; /* We try and resync to an unnested comma, as that will give the user better diagnostics. */ ending = cp_parser_skip_to_closing_parenthesis (parser, /*recovering=*/true, /*or_comma=*/true, /*consume_paren=*/true); if (ending < 0) goto get_comma; if (!ending) return error_mark_node; } /* We built up the list in reverse order so we must reverse it now. */ expression_list = nreverse (expression_list); if (identifier) expression_list = tree_cons (NULL_TREE, identifier, expression_list); return expression_list; } /* Parse a pseudo-destructor-name. pseudo-destructor-name: :: [opt] nested-name-specifier [opt] type-name :: ~ type-name :: [opt] nested-name-specifier template template-id :: ~ type-name :: [opt] nested-name-specifier [opt] ~ type-name If either of the first two productions is used, sets *SCOPE to the TYPE specified before the final `::'. Otherwise, *SCOPE is set to NULL_TREE. *TYPE is set to the TYPE_DECL for the final type-name, or ERROR_MARK_NODE if the parse fails. */ static void cp_parser_pseudo_destructor_name (cp_parser* parser, tree* scope, tree* type) { bool nested_name_specifier_p; /* Assume that things will not work out. */ *type = error_mark_node; /* Look for the optional `::' operator. */ cp_parser_global_scope_opt (parser, /*current_scope_valid_p=*/true); /* Look for the optional nested-name-specifier. */ nested_name_specifier_p = (cp_parser_nested_name_specifier_opt (parser, /*typename_keyword_p=*/false, /*check_dependency_p=*/true, /*type_p=*/false, /*is_declaration=*/true) != NULL_TREE); /* Now, if we saw a nested-name-specifier, we might be doing the second production. */ if (nested_name_specifier_p && cp_lexer_next_token_is_keyword (parser->lexer, RID_TEMPLATE)) { /* Consume the `template' keyword. */ cp_lexer_consume_token (parser->lexer); /* Parse the template-id. */ cp_parser_template_id (parser, /*template_keyword_p=*/true, /*check_dependency_p=*/false, /*is_declaration=*/true); /* Look for the `::' token. */ cp_parser_require (parser, CPP_SCOPE, "`::'"); } /* If the next token is not a `~', then there might be some additional qualification. */ else if (cp_lexer_next_token_is_not (parser->lexer, CPP_COMPL)) { /* Look for the type-name. */ *scope = TREE_TYPE (cp_parser_type_name (parser)); if (*scope == error_mark_node) return; /* If we don't have ::~, then something has gone wrong. Since the only caller of this function is looking for something after `.' or `->' after a scalar type, most likely the program is trying to get a member of a non-aggregate type. */ if (cp_lexer_next_token_is_not (parser->lexer, CPP_SCOPE) || cp_lexer_peek_nth_token (parser->lexer, 2)->type != CPP_COMPL) { cp_parser_error (parser, "request for member of non-aggregate type"); return; } /* Look for the `::' token. */ cp_parser_require (parser, CPP_SCOPE, "`::'"); } else *scope = NULL_TREE; /* Look for the `~'. */ cp_parser_require (parser, CPP_COMPL, "`~'"); /* Look for the type-name again. We are not responsible for checking that it matches the first type-name. */ *type = cp_parser_type_name (parser); } /* Parse a unary-expression. unary-expression: postfix-expression ++ cast-expression -- cast-expression unary-operator cast-expression sizeof unary-expression sizeof ( type-id ) new-expression delete-expression GNU Extensions: unary-expression: __extension__ cast-expression __alignof__ unary-expression __alignof__ ( type-id ) __real__ cast-expression __imag__ cast-expression && identifier ADDRESS_P is true iff the unary-expression is appearing as the operand of the `&' operator. CAST_P is true if this expression is the target of a cast. Returns a representation of the expression. */ static tree cp_parser_unary_expression (cp_parser *parser, bool address_p, bool cast_p) { cp_token *token; enum tree_code unary_operator; /* Peek at the next token. */ token = cp_lexer_peek_token (parser->lexer); /* Some keywords give away the kind of expression. */ if (token->type == CPP_KEYWORD) { enum rid keyword = token->keyword; switch (keyword) { case RID_ALIGNOF: case RID_SIZEOF: { tree operand; enum tree_code op; op = keyword == RID_ALIGNOF ? ALIGNOF_EXPR : SIZEOF_EXPR; /* Consume the token. */ cp_lexer_consume_token (parser->lexer); /* Parse the operand. */ operand = cp_parser_sizeof_operand (parser, keyword); if (TYPE_P (operand)) return cxx_sizeof_or_alignof_type (operand, op, true); else return cxx_sizeof_or_alignof_expr (operand, op); } case RID_NEW: return cp_parser_new_expression (parser); case RID_DELETE: return cp_parser_delete_expression (parser); case RID_EXTENSION: { /* The saved value of the PEDANTIC flag. */ int saved_pedantic; tree expr; /* Save away the PEDANTIC flag. */ cp_parser_extension_opt (parser, &saved_pedantic); /* Parse the cast-expression. */ expr = cp_parser_simple_cast_expression (parser); /* Restore the PEDANTIC flag. */ pedantic = saved_pedantic; return expr; } case RID_REALPART: case RID_IMAGPART: { tree expression; /* Consume the `__real__' or `__imag__' token. */ cp_lexer_consume_token (parser->lexer); /* Parse the cast-expression. */ expression = cp_parser_simple_cast_expression (parser); /* Create the complete representation. */ return build_x_unary_op ((keyword == RID_REALPART ? REALPART_EXPR : IMAGPART_EXPR), expression); } break; default: break; } } /* Look for the `:: new' and `:: delete', which also signal the beginning of a new-expression, or delete-expression, respectively. If the next token is `::', then it might be one of these. */ if (cp_lexer_next_token_is (parser->lexer, CPP_SCOPE)) { enum rid keyword; /* See if the token after the `::' is one of the keywords in which we're interested. */ keyword = cp_lexer_peek_nth_token (parser->lexer, 2)->keyword; /* If it's `new', we have a new-expression. */ if (keyword == RID_NEW) return cp_parser_new_expression (parser); /* Similarly, for `delete'. */ else if (keyword == RID_DELETE) return cp_parser_delete_expression (parser); } /* Look for a unary operator. */ unary_operator = cp_parser_unary_operator (token); /* The `++' and `--' operators can be handled similarly, even though they are not technically unary-operators in the grammar. */ if (unary_operator == ERROR_MARK) { if (token->type == CPP_PLUS_PLUS) unary_operator = PREINCREMENT_EXPR; else if (token->type == CPP_MINUS_MINUS) unary_operator = PREDECREMENT_EXPR; /* Handle the GNU address-of-label extension. */ else if (cp_parser_allow_gnu_extensions_p (parser) && token->type == CPP_AND_AND) { tree identifier; /* Consume the '&&' token. */ cp_lexer_consume_token (parser->lexer); /* Look for the identifier. */ identifier = cp_parser_identifier (parser); /* Create an expression representing the address. */ return finish_label_address_expr (identifier); } } if (unary_operator != ERROR_MARK) { tree cast_expression; tree expression = error_mark_node; const char *non_constant_p = NULL; /* Consume the operator token. */ token = cp_lexer_consume_token (parser->lexer); /* Parse the cast-expression. */ cast_expression = cp_parser_cast_expression (parser, unary_operator == ADDR_EXPR, /*cast_p=*/false); /* Now, build an appropriate representation. */ switch (unary_operator) { case INDIRECT_REF: non_constant_p = "`*'"; expression = build_x_indirect_ref (cast_expression, "unary *"); break; case ADDR_EXPR: non_constant_p = "`&'"; /* Fall through. */ case BIT_NOT_EXPR: expression = build_x_unary_op (unary_operator, cast_expression); break; case PREINCREMENT_EXPR: case PREDECREMENT_EXPR: non_constant_p = (unary_operator == PREINCREMENT_EXPR ? "`++'" : "`--'"); /* Fall through. */ case UNARY_PLUS_EXPR: case NEGATE_EXPR: case TRUTH_NOT_EXPR: expression = finish_unary_op_expr (unary_operator, cast_expression); break; default: gcc_unreachable (); } if (non_constant_p && cp_parser_non_integral_constant_expression (parser, non_constant_p)) expression = error_mark_node; return expression; } return cp_parser_postfix_expression (parser, address_p, cast_p); } /* Returns ERROR_MARK if TOKEN is not a unary-operator. If TOKEN is a unary-operator, the corresponding tree code is returned. */ static enum tree_code cp_parser_unary_operator (cp_token* token) { switch (token->type) { case CPP_MULT: return INDIRECT_REF; case CPP_AND: return ADDR_EXPR; case CPP_PLUS: return UNARY_PLUS_EXPR; case CPP_MINUS: return NEGATE_EXPR; case CPP_NOT: return TRUTH_NOT_EXPR; case CPP_COMPL: return BIT_NOT_EXPR; default: return ERROR_MARK; } } /* Parse a new-expression. new-expression: :: [opt] new new-placement [opt] new-type-id new-initializer [opt] :: [opt] new new-placement [opt] ( type-id ) new-initializer [opt] Returns a representation of the expression. */ static tree cp_parser_new_expression (cp_parser* parser) { bool global_scope_p; tree placement; tree type; tree initializer; tree nelts; /* Look for the optional `::' operator. */ global_scope_p = (cp_parser_global_scope_opt (parser, /*current_scope_valid_p=*/false) != NULL_TREE); /* Look for the `new' operator. */ cp_parser_require_keyword (parser, RID_NEW, "`new'"); /* There's no easy way to tell a new-placement from the `( type-id )' construct. */ cp_parser_parse_tentatively (parser); /* Look for a new-placement. */ placement = cp_parser_new_placement (parser); /* If that didn't work out, there's no new-placement. */ if (!cp_parser_parse_definitely (parser)) placement = NULL_TREE; /* If the next token is a `(', then we have a parenthesized type-id. */ if (cp_lexer_next_token_is (parser->lexer, CPP_OPEN_PAREN)) { /* Consume the `('. */ cp_lexer_consume_token (parser->lexer); /* Parse the type-id. */ type = cp_parser_type_id (parser); /* Look for the closing `)'. */ cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'"); /* There should not be a direct-new-declarator in this production, but GCC used to allowed this, so we check and emit a sensible error message for this case. */ if (cp_lexer_next_token_is (parser->lexer, CPP_OPEN_SQUARE)) { error ("array bound forbidden after parenthesized type-id"); inform ("try removing the parentheses around the type-id"); cp_parser_direct_new_declarator (parser); } nelts = NULL_TREE; } /* Otherwise, there must be a new-type-id. */ else type = cp_parser_new_type_id (parser, &nelts); /* If the next token is a `(', then we have a new-initializer. */ if (cp_lexer_next_token_is (parser->lexer, CPP_OPEN_PAREN)) initializer = cp_parser_new_initializer (parser); else initializer = NULL_TREE; /* A new-expression may not appear in an integral constant expression. */ if (cp_parser_non_integral_constant_expression (parser, "`new'")) return error_mark_node; /* Create a representation of the new-expression. */ return build_new (placement, type, nelts, initializer, global_scope_p); } /* Parse a new-placement. new-placement: ( expression-list ) Returns the same representation as for an expression-list. */ static tree cp_parser_new_placement (cp_parser* parser) { tree expression_list; /* Parse the expression-list. */ expression_list = (cp_parser_parenthesized_expression_list (parser, false, /*cast_p=*/false, /*non_constant_p=*/NULL)); return expression_list; } /* Parse a new-type-id. new-type-id: type-specifier-seq new-declarator [opt] Returns the TYPE allocated. If the new-type-id indicates an array type, *NELTS is set to the number of elements in the last array bound; the TYPE will not include the last array bound. */ static tree cp_parser_new_type_id (cp_parser* parser, tree *nelts) { cp_decl_specifier_seq type_specifier_seq; cp_declarator *new_declarator; cp_declarator *declarator; cp_declarator *outer_declarator; const char *saved_message; tree type; /* The type-specifier sequence must not contain type definitions. (It cannot contain declarations of new types either, but if they are not definitions we will catch that because they are not complete.) */ saved_message = parser->type_definition_forbidden_message; parser->type_definition_forbidden_message = "types may not be defined in a new-type-id"; /* Parse the type-specifier-seq. */ cp_parser_type_specifier_seq (parser, /*is_condition=*/false, &type_specifier_seq); /* Restore the old message. */ parser->type_definition_forbidden_message = saved_message; /* Parse the new-declarator. */ new_declarator = cp_parser_new_declarator_opt (parser); /* Determine the number of elements in the last array dimension, if any. */ *nelts = NULL_TREE; /* Skip down to the last array dimension. */ declarator = new_declarator; outer_declarator = NULL; while (declarator && (declarator->kind == cdk_pointer || declarator->kind == cdk_ptrmem)) { outer_declarator = declarator; declarator = declarator->declarator; } while (declarator && declarator->kind == cdk_array && declarator->declarator && declarator->declarator->kind == cdk_array) { outer_declarator = declarator; declarator = declarator->declarator; } if (declarator && declarator->kind == cdk_array) { *nelts = declarator->u.array.bounds; if (*nelts == error_mark_node) *nelts = integer_one_node; if (outer_declarator) outer_declarator->declarator = declarator->declarator; else new_declarator = NULL; } type = groktypename (&type_specifier_seq, new_declarator); if (TREE_CODE (type) == ARRAY_TYPE && *nelts == NULL_TREE) { *nelts = array_type_nelts_top (type); type = TREE_TYPE (type); } return type; } /* Parse an (optional) new-declarator. new-declarator: ptr-operator new-declarator [opt] direct-new-declarator Returns the declarator. */ static cp_declarator * cp_parser_new_declarator_opt (cp_parser* parser) { enum tree_code code; tree type; cp_cv_quals cv_quals; /* We don't know if there's a ptr-operator next, or not. */ cp_parser_parse_tentatively (parser); /* Look for a ptr-operator. */ code = cp_parser_ptr_operator (parser, &type, &cv_quals); /* If that worked, look for more new-declarators. */ if (cp_parser_parse_definitely (parser)) { cp_declarator *declarator; /* Parse another optional declarator. */ declarator = cp_parser_new_declarator_opt (parser); /* Create the representation of the declarator. */ if (type) declarator = make_ptrmem_declarator (cv_quals, type, declarator); else if (code == INDIRECT_REF) declarator = make_pointer_declarator (cv_quals, declarator); else declarator = make_reference_declarator (cv_quals, declarator); return declarator; } /* If the next token is a `[', there is a direct-new-declarator. */ if (cp_lexer_next_token_is (parser->lexer, CPP_OPEN_SQUARE)) return cp_parser_direct_new_declarator (parser); return NULL; } /* Parse a direct-new-declarator. direct-new-declarator: [ expression ] direct-new-declarator [constant-expression] */ static cp_declarator * cp_parser_direct_new_declarator (cp_parser* parser) { cp_declarator *declarator = NULL; while (true) { tree expression; /* Look for the opening `['. */ cp_parser_require (parser, CPP_OPEN_SQUARE, "`['"); /* The first expression is not required to be constant. */ if (!declarator) { expression = cp_parser_expression (parser, /*cast_p=*/false); /* The standard requires that the expression have integral type. DR 74 adds enumeration types. We believe that the real intent is that these expressions be handled like the expression in a `switch' condition, which also allows classes with a single conversion to integral or enumeration type. */ if (!processing_template_decl) { expression = build_expr_type_conversion (WANT_INT | WANT_ENUM, expression, /*complain=*/true); if (!expression) { error ("expression in new-declarator must have integral " "or enumeration type"); expression = error_mark_node; } } } /* But all the other expressions must be. */ else expression = cp_parser_constant_expression (parser, /*allow_non_constant=*/false, NULL); /* Look for the closing `]'. */ cp_parser_require (parser, CPP_CLOSE_SQUARE, "`]'"); /* Add this bound to the declarator. */ declarator = make_array_declarator (declarator, expression); /* If the next token is not a `[', then there are no more bounds. */ if (cp_lexer_next_token_is_not (parser->lexer, CPP_OPEN_SQUARE)) break; } return declarator; } /* Parse a new-initializer. new-initializer: ( expression-list [opt] ) Returns a representation of the expression-list. If there is no expression-list, VOID_ZERO_NODE is returned. */ static tree cp_parser_new_initializer (cp_parser* parser) { tree expression_list; expression_list = (cp_parser_parenthesized_expression_list (parser, false, /*cast_p=*/false, /*non_constant_p=*/NULL)); if (!expression_list) expression_list = void_zero_node; return expression_list; } /* Parse a delete-expression. delete-expression: :: [opt] delete cast-expression :: [opt] delete [ ] cast-expression Returns a representation of the expression. */ static tree cp_parser_delete_expression (cp_parser* parser) { bool global_scope_p; bool array_p; tree expression; /* Look for the optional `::' operator. */ global_scope_p = (cp_parser_global_scope_opt (parser, /*current_scope_valid_p=*/false) != NULL_TREE); /* Look for the `delete' keyword. */ cp_parser_require_keyword (parser, RID_DELETE, "`delete'"); /* See if the array syntax is in use. */ if (cp_lexer_next_token_is (parser->lexer, CPP_OPEN_SQUARE)) { /* Consume the `[' token. */ cp_lexer_consume_token (parser->lexer); /* Look for the `]' token. */ cp_parser_require (parser, CPP_CLOSE_SQUARE, "`]'"); /* Remember that this is the `[]' construct. */ array_p = true; } else array_p = false; /* Parse the cast-expression. */ expression = cp_parser_simple_cast_expression (parser); /* A delete-expression may not appear in an integral constant expression. */ if (cp_parser_non_integral_constant_expression (parser, "`delete'")) return error_mark_node; return delete_sanity (expression, NULL_TREE, array_p, global_scope_p); } /* Parse a cast-expression. cast-expression: unary-expression ( type-id ) cast-expression ADDRESS_P is true iff the unary-expression is appearing as the operand of the `&' operator. CAST_P is true if this expression is the target of a cast. Returns a representation of the expression. */ static tree cp_parser_cast_expression (cp_parser *parser, bool address_p, bool cast_p) { /* If it's a `(', then we might be looking at a cast. */ if (cp_lexer_next_token_is (parser->lexer, CPP_OPEN_PAREN)) { tree type = NULL_TREE; tree expr = NULL_TREE; bool compound_literal_p; const char *saved_message; /* There's no way to know yet whether or not this is a cast. For example, `(int (3))' is a unary-expression, while `(int) 3' is a cast. So, we resort to parsing tentatively. */ cp_parser_parse_tentatively (parser); /* Types may not be defined in a cast. */ saved_message = parser->type_definition_forbidden_message; parser->type_definition_forbidden_message = "types may not be defined in casts"; /* Consume the `('. */ cp_lexer_consume_token (parser->lexer); /* A very tricky bit is that `(struct S) { 3 }' is a compound-literal (which we permit in C++ as an extension). But, that construct is not a cast-expression -- it is a postfix-expression. (The reason is that `(struct S) { 3 }.i' is legal; if the compound-literal were a cast-expression, you'd need an extra set of parentheses.) But, if we parse the type-id, and it happens to be a class-specifier, then we will commit to the parse at that point, because we cannot undo the action that is done when creating a new class. So, then we cannot back up and do a postfix-expression. Therefore, we scan ahead to the closing `)', and check to see if the token after the `)' is a `{'. If so, we are not looking at a cast-expression. Save tokens so that we can put them back. */ cp_lexer_save_tokens (parser->lexer); /* Skip tokens until the next token is a closing parenthesis. If we find the closing `)', and the next token is a `{', then we are looking at a compound-literal. */ compound_literal_p = (cp_parser_skip_to_closing_parenthesis (parser, false, false, /*consume_paren=*/true) && cp_lexer_next_token_is (parser->lexer, CPP_OPEN_BRACE)); /* Roll back the tokens we skipped. */ cp_lexer_rollback_tokens (parser->lexer); /* If we were looking at a compound-literal, simulate an error so that the call to cp_parser_parse_definitely below will fail. */ if (compound_literal_p) cp_parser_simulate_error (parser); else { bool saved_in_type_id_in_expr_p = parser->in_type_id_in_expr_p; parser->in_type_id_in_expr_p = true; /* Look for the type-id. */ type = cp_parser_type_id (parser); /* Look for the closing `)'. */ cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'"); parser->in_type_id_in_expr_p = saved_in_type_id_in_expr_p; } /* Restore the saved message. */ parser->type_definition_forbidden_message = saved_message; /* If ok so far, parse the dependent expression. We cannot be sure it is a cast. Consider `(T ())'. It is a parenthesized ctor of T, but looks like a cast to function returning T without a dependent expression. */ if (!cp_parser_error_occurred (parser)) expr = cp_parser_cast_expression (parser, /*address_p=*/false, /*cast_p=*/true); if (cp_parser_parse_definitely (parser)) { /* Warn about old-style casts, if so requested. */ if (warn_old_style_cast && !in_system_header && !VOID_TYPE_P (type) && current_lang_name != lang_name_c) warning (OPT_Wold_style_cast, "use of old-style cast"); /* Only type conversions to integral or enumeration types can be used in constant-expressions. */ if (!cast_valid_in_integral_constant_expression_p (type) && (cp_parser_non_integral_constant_expression (parser, "a cast to a type other than an integral or " "enumeration type"))) return error_mark_node; /* Perform the cast. */ expr = build_c_cast (type, expr); return expr; } } /* If we get here, then it's not a cast, so it must be a unary-expression. */ return cp_parser_unary_expression (parser, address_p, cast_p); } /* Parse a binary expression of the general form: pm-expression: cast-expression pm-expression .* cast-expression pm-expression ->* cast-expression multiplicative-expression: pm-expression multiplicative-expression * pm-expression multiplicative-expression / pm-expression multiplicative-expression % pm-expression additive-expression: multiplicative-expression additive-expression + multiplicative-expression additive-expression - multiplicative-expression shift-expression: additive-expression shift-expression << additive-expression shift-expression >> additive-expression relational-expression: shift-expression relational-expression < shift-expression relational-expression > shift-expression relational-expression <= shift-expression relational-expression >= shift-expression GNU Extension: relational-expression: relational-expression <? shift-expression relational-expression >? shift-expression equality-expression: relational-expression equality-expression == relational-expression equality-expression != relational-expression and-expression: equality-expression and-expression & equality-expression exclusive-or-expression: and-expression exclusive-or-expression ^ and-expression inclusive-or-expression: exclusive-or-expression inclusive-or-expression | exclusive-or-expression logical-and-expression: inclusive-or-expression logical-and-expression && inclusive-or-expression logical-or-expression: logical-and-expression logical-or-expression || logical-and-expression All these are implemented with a single function like: binary-expression: simple-cast-expression binary-expression <token> binary-expression CAST_P is true if this expression is the target of a cast. The binops_by_token map is used to get the tree codes for each <token> type. binary-expressions are associated according to a precedence table. */ #define TOKEN_PRECEDENCE(token) \ ((token->type == CPP_GREATER && !parser->greater_than_is_operator_p) \ ? PREC_NOT_OPERATOR \ : binops_by_token[token->type].prec) static tree cp_parser_binary_expression (cp_parser* parser, bool cast_p) { cp_parser_expression_stack stack; cp_parser_expression_stack_entry *sp = &stack[0]; tree lhs, rhs; cp_token *token; enum tree_code tree_type; enum cp_parser_prec prec = PREC_NOT_OPERATOR, new_prec, lookahead_prec; bool overloaded_p; /* Parse the first expression. */ lhs = cp_parser_cast_expression (parser, /*address_p=*/false, cast_p); for (;;) { /* Get an operator token. */ token = cp_lexer_peek_token (parser->lexer); new_prec = TOKEN_PRECEDENCE (token); /* Popping an entry off the stack means we completed a subexpression: - either we found a token which is not an operator (`>' where it is not an operator, or prec == PREC_NOT_OPERATOR), in which case popping will happen repeatedly; - or, we found an operator which has lower priority. This is the case where the recursive descent *ascends*, as in `3 * 4 + 5' after parsing `3 * 4'. */ if (new_prec <= prec) { if (sp == stack) break; else goto pop; } get_rhs: tree_type = binops_by_token[token->type].tree_type; /* We used the operator token. */ cp_lexer_consume_token (parser->lexer); /* Extract another operand. It may be the RHS of this expression or the LHS of a new, higher priority expression. */ rhs = cp_parser_simple_cast_expression (parser); /* Get another operator token. Look up its precedence to avoid building a useless (immediately popped) stack entry for common cases such as 3 + 4 + 5 or 3 * 4 + 5. */ token = cp_lexer_peek_token (parser->lexer); lookahead_prec = TOKEN_PRECEDENCE (token); if (lookahead_prec > new_prec) { /* ... and prepare to parse the RHS of the new, higher priority expression. Since precedence levels on the stack are monotonically increasing, we do not have to care about stack overflows. */ sp->prec = prec; sp->tree_type = tree_type; sp->lhs = lhs; sp++; lhs = rhs; prec = new_prec; new_prec = lookahead_prec; goto get_rhs; pop: /* If the stack is not empty, we have parsed into LHS the right side (`4' in the example above) of an expression we had suspended. We can use the information on the stack to recover the LHS (`3') from the stack together with the tree code (`MULT_EXPR'), and the precedence of the higher level subexpression (`PREC_ADDITIVE_EXPRESSION'). TOKEN is the CPP_PLUS token, which will be used to actually build the additive expression. */ --sp; prec = sp->prec; tree_type = sp->tree_type; rhs = lhs; lhs = sp->lhs; } overloaded_p = false; lhs = build_x_binary_op (tree_type, lhs, rhs, &overloaded_p); /* If the binary operator required the use of an overloaded operator, then this expression cannot be an integral constant-expression. An overloaded operator can be used even if both operands are otherwise permissible in an integral constant-expression if at least one of the operands is of enumeration type. */ if (overloaded_p && (cp_parser_non_integral_constant_expression (parser, "calls to overloaded operators"))) return error_mark_node; } return lhs; } /* Parse the `? expression : assignment-expression' part of a conditional-expression. The LOGICAL_OR_EXPR is the logical-or-expression that started the conditional-expression. Returns a representation of the entire conditional-expression. This routine is used by cp_parser_assignment_expression. ? expression : assignment-expression GNU Extensions: ? : assignment-expression */ static tree cp_parser_question_colon_clause (cp_parser* parser, tree logical_or_expr) { tree expr; tree assignment_expr; /* Consume the `?' token. */ cp_lexer_consume_token (parser->lexer); if (cp_parser_allow_gnu_extensions_p (parser) && cp_lexer_next_token_is (parser->lexer, CPP_COLON)) /* Implicit true clause. */ expr = NULL_TREE; else /* Parse the expression. */ expr = cp_parser_expression (parser, /*cast_p=*/false); /* The next token should be a `:'. */ cp_parser_require (parser, CPP_COLON, "`:'"); /* Parse the assignment-expression. */ assignment_expr = cp_parser_assignment_expression (parser, /*cast_p=*/false); /* Build the conditional-expression. */ return build_x_conditional_expr (logical_or_expr, expr, assignment_expr); } /* Parse an assignment-expression. assignment-expression: conditional-expression logical-or-expression assignment-operator assignment_expression throw-expression CAST_P is true if this expression is the target of a cast. Returns a representation for the expression. */ static tree cp_parser_assignment_expression (cp_parser* parser, bool cast_p) { tree expr; /* If the next token is the `throw' keyword, then we're looking at a throw-expression. */ if (cp_lexer_next_token_is_keyword (parser->lexer, RID_THROW)) expr = cp_parser_throw_expression (parser); /* Otherwise, it must be that we are looking at a logical-or-expression. */ else { /* Parse the binary expressions (logical-or-expression). */ expr = cp_parser_binary_expression (parser, cast_p); /* If the next token is a `?' then we're actually looking at a conditional-expression. */ if (cp_lexer_next_token_is (parser->lexer, CPP_QUERY)) return cp_parser_question_colon_clause (parser, expr); else { enum tree_code assignment_operator; /* If it's an assignment-operator, we're using the second production. */ assignment_operator = cp_parser_assignment_operator_opt (parser); if (assignment_operator != ERROR_MARK) { tree rhs; /* Parse the right-hand side of the assignment. */ rhs = cp_parser_assignment_expression (parser, cast_p); /* An assignment may not appear in a constant-expression. */ if (cp_parser_non_integral_constant_expression (parser, "an assignment")) return error_mark_node; /* Build the assignment expression. */ expr = build_x_modify_expr (expr, assignment_operator, rhs); } } } return expr; } /* Parse an (optional) assignment-operator. assignment-operator: one of = *= /= %= += -= >>= <<= &= ^= |= GNU Extension: assignment-operator: one of <?= >?= If the next token is an assignment operator, the corresponding tree code is returned, and the token is consumed. For example, for `+=', PLUS_EXPR is returned. For `=' itself, the code returned is NOP_EXPR. For `/', TRUNC_DIV_EXPR is returned; for `%', TRUNC_MOD_EXPR is returned. If TOKEN is not an assignment operator, ERROR_MARK is returned. */ static enum tree_code cp_parser_assignment_operator_opt (cp_parser* parser) { enum tree_code op; cp_token *token; /* Peek at the next toen. */ token = cp_lexer_peek_token (parser->lexer); switch (token->type) { case CPP_EQ: op = NOP_EXPR; break; case CPP_MULT_EQ: op = MULT_EXPR; break; case CPP_DIV_EQ: op = TRUNC_DIV_EXPR; break; case CPP_MOD_EQ: op = TRUNC_MOD_EXPR; break; case CPP_PLUS_EQ: op = PLUS_EXPR; break; case CPP_MINUS_EQ: op = MINUS_EXPR; break; case CPP_RSHIFT_EQ: op = RSHIFT_EXPR; break; case CPP_LSHIFT_EQ: op = LSHIFT_EXPR; break; case CPP_AND_EQ: op = BIT_AND_EXPR; break; case CPP_XOR_EQ: op = BIT_XOR_EXPR; break; case CPP_OR_EQ: op = BIT_IOR_EXPR; break; default: /* Nothing else is an assignment operator. */ op = ERROR_MARK; } /* If it was an assignment operator, consume it. */ if (op != ERROR_MARK) cp_lexer_consume_token (parser->lexer); return op; } /* Parse an expression. expression: assignment-expression expression , assignment-expression CAST_P is true if this expression is the target of a cast. Returns a representation of the expression. */ static tree cp_parser_expression (cp_parser* parser, bool cast_p) { tree expression = NULL_TREE; while (true) { tree assignment_expression; /* Parse the next assignment-expression. */ assignment_expression = cp_parser_assignment_expression (parser, cast_p); /* If this is the first assignment-expression, we can just save it away. */ if (!expression) expression = assignment_expression; else expression = build_x_compound_expr (expression, assignment_expression); /* If the next token is not a comma, then we are done with the expression. */ if (cp_lexer_next_token_is_not (parser->lexer, CPP_COMMA)) break; /* Consume the `,'. */ cp_lexer_consume_token (parser->lexer); /* A comma operator cannot appear in a constant-expression. */ if (cp_parser_non_integral_constant_expression (parser, "a comma operator")) expression = error_mark_node; } return expression; } /* Parse a constant-expression. constant-expression: conditional-expression If ALLOW_NON_CONSTANT_P a non-constant expression is silently accepted. If ALLOW_NON_CONSTANT_P is true and the expression is not constant, *NON_CONSTANT_P is set to TRUE. If ALLOW_NON_CONSTANT_P is false, NON_CONSTANT_P should be NULL. */ static tree cp_parser_constant_expression (cp_parser* parser, bool allow_non_constant_p, bool *non_constant_p) { bool saved_integral_constant_expression_p; bool saved_allow_non_integral_constant_expression_p; bool saved_non_integral_constant_expression_p; tree expression; /* It might seem that we could simply parse the conditional-expression, and then check to see if it were TREE_CONSTANT. However, an expression that is TREE_CONSTANT is one that the compiler can figure out is constant, possibly after doing some simplifications or optimizations. The standard has a precise definition of constant-expression, and we must honor that, even though it is somewhat more restrictive. For example: int i[(2, 3)]; is not a legal declaration, because `(2, 3)' is not a constant-expression. The `,' operator is forbidden in a constant-expression. However, GCC's constant-folding machinery will fold this operation to an INTEGER_CST for `3'. */ /* Save the old settings. */ saved_integral_constant_expression_p = parser->integral_constant_expression_p; saved_allow_non_integral_constant_expression_p = parser->allow_non_integral_constant_expression_p; saved_non_integral_constant_expression_p = parser->non_integral_constant_expression_p; /* We are now parsing a constant-expression. */ parser->integral_constant_expression_p = true; parser->allow_non_integral_constant_expression_p = allow_non_constant_p; parser->non_integral_constant_expression_p = false; /* Although the grammar says "conditional-expression", we parse an "assignment-expression", which also permits "throw-expression" and the use of assignment operators. In the case that ALLOW_NON_CONSTANT_P is false, we get better errors than we would otherwise. In the case that ALLOW_NON_CONSTANT_P is true, it is actually essential that we look for an assignment-expression. For example, cp_parser_initializer_clauses uses this function to determine whether a particular assignment-expression is in fact constant. */ expression = cp_parser_assignment_expression (parser, /*cast_p=*/false); /* Restore the old settings. */ parser->integral_constant_expression_p = saved_integral_constant_expression_p; parser->allow_non_integral_constant_expression_p = saved_allow_non_integral_constant_expression_p; if (allow_non_constant_p) *non_constant_p = parser->non_integral_constant_expression_p; else if (parser->non_integral_constant_expression_p) expression = error_mark_node; parser->non_integral_constant_expression_p = saved_non_integral_constant_expression_p; return expression; } /* Parse __builtin_offsetof. offsetof-expression: "__builtin_offsetof" "(" type-id "," offsetof-member-designator ")" offsetof-member-designator: id-expression | offsetof-member-designator "." id-expression | offsetof-member-designator "[" expression "]" */ static tree cp_parser_builtin_offsetof (cp_parser *parser) { int save_ice_p, save_non_ice_p; tree type, expr; cp_id_kind dummy; /* We're about to accept non-integral-constant things, but will definitely yield an integral constant expression. Save and restore these values around our local parsing. */ save_ice_p = parser->integral_constant_expression_p; save_non_ice_p = parser->non_integral_constant_expression_p; /* Consume the "__builtin_offsetof" token. */ cp_lexer_consume_token (parser->lexer); /* Consume the opening `('. */ cp_parser_require (parser, CPP_OPEN_PAREN, "`('"); /* Parse the type-id. */ type = cp_parser_type_id (parser); /* Look for the `,'. */ cp_parser_require (parser, CPP_COMMA, "`,'"); /* Build the (type *)null that begins the traditional offsetof macro. */ expr = build_static_cast (build_pointer_type (type), null_pointer_node); /* Parse the offsetof-member-designator. We begin as if we saw "expr->". */ expr = cp_parser_postfix_dot_deref_expression (parser, CPP_DEREF, expr, true, &dummy); while (true) { cp_token *token = cp_lexer_peek_token (parser->lexer); switch (token->type) { case CPP_OPEN_SQUARE: /* offsetof-member-designator "[" expression "]" */ expr = cp_parser_postfix_open_square_expression (parser, expr, true); break; case CPP_DOT: /* offsetof-member-designator "." identifier */ cp_lexer_consume_token (parser->lexer); expr = cp_parser_postfix_dot_deref_expression (parser, CPP_DOT, expr, true, &dummy); break; case CPP_CLOSE_PAREN: /* Consume the ")" token. */ cp_lexer_consume_token (parser->lexer); goto success; default: /* Error. We know the following require will fail, but that gives the proper error message. */ cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'"); cp_parser_skip_to_closing_parenthesis (parser, true, false, true); expr = error_mark_node; goto failure; } } success: /* If we're processing a template, we can't finish the semantics yet. Otherwise we can fold the entire expression now. */ if (processing_template_decl) expr = build1 (OFFSETOF_EXPR, size_type_node, expr); else expr = finish_offsetof (expr); failure: parser->integral_constant_expression_p = save_ice_p; parser->non_integral_constant_expression_p = save_non_ice_p; return expr; } /* Statements [gram.stmt.stmt] */ /* Parse a statement. statement: labeled-statement expression-statement compound-statement selection-statement iteration-statement jump-statement declaration-statement try-block IN_COMPOUND is true when the statement is nested inside a cp_parser_compound_statement; this matters for certain pragmas. */ static void cp_parser_statement (cp_parser* parser, tree in_statement_expr, bool in_compound) { tree statement; cp_token *token; location_t statement_location; restart: /* There is no statement yet. */ statement = NULL_TREE; /* Peek at the next token. */ token = cp_lexer_peek_token (parser->lexer); /* Remember the location of the first token in the statement. */ statement_location = token->location; /* If this is a keyword, then that will often determine what kind of statement we have. */ if (token->type == CPP_KEYWORD) { enum rid keyword = token->keyword; switch (keyword) { case RID_CASE: case RID_DEFAULT: /* Looks like a labeled-statement with a case label. Parse the label, and then use tail recursion to parse the statement. */ cp_parser_label_for_labeled_statement (parser); goto restart; case RID_IF: case RID_SWITCH: statement = cp_parser_selection_statement (parser); break; case RID_WHILE: case RID_DO: case RID_FOR: statement = cp_parser_iteration_statement (parser); break; case RID_BREAK: case RID_CONTINUE: case RID_RETURN: case RID_GOTO: statement = cp_parser_jump_statement (parser); break; /* Objective-C++ exception-handling constructs. */ case RID_AT_TRY: case RID_AT_CATCH: case RID_AT_FINALLY: case RID_AT_SYNCHRONIZED: case RID_AT_THROW: statement = cp_parser_objc_statement (parser); break; case RID_TRY: statement = cp_parser_try_block (parser); break; default: /* It might be a keyword like `int' that can start a declaration-statement. */ break; } } else if (token->type == CPP_NAME) { /* If the next token is a `:', then we are looking at a labeled-statement. */ token = cp_lexer_peek_nth_token (parser->lexer, 2); if (token->type == CPP_COLON) { /* Looks like a labeled-statement with an ordinary label. Parse the label, and then use tail recursion to parse the statement. */ cp_parser_label_for_labeled_statement (parser); goto restart; } } /* Anything that starts with a `{' must be a compound-statement. */ else if (token->type == CPP_OPEN_BRACE) statement = cp_parser_compound_statement (parser, NULL, false); /* CPP_PRAGMA is a #pragma inside a function body, which constitutes a statement all its own. */ else if (token->type == CPP_PRAGMA) { /* Only certain OpenMP pragmas are attached to statements, and thus are considered statements themselves. All others are not. In the context of a compound, accept the pragma as a "statement" and return so that we can check for a close brace. Otherwise we require a real statement and must go back and read one. */ if (in_compound) cp_parser_pragma (parser, pragma_compound); else if (!cp_parser_pragma (parser, pragma_stmt)) goto restart; return; } else if (token->type == CPP_EOF) { cp_parser_error (parser, "expected statement"); return; } /* Everything else must be a declaration-statement or an expression-statement. Try for the declaration-statement first, unless we are looking at a `;', in which case we know that we have an expression-statement. */ if (!statement) { if (cp_lexer_next_token_is_not (parser->lexer, CPP_SEMICOLON)) { cp_parser_parse_tentatively (parser); /* Try to parse the declaration-statement. */ cp_parser_declaration_statement (parser); /* If that worked, we're done. */ if (cp_parser_parse_definitely (parser)) return; } /* Look for an expression-statement instead. */ statement = cp_parser_expression_statement (parser, in_statement_expr); } /* Set the line number for the statement. */ if (statement && STATEMENT_CODE_P (TREE_CODE (statement))) SET_EXPR_LOCATION (statement, statement_location); } /* Parse the label for a labeled-statement, i.e. identifier : case constant-expression : default : GNU Extension: case constant-expression ... constant-expression : statement When a label is parsed without errors, the label is added to the parse tree by the finish_* functions, so this function doesn't have to return the label. */ static void cp_parser_label_for_labeled_statement (cp_parser* parser) { cp_token *token; /* The next token should be an identifier. */ token = cp_lexer_peek_token (parser->lexer); if (token->type != CPP_NAME && token->type != CPP_KEYWORD) { cp_parser_error (parser, "expected labeled-statement"); return; } switch (token->keyword) { case RID_CASE: { tree expr, expr_hi; cp_token *ellipsis; /* Consume the `case' token. */ cp_lexer_consume_token (parser->lexer); /* Parse the constant-expression. */ expr = cp_parser_constant_expression (parser, /*allow_non_constant_p=*/false, NULL); ellipsis = cp_lexer_peek_token (parser->lexer); if (ellipsis->type == CPP_ELLIPSIS) { /* Consume the `...' token. */ cp_lexer_consume_token (parser->lexer); expr_hi = cp_parser_constant_expression (parser, /*allow_non_constant_p=*/false, NULL); /* We don't need to emit warnings here, as the common code will do this for us. */ } else expr_hi = NULL_TREE; if (parser->in_switch_statement_p) finish_case_label (expr, expr_hi); else error ("case label %qE not within a switch statement", expr); } break; case RID_DEFAULT: /* Consume the `default' token. */ cp_lexer_consume_token (parser->lexer); if (parser->in_switch_statement_p) finish_case_label (NULL_TREE, NULL_TREE); else error ("case label not within a switch statement"); break; default: /* Anything else must be an ordinary label. */ finish_label_stmt (cp_parser_identifier (parser)); break; } /* Require the `:' token. */ cp_parser_require (parser, CPP_COLON, "`:'"); } /* Parse an expression-statement. expression-statement: expression [opt] ; Returns the new EXPR_STMT -- or NULL_TREE if the expression statement consists of nothing more than an `;'. IN_STATEMENT_EXPR_P indicates whether this expression-statement is part of an expression statement. */ static tree cp_parser_expression_statement (cp_parser* parser, tree in_statement_expr) { tree statement = NULL_TREE; /* If the next token is a ';', then there is no expression statement. */ if (cp_lexer_next_token_is_not (parser->lexer, CPP_SEMICOLON)) statement = cp_parser_expression (parser, /*cast_p=*/false); /* Consume the final `;'. */ cp_parser_consume_semicolon_at_end_of_statement (parser); if (in_statement_expr && cp_lexer_next_token_is (parser->lexer, CPP_CLOSE_BRACE)) /* This is the final expression statement of a statement expression. */ statement = finish_stmt_expr_expr (statement, in_statement_expr); else if (statement) statement = finish_expr_stmt (statement); else finish_stmt (); return statement; } /* Parse a compound-statement. compound-statement: { statement-seq [opt] } Returns a tree representing the statement. */ static tree cp_parser_compound_statement (cp_parser *parser, tree in_statement_expr, bool in_try) { tree compound_stmt; /* Consume the `{'. */ if (!cp_parser_require (parser, CPP_OPEN_BRACE, "`{'")) return error_mark_node; /* Begin the compound-statement. */ compound_stmt = begin_compound_stmt (in_try ? BCS_TRY_BLOCK : 0); /* Parse an (optional) statement-seq. */ cp_parser_statement_seq_opt (parser, in_statement_expr); /* Finish the compound-statement. */ finish_compound_stmt (compound_stmt); /* Consume the `}'. */ cp_parser_require (parser, CPP_CLOSE_BRACE, "`}'"); return compound_stmt; } /* Parse an (optional) statement-seq. statement-seq: statement statement-seq [opt] statement */ static void cp_parser_statement_seq_opt (cp_parser* parser, tree in_statement_expr) { /* Scan statements until there aren't any more. */ while (true) { cp_token *token = cp_lexer_peek_token (parser->lexer); /* If we're looking at a `}', then we've run out of statements. */ if (token->type == CPP_CLOSE_BRACE || token->type == CPP_EOF || token->type == CPP_PRAGMA_EOL) break; /* Parse the statement. */ cp_parser_statement (parser, in_statement_expr, true); } } /* Parse a selection-statement. selection-statement: if ( condition ) statement if ( condition ) statement else statement switch ( condition ) statement Returns the new IF_STMT or SWITCH_STMT. */ static tree cp_parser_selection_statement (cp_parser* parser) { cp_token *token; enum rid keyword; /* Peek at the next token. */ token = cp_parser_require (parser, CPP_KEYWORD, "selection-statement"); /* See what kind of keyword it is. */ keyword = token->keyword; switch (keyword) { case RID_IF: case RID_SWITCH: { tree statement; tree condition; /* Look for the `('. */ if (!cp_parser_require (parser, CPP_OPEN_PAREN, "`('")) { cp_parser_skip_to_end_of_statement (parser); return error_mark_node; } /* Begin the selection-statement. */ if (keyword == RID_IF) statement = begin_if_stmt (); else statement = begin_switch_stmt (); /* Parse the condition. */ condition = cp_parser_condition (parser); /* Look for the `)'. */ if (!cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'")) cp_parser_skip_to_closing_parenthesis (parser, true, false, /*consume_paren=*/true); if (keyword == RID_IF) { /* Add the condition. */ finish_if_stmt_cond (condition, statement); /* Parse the then-clause. */ cp_parser_implicitly_scoped_statement (parser); finish_then_clause (statement); /* If the next token is `else', parse the else-clause. */ if (cp_lexer_next_token_is_keyword (parser->lexer, RID_ELSE)) { /* Consume the `else' keyword. */ cp_lexer_consume_token (parser->lexer); begin_else_clause (statement); /* Parse the else-clause. */ cp_parser_implicitly_scoped_statement (parser); finish_else_clause (statement); } /* Now we're all done with the if-statement. */ finish_if_stmt (statement); } else { bool in_switch_statement_p; unsigned char in_statement; /* Add the condition. */ finish_switch_cond (condition, statement); /* Parse the body of the switch-statement. */ in_switch_statement_p = parser->in_switch_statement_p; in_statement = parser->in_statement; parser->in_switch_statement_p = true; parser->in_statement |= IN_SWITCH_STMT; cp_parser_implicitly_scoped_statement (parser); parser->in_switch_statement_p = in_switch_statement_p; parser->in_statement = in_statement; /* Now we're all done with the switch-statement. */ finish_switch_stmt (statement); } return statement; } break; default: cp_parser_error (parser, "expected selection-statement"); return error_mark_node; } } /* Parse a condition. condition: expression type-specifier-seq declarator = assignment-expression GNU Extension: condition: type-specifier-seq declarator asm-specification [opt] attributes [opt] = assignment-expression Returns the expression that should be tested. */ static tree cp_parser_condition (cp_parser* parser) { cp_decl_specifier_seq type_specifiers; const char *saved_message; /* Try the declaration first. */ cp_parser_parse_tentatively (parser); /* New types are not allowed in the type-specifier-seq for a condition. */ saved_message = parser->type_definition_forbidden_message; parser->type_definition_forbidden_message = "types may not be defined in conditions"; /* Parse the type-specifier-seq. */ cp_parser_type_specifier_seq (parser, /*is_condition==*/true, &type_specifiers); /* Restore the saved message. */ parser->type_definition_forbidden_message = saved_message; /* If all is well, we might be looking at a declaration. */ if (!cp_parser_error_occurred (parser)) { tree decl; tree asm_specification; tree attributes; cp_declarator *declarator; tree initializer = NULL_TREE; /* Parse the declarator. */ declarator = cp_parser_declarator (parser, CP_PARSER_DECLARATOR_NAMED, /*ctor_dtor_or_conv_p=*/NULL, /*parenthesized_p=*/NULL, /*member_p=*/false); /* Parse the attributes. */ attributes = cp_parser_attributes_opt (parser); /* Parse the asm-specification. */ asm_specification = cp_parser_asm_specification_opt (parser); /* If the next token is not an `=', then we might still be looking at an expression. For example: if (A(a).x) looks like a decl-specifier-seq and a declarator -- but then there is no `=', so this is an expression. */ cp_parser_require (parser, CPP_EQ, "`='"); /* If we did see an `=', then we are looking at a declaration for sure. */ if (cp_parser_parse_definitely (parser)) { tree pushed_scope; bool non_constant_p; /* Create the declaration. */ decl = start_decl (declarator, &type_specifiers, /*initialized_p=*/true, attributes, /*prefix_attributes=*/NULL_TREE, &pushed_scope); /* Parse the assignment-expression. */ initializer = cp_parser_constant_expression (parser, /*allow_non_constant_p=*/true, &non_constant_p); if (!non_constant_p) initializer = fold_non_dependent_expr (initializer); /* Process the initializer. */ cp_finish_decl (decl, initializer, !non_constant_p, asm_specification, LOOKUP_ONLYCONVERTING); if (pushed_scope) pop_scope (pushed_scope); return convert_from_reference (decl); } } /* If we didn't even get past the declarator successfully, we are definitely not looking at a declaration. */ else cp_parser_abort_tentative_parse (parser); /* Otherwise, we are looking at an expression. */ return cp_parser_expression (parser, /*cast_p=*/false); } /* Parse an iteration-statement. iteration-statement: while ( condition ) statement do statement while ( expression ) ; for ( for-init-statement condition [opt] ; expression [opt] ) statement Returns the new WHILE_STMT, DO_STMT, or FOR_STMT. */ static tree cp_parser_iteration_statement (cp_parser* parser) { cp_token *token; enum rid keyword; tree statement; unsigned char in_statement; /* Peek at the next token. */ token = cp_parser_require (parser, CPP_KEYWORD, "iteration-statement"); if (!token) return error_mark_node; /* Remember whether or not we are already within an iteration statement. */ in_statement = parser->in_statement; /* See what kind of keyword it is. */ keyword = token->keyword; switch (keyword) { case RID_WHILE: { tree condition; /* Begin the while-statement. */ statement = begin_while_stmt (); /* Look for the `('. */ cp_parser_require (parser, CPP_OPEN_PAREN, "`('"); /* Parse the condition. */ condition = cp_parser_condition (parser); finish_while_stmt_cond (condition, statement); /* Look for the `)'. */ cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'"); /* Parse the dependent statement. */ parser->in_statement = IN_ITERATION_STMT; cp_parser_already_scoped_statement (parser); parser->in_statement = in_statement; /* We're done with the while-statement. */ finish_while_stmt (statement); } break; case RID_DO: { tree expression; /* Begin the do-statement. */ statement = begin_do_stmt (); /* Parse the body of the do-statement. */ parser->in_statement = IN_ITERATION_STMT; cp_parser_implicitly_scoped_statement (parser); parser->in_statement = in_statement; finish_do_body (statement); /* Look for the `while' keyword. */ cp_parser_require_keyword (parser, RID_WHILE, "`while'"); /* Look for the `('. */ cp_parser_require (parser, CPP_OPEN_PAREN, "`('"); /* Parse the expression. */ expression = cp_parser_expression (parser, /*cast_p=*/false); /* We're done with the do-statement. */ finish_do_stmt (expression, statement); /* Look for the `)'. */ cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'"); /* Look for the `;'. */ cp_parser_require (parser, CPP_SEMICOLON, "`;'"); } break; case RID_FOR: { tree condition = NULL_TREE; tree expression = NULL_TREE; /* Begin the for-statement. */ statement = begin_for_stmt (); /* Look for the `('. */ cp_parser_require (parser, CPP_OPEN_PAREN, "`('"); /* Parse the initialization. */ cp_parser_for_init_statement (parser); finish_for_init_stmt (statement); /* If there's a condition, process it. */ if (cp_lexer_next_token_is_not (parser->lexer, CPP_SEMICOLON)) condition = cp_parser_condition (parser); finish_for_cond (condition, statement); /* Look for the `;'. */ cp_parser_require (parser, CPP_SEMICOLON, "`;'"); /* If there's an expression, process it. */ if (cp_lexer_next_token_is_not (parser->lexer, CPP_CLOSE_PAREN)) expression = cp_parser_expression (parser, /*cast_p=*/false); finish_for_expr (expression, statement); /* Look for the `)'. */ cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'"); /* Parse the body of the for-statement. */ parser->in_statement = IN_ITERATION_STMT; cp_parser_already_scoped_statement (parser); parser->in_statement = in_statement; /* We're done with the for-statement. */ finish_for_stmt (statement); } break; default: cp_parser_error (parser, "expected iteration-statement"); statement = error_mark_node; break; } return statement; } /* Parse a for-init-statement. for-init-statement: expression-statement simple-declaration */ static void cp_parser_for_init_statement (cp_parser* parser) { /* If the next token is a `;', then we have an empty expression-statement. Grammatically, this is also a simple-declaration, but an invalid one, because it does not declare anything. Therefore, if we did not handle this case specially, we would issue an error message about an invalid declaration. */ if (cp_lexer_next_token_is_not (parser->lexer, CPP_SEMICOLON)) { /* We're going to speculatively look for a declaration, falling back to an expression, if necessary. */ cp_parser_parse_tentatively (parser); /* Parse the declaration. */ cp_parser_simple_declaration (parser, /*function_definition_allowed_p=*/false); /* If the tentative parse failed, then we shall need to look for an expression-statement. */ if (cp_parser_parse_definitely (parser)) return; } cp_parser_expression_statement (parser, false); } /* Parse a jump-statement. jump-statement: break ; continue ; return expression [opt] ; goto identifier ; GNU extension: jump-statement: goto * expression ; Returns the new BREAK_STMT, CONTINUE_STMT, RETURN_EXPR, or GOTO_EXPR. */ static tree cp_parser_jump_statement (cp_parser* parser) { tree statement = error_mark_node; cp_token *token; enum rid keyword; /* Peek at the next token. */ token = cp_parser_require (parser, CPP_KEYWORD, "jump-statement"); if (!token) return error_mark_node; /* See what kind of keyword it is. */ keyword = token->keyword; switch (keyword) { case RID_BREAK: switch (parser->in_statement) { case 0: error ("break statement not within loop or switch"); break; default: gcc_assert ((parser->in_statement & IN_SWITCH_STMT) || parser->in_statement == IN_ITERATION_STMT); statement = finish_break_stmt (); break; case IN_OMP_BLOCK: error ("invalid exit from OpenMP structured block"); break; case IN_OMP_FOR: error ("break statement used with OpenMP for loop"); break; } cp_parser_require (parser, CPP_SEMICOLON, "%<;%>"); break; case RID_CONTINUE: switch (parser->in_statement & ~IN_SWITCH_STMT) { case 0: error ("continue statement not within a loop"); break; case IN_ITERATION_STMT: case IN_OMP_FOR: statement = finish_continue_stmt (); break; case IN_OMP_BLOCK: error ("invalid exit from OpenMP structured block"); break; default: gcc_unreachable (); } cp_parser_require (parser, CPP_SEMICOLON, "%<;%>"); break; case RID_RETURN: { tree expr; /* If the next token is a `;', then there is no expression. */ if (cp_lexer_next_token_is_not (parser->lexer, CPP_SEMICOLON)) expr = cp_parser_expression (parser, /*cast_p=*/false); else expr = NULL_TREE; /* Build the return-statement. */ statement = finish_return_stmt (expr); /* Look for the final `;'. */ cp_parser_require (parser, CPP_SEMICOLON, "%<;%>"); } break; case RID_GOTO: /* Create the goto-statement. */ if (cp_lexer_next_token_is (parser->lexer, CPP_MULT)) { /* Issue a warning about this use of a GNU extension. */ if (pedantic) pedwarn ("ISO C++ forbids computed gotos"); /* Consume the '*' token. */ cp_lexer_consume_token (parser->lexer); /* Parse the dependent expression. */ finish_goto_stmt (cp_parser_expression (parser, /*cast_p=*/false)); } else finish_goto_stmt (cp_parser_identifier (parser)); /* Look for the final `;'. */ cp_parser_require (parser, CPP_SEMICOLON, "%<;%>"); break; default: cp_parser_error (parser, "expected jump-statement"); break; } return statement; } /* Parse a declaration-statement. declaration-statement: block-declaration */ static void cp_parser_declaration_statement (cp_parser* parser) { void *p; /* Get the high-water mark for the DECLARATOR_OBSTACK. */ p = obstack_alloc (&declarator_obstack, 0); /* Parse the block-declaration. */ cp_parser_block_declaration (parser, /*statement_p=*/true); /* Free any declarators allocated. */ obstack_free (&declarator_obstack, p); /* Finish off the statement. */ finish_stmt (); } /* Some dependent statements (like `if (cond) statement'), are implicitly in their own scope. In other words, if the statement is a single statement (as opposed to a compound-statement), it is none-the-less treated as if it were enclosed in braces. Any declarations appearing in the dependent statement are out of scope after control passes that point. This function parses a statement, but ensures that is in its own scope, even if it is not a compound-statement. Returns the new statement. */ static tree cp_parser_implicitly_scoped_statement (cp_parser* parser) { tree statement; /* Mark if () ; with a special NOP_EXPR. */ if (cp_lexer_next_token_is (parser->lexer, CPP_SEMICOLON)) { cp_lexer_consume_token (parser->lexer); statement = add_stmt (build_empty_stmt ()); } /* if a compound is opened, we simply parse the statement directly. */ else if (cp_lexer_next_token_is (parser->lexer, CPP_OPEN_BRACE)) statement = cp_parser_compound_statement (parser, NULL, false); /* If the token is not a `{', then we must take special action. */ else { /* Create a compound-statement. */ statement = begin_compound_stmt (0); /* Parse the dependent-statement. */ cp_parser_statement (parser, NULL_TREE, false); /* Finish the dummy compound-statement. */ finish_compound_stmt (statement); } /* Return the statement. */ return statement; } /* For some dependent statements (like `while (cond) statement'), we have already created a scope. Therefore, even if the dependent statement is a compound-statement, we do not want to create another scope. */ static void cp_parser_already_scoped_statement (cp_parser* parser) { /* If the token is a `{', then we must take special action. */ if (cp_lexer_next_token_is_not (parser->lexer, CPP_OPEN_BRACE)) cp_parser_statement (parser, NULL_TREE, false); else { /* Avoid calling cp_parser_compound_statement, so that we don't create a new scope. Do everything else by hand. */ cp_parser_require (parser, CPP_OPEN_BRACE, "`{'"); cp_parser_statement_seq_opt (parser, NULL_TREE); cp_parser_require (parser, CPP_CLOSE_BRACE, "`}'"); } } /* Declarations [gram.dcl.dcl] */ /* Parse an optional declaration-sequence. declaration-seq: declaration declaration-seq declaration */ static void cp_parser_declaration_seq_opt (cp_parser* parser) { while (true) { cp_token *token; token = cp_lexer_peek_token (parser->lexer); if (token->type == CPP_CLOSE_BRACE || token->type == CPP_EOF || token->type == CPP_PRAGMA_EOL) break; if (token->type == CPP_SEMICOLON) { /* A declaration consisting of a single semicolon is invalid. Allow it unless we're being pedantic. */ cp_lexer_consume_token (parser->lexer); if (pedantic && !in_system_header) pedwarn ("extra %<;%>"); continue; } /* If we're entering or exiting a region that's implicitly extern "C", modify the lang context appropriately. */ if (!parser->implicit_extern_c && token->implicit_extern_c) { push_lang_context (lang_name_c); parser->implicit_extern_c = true; } else if (parser->implicit_extern_c && !token->implicit_extern_c) { pop_lang_context (); parser->implicit_extern_c = false; } if (token->type == CPP_PRAGMA) { /* A top-level declaration can consist solely of a #pragma. A nested declaration cannot, so this is done here and not in cp_parser_declaration. (A #pragma at block scope is handled in cp_parser_statement.) */ cp_parser_pragma (parser, pragma_external); continue; } /* Parse the declaration itself. */ cp_parser_declaration (parser); } } /* Parse a declaration. declaration: block-declaration function-definition template-declaration explicit-instantiation explicit-specialization linkage-specification namespace-definition GNU extension: declaration: __extension__ declaration */ static void cp_parser_declaration (cp_parser* parser) { cp_token token1; cp_token token2; int saved_pedantic; void *p; /* Check for the `__extension__' keyword. */ if (cp_parser_extension_opt (parser, &saved_pedantic)) { /* Parse the qualified declaration. */ cp_parser_declaration (parser); /* Restore the PEDANTIC flag. */ pedantic = saved_pedantic; return; } /* Try to figure out what kind of declaration is present. */ token1 = *cp_lexer_peek_token (parser->lexer); if (token1.type != CPP_EOF) token2 = *cp_lexer_peek_nth_token (parser->lexer, 2); else { token2.type = CPP_EOF; token2.keyword = RID_MAX; } /* Get the high-water mark for the DECLARATOR_OBSTACK. */ p = obstack_alloc (&declarator_obstack, 0); /* If the next token is `extern' and the following token is a string literal, then we have a linkage specification. */ if (token1.keyword == RID_EXTERN && cp_parser_is_string_literal (&token2)) cp_parser_linkage_specification (parser); /* If the next token is `template', then we have either a template declaration, an explicit instantiation, or an explicit specialization. */ else if (token1.keyword == RID_TEMPLATE) { /* `template <>' indicates a template specialization. */ if (token2.type == CPP_LESS && cp_lexer_peek_nth_token (parser->lexer, 3)->type == CPP_GREATER) cp_parser_explicit_specialization (parser); /* `template <' indicates a template declaration. */ else if (token2.type == CPP_LESS) cp_parser_template_declaration (parser, /*member_p=*/false); /* Anything else must be an explicit instantiation. */ else cp_parser_explicit_instantiation (parser); } /* If the next token is `export', then we have a template declaration. */ else if (token1.keyword == RID_EXPORT) cp_parser_template_declaration (parser, /*member_p=*/false); /* If the next token is `extern', 'static' or 'inline' and the one after that is `template', we have a GNU extended explicit instantiation directive. */ else if (cp_parser_allow_gnu_extensions_p (parser) && (token1.keyword == RID_EXTERN || token1.keyword == RID_STATIC || token1.keyword == RID_INLINE) && token2.keyword == RID_TEMPLATE) cp_parser_explicit_instantiation (parser); /* If the next token is `namespace', check for a named or unnamed namespace definition. */ else if (token1.keyword == RID_NAMESPACE && (/* A named namespace definition. */ (token2.type == CPP_NAME && (cp_lexer_peek_nth_token (parser->lexer, 3)->type != CPP_EQ)) /* An unnamed namespace definition. */ || token2.type == CPP_OPEN_BRACE || token2.keyword == RID_ATTRIBUTE)) cp_parser_namespace_definition (parser); /* Objective-C++ declaration/definition. */ else if (c_dialect_objc () && OBJC_IS_AT_KEYWORD (token1.keyword)) cp_parser_objc_declaration (parser); /* We must have either a block declaration or a function definition. */ else /* Try to parse a block-declaration, or a function-definition. */ cp_parser_block_declaration (parser, /*statement_p=*/false); /* Free any declarators allocated. */ obstack_free (&declarator_obstack, p); } /* Parse a block-declaration. block-declaration: simple-declaration asm-definition namespace-alias-definition using-declaration using-directive GNU Extension: block-declaration: __extension__ block-declaration label-declaration If STATEMENT_P is TRUE, then this block-declaration is occurring as part of a declaration-statement. */ static void cp_parser_block_declaration (cp_parser *parser, bool statement_p) { cp_token *token1; int saved_pedantic; /* Check for the `__extension__' keyword. */ if (cp_parser_extension_opt (parser, &saved_pedantic)) { /* Parse the qualified declaration. */ cp_parser_block_declaration (parser, statement_p); /* Restore the PEDANTIC flag. */ pedantic = saved_pedantic; return; } /* Peek at the next token to figure out which kind of declaration is present. */ token1 = cp_lexer_peek_token (parser->lexer); /* If the next keyword is `asm', we have an asm-definition. */ if (token1->keyword == RID_ASM) { if (statement_p) cp_parser_commit_to_tentative_parse (parser); cp_parser_asm_definition (parser); } /* If the next keyword is `namespace', we have a namespace-alias-definition. */ else if (token1->keyword == RID_NAMESPACE) cp_parser_namespace_alias_definition (parser); /* If the next keyword is `using', we have either a using-declaration or a using-directive. */ else if (token1->keyword == RID_USING) { cp_token *token2; if (statement_p) cp_parser_commit_to_tentative_parse (parser); /* If the token after `using' is `namespace', then we have a using-directive. */ token2 = cp_lexer_peek_nth_token (parser->lexer, 2); if (token2->keyword == RID_NAMESPACE) cp_parser_using_directive (parser); /* Otherwise, it's a using-declaration. */ else cp_parser_using_declaration (parser, /*access_declaration_p=*/false); } /* If the next keyword is `__label__' we have a label declaration. */ else if (token1->keyword == RID_LABEL) { if (statement_p) cp_parser_commit_to_tentative_parse (parser); cp_parser_label_declaration (parser); } /* Anything else must be a simple-declaration. */ else cp_parser_simple_declaration (parser, !statement_p); } /* Parse a simple-declaration. simple-declaration: decl-specifier-seq [opt] init-declarator-list [opt] ; init-declarator-list: init-declarator init-declarator-list , init-declarator If FUNCTION_DEFINITION_ALLOWED_P is TRUE, then we also recognize a function-definition as a simple-declaration. */ static void cp_parser_simple_declaration (cp_parser* parser, bool function_definition_allowed_p) { cp_decl_specifier_seq decl_specifiers; int declares_class_or_enum; bool saw_declarator; /* Defer access checks until we know what is being declared; the checks for names appearing in the decl-specifier-seq should be done as if we were in the scope of the thing being declared. */ push_deferring_access_checks (dk_deferred); /* Parse the decl-specifier-seq. We have to keep track of whether or not the decl-specifier-seq declares a named class or enumeration type, since that is the only case in which the init-declarator-list is allowed to be empty. [dcl.dcl] In a simple-declaration, the optional init-declarator-list can be omitted only when declaring a class or enumeration, that is when the decl-specifier-seq contains either a class-specifier, an elaborated-type-specifier, or an enum-specifier. */ cp_parser_decl_specifier_seq (parser, CP_PARSER_FLAGS_OPTIONAL, &decl_specifiers, &declares_class_or_enum); /* We no longer need to defer access checks. */ stop_deferring_access_checks (); /* In a block scope, a valid declaration must always have a decl-specifier-seq. By not trying to parse declarators, we can resolve the declaration/expression ambiguity more quickly. */ if (!function_definition_allowed_p && !decl_specifiers.any_specifiers_p) { cp_parser_error (parser, "expected declaration"); goto done; } /* If the next two tokens are both identifiers, the code is erroneous. The usual cause of this situation is code like: T t; where "T" should name a type -- but does not. */ if (!decl_specifiers.type && cp_parser_parse_and_diagnose_invalid_type_name (parser)) { /* If parsing tentatively, we should commit; we really are looking at a declaration. */ cp_parser_commit_to_tentative_parse (parser); /* Give up. */ goto done; } /* If we have seen at least one decl-specifier, and the next token is not a parenthesis, then we must be looking at a declaration. (After "int (" we might be looking at a functional cast.) */ if (decl_specifiers.any_specifiers_p && cp_lexer_next_token_is_not (parser->lexer, CPP_OPEN_PAREN)) cp_parser_commit_to_tentative_parse (parser); /* Keep going until we hit the `;' at the end of the simple declaration. */ saw_declarator = false; while (cp_lexer_next_token_is_not (parser->lexer, CPP_SEMICOLON)) { cp_token *token; bool function_definition_p; tree decl; if (saw_declarator) { /* If we are processing next declarator, coma is expected */ token = cp_lexer_peek_token (parser->lexer); gcc_assert (token->type == CPP_COMMA); cp_lexer_consume_token (parser->lexer); } else saw_declarator = true; /* Parse the init-declarator. */ decl = cp_parser_init_declarator (parser, &decl_specifiers, /*checks=*/NULL, function_definition_allowed_p, /*member_p=*/false, declares_class_or_enum, &function_definition_p); /* If an error occurred while parsing tentatively, exit quickly. (That usually happens when in the body of a function; each statement is treated as a declaration-statement until proven otherwise.) */ if (cp_parser_error_occurred (parser)) goto done; /* Handle function definitions specially. */ if (function_definition_p) { /* If the next token is a `,', then we are probably processing something like: void f() {}, *p; which is erroneous. */ if (cp_lexer_next_token_is (parser->lexer, CPP_COMMA)) error ("mixing declarations and function-definitions is forbidden"); /* Otherwise, we're done with the list of declarators. */ else { pop_deferring_access_checks (); return; } } /* The next token should be either a `,' or a `;'. */ token = cp_lexer_peek_token (parser->lexer); /* If it's a `,', there are more declarators to come. */ if (token->type == CPP_COMMA) /* will be consumed next time around */; /* If it's a `;', we are done. */ else if (token->type == CPP_SEMICOLON) break; /* Anything else is an error. */ else { /* If we have already issued an error message we don't need to issue another one. */ if (decl != error_mark_node || cp_parser_uncommitted_to_tentative_parse_p (parser)) cp_parser_error (parser, "expected %<,%> or %<;%>"); /* Skip tokens until we reach the end of the statement. */ cp_parser_skip_to_end_of_statement (parser); /* If the next token is now a `;', consume it. */ if (cp_lexer_next_token_is (parser->lexer, CPP_SEMICOLON)) cp_lexer_consume_token (parser->lexer); goto done; } /* After the first time around, a function-definition is not allowed -- even if it was OK at first. For example: int i, f() {} is not valid. */ function_definition_allowed_p = false; } /* Issue an error message if no declarators are present, and the decl-specifier-seq does not itself declare a class or enumeration. */ if (!saw_declarator) { if (cp_parser_declares_only_class_p (parser)) shadow_tag (&decl_specifiers); /* Perform any deferred access checks. */ perform_deferred_access_checks (); } /* Consume the `;'. */ cp_parser_require (parser, CPP_SEMICOLON, "`;'"); done: pop_deferring_access_checks (); } /* Parse a decl-specifier-seq. decl-specifier-seq: decl-specifier-seq [opt] decl-specifier decl-specifier: storage-class-specifier type-specifier function-specifier friend typedef GNU Extension: decl-specifier: attributes Set *DECL_SPECS to a representation of the decl-specifier-seq. The parser flags FLAGS is used to control type-specifier parsing. *DECLARES_CLASS_OR_ENUM is set to the bitwise or of the following flags: 1: one of the decl-specifiers is an elaborated-type-specifier (i.e., a type declaration) 2: one of the decl-specifiers is an enum-specifier or a class-specifier (i.e., a type definition) */ static void cp_parser_decl_specifier_seq (cp_parser* parser, cp_parser_flags flags, cp_decl_specifier_seq *decl_specs, int* declares_class_or_enum) { bool constructor_possible_p = !parser->in_declarator_p; /* Clear DECL_SPECS. */ clear_decl_specs (decl_specs); /* Assume no class or enumeration type is declared. */ *declares_class_or_enum = 0; /* Keep reading specifiers until there are no more to read. */ while (true) { bool constructor_p; bool found_decl_spec; cp_token *token; /* Peek at the next token. */ token = cp_lexer_peek_token (parser->lexer); /* Handle attributes. */ if (token->keyword == RID_ATTRIBUTE) { /* Parse the attributes. */ decl_specs->attributes = chainon (decl_specs->attributes, cp_parser_attributes_opt (parser)); continue; } /* Assume we will find a decl-specifier keyword. */ found_decl_spec = true; /* If the next token is an appropriate keyword, we can simply add it to the list. */ switch (token->keyword) { /* decl-specifier: friend */ case RID_FRIEND: if (!at_class_scope_p ()) { error ("%<friend%> used outside of class"); cp_lexer_purge_token (parser->lexer); } else { ++decl_specs->specs[(int) ds_friend]; /* Consume the token. */ cp_lexer_consume_token (parser->lexer); } break; /* function-specifier: inline virtual explicit */ case RID_INLINE: case RID_VIRTUAL: case RID_EXPLICIT: cp_parser_function_specifier_opt (parser, decl_specs); break; /* decl-specifier: typedef */ case RID_TYPEDEF: ++decl_specs->specs[(int) ds_typedef]; /* Consume the token. */ cp_lexer_consume_token (parser->lexer); /* A constructor declarator cannot appear in a typedef. */ constructor_possible_p = false; /* The "typedef" keyword can only occur in a declaration; we may as well commit at this point. */ cp_parser_commit_to_tentative_parse (parser); if (decl_specs->storage_class != sc_none) decl_specs->conflicting_specifiers_p = true; break; /* storage-class-specifier: auto register static extern mutable GNU Extension: thread */ case RID_AUTO: case RID_REGISTER: case RID_STATIC: case RID_EXTERN: case RID_MUTABLE: /* Consume the token. */ cp_lexer_consume_token (parser->lexer); cp_parser_set_storage_class (parser, decl_specs, token->keyword); break; case RID_THREAD: /* Consume the token. */ cp_lexer_consume_token (parser->lexer); ++decl_specs->specs[(int) ds_thread]; break; default: /* We did not yet find a decl-specifier yet. */ found_decl_spec = false; break; } /* Constructors are a special case. The `S' in `S()' is not a decl-specifier; it is the beginning of the declarator. */ constructor_p = (!found_decl_spec && constructor_possible_p && (cp_parser_constructor_declarator_p (parser, decl_specs->specs[(int) ds_friend] != 0))); /* If we don't have a DECL_SPEC yet, then we must be looking at a type-specifier. */ if (!found_decl_spec && !constructor_p) { int decl_spec_declares_class_or_enum; bool is_cv_qualifier; tree type_spec; type_spec = cp_parser_type_specifier (parser, flags, decl_specs, /*is_declaration=*/true, &decl_spec_declares_class_or_enum, &is_cv_qualifier); *declares_class_or_enum |= decl_spec_declares_class_or_enum; /* If this type-specifier referenced a user-defined type (a typedef, class-name, etc.), then we can't allow any more such type-specifiers henceforth. [dcl.spec] The longest sequence of decl-specifiers that could possibly be a type name is taken as the decl-specifier-seq of a declaration. The sequence shall be self-consistent as described below. [dcl.type] As a general rule, at most one type-specifier is allowed in the complete decl-specifier-seq of a declaration. The only exceptions are the following: -- const or volatile can be combined with any other type-specifier. -- signed or unsigned can be combined with char, long, short, or int. -- .. Example: typedef char* Pc; void g (const int Pc); Here, Pc is *not* part of the decl-specifier seq; it's the declarator. Therefore, once we see a type-specifier (other than a cv-qualifier), we forbid any additional user-defined types. We *do* still allow things like `int int' to be considered a decl-specifier-seq, and issue the error message later. */ if (type_spec && !is_cv_qualifier) flags |= CP_PARSER_FLAGS_NO_USER_DEFINED_TYPES; /* A constructor declarator cannot follow a type-specifier. */ if (type_spec) { constructor_possible_p = false; found_decl_spec = true; } } /* If we still do not have a DECL_SPEC, then there are no more decl-specifiers. */ if (!found_decl_spec) break; decl_specs->any_specifiers_p = true; /* After we see one decl-specifier, further decl-specifiers are always optional. */ flags |= CP_PARSER_FLAGS_OPTIONAL; } cp_parser_check_decl_spec (decl_specs); /* Don't allow a friend specifier with a class definition. */ if (decl_specs->specs[(int) ds_friend] != 0 && (*declares_class_or_enum & 2)) error ("class definition may not be declared a friend"); } /* Parse an (optional) storage-class-specifier. storage-class-specifier: auto register static extern mutable GNU Extension: storage-class-specifier: thread Returns an IDENTIFIER_NODE corresponding to the keyword used. */ static tree cp_parser_storage_class_specifier_opt (cp_parser* parser) { switch (cp_lexer_peek_token (parser->lexer)->keyword) { case RID_AUTO: case RID_REGISTER: case RID_STATIC: case RID_EXTERN: case RID_MUTABLE: case RID_THREAD: /* Consume the token. */ return cp_lexer_consume_token (parser->lexer)->u.value; default: return NULL_TREE; } } /* Parse an (optional) function-specifier. function-specifier: inline virtual explicit Returns an IDENTIFIER_NODE corresponding to the keyword used. Updates DECL_SPECS, if it is non-NULL. */ static tree cp_parser_function_specifier_opt (cp_parser* parser, cp_decl_specifier_seq *decl_specs) { switch (cp_lexer_peek_token (parser->lexer)->keyword) { case RID_INLINE: if (decl_specs) ++decl_specs->specs[(int) ds_inline]; break; case RID_VIRTUAL: /* 14.5.2.3 [temp.mem] A member function template shall not be virtual. */ if (PROCESSING_REAL_TEMPLATE_DECL_P ()) error ("templates may not be %<virtual%>"); else if (decl_specs) ++decl_specs->specs[(int) ds_virtual]; break; case RID_EXPLICIT: if (decl_specs) ++decl_specs->specs[(int) ds_explicit]; break; default: return NULL_TREE; } /* Consume the token. */ return cp_lexer_consume_token (parser->lexer)->u.value; } /* Parse a linkage-specification. linkage-specification: extern string-literal { declaration-seq [opt] } extern string-literal declaration */ static void cp_parser_linkage_specification (cp_parser* parser) { tree linkage; /* Look for the `extern' keyword. */ cp_parser_require_keyword (parser, RID_EXTERN, "`extern'"); /* Look for the string-literal. */ linkage = cp_parser_string_literal (parser, false, false); /* Transform the literal into an identifier. If the literal is a wide-character string, or contains embedded NULs, then we can't handle it as the user wants. */ if (strlen (TREE_STRING_POINTER (linkage)) != (size_t) (TREE_STRING_LENGTH (linkage) - 1)) { cp_parser_error (parser, "invalid linkage-specification"); /* Assume C++ linkage. */ linkage = lang_name_cplusplus; } else linkage = get_identifier (TREE_STRING_POINTER (linkage)); /* We're now using the new linkage. */ push_lang_context (linkage); /* If the next token is a `{', then we're using the first production. */ if (cp_lexer_next_token_is (parser->lexer, CPP_OPEN_BRACE)) { /* Consume the `{' token. */ cp_lexer_consume_token (parser->lexer); /* Parse the declarations. */ cp_parser_declaration_seq_opt (parser); /* Look for the closing `}'. */ cp_parser_require (parser, CPP_CLOSE_BRACE, "`}'"); } /* Otherwise, there's just one declaration. */ else { bool saved_in_unbraced_linkage_specification_p; saved_in_unbraced_linkage_specification_p = parser->in_unbraced_linkage_specification_p; parser->in_unbraced_linkage_specification_p = true; cp_parser_declaration (parser); parser->in_unbraced_linkage_specification_p = saved_in_unbraced_linkage_specification_p; } /* We're done with the linkage-specification. */ pop_lang_context (); } /* Special member functions [gram.special] */ /* Parse a conversion-function-id. conversion-function-id: operator conversion-type-id Returns an IDENTIFIER_NODE representing the operator. */ static tree cp_parser_conversion_function_id (cp_parser* parser) { tree type; tree saved_scope; tree saved_qualifying_scope; tree saved_object_scope; tree pushed_scope = NULL_TREE; /* Look for the `operator' token. */ if (!cp_parser_require_keyword (parser, RID_OPERATOR, "`operator'")) return error_mark_node; /* When we parse the conversion-type-id, the current scope will be reset. However, we need that information in able to look up the conversion function later, so we save it here. */ saved_scope = parser->scope; saved_qualifying_scope = parser->qualifying_scope; saved_object_scope = parser->object_scope; /* We must enter the scope of the class so that the names of entities declared within the class are available in the conversion-type-id. For example, consider: struct S { typedef int I; operator I(); }; S::operator I() { ... } In order to see that `I' is a type-name in the definition, we must be in the scope of `S'. */ if (saved_scope) pushed_scope = push_scope (saved_scope); /* Parse the conversion-type-id. */ type = cp_parser_conversion_type_id (parser); /* Leave the scope of the class, if any. */ if (pushed_scope) pop_scope (pushed_scope); /* Restore the saved scope. */ parser->scope = saved_scope; parser->qualifying_scope = saved_qualifying_scope; parser->object_scope = saved_object_scope; /* If the TYPE is invalid, indicate failure. */ if (type == error_mark_node) return error_mark_node; return mangle_conv_op_name_for_type (type); } /* Parse a conversion-type-id: conversion-type-id: type-specifier-seq conversion-declarator [opt] Returns the TYPE specified. */ static tree cp_parser_conversion_type_id (cp_parser* parser) { tree attributes; cp_decl_specifier_seq type_specifiers; cp_declarator *declarator; tree type_specified; /* Parse the attributes. */ attributes = cp_parser_attributes_opt (parser); /* Parse the type-specifiers. */ cp_parser_type_specifier_seq (parser, /*is_condition=*/false, &type_specifiers); /* If that didn't work, stop. */ if (type_specifiers.type == error_mark_node) return error_mark_node; /* Parse the conversion-declarator. */ declarator = cp_parser_conversion_declarator_opt (parser); type_specified = grokdeclarator (declarator, &type_specifiers, TYPENAME, /*initialized=*/0, &attributes); if (attributes) cplus_decl_attributes (&type_specified, attributes, /*flags=*/0); return type_specified; } /* Parse an (optional) conversion-declarator. conversion-declarator: ptr-operator conversion-declarator [opt] */ static cp_declarator * cp_parser_conversion_declarator_opt (cp_parser* parser) { enum tree_code code; tree class_type; cp_cv_quals cv_quals; /* We don't know if there's a ptr-operator next, or not. */ cp_parser_parse_tentatively (parser); /* Try the ptr-operator. */ code = cp_parser_ptr_operator (parser, &class_type, &cv_quals); /* If it worked, look for more conversion-declarators. */ if (cp_parser_parse_definitely (parser)) { cp_declarator *declarator; /* Parse another optional declarator. */ declarator = cp_parser_conversion_declarator_opt (parser); /* Create the representation of the declarator. */ if (class_type) declarator = make_ptrmem_declarator (cv_quals, class_type, declarator); else if (code == INDIRECT_REF) declarator = make_pointer_declarator (cv_quals, declarator); else declarator = make_reference_declarator (cv_quals, declarator); return declarator; } return NULL; } /* Parse an (optional) ctor-initializer. ctor-initializer: : mem-initializer-list Returns TRUE iff the ctor-initializer was actually present. */ static bool cp_parser_ctor_initializer_opt (cp_parser* parser) { /* If the next token is not a `:', then there is no ctor-initializer. */ if (cp_lexer_next_token_is_not (parser->lexer, CPP_COLON)) { /* Do default initialization of any bases and members. */ if (DECL_CONSTRUCTOR_P (current_function_decl)) finish_mem_initializers (NULL_TREE); return false; } /* Consume the `:' token. */ cp_lexer_consume_token (parser->lexer); /* And the mem-initializer-list. */ cp_parser_mem_initializer_list (parser); return true; } /* Parse a mem-initializer-list. mem-initializer-list: mem-initializer mem-initializer , mem-initializer-list */ static void cp_parser_mem_initializer_list (cp_parser* parser) { tree mem_initializer_list = NULL_TREE; /* Let the semantic analysis code know that we are starting the mem-initializer-list. */ if (!DECL_CONSTRUCTOR_P (current_function_decl)) error ("only constructors take base initializers"); /* Loop through the list. */ while (true) { tree mem_initializer; /* Parse the mem-initializer. */ mem_initializer = cp_parser_mem_initializer (parser); /* Add it to the list, unless it was erroneous. */ if (mem_initializer != error_mark_node) { TREE_CHAIN (mem_initializer) = mem_initializer_list; mem_initializer_list = mem_initializer; } /* If the next token is not a `,', we're done. */ if (cp_lexer_next_token_is_not (parser->lexer, CPP_COMMA)) break; /* Consume the `,' token. */ cp_lexer_consume_token (parser->lexer); } /* Perform semantic analysis. */ if (DECL_CONSTRUCTOR_P (current_function_decl)) finish_mem_initializers (mem_initializer_list); } /* Parse a mem-initializer. mem-initializer: mem-initializer-id ( expression-list [opt] ) GNU extension: mem-initializer: ( expression-list [opt] ) Returns a TREE_LIST. The TREE_PURPOSE is the TYPE (for a base class) or FIELD_DECL (for a non-static data member) to initialize; the TREE_VALUE is the expression-list. An empty initialization list is represented by void_list_node. */ static tree cp_parser_mem_initializer (cp_parser* parser) { tree mem_initializer_id; tree expression_list; tree member; /* Find out what is being initialized. */ if (cp_lexer_next_token_is (parser->lexer, CPP_OPEN_PAREN)) { pedwarn ("anachronistic old-style base class initializer"); mem_initializer_id = NULL_TREE; } else mem_initializer_id = cp_parser_mem_initializer_id (parser); member = expand_member_init (mem_initializer_id); if (member && !DECL_P (member)) in_base_initializer = 1; expression_list = cp_parser_parenthesized_expression_list (parser, false, /*cast_p=*/false, /*non_constant_p=*/NULL); if (expression_list == error_mark_node) return error_mark_node; if (!expression_list) expression_list = void_type_node; in_base_initializer = 0; return member ? build_tree_list (member, expression_list) : error_mark_node; } /* Parse a mem-initializer-id. mem-initializer-id: :: [opt] nested-name-specifier [opt] class-name identifier Returns a TYPE indicating the class to be initializer for the first production. Returns an IDENTIFIER_NODE indicating the data member to be initialized for the second production. */ static tree cp_parser_mem_initializer_id (cp_parser* parser) { bool global_scope_p; bool nested_name_specifier_p; bool template_p = false; tree id; /* `typename' is not allowed in this context ([temp.res]). */ if (cp_lexer_next_token_is_keyword (parser->lexer, RID_TYPENAME)) { error ("keyword %<typename%> not allowed in this context (a qualified " "member initializer is implicitly a type)"); cp_lexer_consume_token (parser->lexer); } /* Look for the optional `::' operator. */ global_scope_p = (cp_parser_global_scope_opt (parser, /*current_scope_valid_p=*/false) != NULL_TREE); /* Look for the optional nested-name-specifier. The simplest way to implement: [temp.res] The keyword `typename' is not permitted in a base-specifier or mem-initializer; in these contexts a qualified name that depends on a template-parameter is implicitly assumed to be a type name. is to assume that we have seen the `typename' keyword at this point. */ nested_name_specifier_p = (cp_parser_nested_name_specifier_opt (parser, /*typename_keyword_p=*/true, /*check_dependency_p=*/true, /*type_p=*/true, /*is_declaration=*/true) != NULL_TREE); if (nested_name_specifier_p) template_p = cp_parser_optional_template_keyword (parser); /* If there is a `::' operator or a nested-name-specifier, then we are definitely looking for a class-name. */ if (global_scope_p || nested_name_specifier_p) return cp_parser_class_name (parser, /*typename_keyword_p=*/true, /*template_keyword_p=*/template_p, none_type, /*check_dependency_p=*/true, /*class_head_p=*/false, /*is_declaration=*/true); /* Otherwise, we could also be looking for an ordinary identifier. */ cp_parser_parse_tentatively (parser); /* Try a class-name. */ id = cp_parser_class_name (parser, /*typename_keyword_p=*/true, /*template_keyword_p=*/false, none_type, /*check_dependency_p=*/true, /*class_head_p=*/false, /*is_declaration=*/true); /* If we found one, we're done. */ if (cp_parser_parse_definitely (parser)) return id; /* Otherwise, look for an ordinary identifier. */ return cp_parser_identifier (parser); } /* Overloading [gram.over] */ /* Parse an operator-function-id. operator-function-id: operator operator Returns an IDENTIFIER_NODE for the operator which is a human-readable spelling of the identifier, e.g., `operator +'. */ static tree cp_parser_operator_function_id (cp_parser* parser) { /* Look for the `operator' keyword. */ if (!cp_parser_require_keyword (parser, RID_OPERATOR, "`operator'")) return error_mark_node; /* And then the name of the operator itself. */ return cp_parser_operator (parser); } /* Parse an operator. operator: new delete new[] delete[] + - * / % ^ & | ~ ! = < > += -= *= /= %= ^= &= |= << >> >>= <<= == != <= >= && || ++ -- , ->* -> () [] GNU Extensions: operator: <? >? <?= >?= Returns an IDENTIFIER_NODE for the operator which is a human-readable spelling of the identifier, e.g., `operator +'. */ static tree cp_parser_operator (cp_parser* parser) { tree id = NULL_TREE; cp_token *token; /* Peek at the next token. */ token = cp_lexer_peek_token (parser->lexer); /* Figure out which operator we have. */ switch (token->type) { case CPP_KEYWORD: { enum tree_code op; /* The keyword should be either `new' or `delete'. */ if (token->keyword == RID_NEW) op = NEW_EXPR; else if (token->keyword == RID_DELETE) op = DELETE_EXPR; else break; /* Consume the `new' or `delete' token. */ cp_lexer_consume_token (parser->lexer); /* Peek at the next token. */ token = cp_lexer_peek_token (parser->lexer); /* If it's a `[' token then this is the array variant of the operator. */ if (token->type == CPP_OPEN_SQUARE) { /* Consume the `[' token. */ cp_lexer_consume_token (parser->lexer); /* Look for the `]' token. */ cp_parser_require (parser, CPP_CLOSE_SQUARE, "`]'"); id = ansi_opname (op == NEW_EXPR ? VEC_NEW_EXPR : VEC_DELETE_EXPR); } /* Otherwise, we have the non-array variant. */ else id = ansi_opname (op); return id; } case CPP_PLUS: id = ansi_opname (PLUS_EXPR); break; case CPP_MINUS: id = ansi_opname (MINUS_EXPR); break; case CPP_MULT: id = ansi_opname (MULT_EXPR); break; case CPP_DIV: id = ansi_opname (TRUNC_DIV_EXPR); break; case CPP_MOD: id = ansi_opname (TRUNC_MOD_EXPR); break; case CPP_XOR: id = ansi_opname (BIT_XOR_EXPR); break; case CPP_AND: id = ansi_opname (BIT_AND_EXPR); break; case CPP_OR: id = ansi_opname (BIT_IOR_EXPR); break; case CPP_COMPL: id = ansi_opname (BIT_NOT_EXPR); break; case CPP_NOT: id = ansi_opname (TRUTH_NOT_EXPR); break; case CPP_EQ: id = ansi_assopname (NOP_EXPR); break; case CPP_LESS: id = ansi_opname (LT_EXPR); break; case CPP_GREATER: id = ansi_opname (GT_EXPR); break; case CPP_PLUS_EQ: id = ansi_assopname (PLUS_EXPR); break; case CPP_MINUS_EQ: id = ansi_assopname (MINUS_EXPR); break; case CPP_MULT_EQ: id = ansi_assopname (MULT_EXPR); break; case CPP_DIV_EQ: id = ansi_assopname (TRUNC_DIV_EXPR); break; case CPP_MOD_EQ: id = ansi_assopname (TRUNC_MOD_EXPR); break; case CPP_XOR_EQ: id = ansi_assopname (BIT_XOR_EXPR); break; case CPP_AND_EQ: id = ansi_assopname (BIT_AND_EXPR); break; case CPP_OR_EQ: id = ansi_assopname (BIT_IOR_EXPR); break; case CPP_LSHIFT: id = ansi_opname (LSHIFT_EXPR); break; case CPP_RSHIFT: id = ansi_opname (RSHIFT_EXPR); break; case CPP_LSHIFT_EQ: id = ansi_assopname (LSHIFT_EXPR); break; case CPP_RSHIFT_EQ: id = ansi_assopname (RSHIFT_EXPR); break; case CPP_EQ_EQ: id = ansi_opname (EQ_EXPR); break; case CPP_NOT_EQ: id = ansi_opname (NE_EXPR); break; case CPP_LESS_EQ: id = ansi_opname (LE_EXPR); break; case CPP_GREATER_EQ: id = ansi_opname (GE_EXPR); break; case CPP_AND_AND: id = ansi_opname (TRUTH_ANDIF_EXPR); break; case CPP_OR_OR: id = ansi_opname (TRUTH_ORIF_EXPR); break; case CPP_PLUS_PLUS: id = ansi_opname (POSTINCREMENT_EXPR); break; case CPP_MINUS_MINUS: id = ansi_opname (PREDECREMENT_EXPR); break; case CPP_COMMA: id = ansi_opname (COMPOUND_EXPR); break; case CPP_DEREF_STAR: id = ansi_opname (MEMBER_REF); break; case CPP_DEREF: id = ansi_opname (COMPONENT_REF); break; case CPP_OPEN_PAREN: /* Consume the `('. */ cp_lexer_consume_token (parser->lexer); /* Look for the matching `)'. */ cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'"); return ansi_opname (CALL_EXPR); case CPP_OPEN_SQUARE: /* Consume the `['. */ cp_lexer_consume_token (parser->lexer); /* Look for the matching `]'. */ cp_parser_require (parser, CPP_CLOSE_SQUARE, "`]'"); return ansi_opname (ARRAY_REF); default: /* Anything else is an error. */ break; } /* If we have selected an identifier, we need to consume the operator token. */ if (id) cp_lexer_consume_token (parser->lexer); /* Otherwise, no valid operator name was present. */ else { cp_parser_error (parser, "expected operator"); id = error_mark_node; } return id; } /* Parse a template-declaration. template-declaration: export [opt] template < template-parameter-list > declaration If MEMBER_P is TRUE, this template-declaration occurs within a class-specifier. The grammar rule given by the standard isn't correct. What is really meant is: template-declaration: export [opt] template-parameter-list-seq decl-specifier-seq [opt] init-declarator [opt] ; export [opt] template-parameter-list-seq function-definition template-parameter-list-seq: template-parameter-list-seq [opt] template < template-parameter-list > */ static void cp_parser_template_declaration (cp_parser* parser, bool member_p) { /* Check for `export'. */ if (cp_lexer_next_token_is_keyword (parser->lexer, RID_EXPORT)) { /* Consume the `export' token. */ cp_lexer_consume_token (parser->lexer); /* Warn that we do not support `export'. */ warning (0, "keyword %<export%> not implemented, and will be ignored"); } cp_parser_template_declaration_after_export (parser, member_p); } /* Parse a template-parameter-list. template-parameter-list: template-parameter template-parameter-list , template-parameter Returns a TREE_LIST. Each node represents a template parameter. The nodes are connected via their TREE_CHAINs. */ static tree cp_parser_template_parameter_list (cp_parser* parser) { tree parameter_list = NULL_TREE; begin_template_parm_list (); while (true) { tree parameter; cp_token *token; bool is_non_type; /* Parse the template-parameter. */ parameter = cp_parser_template_parameter (parser, &is_non_type); /* Add it to the list. */ if (parameter != error_mark_node) parameter_list = process_template_parm (parameter_list, parameter, is_non_type); else { tree err_parm = build_tree_list (parameter, parameter); TREE_VALUE (err_parm) = error_mark_node; parameter_list = chainon (parameter_list, err_parm); } /* Peek at the next token. */ token = cp_lexer_peek_token (parser->lexer); /* If it's not a `,', we're done. */ if (token->type != CPP_COMMA) break; /* Otherwise, consume the `,' token. */ cp_lexer_consume_token (parser->lexer); } return end_template_parm_list (parameter_list); } /* Parse a template-parameter. template-parameter: type-parameter parameter-declaration If all goes well, returns a TREE_LIST. The TREE_VALUE represents the parameter. The TREE_PURPOSE is the default value, if any. Returns ERROR_MARK_NODE on failure. *IS_NON_TYPE is set to true iff this parameter is a non-type parameter. */ static tree cp_parser_template_parameter (cp_parser* parser, bool *is_non_type) { cp_token *token; cp_parameter_declarator *parameter_declarator; tree parm; /* Assume it is a type parameter or a template parameter. */ *is_non_type = false; /* Peek at the next token. */ token = cp_lexer_peek_token (parser->lexer); /* If it is `class' or `template', we have a type-parameter. */ if (token->keyword == RID_TEMPLATE) return cp_parser_type_parameter (parser); /* If it is `class' or `typename' we do not know yet whether it is a type parameter or a non-type parameter. Consider: template <typename T, typename T::X X> ... or: template <class C, class D*> ... Here, the first parameter is a type parameter, and the second is a non-type parameter. We can tell by looking at the token after the identifier -- if it is a `,', `=', or `>' then we have a type parameter. */ if (token->keyword == RID_TYPENAME || token->keyword == RID_CLASS) { /* Peek at the token after `class' or `typename'. */ token = cp_lexer_peek_nth_token (parser->lexer, 2); /* If it's an identifier, skip it. */ if (token->type == CPP_NAME) token = cp_lexer_peek_nth_token (parser->lexer, 3); /* Now, see if the token looks like the end of a template parameter. */ if (token->type == CPP_COMMA || token->type == CPP_EQ || token->type == CPP_GREATER) return cp_parser_type_parameter (parser); } /* Otherwise, it is a non-type parameter. [temp.param] When parsing a default template-argument for a non-type template-parameter, the first non-nested `>' is taken as the end of the template parameter-list rather than a greater-than operator. */ *is_non_type = true; parameter_declarator = cp_parser_parameter_declaration (parser, /*template_parm_p=*/true, /*parenthesized_p=*/NULL); parm = grokdeclarator (parameter_declarator->declarator, &parameter_declarator->decl_specifiers, PARM, /*initialized=*/0, /*attrlist=*/NULL); if (parm == error_mark_node) return error_mark_node; return build_tree_list (parameter_declarator->default_argument, parm); } /* Parse a type-parameter. type-parameter: class identifier [opt] class identifier [opt] = type-id typename identifier [opt] typename identifier [opt] = type-id template < template-parameter-list > class identifier [opt] template < template-parameter-list > class identifier [opt] = id-expression Returns a TREE_LIST. The TREE_VALUE is itself a TREE_LIST. The TREE_PURPOSE is the default-argument, if any. The TREE_VALUE is the declaration of the parameter. */ static tree cp_parser_type_parameter (cp_parser* parser) { cp_token *token; tree parameter; /* Look for a keyword to tell us what kind of parameter this is. */ token = cp_parser_require (parser, CPP_KEYWORD, "`class', `typename', or `template'"); if (!token) return error_mark_node; switch (token->keyword) { case RID_CLASS: case RID_TYPENAME: { tree identifier; tree default_argument; /* If the next token is an identifier, then it names the parameter. */ if (cp_lexer_next_token_is (parser->lexer, CPP_NAME)) identifier = cp_parser_identifier (parser); else identifier = NULL_TREE; /* Create the parameter. */ parameter = finish_template_type_parm (class_type_node, identifier); /* If the next token is an `=', we have a default argument. */ if (cp_lexer_next_token_is (parser->lexer, CPP_EQ)) { /* Consume the `=' token. */ cp_lexer_consume_token (parser->lexer); /* Parse the default-argument. */ push_deferring_access_checks (dk_no_deferred); default_argument = cp_parser_type_id (parser); pop_deferring_access_checks (); } else default_argument = NULL_TREE; /* Create the combined representation of the parameter and the default argument. */ parameter = build_tree_list (default_argument, parameter); } break; case RID_TEMPLATE: { tree parameter_list; tree identifier; tree default_argument; /* Look for the `<'. */ cp_parser_require (parser, CPP_LESS, "`<'"); /* Parse the template-parameter-list. */ parameter_list = cp_parser_template_parameter_list (parser); /* Look for the `>'. */ cp_parser_require (parser, CPP_GREATER, "`>'"); /* Look for the `class' keyword. */ cp_parser_require_keyword (parser, RID_CLASS, "`class'"); /* If the next token is an `=', then there is a default-argument. If the next token is a `>', we are at the end of the parameter-list. If the next token is a `,', then we are at the end of this parameter. */ if (cp_lexer_next_token_is_not (parser->lexer, CPP_EQ) && cp_lexer_next_token_is_not (parser->lexer, CPP_GREATER) && cp_lexer_next_token_is_not (parser->lexer, CPP_COMMA)) { identifier = cp_parser_identifier (parser); /* Treat invalid names as if the parameter were nameless. */ if (identifier == error_mark_node) identifier = NULL_TREE; } else identifier = NULL_TREE; /* Create the template parameter. */ parameter = finish_template_template_parm (class_type_node, identifier); /* If the next token is an `=', then there is a default-argument. */ if (cp_lexer_next_token_is (parser->lexer, CPP_EQ)) { bool is_template; /* Consume the `='. */ cp_lexer_consume_token (parser->lexer); /* Parse the id-expression. */ push_deferring_access_checks (dk_no_deferred); default_argument = cp_parser_id_expression (parser, /*template_keyword_p=*/false, /*check_dependency_p=*/true, /*template_p=*/&is_template, /*declarator_p=*/false, /*optional_p=*/false); if (TREE_CODE (default_argument) == TYPE_DECL) /* If the id-expression was a template-id that refers to a template-class, we already have the declaration here, so no further lookup is needed. */ ; else /* Look up the name. */ default_argument = cp_parser_lookup_name (parser, default_argument, none_type, /*is_template=*/is_template, /*is_namespace=*/false, /*check_dependency=*/true, /*ambiguous_decls=*/NULL); /* See if the default argument is valid. */ default_argument = check_template_template_default_arg (default_argument); pop_deferring_access_checks (); } else default_argument = NULL_TREE; /* Create the combined representation of the parameter and the default argument. */ parameter = build_tree_list (default_argument, parameter); } break; default: gcc_unreachable (); break; } return parameter; } /* Parse a template-id. template-id: template-name < template-argument-list [opt] > If TEMPLATE_KEYWORD_P is TRUE, then we have just seen the `template' keyword. In this case, a TEMPLATE_ID_EXPR will be returned. Otherwise, if the template-name names a function, or set of functions, returns a TEMPLATE_ID_EXPR. If the template-name names a class, returns a TYPE_DECL for the specialization. If CHECK_DEPENDENCY_P is FALSE, names are looked up in uninstantiated templates. */ static tree cp_parser_template_id (cp_parser *parser, bool template_keyword_p, bool check_dependency_p, bool is_declaration) { int i; tree template; tree arguments; tree template_id; cp_token_position start_of_id = 0; deferred_access_check *chk; VEC (deferred_access_check,gc) *access_check; cp_token *next_token, *next_token_2; bool is_identifier; /* If the next token corresponds to a template-id, there is no need to reparse it. */ next_token = cp_lexer_peek_token (parser->lexer); if (next_token->type == CPP_TEMPLATE_ID) { struct tree_check *check_value; /* Get the stored value. */ check_value = cp_lexer_consume_token (parser->lexer)->u.tree_check_value; /* Perform any access checks that were deferred. */ access_check = check_value->checks; if (access_check) { for (i = 0 ; VEC_iterate (deferred_access_check, access_check, i, chk) ; ++i) { perform_or_defer_access_check (chk->binfo, chk->decl, chk->diag_decl); } } /* Return the stored value. */ return check_value->value; } /* Avoid performing name lookup if there is no possibility of finding a template-id. */ if ((next_token->type != CPP_NAME && next_token->keyword != RID_OPERATOR) || (next_token->type == CPP_NAME && !cp_parser_nth_token_starts_template_argument_list_p (parser, 2))) { cp_parser_error (parser, "expected template-id"); return error_mark_node; } /* Remember where the template-id starts. */ if (cp_parser_uncommitted_to_tentative_parse_p (parser)) start_of_id = cp_lexer_token_position (parser->lexer, false); push_deferring_access_checks (dk_deferred); /* Parse the template-name. */ is_identifier = false; template = cp_parser_template_name (parser, template_keyword_p, check_dependency_p, is_declaration, &is_identifier); if (template == error_mark_node || is_identifier) { pop_deferring_access_checks (); return template; } /* If we find the sequence `[:' after a template-name, it's probably a digraph-typo for `< ::'. Substitute the tokens and check if we can parse correctly the argument list. */ next_token = cp_lexer_peek_token (parser->lexer); next_token_2 = cp_lexer_peek_nth_token (parser->lexer, 2); if (next_token->type == CPP_OPEN_SQUARE && next_token->flags & DIGRAPH && next_token_2->type == CPP_COLON && !(next_token_2->flags & PREV_WHITE)) { cp_parser_parse_tentatively (parser); /* Change `:' into `::'. */ next_token_2->type = CPP_SCOPE; /* Consume the first token (CPP_OPEN_SQUARE - which we pretend it is CPP_LESS. */ cp_lexer_consume_token (parser->lexer); /* Parse the arguments. */ arguments = cp_parser_enclosed_template_argument_list (parser); if (!cp_parser_parse_definitely (parser)) { /* If we couldn't parse an argument list, then we revert our changes and return simply an error. Maybe this is not a template-id after all. */ next_token_2->type = CPP_COLON; cp_parser_error (parser, "expected %<<%>"); pop_deferring_access_checks (); return error_mark_node; } /* Otherwise, emit an error about the invalid digraph, but continue parsing because we got our argument list. */ pedwarn ("%<<::%> cannot begin a template-argument list"); inform ("%<<:%> is an alternate spelling for %<[%>. Insert whitespace " "between %<<%> and %<::%>"); if (!flag_permissive) { static bool hint; if (!hint) { inform ("(if you use -fpermissive G++ will accept your code)"); hint = true; } } } else { /* Look for the `<' that starts the template-argument-list. */ if (!cp_parser_require (parser, CPP_LESS, "`<'")) { pop_deferring_access_checks (); return error_mark_node; } /* Parse the arguments. */ arguments = cp_parser_enclosed_template_argument_list (parser); } /* Build a representation of the specialization. */ if (TREE_CODE (template) == IDENTIFIER_NODE) template_id = build_min_nt (TEMPLATE_ID_EXPR, template, arguments); else if (DECL_CLASS_TEMPLATE_P (template) || DECL_TEMPLATE_TEMPLATE_PARM_P (template)) { bool entering_scope; /* In "template <typename T> ... A<T>::", A<T> is the abstract A template (rather than some instantiation thereof) only if is not nested within some other construct. For example, in "template <typename T> void f(T) { A<T>::", A<T> is just an instantiation of A. */ entering_scope = (template_parm_scope_p () && cp_lexer_next_token_is (parser->lexer, CPP_SCOPE)); template_id = finish_template_type (template, arguments, entering_scope); } else { /* If it's not a class-template or a template-template, it should be a function-template. */ gcc_assert ((DECL_FUNCTION_TEMPLATE_P (template) || TREE_CODE (template) == OVERLOAD || BASELINK_P (template))); template_id = lookup_template_function (template, arguments); } /* If parsing tentatively, replace the sequence of tokens that makes up the template-id with a CPP_TEMPLATE_ID token. That way, should we re-parse the token stream, we will not have to repeat the effort required to do the parse, nor will we issue duplicate error messages about problems during instantiation of the template. */ if (start_of_id) { cp_token *token = cp_lexer_token_at (parser->lexer, start_of_id); /* Reset the contents of the START_OF_ID token. */ token->type = CPP_TEMPLATE_ID; /* Retrieve any deferred checks. Do not pop this access checks yet so the memory will not be reclaimed during token replacing below. */ token->u.tree_check_value = GGC_CNEW (struct tree_check); token->u.tree_check_value->value = template_id; token->u.tree_check_value->checks = get_deferred_access_checks (); token->keyword = RID_MAX; /* Purge all subsequent tokens. */ cp_lexer_purge_tokens_after (parser->lexer, start_of_id); /* ??? Can we actually assume that, if template_id == error_mark_node, we will have issued a diagnostic to the user, as opposed to simply marking the tentative parse as failed? */ if (cp_parser_error_occurred (parser) && template_id != error_mark_node) error ("parse error in template argument list"); } pop_deferring_access_checks (); return template_id; } /* Parse a template-name. template-name: identifier The standard should actually say: template-name: identifier operator-function-id A defect report has been filed about this issue. A conversion-function-id cannot be a template name because they cannot be part of a template-id. In fact, looking at this code: a.operator K<int>() the conversion-function-id is "operator K<int>", and K<int> is a type-id. It is impossible to call a templated conversion-function-id with an explicit argument list, since the only allowed template parameter is the type to which it is converting. If TEMPLATE_KEYWORD_P is true, then we have just seen the `template' keyword, in a construction like: T::template f<3>() In that case `f' is taken to be a template-name, even though there is no way of knowing for sure. Returns the TEMPLATE_DECL for the template, or an OVERLOAD if the name refers to a set of overloaded functions, at least one of which is a template, or an IDENTIFIER_NODE with the name of the template, if TEMPLATE_KEYWORD_P is true. If CHECK_DEPENDENCY_P is FALSE, names are looked up inside uninstantiated templates. */ static tree cp_parser_template_name (cp_parser* parser, bool template_keyword_p, bool check_dependency_p, bool is_declaration, bool *is_identifier) { tree identifier; tree decl; tree fns; /* If the next token is `operator', then we have either an operator-function-id or a conversion-function-id. */ if (cp_lexer_next_token_is_keyword (parser->lexer, RID_OPERATOR)) { /* We don't know whether we're looking at an operator-function-id or a conversion-function-id. */ cp_parser_parse_tentatively (parser); /* Try an operator-function-id. */ identifier = cp_parser_operator_function_id (parser); /* If that didn't work, try a conversion-function-id. */ if (!cp_parser_parse_definitely (parser)) { cp_parser_error (parser, "expected template-name"); return error_mark_node; } } /* Look for the identifier. */ else identifier = cp_parser_identifier (parser); /* If we didn't find an identifier, we don't have a template-id. */ if (identifier == error_mark_node) return error_mark_node; /* If the name immediately followed the `template' keyword, then it is a template-name. However, if the next token is not `<', then we do not treat it as a template-name, since it is not being used as part of a template-id. This enables us to handle constructs like: template <typename T> struct S { S(); }; template <typename T> S<T>::S(); correctly. We would treat `S' as a template -- if it were `S<T>' -- but we do not if there is no `<'. */ if (processing_template_decl && cp_parser_nth_token_starts_template_argument_list_p (parser, 1)) { /* In a declaration, in a dependent context, we pretend that the "template" keyword was present in order to improve error recovery. For example, given: template <typename T> void f(T::X<int>); we want to treat "X<int>" as a template-id. */ if (is_declaration && !template_keyword_p && parser->scope && TYPE_P (parser->scope) && check_dependency_p && dependent_type_p (parser->scope) /* Do not do this for dtors (or ctors), since they never need the template keyword before their name. */ && !constructor_name_p (identifier, parser->scope)) { cp_token_position start = 0; /* Explain what went wrong. */ error ("non-template %qD used as template", identifier); inform ("use %<%T::template %D%> to indicate that it is a template", parser->scope, identifier); /* If parsing tentatively, find the location of the "<" token. */ if (cp_parser_simulate_error (parser)) start = cp_lexer_token_position (parser->lexer, true); /* Parse the template arguments so that we can issue error messages about them. */ cp_lexer_consume_token (parser->lexer); cp_parser_enclosed_template_argument_list (parser); /* Skip tokens until we find a good place from which to continue parsing. */ cp_parser_skip_to_closing_parenthesis (parser, /*recovering=*/true, /*or_comma=*/true, /*consume_paren=*/false); /* If parsing tentatively, permanently remove the template argument list. That will prevent duplicate error messages from being issued about the missing "template" keyword. */ if (start) cp_lexer_purge_tokens_after (parser->lexer, start); if (is_identifier) *is_identifier = true; return identifier; } /* If the "template" keyword is present, then there is generally no point in doing name-lookup, so we just return IDENTIFIER. But, if the qualifying scope is non-dependent then we can (and must) do name-lookup normally. */ if (template_keyword_p && (!parser->scope || (TYPE_P (parser->scope) && dependent_type_p (parser->scope)))) return identifier; } /* Look up the name. */ decl = cp_parser_lookup_name (parser, identifier, none_type, /*is_template=*/false, /*is_namespace=*/false, check_dependency_p, /*ambiguous_decls=*/NULL); decl = maybe_get_template_decl_from_type_decl (decl); /* If DECL is a template, then the name was a template-name. */ if (TREE_CODE (decl) == TEMPLATE_DECL) ; else { tree fn = NULL_TREE; /* The standard does not explicitly indicate whether a name that names a set of overloaded declarations, some of which are templates, is a template-name. However, such a name should be a template-name; otherwise, there is no way to form a template-id for the overloaded templates. */ fns = BASELINK_P (decl) ? BASELINK_FUNCTIONS (decl) : decl; if (TREE_CODE (fns) == OVERLOAD) for (fn = fns; fn; fn = OVL_NEXT (fn)) if (TREE_CODE (OVL_CURRENT (fn)) == TEMPLATE_DECL) break; if (!fn) { /* The name does not name a template. */ cp_parser_error (parser, "expected template-name"); return error_mark_node; } } /* If DECL is dependent, and refers to a function, then just return its name; we will look it up again during template instantiation. */ if (DECL_FUNCTION_TEMPLATE_P (decl) || !DECL_P (decl)) { tree scope = CP_DECL_CONTEXT (get_first_fn (decl)); if (TYPE_P (scope) && dependent_type_p (scope)) return identifier; } return decl; } /* Parse a template-argument-list. template-argument-list: template-argument template-argument-list , template-argument Returns a TREE_VEC containing the arguments. */ static tree cp_parser_template_argument_list (cp_parser* parser) { tree fixed_args[10]; unsigned n_args = 0; unsigned alloced = 10; tree *arg_ary = fixed_args; tree vec; bool saved_in_template_argument_list_p; bool saved_ice_p; bool saved_non_ice_p; saved_in_template_argument_list_p = parser->in_template_argument_list_p; parser->in_template_argument_list_p = true; /* Even if the template-id appears in an integral constant-expression, the contents of the argument list do not. */ saved_ice_p = parser->integral_constant_expression_p; parser->integral_constant_expression_p = false; saved_non_ice_p = parser->non_integral_constant_expression_p; parser->non_integral_constant_expression_p = false; /* Parse the arguments. */ do { tree argument; if (n_args) /* Consume the comma. */ cp_lexer_consume_token (parser->lexer); /* Parse the template-argument. */ argument = cp_parser_template_argument (parser); if (n_args == alloced) { alloced *= 2; if (arg_ary == fixed_args) { arg_ary = XNEWVEC (tree, alloced); memcpy (arg_ary, fixed_args, sizeof (tree) * n_args); } else arg_ary = XRESIZEVEC (tree, arg_ary, alloced); } arg_ary[n_args++] = argument; } while (cp_lexer_next_token_is (parser->lexer, CPP_COMMA)); vec = make_tree_vec (n_args); while (n_args--) TREE_VEC_ELT (vec, n_args) = arg_ary[n_args]; if (arg_ary != fixed_args) free (arg_ary); parser->non_integral_constant_expression_p = saved_non_ice_p; parser->integral_constant_expression_p = saved_ice_p; parser->in_template_argument_list_p = saved_in_template_argument_list_p; return vec; } /* Parse a template-argument. template-argument: assignment-expression type-id id-expression The representation is that of an assignment-expression, type-id, or id-expression -- except that the qualified id-expression is evaluated, so that the value returned is either a DECL or an OVERLOAD. Although the standard says "assignment-expression", it forbids throw-expressions or assignments in the template argument. Therefore, we use "conditional-expression" instead. */ static tree cp_parser_template_argument (cp_parser* parser) { tree argument; bool template_p; bool address_p; bool maybe_type_id = false; cp_token *token; cp_id_kind idk; /* There's really no way to know what we're looking at, so we just try each alternative in order. [temp.arg] In a template-argument, an ambiguity between a type-id and an expression is resolved to a type-id, regardless of the form of the corresponding template-parameter. Therefore, we try a type-id first. */ cp_parser_parse_tentatively (parser); argument = cp_parser_type_id (parser); /* If there was no error parsing the type-id but the next token is a '>>', we probably found a typo for '> >'. But there are type-id which are also valid expressions. For instance: struct X { int operator >> (int); }; template <int V> struct Foo {}; Foo<X () >> 5> r; Here 'X()' is a valid type-id of a function type, but the user just wanted to write the expression "X() >> 5". Thus, we remember that we found a valid type-id, but we still try to parse the argument as an expression to see what happens. */ if (!cp_parser_error_occurred (parser) && cp_lexer_next_token_is (parser->lexer, CPP_RSHIFT)) { maybe_type_id = true; cp_parser_abort_tentative_parse (parser); } else { /* If the next token isn't a `,' or a `>', then this argument wasn't really finished. This means that the argument is not a valid type-id. */ if (!cp_parser_next_token_ends_template_argument_p (parser)) cp_parser_error (parser, "expected template-argument"); /* If that worked, we're done. */ if (cp_parser_parse_definitely (parser)) return argument; } /* We're still not sure what the argument will be. */ cp_parser_parse_tentatively (parser); /* Try a template. */ argument = cp_parser_id_expression (parser, /*template_keyword_p=*/false, /*check_dependency_p=*/true, &template_p, /*declarator_p=*/false, /*optional_p=*/false); /* If the next token isn't a `,' or a `>', then this argument wasn't really finished. */ if (!cp_parser_next_token_ends_template_argument_p (parser)) cp_parser_error (parser, "expected template-argument"); if (!cp_parser_error_occurred (parser)) { /* Figure out what is being referred to. If the id-expression was for a class template specialization, then we will have a TYPE_DECL at this point. There is no need to do name lookup at this point in that case. */ if (TREE_CODE (argument) != TYPE_DECL) argument = cp_parser_lookup_name (parser, argument, none_type, /*is_template=*/template_p, /*is_namespace=*/false, /*check_dependency=*/true, /*ambiguous_decls=*/NULL); if (TREE_CODE (argument) != TEMPLATE_DECL && TREE_CODE (argument) != UNBOUND_CLASS_TEMPLATE) cp_parser_error (parser, "expected template-name"); } if (cp_parser_parse_definitely (parser)) return argument; /* It must be a non-type argument. There permitted cases are given in [temp.arg.nontype]: -- an integral constant-expression of integral or enumeration type; or -- the name of a non-type template-parameter; or -- the name of an object or function with external linkage... -- the address of an object or function with external linkage... -- a pointer to member... */ /* Look for a non-type template parameter. */ if (cp_lexer_next_token_is (parser->lexer, CPP_NAME)) { cp_parser_parse_tentatively (parser); argument = cp_parser_primary_expression (parser, /*adress_p=*/false, /*cast_p=*/false, /*template_arg_p=*/true, &idk); if (TREE_CODE (argument) != TEMPLATE_PARM_INDEX || !cp_parser_next_token_ends_template_argument_p (parser)) cp_parser_simulate_error (parser); if (cp_parser_parse_definitely (parser)) return argument; } /* If the next token is "&", the argument must be the address of an object or function with external linkage. */ address_p = cp_lexer_next_token_is (parser->lexer, CPP_AND); if (address_p) cp_lexer_consume_token (parser->lexer); /* See if we might have an id-expression. */ token = cp_lexer_peek_token (parser->lexer); if (token->type == CPP_NAME || token->keyword == RID_OPERATOR || token->type == CPP_SCOPE || token->type == CPP_TEMPLATE_ID || token->type == CPP_NESTED_NAME_SPECIFIER) { cp_parser_parse_tentatively (parser); argument = cp_parser_primary_expression (parser, address_p, /*cast_p=*/false, /*template_arg_p=*/true, &idk); if (cp_parser_error_occurred (parser) || !cp_parser_next_token_ends_template_argument_p (parser)) cp_parser_abort_tentative_parse (parser); else { if (TREE_CODE (argument) == INDIRECT_REF) { gcc_assert (REFERENCE_REF_P (argument)); argument = TREE_OPERAND (argument, 0); } if (TREE_CODE (argument) == VAR_DECL) { /* A variable without external linkage might still be a valid constant-expression, so no error is issued here if the external-linkage check fails. */ if (!address_p && !DECL_EXTERNAL_LINKAGE_P (argument)) cp_parser_simulate_error (parser); } else if (is_overloaded_fn (argument)) /* All overloaded functions are allowed; if the external linkage test does not pass, an error will be issued later. */ ; else if (address_p && (TREE_CODE (argument) == OFFSET_REF || TREE_CODE (argument) == SCOPE_REF)) /* A pointer-to-member. */ ; else if (TREE_CODE (argument) == TEMPLATE_PARM_INDEX) ; else cp_parser_simulate_error (parser); if (cp_parser_parse_definitely (parser)) { if (address_p) argument = build_x_unary_op (ADDR_EXPR, argument); return argument; } } } /* If the argument started with "&", there are no other valid alternatives at this point. */ if (address_p) { cp_parser_error (parser, "invalid non-type template argument"); return error_mark_node; } /* If the argument wasn't successfully parsed as a type-id followed by '>>', the argument can only be a constant expression now. Otherwise, we try parsing the constant-expression tentatively, because the argument could really be a type-id. */ if (maybe_type_id) cp_parser_parse_tentatively (parser); argument = cp_parser_constant_expression (parser, /*allow_non_constant_p=*/false, /*non_constant_p=*/NULL); argument = fold_non_dependent_expr (argument); if (!maybe_type_id) return argument; if (!cp_parser_next_token_ends_template_argument_p (parser)) cp_parser_error (parser, "expected template-argument"); if (cp_parser_parse_definitely (parser)) return argument; /* We did our best to parse the argument as a non type-id, but that was the only alternative that matched (albeit with a '>' after it). We can assume it's just a typo from the user, and a diagnostic will then be issued. */ return cp_parser_type_id (parser); } /* Parse an explicit-instantiation. explicit-instantiation: template declaration Although the standard says `declaration', what it really means is: explicit-instantiation: template decl-specifier-seq [opt] declarator [opt] ; Things like `template int S<int>::i = 5, int S<double>::j;' are not supposed to be allowed. A defect report has been filed about this issue. GNU Extension: explicit-instantiation: storage-class-specifier template decl-specifier-seq [opt] declarator [opt] ; function-specifier template decl-specifier-seq [opt] declarator [opt] ; */ static void cp_parser_explicit_instantiation (cp_parser* parser) { int declares_class_or_enum; cp_decl_specifier_seq decl_specifiers; tree extension_specifier = NULL_TREE; /* Look for an (optional) storage-class-specifier or function-specifier. */ if (cp_parser_allow_gnu_extensions_p (parser)) { extension_specifier = cp_parser_storage_class_specifier_opt (parser); if (!extension_specifier) extension_specifier = cp_parser_function_specifier_opt (parser, /*decl_specs=*/NULL); } /* Look for the `template' keyword. */ cp_parser_require_keyword (parser, RID_TEMPLATE, "`template'"); /* Let the front end know that we are processing an explicit instantiation. */ begin_explicit_instantiation (); /* [temp.explicit] says that we are supposed to ignore access control while processing explicit instantiation directives. */ push_deferring_access_checks (dk_no_check); /* Parse a decl-specifier-seq. */ cp_parser_decl_specifier_seq (parser, CP_PARSER_FLAGS_OPTIONAL, &decl_specifiers, &declares_class_or_enum); /* If there was exactly one decl-specifier, and it declared a class, and there's no declarator, then we have an explicit type instantiation. */ if (declares_class_or_enum && cp_parser_declares_only_class_p (parser)) { tree type; type = check_tag_decl (&decl_specifiers); /* Turn access control back on for names used during template instantiation. */ pop_deferring_access_checks (); if (type) do_type_instantiation (type, extension_specifier, /*complain=*/tf_error); } else { cp_declarator *declarator; tree decl; /* Parse the declarator. */ declarator = cp_parser_declarator (parser, CP_PARSER_DECLARATOR_NAMED, /*ctor_dtor_or_conv_p=*/NULL, /*parenthesized_p=*/NULL, /*member_p=*/false); if (declares_class_or_enum & 2) cp_parser_check_for_definition_in_return_type (declarator, decl_specifiers.type); if (declarator != cp_error_declarator) { decl = grokdeclarator (declarator, &decl_specifiers, NORMAL, 0, &decl_specifiers.attributes); /* Turn access control back on for names used during template instantiation. */ pop_deferring_access_checks (); /* Do the explicit instantiation. */ do_decl_instantiation (decl, extension_specifier); } else { pop_deferring_access_checks (); /* Skip the body of the explicit instantiation. */ cp_parser_skip_to_end_of_statement (parser); } } /* We're done with the instantiation. */ end_explicit_instantiation (); cp_parser_consume_semicolon_at_end_of_statement (parser); } /* Parse an explicit-specialization. explicit-specialization: template < > declaration Although the standard says `declaration', what it really means is: explicit-specialization: template <> decl-specifier [opt] init-declarator [opt] ; template <> function-definition template <> explicit-specialization template <> template-declaration */ static void cp_parser_explicit_specialization (cp_parser* parser) { bool need_lang_pop; /* Look for the `template' keyword. */ cp_parser_require_keyword (parser, RID_TEMPLATE, "`template'"); /* Look for the `<'. */ cp_parser_require (parser, CPP_LESS, "`<'"); /* Look for the `>'. */ cp_parser_require (parser, CPP_GREATER, "`>'"); /* We have processed another parameter list. */ ++parser->num_template_parameter_lists; /* [temp] A template ... explicit specialization ... shall not have C linkage. */ if (current_lang_name == lang_name_c) { error ("template specialization with C linkage"); /* Give it C++ linkage to avoid confusing other parts of the front end. */ push_lang_context (lang_name_cplusplus); need_lang_pop = true; } else need_lang_pop = false; /* Let the front end know that we are beginning a specialization. */ if (!begin_specialization ()) { end_specialization (); cp_parser_skip_to_end_of_block_or_statement (parser); return; } /* If the next keyword is `template', we need to figure out whether or not we're looking a template-declaration. */ if (cp_lexer_next_token_is_keyword (parser->lexer, RID_TEMPLATE)) { if (cp_lexer_peek_nth_token (parser->lexer, 2)->type == CPP_LESS && cp_lexer_peek_nth_token (parser->lexer, 3)->type != CPP_GREATER) cp_parser_template_declaration_after_export (parser, /*member_p=*/false); else cp_parser_explicit_specialization (parser); } else /* Parse the dependent declaration. */ cp_parser_single_declaration (parser, /*checks=*/NULL, /*member_p=*/false, /*friend_p=*/NULL); /* We're done with the specialization. */ end_specialization (); /* For the erroneous case of a template with C linkage, we pushed an implicit C++ linkage scope; exit that scope now. */ if (need_lang_pop) pop_lang_context (); /* We're done with this parameter list. */ --parser->num_template_parameter_lists; } /* Parse a type-specifier. type-specifier: simple-type-specifier class-specifier enum-specifier elaborated-type-specifier cv-qualifier GNU Extension: type-specifier: __complex__ Returns a representation of the type-specifier. For a class-specifier, enum-specifier, or elaborated-type-specifier, a TREE_TYPE is returned; otherwise, a TYPE_DECL is returned. The parser flags FLAGS is used to control type-specifier parsing. If IS_DECLARATION is TRUE, then this type-specifier is appearing in a decl-specifier-seq. If DECLARES_CLASS_OR_ENUM is non-NULL, and the type-specifier is a class-specifier, enum-specifier, or elaborated-type-specifier, then *DECLARES_CLASS_OR_ENUM is set to a nonzero value. The value is 1 if a type is declared; 2 if it is defined. Otherwise, it is set to zero. If IS_CV_QUALIFIER is non-NULL, and the type-specifier is a cv-qualifier, then IS_CV_QUALIFIER is set to TRUE. Otherwise, it is set to FALSE. */ static tree cp_parser_type_specifier (cp_parser* parser, cp_parser_flags flags, cp_decl_specifier_seq *decl_specs, bool is_declaration, int* declares_class_or_enum, bool* is_cv_qualifier) { tree type_spec = NULL_TREE; cp_token *token; enum rid keyword; cp_decl_spec ds = ds_last; /* Assume this type-specifier does not declare a new type. */ if (declares_class_or_enum) *declares_class_or_enum = 0; /* And that it does not specify a cv-qualifier. */ if (is_cv_qualifier) *is_cv_qualifier = false; /* Peek at the next token. */ token = cp_lexer_peek_token (parser->lexer); /* If we're looking at a keyword, we can use that to guide the production we choose. */ keyword = token->keyword; switch (keyword) { case RID_ENUM: /* Look for the enum-specifier. */ type_spec = cp_parser_enum_specifier (parser); /* If that worked, we're done. */ if (type_spec) { if (declares_class_or_enum) *declares_class_or_enum = 2; if (decl_specs) cp_parser_set_decl_spec_type (decl_specs, type_spec, /*user_defined_p=*/true); return type_spec; } else goto elaborated_type_specifier; /* Any of these indicate either a class-specifier, or an elaborated-type-specifier. */ case RID_CLASS: case RID_STRUCT: case RID_UNION: /* Parse tentatively so that we can back up if we don't find a class-specifier. */ cp_parser_parse_tentatively (parser); /* Look for the class-specifier. */ type_spec = cp_parser_class_specifier (parser); /* If that worked, we're done. */ if (cp_parser_parse_definitely (parser)) { if (declares_class_or_enum) *declares_class_or_enum = 2; if (decl_specs) cp_parser_set_decl_spec_type (decl_specs, type_spec, /*user_defined_p=*/true); return type_spec; } /* Fall through. */ elaborated_type_specifier: /* We're declaring (not defining) a class or enum. */ if (declares_class_or_enum) *declares_class_or_enum = 1; /* Fall through. */ case RID_TYPENAME: /* Look for an elaborated-type-specifier. */ type_spec = (cp_parser_elaborated_type_specifier (parser, decl_specs && decl_specs->specs[(int) ds_friend], is_declaration)); if (decl_specs) cp_parser_set_decl_spec_type (decl_specs, type_spec, /*user_defined_p=*/true); return type_spec; case RID_CONST: ds = ds_const; if (is_cv_qualifier) *is_cv_qualifier = true; break; case RID_VOLATILE: ds = ds_volatile; if (is_cv_qualifier) *is_cv_qualifier = true; break; case RID_RESTRICT: ds = ds_restrict; if (is_cv_qualifier) *is_cv_qualifier = true; break; case RID_COMPLEX: /* The `__complex__' keyword is a GNU extension. */ ds = ds_complex; break; default: break; } /* Handle simple keywords. */ if (ds != ds_last) { if (decl_specs) { ++decl_specs->specs[(int)ds]; decl_specs->any_specifiers_p = true; } return cp_lexer_consume_token (parser->lexer)->u.value; } /* If we do not already have a type-specifier, assume we are looking at a simple-type-specifier. */ type_spec = cp_parser_simple_type_specifier (parser, decl_specs, flags); /* If we didn't find a type-specifier, and a type-specifier was not optional in this context, issue an error message. */ if (!type_spec && !(flags & CP_PARSER_FLAGS_OPTIONAL)) { cp_parser_error (parser, "expected type specifier"); return error_mark_node; } return type_spec; } /* Parse a simple-type-specifier. simple-type-specifier: :: [opt] nested-name-specifier [opt] type-name :: [opt] nested-name-specifier template template-id char wchar_t bool short int long signed unsigned float double void GNU Extension: simple-type-specifier: __typeof__ unary-expression __typeof__ ( type-id ) Returns the indicated TYPE_DECL. If DECL_SPECS is not NULL, it is appropriately updated. */ static tree cp_parser_simple_type_specifier (cp_parser* parser, cp_decl_specifier_seq *decl_specs, cp_parser_flags flags) { tree type = NULL_TREE; cp_token *token; /* Peek at the next token. */ token = cp_lexer_peek_token (parser->lexer); /* If we're looking at a keyword, things are easy. */ switch (token->keyword) { case RID_CHAR: if (decl_specs) decl_specs->explicit_char_p = true; type = char_type_node; break; case RID_WCHAR: type = wchar_type_node; break; case RID_BOOL: type = boolean_type_node; break; case RID_SHORT: if (decl_specs) ++decl_specs->specs[(int) ds_short]; type = short_integer_type_node; break; case RID_INT: if (decl_specs) decl_specs->explicit_int_p = true; type = integer_type_node; break; case RID_LONG: if (decl_specs) ++decl_specs->specs[(int) ds_long]; type = long_integer_type_node; break; case RID_SIGNED: if (decl_specs) ++decl_specs->specs[(int) ds_signed]; type = integer_type_node; break; case RID_UNSIGNED: if (decl_specs) ++decl_specs->specs[(int) ds_unsigned]; type = unsigned_type_node; break; case RID_FLOAT: type = float_type_node; break; case RID_DOUBLE: type = double_type_node; break; case RID_VOID: type = void_type_node; break; case RID_TYPEOF: /* Consume the `typeof' token. */ cp_lexer_consume_token (parser->lexer); /* Parse the operand to `typeof'. */ type = cp_parser_sizeof_operand (parser, RID_TYPEOF); /* If it is not already a TYPE, take its type. */ if (!TYPE_P (type)) type = finish_typeof (type); if (decl_specs) cp_parser_set_decl_spec_type (decl_specs, type, /*user_defined_p=*/true); return type; default: break; } /* If the type-specifier was for a built-in type, we're done. */ if (type) { tree id; /* Record the type. */ if (decl_specs && (token->keyword != RID_SIGNED && token->keyword != RID_UNSIGNED && token->keyword != RID_SHORT && token->keyword != RID_LONG)) cp_parser_set_decl_spec_type (decl_specs, type, /*user_defined=*/false); if (decl_specs) decl_specs->any_specifiers_p = true; /* Consume the token. */ id = cp_lexer_consume_token (parser->lexer)->u.value; /* There is no valid C++ program where a non-template type is followed by a "<". That usually indicates that the user thought that the type was a template. */ cp_parser_check_for_invalid_template_id (parser, type); return TYPE_NAME (type); } /* The type-specifier must be a user-defined type. */ if (!(flags & CP_PARSER_FLAGS_NO_USER_DEFINED_TYPES)) { bool qualified_p; bool global_p; /* Don't gobble tokens or issue error messages if this is an optional type-specifier. */ if (flags & CP_PARSER_FLAGS_OPTIONAL) cp_parser_parse_tentatively (parser); /* Look for the optional `::' operator. */ global_p = (cp_parser_global_scope_opt (parser, /*current_scope_valid_p=*/false) != NULL_TREE); /* Look for the nested-name specifier. */ qualified_p = (cp_parser_nested_name_specifier_opt (parser, /*typename_keyword_p=*/false, /*check_dependency_p=*/true, /*type_p=*/false, /*is_declaration=*/false) != NULL_TREE); /* If we have seen a nested-name-specifier, and the next token is `template', then we are using the template-id production. */ if (parser->scope && cp_parser_optional_template_keyword (parser)) { /* Look for the template-id. */ type = cp_parser_template_id (parser, /*template_keyword_p=*/true, /*check_dependency_p=*/true, /*is_declaration=*/false); /* If the template-id did not name a type, we are out of luck. */ if (TREE_CODE (type) != TYPE_DECL) { cp_parser_error (parser, "expected template-id for type"); type = NULL_TREE; } } /* Otherwise, look for a type-name. */ else type = cp_parser_type_name (parser); /* Keep track of all name-lookups performed in class scopes. */ if (type && !global_p && !qualified_p && TREE_CODE (type) == TYPE_DECL && TREE_CODE (DECL_NAME (type)) == IDENTIFIER_NODE) maybe_note_name_used_in_class (DECL_NAME (type), type); /* If it didn't work out, we don't have a TYPE. */ if ((flags & CP_PARSER_FLAGS_OPTIONAL) && !cp_parser_parse_definitely (parser)) type = NULL_TREE; if (type && decl_specs) cp_parser_set_decl_spec_type (decl_specs, type, /*user_defined=*/true); } /* If we didn't get a type-name, issue an error message. */ if (!type && !(flags & CP_PARSER_FLAGS_OPTIONAL)) { cp_parser_error (parser, "expected type-name"); return error_mark_node; } /* There is no valid C++ program where a non-template type is followed by a "<". That usually indicates that the user thought that the type was a template. */ if (type && type != error_mark_node) { /* As a last-ditch effort, see if TYPE is an Objective-C type. If it is, then the '<'...'>' enclose protocol names rather than template arguments, and so everything is fine. */ if (c_dialect_objc () && (objc_is_id (type) || objc_is_class_name (type))) { tree protos = cp_parser_objc_protocol_refs_opt (parser); tree qual_type = objc_get_protocol_qualified_type (type, protos); /* Clobber the "unqualified" type previously entered into DECL_SPECS with the new, improved protocol-qualified version. */ if (decl_specs) decl_specs->type = qual_type; return qual_type; } cp_parser_check_for_invalid_template_id (parser, TREE_TYPE (type)); } return type; } /* Parse a type-name. type-name: class-name enum-name typedef-name enum-name: identifier typedef-name: identifier Returns a TYPE_DECL for the type. */ static tree cp_parser_type_name (cp_parser* parser) { tree type_decl; tree identifier; /* We can't know yet whether it is a class-name or not. */ cp_parser_parse_tentatively (parser); /* Try a class-name. */ type_decl = cp_parser_class_name (parser, /*typename_keyword_p=*/false, /*template_keyword_p=*/false, none_type, /*check_dependency_p=*/true, /*class_head_p=*/false, /*is_declaration=*/false); /* If it's not a class-name, keep looking. */ if (!cp_parser_parse_definitely (parser)) { /* It must be a typedef-name or an enum-name. */ identifier = cp_parser_identifier (parser); if (identifier == error_mark_node) return error_mark_node; /* Look up the type-name. */ type_decl = cp_parser_lookup_name_simple (parser, identifier); if (TREE_CODE (type_decl) != TYPE_DECL && (objc_is_id (identifier) || objc_is_class_name (identifier))) { /* See if this is an Objective-C type. */ tree protos = cp_parser_objc_protocol_refs_opt (parser); tree type = objc_get_protocol_qualified_type (identifier, protos); if (type) type_decl = TYPE_NAME (type); } /* Issue an error if we did not find a type-name. */ if (TREE_CODE (type_decl) != TYPE_DECL) { if (!cp_parser_simulate_error (parser)) cp_parser_name_lookup_error (parser, identifier, type_decl, "is not a type"); type_decl = error_mark_node; } /* Remember that the name was used in the definition of the current class so that we can check later to see if the meaning would have been different after the class was entirely defined. */ else if (type_decl != error_mark_node && !parser->scope) maybe_note_name_used_in_class (identifier, type_decl); } return type_decl; } /* Parse an elaborated-type-specifier. Note that the grammar given here incorporates the resolution to DR68. elaborated-type-specifier: class-key :: [opt] nested-name-specifier [opt] identifier class-key :: [opt] nested-name-specifier [opt] template [opt] template-id enum :: [opt] nested-name-specifier [opt] identifier typename :: [opt] nested-name-specifier identifier typename :: [opt] nested-name-specifier template [opt] template-id GNU extension: elaborated-type-specifier: class-key attributes :: [opt] nested-name-specifier [opt] identifier class-key attributes :: [opt] nested-name-specifier [opt] template [opt] template-id enum attributes :: [opt] nested-name-specifier [opt] identifier If IS_FRIEND is TRUE, then this elaborated-type-specifier is being declared `friend'. If IS_DECLARATION is TRUE, then this elaborated-type-specifier appears in a decl-specifiers-seq, i.e., something is being declared. Returns the TYPE specified. */ static tree cp_parser_elaborated_type_specifier (cp_parser* parser, bool is_friend, bool is_declaration) { enum tag_types tag_type; tree identifier; tree type = NULL_TREE; tree attributes = NULL_TREE; /* See if we're looking at the `enum' keyword. */ if (cp_lexer_next_token_is_keyword (parser->lexer, RID_ENUM)) { /* Consume the `enum' token. */ cp_lexer_consume_token (parser->lexer); /* Remember that it's an enumeration type. */ tag_type = enum_type; /* Parse the attributes. */ attributes = cp_parser_attributes_opt (parser); } /* Or, it might be `typename'. */ else if (cp_lexer_next_token_is_keyword (parser->lexer, RID_TYPENAME)) { /* Consume the `typename' token. */ cp_lexer_consume_token (parser->lexer); /* Remember that it's a `typename' type. */ tag_type = typename_type; /* The `typename' keyword is only allowed in templates. */ if (!processing_template_decl) pedwarn ("using %<typename%> outside of template"); } /* Otherwise it must be a class-key. */ else { tag_type = cp_parser_class_key (parser); if (tag_type == none_type) return error_mark_node; /* Parse the attributes. */ attributes = cp_parser_attributes_opt (parser); } /* Look for the `::' operator. */ cp_parser_global_scope_opt (parser, /*current_scope_valid_p=*/false); /* Look for the nested-name-specifier. */ if (tag_type == typename_type) { if (!cp_parser_nested_name_specifier (parser, /*typename_keyword_p=*/true, /*check_dependency_p=*/true, /*type_p=*/true, is_declaration)) return error_mark_node; } else /* Even though `typename' is not present, the proposed resolution to Core Issue 180 says that in `class A<T>::B', `B' should be considered a type-name, even if `A<T>' is dependent. */ cp_parser_nested_name_specifier_opt (parser, /*typename_keyword_p=*/true, /*check_dependency_p=*/true, /*type_p=*/true, is_declaration); /* For everything but enumeration types, consider a template-id. For an enumeration type, consider only a plain identifier. */ if (tag_type != enum_type) { bool template_p = false; tree decl; /* Allow the `template' keyword. */ template_p = cp_parser_optional_template_keyword (parser); /* If we didn't see `template', we don't know if there's a template-id or not. */ if (!template_p) cp_parser_parse_tentatively (parser); /* Parse the template-id. */ decl = cp_parser_template_id (parser, template_p, /*check_dependency_p=*/true, is_declaration); /* If we didn't find a template-id, look for an ordinary identifier. */ if (!template_p && !cp_parser_parse_definitely (parser)) ; /* If DECL is a TEMPLATE_ID_EXPR, and the `typename' keyword is in effect, then we must assume that, upon instantiation, the template will correspond to a class. */ else if (TREE_CODE (decl) == TEMPLATE_ID_EXPR && tag_type == typename_type) type = make_typename_type (parser->scope, decl, typename_type, /*complain=*/tf_error); else type = TREE_TYPE (decl); } if (!type) { identifier = cp_parser_identifier (parser); if (identifier == error_mark_node) { parser->scope = NULL_TREE; return error_mark_node; } /* For a `typename', we needn't call xref_tag. */ if (tag_type == typename_type && TREE_CODE (parser->scope) != NAMESPACE_DECL) return cp_parser_make_typename_type (parser, parser->scope, identifier); /* Look up a qualified name in the usual way. */ if (parser->scope) { tree decl; decl = cp_parser_lookup_name (parser, identifier, tag_type, /*is_template=*/false, /*is_namespace=*/false, /*check_dependency=*/true, /*ambiguous_decls=*/NULL); /* If we are parsing friend declaration, DECL may be a TEMPLATE_DECL tree node here. However, we need to check whether this TEMPLATE_DECL results in valid code. Consider the following example: namespace N { template <class T> class C {}; } class X { template <class T> friend class N::C; // #1, valid code }; template <class T> class Y { friend class N::C; // #2, invalid code }; For both case #1 and #2, we arrive at a TEMPLATE_DECL after name lookup of `N::C'. We see that friend declaration must be template for the code to be valid. Note that processing_template_decl does not work here since it is always 1 for the above two cases. */ decl = (cp_parser_maybe_treat_template_as_class (decl, /*tag_name_p=*/is_friend && parser->num_template_parameter_lists)); if (TREE_CODE (decl) != TYPE_DECL) { cp_parser_diagnose_invalid_type_name (parser, parser->scope, identifier); return error_mark_node; } if (TREE_CODE (TREE_TYPE (decl)) != TYPENAME_TYPE) { bool allow_template = (parser->num_template_parameter_lists || DECL_SELF_REFERENCE_P (decl)); type = check_elaborated_type_specifier (tag_type, decl, allow_template); if (type == error_mark_node) return error_mark_node; } type = TREE_TYPE (decl); } else { /* An elaborated-type-specifier sometimes introduces a new type and sometimes names an existing type. Normally, the rule is that it introduces a new type only if there is not an existing type of the same name already in scope. For example, given: struct S {}; void f() { struct S s; } the `struct S' in the body of `f' is the same `struct S' as in the global scope; the existing definition is used. However, if there were no global declaration, this would introduce a new local class named `S'. An exception to this rule applies to the following code: namespace N { struct S; } Here, the elaborated-type-specifier names a new type unconditionally; even if there is already an `S' in the containing scope this declaration names a new type. This exception only applies if the elaborated-type-specifier forms the complete declaration: [class.name] A declaration consisting solely of `class-key identifier ;' is either a redeclaration of the name in the current scope or a forward declaration of the identifier as a class name. It introduces the name into the current scope. We are in this situation precisely when the next token is a `;'. An exception to the exception is that a `friend' declaration does *not* name a new type; i.e., given: struct S { friend struct T; }; `T' is not a new type in the scope of `S'. Also, `new struct S' or `sizeof (struct S)' never results in the definition of a new type; a new type can only be declared in a declaration context. */ tag_scope ts; bool template_p; if (is_friend) /* Friends have special name lookup rules. */ ts = ts_within_enclosing_non_class; else if (is_declaration && cp_lexer_next_token_is (parser->lexer, CPP_SEMICOLON)) /* This is a `class-key identifier ;' */ ts = ts_current; else ts = ts_global; template_p = (parser->num_template_parameter_lists && (cp_parser_next_token_starts_class_definition_p (parser) || cp_lexer_next_token_is (parser->lexer, CPP_SEMICOLON))); /* An unqualified name was used to reference this type, so there were no qualifying templates. */ if (!cp_parser_check_template_parameters (parser, /*num_templates=*/0)) return error_mark_node; type = xref_tag (tag_type, identifier, ts, template_p); } } if (type == error_mark_node) return error_mark_node; /* Allow attributes on forward declarations of classes. */ if (attributes) { if (TREE_CODE (type) == TYPENAME_TYPE) warning (OPT_Wattributes, "attributes ignored on uninstantiated type"); else if (tag_type != enum_type && CLASSTYPE_TEMPLATE_INSTANTIATION (type) && ! processing_explicit_instantiation) warning (OPT_Wattributes, "attributes ignored on template instantiation"); else if (is_declaration && cp_parser_declares_only_class_p (parser)) cplus_decl_attributes (&type, attributes, (int) ATTR_FLAG_TYPE_IN_PLACE); else warning (OPT_Wattributes, "attributes ignored on elaborated-type-specifier that is not a forward declaration"); } if (tag_type != enum_type) cp_parser_check_class_key (tag_type, type); /* A "<" cannot follow an elaborated type specifier. If that happens, the user was probably trying to form a template-id. */ cp_parser_check_for_invalid_template_id (parser, type); return type; } /* Parse an enum-specifier. enum-specifier: enum identifier [opt] { enumerator-list [opt] } GNU Extensions: enum attributes[opt] identifier [opt] { enumerator-list [opt] } attributes[opt] Returns an ENUM_TYPE representing the enumeration, or NULL_TREE if the token stream isn't an enum-specifier after all. */ static tree cp_parser_enum_specifier (cp_parser* parser) { tree identifier; tree type; tree attributes; /* Parse tentatively so that we can back up if we don't find a enum-specifier. */ cp_parser_parse_tentatively (parser); /* Caller guarantees that the current token is 'enum', an identifier possibly follows, and the token after that is an opening brace. If we don't have an identifier, fabricate an anonymous name for the enumeration being defined. */ cp_lexer_consume_token (parser->lexer); attributes = cp_parser_attributes_opt (parser); if (cp_lexer_next_token_is (parser->lexer, CPP_NAME)) identifier = cp_parser_identifier (parser); else identifier = make_anon_name (); /* Look for the `{' but don't consume it yet. */ if (!cp_lexer_next_token_is (parser->lexer, CPP_OPEN_BRACE)) cp_parser_simulate_error (parser); if (!cp_parser_parse_definitely (parser)) return NULL_TREE; /* Issue an error message if type-definitions are forbidden here. */ if (!cp_parser_check_type_definition (parser)) type = error_mark_node; else /* Create the new type. We do this before consuming the opening brace so the enum will be recorded as being on the line of its tag (or the 'enum' keyword, if there is no tag). */ type = start_enum (identifier); /* Consume the opening brace. */ cp_lexer_consume_token (parser->lexer); if (type == error_mark_node) { cp_parser_skip_to_end_of_block_or_statement (parser); return error_mark_node; } /* If the next token is not '}', then there are some enumerators. */ if (cp_lexer_next_token_is_not (parser->lexer, CPP_CLOSE_BRACE)) cp_parser_enumerator_list (parser, type); /* Consume the final '}'. */ cp_parser_require (parser, CPP_CLOSE_BRACE, "`}'"); /* Look for trailing attributes to apply to this enumeration, and apply them if appropriate. */ if (cp_parser_allow_gnu_extensions_p (parser)) { tree trailing_attr = cp_parser_attributes_opt (parser); cplus_decl_attributes (&type, trailing_attr, (int) ATTR_FLAG_TYPE_IN_PLACE); } /* Finish up the enumeration. */ finish_enum (type); return type; } /* Parse an enumerator-list. The enumerators all have the indicated TYPE. enumerator-list: enumerator-definition enumerator-list , enumerator-definition */ static void cp_parser_enumerator_list (cp_parser* parser, tree type) { while (true) { /* Parse an enumerator-definition. */ cp_parser_enumerator_definition (parser, type); /* If the next token is not a ',', we've reached the end of the list. */ if (cp_lexer_next_token_is_not (parser->lexer, CPP_COMMA)) break; /* Otherwise, consume the `,' and keep going. */ cp_lexer_consume_token (parser->lexer); /* If the next token is a `}', there is a trailing comma. */ if (cp_lexer_next_token_is (parser->lexer, CPP_CLOSE_BRACE)) { if (pedantic && !in_system_header) pedwarn ("comma at end of enumerator list"); break; } } } /* Parse an enumerator-definition. The enumerator has the indicated TYPE. enumerator-definition: enumerator enumerator = constant-expression enumerator: identifier */ static void cp_parser_enumerator_definition (cp_parser* parser, tree type) { tree identifier; tree value; /* Look for the identifier. */ identifier = cp_parser_identifier (parser); if (identifier == error_mark_node) return; /* If the next token is an '=', then there is an explicit value. */ if (cp_lexer_next_token_is (parser->lexer, CPP_EQ)) { /* Consume the `=' token. */ cp_lexer_consume_token (parser->lexer); /* Parse the value. */ value = cp_parser_constant_expression (parser, /*allow_non_constant_p=*/false, NULL); } else value = NULL_TREE; /* Create the enumerator. */ build_enumerator (identifier, value, type); } /* Parse a namespace-name. namespace-name: original-namespace-name namespace-alias Returns the NAMESPACE_DECL for the namespace. */ static tree cp_parser_namespace_name (cp_parser* parser) { tree identifier; tree namespace_decl; /* Get the name of the namespace. */ identifier = cp_parser_identifier (parser); if (identifier == error_mark_node) return error_mark_node; /* Look up the identifier in the currently active scope. Look only for namespaces, due to: [basic.lookup.udir] When looking up a namespace-name in a using-directive or alias definition, only namespace names are considered. And: [basic.lookup.qual] During the lookup of a name preceding the :: scope resolution operator, object, function, and enumerator names are ignored. (Note that cp_parser_class_or_namespace_name only calls this function if the token after the name is the scope resolution operator.) */ namespace_decl = cp_parser_lookup_name (parser, identifier, none_type, /*is_template=*/false, /*is_namespace=*/true, /*check_dependency=*/true, /*ambiguous_decls=*/NULL); /* If it's not a namespace, issue an error. */ if (namespace_decl == error_mark_node || TREE_CODE (namespace_decl) != NAMESPACE_DECL) { if (!cp_parser_uncommitted_to_tentative_parse_p (parser)) error ("%qD is not a namespace-name", identifier); cp_parser_error (parser, "expected namespace-name"); namespace_decl = error_mark_node; } return namespace_decl; } /* Parse a namespace-definition. namespace-definition: named-namespace-definition unnamed-namespace-definition named-namespace-definition: original-namespace-definition extension-namespace-definition original-namespace-definition: namespace identifier { namespace-body } extension-namespace-definition: namespace original-namespace-name { namespace-body } unnamed-namespace-definition: namespace { namespace-body } */ static void cp_parser_namespace_definition (cp_parser* parser) { tree identifier, attribs; /* Look for the `namespace' keyword. */ cp_parser_require_keyword (parser, RID_NAMESPACE, "`namespace'"); /* Get the name of the namespace. We do not attempt to distinguish between an original-namespace-definition and an extension-namespace-definition at this point. The semantic analysis routines are responsible for that. */ if (cp_lexer_next_token_is (parser->lexer, CPP_NAME)) identifier = cp_parser_identifier (parser); else identifier = NULL_TREE; /* Parse any specified attributes. */ attribs = cp_parser_attributes_opt (parser); /* Look for the `{' to start the namespace. */ cp_parser_require (parser, CPP_OPEN_BRACE, "`{'"); /* Start the namespace. */ push_namespace_with_attribs (identifier, attribs); /* Parse the body of the namespace. */ cp_parser_namespace_body (parser); /* Finish the namespace. */ pop_namespace (); /* Look for the final `}'. */ cp_parser_require (parser, CPP_CLOSE_BRACE, "`}'"); } /* Parse a namespace-body. namespace-body: declaration-seq [opt] */ static void cp_parser_namespace_body (cp_parser* parser) { cp_parser_declaration_seq_opt (parser); } /* Parse a namespace-alias-definition. namespace-alias-definition: namespace identifier = qualified-namespace-specifier ; */ static void cp_parser_namespace_alias_definition (cp_parser* parser) { tree identifier; tree namespace_specifier; /* Look for the `namespace' keyword. */ cp_parser_require_keyword (parser, RID_NAMESPACE, "`namespace'"); /* Look for the identifier. */ identifier = cp_parser_identifier (parser); if (identifier == error_mark_node) return; /* Look for the `=' token. */ cp_parser_require (parser, CPP_EQ, "`='"); /* Look for the qualified-namespace-specifier. */ namespace_specifier = cp_parser_qualified_namespace_specifier (parser); /* Look for the `;' token. */ cp_parser_require (parser, CPP_SEMICOLON, "`;'"); /* Register the alias in the symbol table. */ do_namespace_alias (identifier, namespace_specifier); } /* Parse a qualified-namespace-specifier. qualified-namespace-specifier: :: [opt] nested-name-specifier [opt] namespace-name Returns a NAMESPACE_DECL corresponding to the specified namespace. */ static tree cp_parser_qualified_namespace_specifier (cp_parser* parser) { /* Look for the optional `::'. */ cp_parser_global_scope_opt (parser, /*current_scope_valid_p=*/false); /* Look for the optional nested-name-specifier. */ cp_parser_nested_name_specifier_opt (parser, /*typename_keyword_p=*/false, /*check_dependency_p=*/true, /*type_p=*/false, /*is_declaration=*/true); return cp_parser_namespace_name (parser); } /* Parse a using-declaration, or, if ACCESS_DECLARATION_P is true, an access declaration. using-declaration: using typename [opt] :: [opt] nested-name-specifier unqualified-id ; using :: unqualified-id ; access-declaration: qualified-id ; */ static bool cp_parser_using_declaration (cp_parser* parser, bool access_declaration_p) { cp_token *token; bool typename_p = false; bool global_scope_p; tree decl; tree identifier; tree qscope; if (access_declaration_p) cp_parser_parse_tentatively (parser); else { /* Look for the `using' keyword. */ cp_parser_require_keyword (parser, RID_USING, "`using'"); /* Peek at the next token. */ token = cp_lexer_peek_token (parser->lexer); /* See if it's `typename'. */ if (token->keyword == RID_TYPENAME) { /* Remember that we've seen it. */ typename_p = true; /* Consume the `typename' token. */ cp_lexer_consume_token (parser->lexer); } } /* Look for the optional global scope qualification. */ global_scope_p = (cp_parser_global_scope_opt (parser, /*current_scope_valid_p=*/false) != NULL_TREE); /* If we saw `typename', or didn't see `::', then there must be a nested-name-specifier present. */ if (typename_p || !global_scope_p) qscope = cp_parser_nested_name_specifier (parser, typename_p, /*check_dependency_p=*/true, /*type_p=*/false, /*is_declaration=*/true); /* Otherwise, we could be in either of the two productions. In that case, treat the nested-name-specifier as optional. */ else qscope = cp_parser_nested_name_specifier_opt (parser, /*typename_keyword_p=*/false, /*check_dependency_p=*/true, /*type_p=*/false, /*is_declaration=*/true); if (!qscope) qscope = global_namespace; if (access_declaration_p && cp_parser_error_occurred (parser)) /* Something has already gone wrong; there's no need to parse further. Since an error has occurred, the return value of cp_parser_parse_definitely will be false, as required. */ return cp_parser_parse_definitely (parser); /* Parse the unqualified-id. */ identifier = cp_parser_unqualified_id (parser, /*template_keyword_p=*/false, /*check_dependency_p=*/true, /*declarator_p=*/true, /*optional_p=*/false); if (access_declaration_p) { if (cp_lexer_next_token_is_not (parser->lexer, CPP_SEMICOLON)) cp_parser_simulate_error (parser); if (!cp_parser_parse_definitely (parser)) return false; } /* The function we call to handle a using-declaration is different depending on what scope we are in. */ if (qscope == error_mark_node || identifier == error_mark_node) ; else if (TREE_CODE (identifier) != IDENTIFIER_NODE && TREE_CODE (identifier) != BIT_NOT_EXPR) /* [namespace.udecl] A using declaration shall not name a template-id. */ error ("a template-id may not appear in a using-declaration"); else { if (at_class_scope_p ()) { /* Create the USING_DECL. */ decl = do_class_using_decl (parser->scope, identifier); /* Add it to the list of members in this class. */ finish_member_declaration (decl); } else { decl = cp_parser_lookup_name_simple (parser, identifier); if (decl == error_mark_node) cp_parser_name_lookup_error (parser, identifier, decl, NULL); else if (!at_namespace_scope_p ()) do_local_using_decl (decl, qscope, identifier); else do_toplevel_using_decl (decl, qscope, identifier); } } /* Look for the final `;'. */ cp_parser_require (parser, CPP_SEMICOLON, "`;'"); return true; } /* Parse a using-directive. using-directive: using namespace :: [opt] nested-name-specifier [opt] namespace-name ; */ static void cp_parser_using_directive (cp_parser* parser) { tree namespace_decl; tree attribs; /* Look for the `using' keyword. */ cp_parser_require_keyword (parser, RID_USING, "`using'"); /* And the `namespace' keyword. */ cp_parser_require_keyword (parser, RID_NAMESPACE, "`namespace'"); /* Look for the optional `::' operator. */ cp_parser_global_scope_opt (parser, /*current_scope_valid_p=*/false); /* And the optional nested-name-specifier. */ cp_parser_nested_name_specifier_opt (parser, /*typename_keyword_p=*/false, /*check_dependency_p=*/true, /*type_p=*/false, /*is_declaration=*/true); /* Get the namespace being used. */ namespace_decl = cp_parser_namespace_name (parser); /* And any specified attributes. */ attribs = cp_parser_attributes_opt (parser); /* Update the symbol table. */ parse_using_directive (namespace_decl, attribs); /* Look for the final `;'. */ cp_parser_require (parser, CPP_SEMICOLON, "`;'"); } /* Parse an asm-definition. asm-definition: asm ( string-literal ) ; GNU Extension: asm-definition: asm volatile [opt] ( string-literal ) ; asm volatile [opt] ( string-literal : asm-operand-list [opt] ) ; asm volatile [opt] ( string-literal : asm-operand-list [opt] : asm-operand-list [opt] ) ; asm volatile [opt] ( string-literal : asm-operand-list [opt] : asm-operand-list [opt] : asm-operand-list [opt] ) ; */ static void cp_parser_asm_definition (cp_parser* parser) { tree string; tree outputs = NULL_TREE; tree inputs = NULL_TREE; tree clobbers = NULL_TREE; tree asm_stmt; bool volatile_p = false; bool extended_p = false; /* Look for the `asm' keyword. */ cp_parser_require_keyword (parser, RID_ASM, "`asm'"); /* See if the next token is `volatile'. */ if (cp_parser_allow_gnu_extensions_p (parser) && cp_lexer_next_token_is_keyword (parser->lexer, RID_VOLATILE)) { /* Remember that we saw the `volatile' keyword. */ volatile_p = true; /* Consume the token. */ cp_lexer_consume_token (parser->lexer); } /* Look for the opening `('. */ if (!cp_parser_require (parser, CPP_OPEN_PAREN, "`('")) return; /* Look for the string. */ string = cp_parser_string_literal (parser, false, false); if (string == error_mark_node) { cp_parser_skip_to_closing_parenthesis (parser, true, false, /*consume_paren=*/true); return; } /* If we're allowing GNU extensions, check for the extended assembly syntax. Unfortunately, the `:' tokens need not be separated by a space in C, and so, for compatibility, we tolerate that here too. Doing that means that we have to treat the `::' operator as two `:' tokens. */ if (cp_parser_allow_gnu_extensions_p (parser) && parser->in_function_body && (cp_lexer_next_token_is (parser->lexer, CPP_COLON) || cp_lexer_next_token_is (parser->lexer, CPP_SCOPE))) { bool inputs_p = false; bool clobbers_p = false; /* The extended syntax was used. */ extended_p = true; /* Look for outputs. */ if (cp_lexer_next_token_is (parser->lexer, CPP_COLON)) { /* Consume the `:'. */ cp_lexer_consume_token (parser->lexer); /* Parse the output-operands. */ if (cp_lexer_next_token_is_not (parser->lexer, CPP_COLON) && cp_lexer_next_token_is_not (parser->lexer, CPP_SCOPE) && cp_lexer_next_token_is_not (parser->lexer, CPP_CLOSE_PAREN)) outputs = cp_parser_asm_operand_list (parser); } /* If the next token is `::', there are no outputs, and the next token is the beginning of the inputs. */ else if (cp_lexer_next_token_is (parser->lexer, CPP_SCOPE)) /* The inputs are coming next. */ inputs_p = true; /* Look for inputs. */ if (inputs_p || cp_lexer_next_token_is (parser->lexer, CPP_COLON)) { /* Consume the `:' or `::'. */ cp_lexer_consume_token (parser->lexer); /* Parse the output-operands. */ if (cp_lexer_next_token_is_not (parser->lexer, CPP_COLON) && cp_lexer_next_token_is_not (parser->lexer, CPP_CLOSE_PAREN)) inputs = cp_parser_asm_operand_list (parser); } else if (cp_lexer_next_token_is (parser->lexer, CPP_SCOPE)) /* The clobbers are coming next. */ clobbers_p = true; /* Look for clobbers. */ if (clobbers_p || cp_lexer_next_token_is (parser->lexer, CPP_COLON)) { /* Consume the `:' or `::'. */ cp_lexer_consume_token (parser->lexer); /* Parse the clobbers. */ if (cp_lexer_next_token_is_not (parser->lexer, CPP_CLOSE_PAREN)) clobbers = cp_parser_asm_clobber_list (parser); } } /* Look for the closing `)'. */ if (!cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'")) cp_parser_skip_to_closing_parenthesis (parser, true, false, /*consume_paren=*/true); cp_parser_require (parser, CPP_SEMICOLON, "`;'"); /* Create the ASM_EXPR. */ if (parser->in_function_body) { asm_stmt = finish_asm_stmt (volatile_p, string, outputs, inputs, clobbers); /* If the extended syntax was not used, mark the ASM_EXPR. */ if (!extended_p) { tree temp = asm_stmt; if (TREE_CODE (temp) == CLEANUP_POINT_EXPR) temp = TREE_OPERAND (temp, 0); ASM_INPUT_P (temp) = 1; } } else cgraph_add_asm_node (string); } /* Declarators [gram.dcl.decl] */ /* Parse an init-declarator. init-declarator: declarator initializer [opt] GNU Extension: init-declarator: declarator asm-specification [opt] attributes [opt] initializer [opt] function-definition: decl-specifier-seq [opt] declarator ctor-initializer [opt] function-body decl-specifier-seq [opt] declarator function-try-block GNU Extension: function-definition: __extension__ function-definition The DECL_SPECIFIERS apply to this declarator. Returns a representation of the entity declared. If MEMBER_P is TRUE, then this declarator appears in a class scope. The new DECL created by this declarator is returned. The CHECKS are access checks that should be performed once we know what entity is being declared (and, therefore, what classes have befriended it). If FUNCTION_DEFINITION_ALLOWED_P then we handle the declarator and for a function-definition here as well. If the declarator is a declarator for a function-definition, *FUNCTION_DEFINITION_P will be TRUE upon return. By that point, the function-definition will have been completely parsed. FUNCTION_DEFINITION_P may be NULL if FUNCTION_DEFINITION_ALLOWED_P is FALSE. */ static tree cp_parser_init_declarator (cp_parser* parser, cp_decl_specifier_seq *decl_specifiers, VEC (deferred_access_check,gc)* checks, bool function_definition_allowed_p, bool member_p, int declares_class_or_enum, bool* function_definition_p) { cp_token *token; cp_declarator *declarator; tree prefix_attributes; tree attributes; tree asm_specification; tree initializer; tree decl = NULL_TREE; tree scope; bool is_initialized; /* Only valid if IS_INITIALIZED is true. In that case, CPP_EQ if initialized with "= ..", CPP_OPEN_PAREN if initialized with "(...)". */ enum cpp_ttype initialization_kind; bool is_parenthesized_init = false; bool is_non_constant_init; int ctor_dtor_or_conv_p; bool friend_p; tree pushed_scope = NULL; /* Gather the attributes that were provided with the decl-specifiers. */ prefix_attributes = decl_specifiers->attributes; /* Assume that this is not the declarator for a function definition. */ if (function_definition_p) *function_definition_p = false; /* Defer access checks while parsing the declarator; we cannot know what names are accessible until we know what is being declared. */ resume_deferring_access_checks (); /* Parse the declarator. */ declarator = cp_parser_declarator (parser, CP_PARSER_DECLARATOR_NAMED, &ctor_dtor_or_conv_p, /*parenthesized_p=*/NULL, /*member_p=*/false); /* Gather up the deferred checks. */ stop_deferring_access_checks (); /* If the DECLARATOR was erroneous, there's no need to go further. */ if (declarator == cp_error_declarator) return error_mark_node; /* Check that the number of template-parameter-lists is OK. */ if (!cp_parser_check_declarator_template_parameters (parser, declarator)) return error_mark_node; if (declares_class_or_enum & 2) cp_parser_check_for_definition_in_return_type (declarator, decl_specifiers->type); /* Figure out what scope the entity declared by the DECLARATOR is located in. `grokdeclarator' sometimes changes the scope, so we compute it now. */ scope = get_scope_of_declarator (declarator); /* If we're allowing GNU extensions, look for an asm-specification and attributes. */ if (cp_parser_allow_gnu_extensions_p (parser)) { /* Look for an asm-specification. */ asm_specification = cp_parser_asm_specification_opt (parser); /* And attributes. */ attributes = cp_parser_attributes_opt (parser); } else { asm_specification = NULL_TREE; attributes = NULL_TREE; } /* Peek at the next token. */ token = cp_lexer_peek_token (parser->lexer); /* Check to see if the token indicates the start of a function-definition. */ if (cp_parser_token_starts_function_definition_p (token)) { if (!function_definition_allowed_p) { /* If a function-definition should not appear here, issue an error message. */ cp_parser_error (parser, "a function-definition is not allowed here"); return error_mark_node; } else { /* Neither attributes nor an asm-specification are allowed on a function-definition. */ if (asm_specification) error ("an asm-specification is not allowed on a function-definition"); if (attributes) error ("attributes are not allowed on a function-definition"); /* This is a function-definition. */ *function_definition_p = true; /* Parse the function definition. */ if (member_p) decl = cp_parser_save_member_function_body (parser, decl_specifiers, declarator, prefix_attributes); else decl = (cp_parser_function_definition_from_specifiers_and_declarator (parser, decl_specifiers, prefix_attributes, declarator)); return decl; } } /* [dcl.dcl] Only in function declarations for constructors, destructors, and type conversions can the decl-specifier-seq be omitted. We explicitly postpone this check past the point where we handle function-definitions because we tolerate function-definitions that are missing their return types in some modes. */ if (!decl_specifiers->any_specifiers_p && ctor_dtor_or_conv_p <= 0) { cp_parser_error (parser, "expected constructor, destructor, or type conversion"); return error_mark_node; } /* An `=' or an `(' indicates an initializer. */ if (token->type == CPP_EQ || token->type == CPP_OPEN_PAREN) { is_initialized = true; initialization_kind = token->type; } else { /* If the init-declarator isn't initialized and isn't followed by a `,' or `;', it's not a valid init-declarator. */ if (token->type != CPP_COMMA && token->type != CPP_SEMICOLON) { cp_parser_error (parser, "expected initializer"); return error_mark_node; } is_initialized = false; initialization_kind = CPP_EOF; } /* Because start_decl has side-effects, we should only call it if we know we're going ahead. By this point, we know that we cannot possibly be looking at any other construct. */ cp_parser_commit_to_tentative_parse (parser); /* If the decl specifiers were bad, issue an error now that we're sure this was intended to be a declarator. Then continue declaring the variable(s), as int, to try to cut down on further errors. */ if (decl_specifiers->any_specifiers_p && decl_specifiers->type == error_mark_node) { cp_parser_error (parser, "invalid type in declaration"); decl_specifiers->type = integer_type_node; } /* Check to see whether or not this declaration is a friend. */ friend_p = cp_parser_friend_p (decl_specifiers); /* Enter the newly declared entry in the symbol table. If we're processing a declaration in a class-specifier, we wait until after processing the initializer. */ if (!member_p) { if (parser->in_unbraced_linkage_specification_p) decl_specifiers->storage_class = sc_extern; decl = start_decl (declarator, decl_specifiers, is_initialized, attributes, prefix_attributes, &pushed_scope); } else if (scope) /* Enter the SCOPE. That way unqualified names appearing in the initializer will be looked up in SCOPE. */ pushed_scope = push_scope (scope); /* Perform deferred access control checks, now that we know in which SCOPE the declared entity resides. */ if (!member_p && decl) { tree saved_current_function_decl = NULL_TREE; /* If the entity being declared is a function, pretend that we are in its scope. If it is a `friend', it may have access to things that would not otherwise be accessible. */ if (TREE_CODE (decl) == FUNCTION_DECL) { saved_current_function_decl = current_function_decl; current_function_decl = decl; } /* Perform access checks for template parameters. */ cp_parser_perform_template_parameter_access_checks (checks); /* Perform the access control checks for the declarator and the the decl-specifiers. */ perform_deferred_access_checks (); /* Restore the saved value. */ if (TREE_CODE (decl) == FUNCTION_DECL) current_function_decl = saved_current_function_decl; } /* Parse the initializer. */ initializer = NULL_TREE; is_parenthesized_init = false; is_non_constant_init = true; if (is_initialized) { if (function_declarator_p (declarator)) { if (initialization_kind == CPP_EQ) initializer = cp_parser_pure_specifier (parser); else { /* If the declaration was erroneous, we don't really know what the user intended, so just silently consume the initializer. */ if (decl != error_mark_node) error ("initializer provided for function"); cp_parser_skip_to_closing_parenthesis (parser, /*recovering=*/true, /*or_comma=*/false, /*consume_paren=*/true); } } else initializer = cp_parser_initializer (parser, &is_parenthesized_init, &is_non_constant_init); } /* The old parser allows attributes to appear after a parenthesized initializer. Mark Mitchell proposed removing this functionality on the GCC mailing lists on 2002-08-13. This parser accepts the attributes -- but ignores them. */ if (cp_parser_allow_gnu_extensions_p (parser) && is_parenthesized_init) if (cp_parser_attributes_opt (parser)) warning (OPT_Wattributes, "attributes after parenthesized initializer ignored"); /* For an in-class declaration, use `grokfield' to create the declaration. */ if (member_p) { if (pushed_scope) { pop_scope (pushed_scope); pushed_scope = false; } decl = grokfield (declarator, decl_specifiers, initializer, !is_non_constant_init, /*asmspec=*/NULL_TREE, prefix_attributes); if (decl && TREE_CODE (decl) == FUNCTION_DECL) cp_parser_save_default_args (parser, decl); } /* Finish processing the declaration. But, skip friend declarations. */ if (!friend_p && decl && decl != error_mark_node) { cp_finish_decl (decl, initializer, !is_non_constant_init, asm_specification, /* If the initializer is in parentheses, then this is a direct-initialization, which means that an `explicit' constructor is OK. Otherwise, an `explicit' constructor cannot be used. */ ((is_parenthesized_init || !is_initialized) ? 0 : LOOKUP_ONLYCONVERTING)); } if (!friend_p && pushed_scope) pop_scope (pushed_scope); return decl; } /* Parse a declarator. declarator: direct-declarator ptr-operator declarator abstract-declarator: ptr-operator abstract-declarator [opt] direct-abstract-declarator GNU Extensions: declarator: attributes [opt] direct-declarator attributes [opt] ptr-operator declarator abstract-declarator: attributes [opt] ptr-operator abstract-declarator [opt] attributes [opt] direct-abstract-declarator If CTOR_DTOR_OR_CONV_P is not NULL, *CTOR_DTOR_OR_CONV_P is used to detect constructor, destructor or conversion operators. It is set to -1 if the declarator is a name, and +1 if it is a function. Otherwise it is set to zero. Usually you just want to test for >0, but internally the negative value is used. (The reason for CTOR_DTOR_OR_CONV_P is that a declaration must have a decl-specifier-seq unless it declares a constructor, destructor, or conversion. It might seem that we could check this condition in semantic analysis, rather than parsing, but that makes it difficult to handle something like `f()'. We want to notice that there are no decl-specifiers, and therefore realize that this is an expression, not a declaration.) If PARENTHESIZED_P is non-NULL, *PARENTHESIZED_P is set to true iff the declarator is a direct-declarator of the form "(...)". MEMBER_P is true iff this declarator is a member-declarator. */ static cp_declarator * cp_parser_declarator (cp_parser* parser, cp_parser_declarator_kind dcl_kind, int* ctor_dtor_or_conv_p, bool* parenthesized_p, bool member_p) { cp_token *token; cp_declarator *declarator; enum tree_code code; cp_cv_quals cv_quals; tree class_type; tree attributes = NULL_TREE; /* Assume this is not a constructor, destructor, or type-conversion operator. */ if (ctor_dtor_or_conv_p) *ctor_dtor_or_conv_p = 0; if (cp_parser_allow_gnu_extensions_p (parser)) attributes = cp_parser_attributes_opt (parser); /* Peek at the next token. */ token = cp_lexer_peek_token (parser->lexer); /* Check for the ptr-operator production. */ cp_parser_parse_tentatively (parser); /* Parse the ptr-operator. */ code = cp_parser_ptr_operator (parser, &class_type, &cv_quals); /* If that worked, then we have a ptr-operator. */ if (cp_parser_parse_definitely (parser)) { /* If a ptr-operator was found, then this declarator was not parenthesized. */ if (parenthesized_p) *parenthesized_p = true; /* The dependent declarator is optional if we are parsing an abstract-declarator. */ if (dcl_kind != CP_PARSER_DECLARATOR_NAMED) cp_parser_parse_tentatively (parser); /* Parse the dependent declarator. */ declarator = cp_parser_declarator (parser, dcl_kind, /*ctor_dtor_or_conv_p=*/NULL, /*parenthesized_p=*/NULL, /*member_p=*/false); /* If we are parsing an abstract-declarator, we must handle the case where the dependent declarator is absent. */ if (dcl_kind != CP_PARSER_DECLARATOR_NAMED && !cp_parser_parse_definitely (parser)) declarator = NULL; /* Build the representation of the ptr-operator. */ if (class_type) declarator = make_ptrmem_declarator (cv_quals, class_type, declarator); else if (code == INDIRECT_REF) declarator = make_pointer_declarator (cv_quals, declarator); else declarator = make_reference_declarator (cv_quals, declarator); } /* Everything else is a direct-declarator. */ else { if (parenthesized_p) *parenthesized_p = cp_lexer_next_token_is (parser->lexer, CPP_OPEN_PAREN); declarator = cp_parser_direct_declarator (parser, dcl_kind, ctor_dtor_or_conv_p, member_p); } if (attributes && declarator && declarator != cp_error_declarator) declarator->attributes = attributes; return declarator; } /* Parse a direct-declarator or direct-abstract-declarator. direct-declarator: declarator-id direct-declarator ( parameter-declaration-clause ) cv-qualifier-seq [opt] exception-specification [opt] direct-declarator [ constant-expression [opt] ] ( declarator ) direct-abstract-declarator: direct-abstract-declarator [opt] ( parameter-declaration-clause ) cv-qualifier-seq [opt] exception-specification [opt] direct-abstract-declarator [opt] [ constant-expression [opt] ] ( abstract-declarator ) Returns a representation of the declarator. DCL_KIND is CP_PARSER_DECLARATOR_ABSTRACT, if we are parsing a direct-abstract-declarator. It is CP_PARSER_DECLARATOR_NAMED, if we are parsing a direct-declarator. It is CP_PARSER_DECLARATOR_EITHER, if we can accept either - in the case of ambiguity we prefer an abstract declarator, as per [dcl.ambig.res]. CTOR_DTOR_OR_CONV_P and MEMBER_P are as for cp_parser_declarator. */ static cp_declarator * cp_parser_direct_declarator (cp_parser* parser, cp_parser_declarator_kind dcl_kind, int* ctor_dtor_or_conv_p, bool member_p) { cp_token *token; cp_declarator *declarator = NULL; tree scope = NULL_TREE; bool saved_default_arg_ok_p = parser->default_arg_ok_p; bool saved_in_declarator_p = parser->in_declarator_p; bool first = true; tree pushed_scope = NULL_TREE; while (true) { /* Peek at the next token. */ token = cp_lexer_peek_token (parser->lexer); if (token->type == CPP_OPEN_PAREN) { /* This is either a parameter-declaration-clause, or a parenthesized declarator. When we know we are parsing a named declarator, it must be a parenthesized declarator if FIRST is true. For instance, `(int)' is a parameter-declaration-clause, with an omitted direct-abstract-declarator. But `((*))', is a parenthesized abstract declarator. Finally, when T is a template parameter `(T)' is a parameter-declaration-clause, and not a parenthesized named declarator. We first try and parse a parameter-declaration-clause, and then try a nested declarator (if FIRST is true). It is not an error for it not to be a parameter-declaration-clause, even when FIRST is false. Consider, int i (int); int i (3); The first is the declaration of a function while the second is a the definition of a variable, including its initializer. Having seen only the parenthesis, we cannot know which of these two alternatives should be selected. Even more complex are examples like: int i (int (a)); int i (int (3)); The former is a function-declaration; the latter is a variable initialization. Thus again, we try a parameter-declaration-clause, and if that fails, we back out and return. */ if (!first || dcl_kind != CP_PARSER_DECLARATOR_NAMED) { cp_parameter_declarator *params; unsigned saved_num_template_parameter_lists; /* In a member-declarator, the only valid interpretation of a parenthesis is the start of a parameter-declaration-clause. (It is invalid to initialize a static data member with a parenthesized initializer; only the "=" form of initialization is permitted.) */ if (!member_p) cp_parser_parse_tentatively (parser); /* Consume the `('. */ cp_lexer_consume_token (parser->lexer); if (first) { /* If this is going to be an abstract declarator, we're in a declarator and we can't have default args. */ parser->default_arg_ok_p = false; parser->in_declarator_p = true; } /* Inside the function parameter list, surrounding template-parameter-lists do not apply. */ saved_num_template_parameter_lists = parser->num_template_parameter_lists; parser->num_template_parameter_lists = 0; /* Parse the parameter-declaration-clause. */ params = cp_parser_parameter_declaration_clause (parser); parser->num_template_parameter_lists = saved_num_template_parameter_lists; /* If all went well, parse the cv-qualifier-seq and the exception-specification. */ if (member_p || cp_parser_parse_definitely (parser)) { cp_cv_quals cv_quals; tree exception_specification; if (ctor_dtor_or_conv_p) *ctor_dtor_or_conv_p = *ctor_dtor_or_conv_p < 0; first = false; /* Consume the `)'. */ cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'"); /* Parse the cv-qualifier-seq. */ cv_quals = cp_parser_cv_qualifier_seq_opt (parser); /* And the exception-specification. */ exception_specification = cp_parser_exception_specification_opt (parser); /* Create the function-declarator. */ declarator = make_call_declarator (declarator, params, cv_quals, exception_specification); /* Any subsequent parameter lists are to do with return type, so are not those of the declared function. */ parser->default_arg_ok_p = false; /* Repeat the main loop. */ continue; } } /* If this is the first, we can try a parenthesized declarator. */ if (first) { bool saved_in_type_id_in_expr_p; parser->default_arg_ok_p = saved_default_arg_ok_p; parser->in_declarator_p = saved_in_declarator_p; /* Consume the `('. */ cp_lexer_consume_token (parser->lexer); /* Parse the nested declarator. */ saved_in_type_id_in_expr_p = parser->in_type_id_in_expr_p; parser->in_type_id_in_expr_p = true; declarator = cp_parser_declarator (parser, dcl_kind, ctor_dtor_or_conv_p, /*parenthesized_p=*/NULL, member_p); parser->in_type_id_in_expr_p = saved_in_type_id_in_expr_p; first = false; /* Expect a `)'. */ if (!cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'")) declarator = cp_error_declarator; if (declarator == cp_error_declarator) break; goto handle_declarator; } /* Otherwise, we must be done. */ else break; } else if ((!first || dcl_kind != CP_PARSER_DECLARATOR_NAMED) && token->type == CPP_OPEN_SQUARE) { /* Parse an array-declarator. */ tree bounds; if (ctor_dtor_or_conv_p) *ctor_dtor_or_conv_p = 0; first = false; parser->default_arg_ok_p = false; parser->in_declarator_p = true; /* Consume the `['. */ cp_lexer_consume_token (parser->lexer); /* Peek at the next token. */ token = cp_lexer_peek_token (parser->lexer); /* If the next token is `]', then there is no constant-expression. */ if (token->type != CPP_CLOSE_SQUARE) { bool non_constant_p; bounds = cp_parser_constant_expression (parser, /*allow_non_constant=*/true, &non_constant_p); if (!non_constant_p) bounds = fold_non_dependent_expr (bounds); /* Normally, the array bound must be an integral constant expression. However, as an extension, we allow VLAs in function scopes. */ else if (!parser->in_function_body) { error ("array bound is not an integer constant"); bounds = error_mark_node; } } else bounds = NULL_TREE; /* Look for the closing `]'. */ if (!cp_parser_require (parser, CPP_CLOSE_SQUARE, "`]'")) { declarator = cp_error_declarator; break; } declarator = make_array_declarator (declarator, bounds); } else if (first && dcl_kind != CP_PARSER_DECLARATOR_ABSTRACT) { tree qualifying_scope; tree unqualified_name; special_function_kind sfk; bool abstract_ok; /* Parse a declarator-id */ abstract_ok = (dcl_kind == CP_PARSER_DECLARATOR_EITHER); if (abstract_ok) cp_parser_parse_tentatively (parser); unqualified_name = cp_parser_declarator_id (parser, /*optional_p=*/abstract_ok); qualifying_scope = parser->scope; if (abstract_ok) { if (!cp_parser_parse_definitely (parser)) unqualified_name = error_mark_node; else if (unqualified_name && (qualifying_scope || (TREE_CODE (unqualified_name) != IDENTIFIER_NODE))) { cp_parser_error (parser, "expected unqualified-id"); unqualified_name = error_mark_node; } } if (!unqualified_name) return NULL; if (unqualified_name == error_mark_node) { declarator = cp_error_declarator; break; } if (qualifying_scope && at_namespace_scope_p () && TREE_CODE (qualifying_scope) == TYPENAME_TYPE) { /* In the declaration of a member of a template class outside of the class itself, the SCOPE will sometimes be a TYPENAME_TYPE. For example, given: template <typename T> int S<T>::R::i = 3; the SCOPE will be a TYPENAME_TYPE for `S<T>::R'. In this context, we must resolve S<T>::R to an ordinary type, rather than a typename type. The reason we normally avoid resolving TYPENAME_TYPEs is that a specialization of `S' might render `S<T>::R' not a type. However, if `S' is specialized, then this `i' will not be used, so there is no harm in resolving the types here. */ tree type; /* Resolve the TYPENAME_TYPE. */ type = resolve_typename_type (qualifying_scope, /*only_current_p=*/false); /* If that failed, the declarator is invalid. */ if (type == error_mark_node) error ("%<%T::%D%> is not a type", TYPE_CONTEXT (qualifying_scope), TYPE_IDENTIFIER (qualifying_scope)); qualifying_scope = type; } sfk = sfk_none; if (unqualified_name) { tree class_type; if (qualifying_scope && CLASS_TYPE_P (qualifying_scope)) class_type = qualifying_scope; else class_type = current_class_type; if (TREE_CODE (unqualified_name) == TYPE_DECL) { tree name_type = TREE_TYPE (unqualified_name); if (class_type && same_type_p (name_type, class_type)) { if (qualifying_scope && CLASSTYPE_USE_TEMPLATE (name_type)) { error ("invalid use of constructor as a template"); inform ("use %<%T::%D%> instead of %<%T::%D%> to " "name the constructor in a qualified name", class_type, DECL_NAME (TYPE_TI_TEMPLATE (class_type)), class_type, name_type); declarator = cp_error_declarator; break; } else unqualified_name = constructor_name (class_type); } else { /* We do not attempt to print the declarator here because we do not have enough information about its original syntactic form. */ cp_parser_error (parser, "invalid declarator"); declarator = cp_error_declarator; break; } } if (class_type) { if (TREE_CODE (unqualified_name) == BIT_NOT_EXPR) sfk = sfk_destructor; else if (IDENTIFIER_TYPENAME_P (unqualified_name)) sfk = sfk_conversion; else if (/* There's no way to declare a constructor for an anonymous type, even if the type got a name for linkage purposes. */ !TYPE_WAS_ANONYMOUS (class_type) && constructor_name_p (unqualified_name, class_type)) { unqualified_name = constructor_name (class_type); sfk = sfk_constructor; } if (ctor_dtor_or_conv_p && sfk != sfk_none) *ctor_dtor_or_conv_p = -1; } } declarator = make_id_declarator (qualifying_scope, unqualified_name, sfk); declarator->id_loc = token->location; handle_declarator:; scope = get_scope_of_declarator (declarator); if (scope) /* Any names that appear after the declarator-id for a member are looked up in the containing scope. */ pushed_scope = push_scope (scope); parser->in_declarator_p = true; if ((ctor_dtor_or_conv_p && *ctor_dtor_or_conv_p) || (declarator && declarator->kind == cdk_id)) /* Default args are only allowed on function declarations. */ parser->default_arg_ok_p = saved_default_arg_ok_p; else parser->default_arg_ok_p = false; first = false; } /* We're done. */ else break; } /* For an abstract declarator, we might wind up with nothing at this point. That's an error; the declarator is not optional. */ if (!declarator) cp_parser_error (parser, "expected declarator"); /* If we entered a scope, we must exit it now. */ if (pushed_scope) pop_scope (pushed_scope); parser->default_arg_ok_p = saved_default_arg_ok_p; parser->in_declarator_p = saved_in_declarator_p; return declarator; } /* Parse a ptr-operator. ptr-operator: * cv-qualifier-seq [opt] & :: [opt] nested-name-specifier * cv-qualifier-seq [opt] GNU Extension: ptr-operator: & cv-qualifier-seq [opt] Returns INDIRECT_REF if a pointer, or pointer-to-member, was used. Returns ADDR_EXPR if a reference was used. In the case of a pointer-to-member, *TYPE is filled in with the TYPE containing the member. *CV_QUALS is filled in with the cv-qualifier-seq, or TYPE_UNQUALIFIED, if there are no cv-qualifiers. Returns ERROR_MARK if an error occurred. */ static enum tree_code cp_parser_ptr_operator (cp_parser* parser, tree* type, cp_cv_quals *cv_quals) { enum tree_code code = ERROR_MARK; cp_token *token; /* Assume that it's not a pointer-to-member. */ *type = NULL_TREE; /* And that there are no cv-qualifiers. */ *cv_quals = TYPE_UNQUALIFIED; /* Peek at the next token. */ token = cp_lexer_peek_token (parser->lexer); /* If it's a `*' or `&' we have a pointer or reference. */ if (token->type == CPP_MULT || token->type == CPP_AND) { /* Remember which ptr-operator we were processing. */ code = (token->type == CPP_AND ? ADDR_EXPR : INDIRECT_REF); /* Consume the `*' or `&'. */ cp_lexer_consume_token (parser->lexer); /* A `*' can be followed by a cv-qualifier-seq, and so can a `&', if we are allowing GNU extensions. (The only qualifier that can legally appear after `&' is `restrict', but that is enforced during semantic analysis. */ if (code == INDIRECT_REF || cp_parser_allow_gnu_extensions_p (parser)) *cv_quals = cp_parser_cv_qualifier_seq_opt (parser); } else { /* Try the pointer-to-member case. */ cp_parser_parse_tentatively (parser); /* Look for the optional `::' operator. */ cp_parser_global_scope_opt (parser, /*current_scope_valid_p=*/false); /* Look for the nested-name specifier. */ cp_parser_nested_name_specifier (parser, /*typename_keyword_p=*/false, /*check_dependency_p=*/true, /*type_p=*/false, /*is_declaration=*/false); /* If we found it, and the next token is a `*', then we are indeed looking at a pointer-to-member operator. */ if (!cp_parser_error_occurred (parser) && cp_parser_require (parser, CPP_MULT, "`*'")) { /* Indicate that the `*' operator was used. */ code = INDIRECT_REF; if (TREE_CODE (parser->scope) == NAMESPACE_DECL) error ("%qD is a namespace", parser->scope); else { /* The type of which the member is a member is given by the current SCOPE. */ *type = parser->scope; /* The next name will not be qualified. */ parser->scope = NULL_TREE; parser->qualifying_scope = NULL_TREE; parser->object_scope = NULL_TREE; /* Look for the optional cv-qualifier-seq. */ *cv_quals = cp_parser_cv_qualifier_seq_opt (parser); } } /* If that didn't work we don't have a ptr-operator. */ if (!cp_parser_parse_definitely (parser)) cp_parser_error (parser, "expected ptr-operator"); } return code; } /* Parse an (optional) cv-qualifier-seq. cv-qualifier-seq: cv-qualifier cv-qualifier-seq [opt] cv-qualifier: const volatile GNU Extension: cv-qualifier: __restrict__ Returns a bitmask representing the cv-qualifiers. */ static cp_cv_quals cp_parser_cv_qualifier_seq_opt (cp_parser* parser) { cp_cv_quals cv_quals = TYPE_UNQUALIFIED; while (true) { cp_token *token; cp_cv_quals cv_qualifier; /* Peek at the next token. */ token = cp_lexer_peek_token (parser->lexer); /* See if it's a cv-qualifier. */ switch (token->keyword) { case RID_CONST: cv_qualifier = TYPE_QUAL_CONST; break; case RID_VOLATILE: cv_qualifier = TYPE_QUAL_VOLATILE; break; case RID_RESTRICT: cv_qualifier = TYPE_QUAL_RESTRICT; break; default: cv_qualifier = TYPE_UNQUALIFIED; break; } if (!cv_qualifier) break; if (cv_quals & cv_qualifier) { error ("duplicate cv-qualifier"); cp_lexer_purge_token (parser->lexer); } else { cp_lexer_consume_token (parser->lexer); cv_quals |= cv_qualifier; } } return cv_quals; } /* Parse a declarator-id. declarator-id: id-expression :: [opt] nested-name-specifier [opt] type-name In the `id-expression' case, the value returned is as for cp_parser_id_expression if the id-expression was an unqualified-id. If the id-expression was a qualified-id, then a SCOPE_REF is returned. The first operand is the scope (either a NAMESPACE_DECL or TREE_TYPE), but the second is still just a representation of an unqualified-id. */ static tree cp_parser_declarator_id (cp_parser* parser, bool optional_p) { tree id; /* The expression must be an id-expression. Assume that qualified names are the names of types so that: template <class T> int S<T>::R::i = 3; will work; we must treat `S<T>::R' as the name of a type. Similarly, assume that qualified names are templates, where required, so that: template <class T> int S<T>::R<T>::i = 3; will work, too. */ id = cp_parser_id_expression (parser, /*template_keyword_p=*/false, /*check_dependency_p=*/false, /*template_p=*/NULL, /*declarator_p=*/true, optional_p); if (id && BASELINK_P (id)) id = BASELINK_FUNCTIONS (id); return id; } /* Parse a type-id. type-id: type-specifier-seq abstract-declarator [opt] Returns the TYPE specified. */ static tree cp_parser_type_id (cp_parser* parser) { cp_decl_specifier_seq type_specifier_seq; cp_declarator *abstract_declarator; /* Parse the type-specifier-seq. */ cp_parser_type_specifier_seq (parser, /*is_condition=*/false, &type_specifier_seq); if (type_specifier_seq.type == error_mark_node) return error_mark_node; /* There might or might not be an abstract declarator. */ cp_parser_parse_tentatively (parser); /* Look for the declarator. */ abstract_declarator = cp_parser_declarator (parser, CP_PARSER_DECLARATOR_ABSTRACT, NULL, /*parenthesized_p=*/NULL, /*member_p=*/false); /* Check to see if there really was a declarator. */ if (!cp_parser_parse_definitely (parser)) abstract_declarator = NULL; return groktypename (&type_specifier_seq, abstract_declarator); } /* Parse a type-specifier-seq. type-specifier-seq: type-specifier type-specifier-seq [opt] GNU extension: type-specifier-seq: attributes type-specifier-seq [opt] If IS_CONDITION is true, we are at the start of a "condition", e.g., we've just seen "if (". Sets *TYPE_SPECIFIER_SEQ to represent the sequence. */ static void cp_parser_type_specifier_seq (cp_parser* parser, bool is_condition, cp_decl_specifier_seq *type_specifier_seq) { bool seen_type_specifier = false; cp_parser_flags flags = CP_PARSER_FLAGS_OPTIONAL; /* Clear the TYPE_SPECIFIER_SEQ. */ clear_decl_specs (type_specifier_seq); /* Parse the type-specifiers and attributes. */ while (true) { tree type_specifier; bool is_cv_qualifier; /* Check for attributes first. */ if (cp_lexer_next_token_is_keyword (parser->lexer, RID_ATTRIBUTE)) { type_specifier_seq->attributes = chainon (type_specifier_seq->attributes, cp_parser_attributes_opt (parser)); continue; } /* Look for the type-specifier. */ type_specifier = cp_parser_type_specifier (parser, flags, type_specifier_seq, /*is_declaration=*/false, NULL, &is_cv_qualifier); if (!type_specifier) { /* If the first type-specifier could not be found, this is not a type-specifier-seq at all. */ if (!seen_type_specifier) { cp_parser_error (parser, "expected type-specifier"); type_specifier_seq->type = error_mark_node; return; } /* If subsequent type-specifiers could not be found, the type-specifier-seq is complete. */ break; } seen_type_specifier = true; /* The standard says that a condition can be: type-specifier-seq declarator = assignment-expression However, given: struct S {}; if (int S = ...) we should treat the "S" as a declarator, not as a type-specifier. The standard doesn't say that explicitly for type-specifier-seq, but it does say that for decl-specifier-seq in an ordinary declaration. Perhaps it would be clearer just to allow a decl-specifier-seq here, and then add a semantic restriction that if any decl-specifiers that are not type-specifiers appear, the program is invalid. */ if (is_condition && !is_cv_qualifier) flags |= CP_PARSER_FLAGS_NO_USER_DEFINED_TYPES; } cp_parser_check_decl_spec (type_specifier_seq); } /* Parse a parameter-declaration-clause. parameter-declaration-clause: parameter-declaration-list [opt] ... [opt] parameter-declaration-list , ... Returns a representation for the parameter declarations. A return value of NULL indicates a parameter-declaration-clause consisting only of an ellipsis. */ static cp_parameter_declarator * cp_parser_parameter_declaration_clause (cp_parser* parser) { cp_parameter_declarator *parameters; cp_token *token; bool ellipsis_p; bool is_error; /* Peek at the next token. */ token = cp_lexer_peek_token (parser->lexer); /* Check for trivial parameter-declaration-clauses. */ if (token->type == CPP_ELLIPSIS) { /* Consume the `...' token. */ cp_lexer_consume_token (parser->lexer); return NULL; } else if (token->type == CPP_CLOSE_PAREN) /* There are no parameters. */ { #ifndef NO_IMPLICIT_EXTERN_C if (in_system_header && current_class_type == NULL && current_lang_name == lang_name_c) return NULL; else #endif return no_parameters; } /* Check for `(void)', too, which is a special case. */ else if (token->keyword == RID_VOID && (cp_lexer_peek_nth_token (parser->lexer, 2)->type == CPP_CLOSE_PAREN)) { /* Consume the `void' token. */ cp_lexer_consume_token (parser->lexer); /* There are no parameters. */ return no_parameters; } /* Parse the parameter-declaration-list. */ parameters = cp_parser_parameter_declaration_list (parser, &is_error); /* If a parse error occurred while parsing the parameter-declaration-list, then the entire parameter-declaration-clause is erroneous. */ if (is_error) return NULL; /* Peek at the next token. */ token = cp_lexer_peek_token (parser->lexer); /* If it's a `,', the clause should terminate with an ellipsis. */ if (token->type == CPP_COMMA) { /* Consume the `,'. */ cp_lexer_consume_token (parser->lexer); /* Expect an ellipsis. */ ellipsis_p = (cp_parser_require (parser, CPP_ELLIPSIS, "`...'") != NULL); } /* It might also be `...' if the optional trailing `,' was omitted. */ else if (token->type == CPP_ELLIPSIS) { /* Consume the `...' token. */ cp_lexer_consume_token (parser->lexer); /* And remember that we saw it. */ ellipsis_p = true; } else ellipsis_p = false; /* Finish the parameter list. */ if (parameters && ellipsis_p) parameters->ellipsis_p = true; return parameters; } /* Parse a parameter-declaration-list. parameter-declaration-list: parameter-declaration parameter-declaration-list , parameter-declaration Returns a representation of the parameter-declaration-list, as for cp_parser_parameter_declaration_clause. However, the `void_list_node' is never appended to the list. Upon return, *IS_ERROR will be true iff an error occurred. */ static cp_parameter_declarator * cp_parser_parameter_declaration_list (cp_parser* parser, bool *is_error) { cp_parameter_declarator *parameters = NULL; cp_parameter_declarator **tail = &parameters; bool saved_in_unbraced_linkage_specification_p; /* Assume all will go well. */ *is_error = false; /* The special considerations that apply to a function within an unbraced linkage specifications do not apply to the parameters to the function. */ saved_in_unbraced_linkage_specification_p = parser->in_unbraced_linkage_specification_p; parser->in_unbraced_linkage_specification_p = false; /* Look for more parameters. */ while (true) { cp_parameter_declarator *parameter; bool parenthesized_p; /* Parse the parameter. */ parameter = cp_parser_parameter_declaration (parser, /*template_parm_p=*/false, &parenthesized_p); /* If a parse error occurred parsing the parameter declaration, then the entire parameter-declaration-list is erroneous. */ if (!parameter) { *is_error = true; parameters = NULL; break; } /* Add the new parameter to the list. */ *tail = parameter; tail = &parameter->next; /* Peek at the next token. */ if (cp_lexer_next_token_is (parser->lexer, CPP_CLOSE_PAREN) || cp_lexer_next_token_is (parser->lexer, CPP_ELLIPSIS) /* These are for Objective-C++ */ || cp_lexer_next_token_is (parser->lexer, CPP_SEMICOLON) || cp_lexer_next_token_is (parser->lexer, CPP_OPEN_BRACE)) /* The parameter-declaration-list is complete. */ break; else if (cp_lexer_next_token_is (parser->lexer, CPP_COMMA)) { cp_token *token; /* Peek at the next token. */ token = cp_lexer_peek_nth_token (parser->lexer, 2); /* If it's an ellipsis, then the list is complete. */ if (token->type == CPP_ELLIPSIS) break; /* Otherwise, there must be more parameters. Consume the `,'. */ cp_lexer_consume_token (parser->lexer); /* When parsing something like: int i(float f, double d) we can tell after seeing the declaration for "f" that we are not looking at an initialization of a variable "i", but rather at the declaration of a function "i". Due to the fact that the parsing of template arguments (as specified to a template-id) requires backtracking we cannot use this technique when inside a template argument list. */ if (!parser->in_template_argument_list_p && !parser->in_type_id_in_expr_p && cp_parser_uncommitted_to_tentative_parse_p (parser) /* However, a parameter-declaration of the form "foat(f)" (which is a valid declaration of a parameter "f") can also be interpreted as an expression (the conversion of "f" to "float"). */ && !parenthesized_p) cp_parser_commit_to_tentative_parse (parser); } else { cp_parser_error (parser, "expected %<,%> or %<...%>"); if (!cp_parser_uncommitted_to_tentative_parse_p (parser)) cp_parser_skip_to_closing_parenthesis (parser, /*recovering=*/true, /*or_comma=*/false, /*consume_paren=*/false); break; } } parser->in_unbraced_linkage_specification_p = saved_in_unbraced_linkage_specification_p; return parameters; } /* Parse a parameter declaration. parameter-declaration: decl-specifier-seq declarator decl-specifier-seq declarator = assignment-expression decl-specifier-seq abstract-declarator [opt] decl-specifier-seq abstract-declarator [opt] = assignment-expression If TEMPLATE_PARM_P is TRUE, then this parameter-declaration declares a template parameter. (In that case, a non-nested `>' token encountered during the parsing of the assignment-expression is not interpreted as a greater-than operator.) Returns a representation of the parameter, or NULL if an error occurs. If PARENTHESIZED_P is non-NULL, *PARENTHESIZED_P is set to true iff the declarator is of the form "(p)". */ static cp_parameter_declarator * cp_parser_parameter_declaration (cp_parser *parser, bool template_parm_p, bool *parenthesized_p) { int declares_class_or_enum; bool greater_than_is_operator_p; cp_decl_specifier_seq decl_specifiers; cp_declarator *declarator; tree default_argument; cp_token *token; const char *saved_message; /* In a template parameter, `>' is not an operator. [temp.param] When parsing a default template-argument for a non-type template-parameter, the first non-nested `>' is taken as the end of the template parameter-list rather than a greater-than operator. */ greater_than_is_operator_p = !template_parm_p; /* Type definitions may not appear in parameter types. */ saved_message = parser->type_definition_forbidden_message; parser->type_definition_forbidden_message = "types may not be defined in parameter types"; /* Parse the declaration-specifiers. */ cp_parser_decl_specifier_seq (parser, CP_PARSER_FLAGS_NONE, &decl_specifiers, &declares_class_or_enum); /* If an error occurred, there's no reason to attempt to parse the rest of the declaration. */ if (cp_parser_error_occurred (parser)) { parser->type_definition_forbidden_message = saved_message; return NULL; } /* Peek at the next token. */ token = cp_lexer_peek_token (parser->lexer); /* If the next token is a `)', `,', `=', `>', or `...', then there is no declarator. */ if (token->type == CPP_CLOSE_PAREN || token->type == CPP_COMMA || token->type == CPP_EQ || token->type == CPP_ELLIPSIS || token->type == CPP_GREATER) { declarator = NULL; if (parenthesized_p) *parenthesized_p = false; } /* Otherwise, there should be a declarator. */ else { bool saved_default_arg_ok_p = parser->default_arg_ok_p; parser->default_arg_ok_p = false; /* After seeing a decl-specifier-seq, if the next token is not a "(", there is no possibility that the code is a valid expression. Therefore, if parsing tentatively, we commit at this point. */ if (!parser->in_template_argument_list_p /* In an expression context, having seen: (int((char ... we cannot be sure whether we are looking at a function-type (taking a "char" as a parameter) or a cast of some object of type "char" to "int". */ && !parser->in_type_id_in_expr_p && cp_parser_uncommitted_to_tentative_parse_p (parser) && cp_lexer_next_token_is_not (parser->lexer, CPP_OPEN_PAREN)) cp_parser_commit_to_tentative_parse (parser); /* Parse the declarator. */ declarator = cp_parser_declarator (parser, CP_PARSER_DECLARATOR_EITHER, /*ctor_dtor_or_conv_p=*/NULL, parenthesized_p, /*member_p=*/false); parser->default_arg_ok_p = saved_default_arg_ok_p; /* After the declarator, allow more attributes. */ decl_specifiers.attributes = chainon (decl_specifiers.attributes, cp_parser_attributes_opt (parser)); } /* The restriction on defining new types applies only to the type of the parameter, not to the default argument. */ parser->type_definition_forbidden_message = saved_message; /* If the next token is `=', then process a default argument. */ if (cp_lexer_next_token_is (parser->lexer, CPP_EQ)) { bool saved_greater_than_is_operator_p; /* Consume the `='. */ cp_lexer_consume_token (parser->lexer); /* If we are defining a class, then the tokens that make up the default argument must be saved and processed later. */ if (!template_parm_p && at_class_scope_p () && TYPE_BEING_DEFINED (current_class_type)) { unsigned depth = 0; cp_token *first_token; cp_token *token; /* Add tokens until we have processed the entire default argument. We add the range [first_token, token). */ first_token = cp_lexer_peek_token (parser->lexer); while (true) { bool done = false; /* Peek at the next token. */ token = cp_lexer_peek_token (parser->lexer); /* What we do depends on what token we have. */ switch (token->type) { /* In valid code, a default argument must be immediately followed by a `,' `)', or `...'. */ case CPP_COMMA: case CPP_CLOSE_PAREN: case CPP_ELLIPSIS: /* If we run into a non-nested `;', `}', or `]', then the code is invalid -- but the default argument is certainly over. */ case CPP_SEMICOLON: case CPP_CLOSE_BRACE: case CPP_CLOSE_SQUARE: if (depth == 0) done = true; /* Update DEPTH, if necessary. */ else if (token->type == CPP_CLOSE_PAREN || token->type == CPP_CLOSE_BRACE || token->type == CPP_CLOSE_SQUARE) --depth; break; case CPP_OPEN_PAREN: case CPP_OPEN_SQUARE: case CPP_OPEN_BRACE: ++depth; break; case CPP_GREATER: /* If we see a non-nested `>', and `>' is not an operator, then it marks the end of the default argument. */ if (!depth && !greater_than_is_operator_p) done = true; break; /* If we run out of tokens, issue an error message. */ case CPP_EOF: case CPP_PRAGMA_EOL: error ("file ends in default argument"); done = true; break; case CPP_NAME: case CPP_SCOPE: /* In these cases, we should look for template-ids. For example, if the default argument is `X<int, double>()', we need to do name lookup to figure out whether or not `X' is a template; if so, the `,' does not end the default argument. That is not yet done. */ break; default: break; } /* If we've reached the end, stop. */ if (done) break; /* Add the token to the token block. */ token = cp_lexer_consume_token (parser->lexer); } /* Create a DEFAULT_ARG to represented the unparsed default argument. */ default_argument = make_node (DEFAULT_ARG); DEFARG_TOKENS (default_argument) = cp_token_cache_new (first_token, token); DEFARG_INSTANTIATIONS (default_argument) = NULL; } /* Outside of a class definition, we can just parse the assignment-expression. */ else { bool saved_local_variables_forbidden_p; /* Make sure that PARSER->GREATER_THAN_IS_OPERATOR_P is set correctly. */ saved_greater_than_is_operator_p = parser->greater_than_is_operator_p; parser->greater_than_is_operator_p = greater_than_is_operator_p; /* Local variable names (and the `this' keyword) may not appear in a default argument. */ saved_local_variables_forbidden_p = parser->local_variables_forbidden_p; parser->local_variables_forbidden_p = true; /* The default argument expression may cause implicitly defined member functions to be synthesized, which will result in garbage collection. We must treat this situation as if we were within the body of function so as to avoid collecting live data on the stack. */ ++function_depth; /* Parse the assignment-expression. */ if (template_parm_p) push_deferring_access_checks (dk_no_deferred); default_argument = cp_parser_assignment_expression (parser, /*cast_p=*/false); if (template_parm_p) pop_deferring_access_checks (); /* Restore saved state. */ --function_depth; parser->greater_than_is_operator_p = saved_greater_than_is_operator_p; parser->local_variables_forbidden_p = saved_local_variables_forbidden_p; } if (!parser->default_arg_ok_p) { if (!flag_pedantic_errors) warning (0, "deprecated use of default argument for parameter of non-function"); else { error ("default arguments are only permitted for function parameters"); default_argument = NULL_TREE; } } } else default_argument = NULL_TREE; return make_parameter_declarator (&decl_specifiers, declarator, default_argument); } /* Parse a function-body. function-body: compound_statement */ static void cp_parser_function_body (cp_parser *parser) { cp_parser_compound_statement (parser, NULL, false); } /* Parse a ctor-initializer-opt followed by a function-body. Return true if a ctor-initializer was present. */ static bool cp_parser_ctor_initializer_opt_and_function_body (cp_parser *parser) { tree body; bool ctor_initializer_p; /* Begin the function body. */ body = begin_function_body (); /* Parse the optional ctor-initializer. */ ctor_initializer_p = cp_parser_ctor_initializer_opt (parser); /* Parse the function-body. */ cp_parser_function_body (parser); /* Finish the function body. */ finish_function_body (body); return ctor_initializer_p; } /* Parse an initializer. initializer: = initializer-clause ( expression-list ) Returns an expression representing the initializer. If no initializer is present, NULL_TREE is returned. *IS_PARENTHESIZED_INIT is set to TRUE if the `( expression-list )' production is used, and zero otherwise. *IS_PARENTHESIZED_INIT is set to FALSE if there is no initializer present. If there is an initializer, and it is not a constant-expression, *NON_CONSTANT_P is set to true; otherwise it is set to false. */ static tree cp_parser_initializer (cp_parser* parser, bool* is_parenthesized_init, bool* non_constant_p) { cp_token *token; tree init; /* Peek at the next token. */ token = cp_lexer_peek_token (parser->lexer); /* Let our caller know whether or not this initializer was parenthesized. */ *is_parenthesized_init = (token->type == CPP_OPEN_PAREN); /* Assume that the initializer is constant. */ *non_constant_p = false; if (token->type == CPP_EQ) { /* Consume the `='. */ cp_lexer_consume_token (parser->lexer); /* Parse the initializer-clause. */ init = cp_parser_initializer_clause (parser, non_constant_p); } else if (token->type == CPP_OPEN_PAREN) init = cp_parser_parenthesized_expression_list (parser, false, /*cast_p=*/false, non_constant_p); else { /* Anything else is an error. */ cp_parser_error (parser, "expected initializer"); init = error_mark_node; } return init; } /* Parse an initializer-clause. initializer-clause: assignment-expression { initializer-list , [opt] } { } Returns an expression representing the initializer. If the `assignment-expression' production is used the value returned is simply a representation for the expression. Otherwise, a CONSTRUCTOR is returned. The CONSTRUCTOR_ELTS will be the elements of the initializer-list (or NULL, if the last production is used). The TREE_TYPE for the CONSTRUCTOR will be NULL_TREE. There is no way to detect whether or not the optional trailing `,' was provided. NON_CONSTANT_P is as for cp_parser_initializer. */ static tree cp_parser_initializer_clause (cp_parser* parser, bool* non_constant_p) { tree initializer; /* Assume the expression is constant. */ *non_constant_p = false; /* If it is not a `{', then we are looking at an assignment-expression. */ if (cp_lexer_next_token_is_not (parser->lexer, CPP_OPEN_BRACE)) { initializer = cp_parser_constant_expression (parser, /*allow_non_constant_p=*/true, non_constant_p); if (!*non_constant_p) initializer = fold_non_dependent_expr (initializer); } else { /* Consume the `{' token. */ cp_lexer_consume_token (parser->lexer); /* Create a CONSTRUCTOR to represent the braced-initializer. */ initializer = make_node (CONSTRUCTOR); /* If it's not a `}', then there is a non-trivial initializer. */ if (cp_lexer_next_token_is_not (parser->lexer, CPP_CLOSE_BRACE)) { /* Parse the initializer list. */ CONSTRUCTOR_ELTS (initializer) = cp_parser_initializer_list (parser, non_constant_p); /* A trailing `,' token is allowed. */ if (cp_lexer_next_token_is (parser->lexer, CPP_COMMA)) cp_lexer_consume_token (parser->lexer); } /* Now, there should be a trailing `}'. */ cp_parser_require (parser, CPP_CLOSE_BRACE, "`}'"); } return initializer; } /* Parse an initializer-list. initializer-list: initializer-clause initializer-list , initializer-clause GNU Extension: initializer-list: identifier : initializer-clause initializer-list, identifier : initializer-clause Returns a VEC of constructor_elt. The VALUE of each elt is an expression for the initializer. If the INDEX of the elt is non-NULL, it is the IDENTIFIER_NODE naming the field to initialize. NON_CONSTANT_P is as for cp_parser_initializer. */ static VEC(constructor_elt,gc) * cp_parser_initializer_list (cp_parser* parser, bool* non_constant_p) { VEC(constructor_elt,gc) *v = NULL; /* Assume all of the expressions are constant. */ *non_constant_p = false; /* Parse the rest of the list. */ while (true) { cp_token *token; tree identifier; tree initializer; bool clause_non_constant_p; /* If the next token is an identifier and the following one is a colon, we are looking at the GNU designated-initializer syntax. */ if (cp_parser_allow_gnu_extensions_p (parser) && cp_lexer_next_token_is (parser->lexer, CPP_NAME) && cp_lexer_peek_nth_token (parser->lexer, 2)->type == CPP_COLON) { /* Warn the user that they are using an extension. */ if (pedantic) pedwarn ("ISO C++ does not allow designated initializers"); /* Consume the identifier. */ identifier = cp_lexer_consume_token (parser->lexer)->u.value; /* Consume the `:'. */ cp_lexer_consume_token (parser->lexer); } else identifier = NULL_TREE; /* Parse the initializer. */ initializer = cp_parser_initializer_clause (parser, &clause_non_constant_p); /* If any clause is non-constant, so is the entire initializer. */ if (clause_non_constant_p) *non_constant_p = true; /* Add it to the vector. */ CONSTRUCTOR_APPEND_ELT(v, identifier, initializer); /* If the next token is not a comma, we have reached the end of the list. */ if (cp_lexer_next_token_is_not (parser->lexer, CPP_COMMA)) break; /* Peek at the next token. */ token = cp_lexer_peek_nth_token (parser->lexer, 2); /* If the next token is a `}', then we're still done. An initializer-clause can have a trailing `,' after the initializer-list and before the closing `}'. */ if (token->type == CPP_CLOSE_BRACE) break; /* Consume the `,' token. */ cp_lexer_consume_token (parser->lexer); } return v; } /* Classes [gram.class] */ /* Parse a class-name. class-name: identifier template-id TYPENAME_KEYWORD_P is true iff the `typename' keyword has been used to indicate that names looked up in dependent types should be assumed to be types. TEMPLATE_KEYWORD_P is true iff the `template' keyword has been used to indicate that the name that appears next is a template. TAG_TYPE indicates the explicit tag given before the type name, if any. If CHECK_DEPENDENCY_P is FALSE, names are looked up in dependent scopes. If CLASS_HEAD_P is TRUE, this class is the class being defined in a class-head. Returns the TYPE_DECL representing the class. */ static tree cp_parser_class_name (cp_parser *parser, bool typename_keyword_p, bool template_keyword_p, enum tag_types tag_type, bool check_dependency_p, bool class_head_p, bool is_declaration) { tree decl; tree scope; bool typename_p; cp_token *token; /* All class-names start with an identifier. */ token = cp_lexer_peek_token (parser->lexer); if (token->type != CPP_NAME && token->type != CPP_TEMPLATE_ID) { cp_parser_error (parser, "expected class-name"); return error_mark_node; } /* PARSER->SCOPE can be cleared when parsing the template-arguments to a template-id, so we save it here. */ scope = parser->scope; if (scope == error_mark_node) return error_mark_node; /* Any name names a type if we're following the `typename' keyword in a qualified name where the enclosing scope is type-dependent. */ typename_p = (typename_keyword_p && scope && TYPE_P (scope) && dependent_type_p (scope)); /* Handle the common case (an identifier, but not a template-id) efficiently. */ if (token->type == CPP_NAME && !cp_parser_nth_token_starts_template_argument_list_p (parser, 2)) { cp_token *identifier_token; tree identifier; bool ambiguous_p; /* Look for the identifier. */ identifier_token = cp_lexer_peek_token (parser->lexer); ambiguous_p = identifier_token->ambiguous_p; identifier = cp_parser_identifier (parser); /* If the next token isn't an identifier, we are certainly not looking at a class-name. */ if (identifier == error_mark_node) decl = error_mark_node; /* If we know this is a type-name, there's no need to look it up. */ else if (typename_p) decl = identifier; else { tree ambiguous_decls; /* If we already know that this lookup is ambiguous, then we've already issued an error message; there's no reason to check again. */ if (ambiguous_p) { cp_parser_simulate_error (parser); return error_mark_node; } /* If the next token is a `::', then the name must be a type name. [basic.lookup.qual] During the lookup for a name preceding the :: scope resolution operator, object, function, and enumerator names are ignored. */ if (cp_lexer_next_token_is (parser->lexer, CPP_SCOPE)) tag_type = typename_type; /* Look up the name. */ decl = cp_parser_lookup_name (parser, identifier, tag_type, /*is_template=*/false, /*is_namespace=*/false, check_dependency_p, &ambiguous_decls); if (ambiguous_decls) { error ("reference to %qD is ambiguous", identifier); print_candidates (ambiguous_decls); if (cp_parser_parsing_tentatively (parser)) { identifier_token->ambiguous_p = true; cp_parser_simulate_error (parser); } return error_mark_node; } } } else { /* Try a template-id. */ decl = cp_parser_template_id (parser, template_keyword_p, check_dependency_p, is_declaration); if (decl == error_mark_node) return error_mark_node; } decl = cp_parser_maybe_treat_template_as_class (decl, class_head_p); /* If this is a typename, create a TYPENAME_TYPE. */ if (typename_p && decl != error_mark_node) { decl = make_typename_type (scope, decl, typename_type, /*complain=*/tf_error); if (decl != error_mark_node) decl = TYPE_NAME (decl); } /* Check to see that it is really the name of a class. */ if (TREE_CODE (decl) == TEMPLATE_ID_EXPR && TREE_CODE (TREE_OPERAND (decl, 0)) == IDENTIFIER_NODE && cp_lexer_next_token_is (parser->lexer, CPP_SCOPE)) /* Situations like this: template <typename T> struct A { typename T::template X<int>::I i; }; are problematic. Is `T::template X<int>' a class-name? The standard does not seem to be definitive, but there is no other valid interpretation of the following `::'. Therefore, those names are considered class-names. */ { decl = make_typename_type (scope, decl, tag_type, tf_error); if (decl != error_mark_node) decl = TYPE_NAME (decl); } else if (TREE_CODE (decl) != TYPE_DECL || TREE_TYPE (decl) == error_mark_node || !IS_AGGR_TYPE (TREE_TYPE (decl))) decl = error_mark_node; if (decl == error_mark_node) cp_parser_error (parser, "expected class-name"); return decl; } /* Parse a class-specifier. class-specifier: class-head { member-specification [opt] } Returns the TREE_TYPE representing the class. */ static tree cp_parser_class_specifier (cp_parser* parser) { cp_token *token; tree type; tree attributes = NULL_TREE; int has_trailing_semicolon; bool nested_name_specifier_p; unsigned saved_num_template_parameter_lists; bool saved_in_function_body; tree old_scope = NULL_TREE; tree scope = NULL_TREE; tree bases; push_deferring_access_checks (dk_no_deferred); /* Parse the class-head. */ type = cp_parser_class_head (parser, &nested_name_specifier_p, &attributes, &bases); /* If the class-head was a semantic disaster, skip the entire body of the class. */ if (!type) { cp_parser_skip_to_end_of_block_or_statement (parser); pop_deferring_access_checks (); return error_mark_node; } /* Look for the `{'. */ if (!cp_parser_require (parser, CPP_OPEN_BRACE, "`{'")) { pop_deferring_access_checks (); return error_mark_node; } /* Process the base classes. If they're invalid, skip the entire class body. */ if (!xref_basetypes (type, bases)) { cp_parser_skip_to_closing_brace (parser); /* Consuming the closing brace yields better error messages later on. */ cp_lexer_consume_token (parser->lexer); pop_deferring_access_checks (); return error_mark_node; } /* Issue an error message if type-definitions are forbidden here. */ cp_parser_check_type_definition (parser); /* Remember that we are defining one more class. */ ++parser->num_classes_being_defined; /* Inside the class, surrounding template-parameter-lists do not apply. */ saved_num_template_parameter_lists = parser->num_template_parameter_lists; parser->num_template_parameter_lists = 0; /* We are not in a function body. */ saved_in_function_body = parser->in_function_body; parser->in_function_body = false; /* Start the class. */ if (nested_name_specifier_p) { scope = CP_DECL_CONTEXT (TYPE_MAIN_DECL (type)); old_scope = push_inner_scope (scope); } type = begin_class_definition (type, attributes); if (type == error_mark_node) /* If the type is erroneous, skip the entire body of the class. */ cp_parser_skip_to_closing_brace (parser); else /* Parse the member-specification. */ cp_parser_member_specification_opt (parser); /* Look for the trailing `}'. */ cp_parser_require (parser, CPP_CLOSE_BRACE, "`}'"); /* We get better error messages by noticing a common problem: a missing trailing `;'. */ token = cp_lexer_peek_token (parser->lexer); has_trailing_semicolon = (token->type == CPP_SEMICOLON); /* Look for trailing attributes to apply to this class. */ if (cp_parser_allow_gnu_extensions_p (parser)) attributes = cp_parser_attributes_opt (parser); if (type != error_mark_node) type = finish_struct (type, attributes); if (nested_name_specifier_p) pop_inner_scope (old_scope, scope); /* If this class is not itself within the scope of another class, then we need to parse the bodies of all of the queued function definitions. Note that the queued functions defined in a class are not always processed immediately following the class-specifier for that class. Consider: struct A { struct B { void f() { sizeof (A); } }; }; If `f' were processed before the processing of `A' were completed, there would be no way to compute the size of `A'. Note that the nesting we are interested in here is lexical -- not the semantic nesting given by TYPE_CONTEXT. In particular, for: struct A { struct B; }; struct A::B { void f() { } }; there is no need to delay the parsing of `A::B::f'. */ if (--parser->num_classes_being_defined == 0) { tree queue_entry; tree fn; tree class_type = NULL_TREE; tree pushed_scope = NULL_TREE; /* In a first pass, parse default arguments to the functions. Then, in a second pass, parse the bodies of the functions. This two-phased approach handles cases like: struct S { void f() { g(); } void g(int i = 3); }; */ for (TREE_PURPOSE (parser->unparsed_functions_queues) = nreverse (TREE_PURPOSE (parser->unparsed_functions_queues)); (queue_entry = TREE_PURPOSE (parser->unparsed_functions_queues)); TREE_PURPOSE (parser->unparsed_functions_queues) = TREE_CHAIN (TREE_PURPOSE (parser->unparsed_functions_queues))) { fn = TREE_VALUE (queue_entry); /* If there are default arguments that have not yet been processed, take care of them now. */ if (class_type != TREE_PURPOSE (queue_entry)) { if (pushed_scope) pop_scope (pushed_scope); class_type = TREE_PURPOSE (queue_entry); pushed_scope = push_scope (class_type); } /* Make sure that any template parameters are in scope. */ maybe_begin_member_template_processing (fn); /* Parse the default argument expressions. */ cp_parser_late_parsing_default_args (parser, fn); /* Remove any template parameters from the symbol table. */ maybe_end_member_template_processing (); } if (pushed_scope) pop_scope (pushed_scope); /* Now parse the body of the functions. */ for (TREE_VALUE (parser->unparsed_functions_queues) = nreverse (TREE_VALUE (parser->unparsed_functions_queues)); (queue_entry = TREE_VALUE (parser->unparsed_functions_queues)); TREE_VALUE (parser->unparsed_functions_queues) = TREE_CHAIN (TREE_VALUE (parser->unparsed_functions_queues))) { /* Figure out which function we need to process. */ fn = TREE_VALUE (queue_entry); /* Parse the function. */ cp_parser_late_parsing_for_member (parser, fn); } } /* Put back any saved access checks. */ pop_deferring_access_checks (); /* Restore saved state. */ parser->in_function_body = saved_in_function_body; parser->num_template_parameter_lists = saved_num_template_parameter_lists; return type; } /* Parse a class-head. class-head: class-key identifier [opt] base-clause [opt] class-key nested-name-specifier identifier base-clause [opt] class-key nested-name-specifier [opt] template-id base-clause [opt] GNU Extensions: class-key attributes identifier [opt] base-clause [opt] class-key attributes nested-name-specifier identifier base-clause [opt] class-key attributes nested-name-specifier [opt] template-id base-clause [opt] Returns the TYPE of the indicated class. Sets *NESTED_NAME_SPECIFIER_P to TRUE iff one of the productions involving a nested-name-specifier was used, and FALSE otherwise. Returns error_mark_node if this is not a class-head. Returns NULL_TREE if the class-head is syntactically valid, but semantically invalid in a way that means we should skip the entire body of the class. */ static tree cp_parser_class_head (cp_parser* parser, bool* nested_name_specifier_p, tree *attributes_p, tree *bases) { tree nested_name_specifier; enum tag_types class_key; tree id = NULL_TREE; tree type = NULL_TREE; tree attributes; bool template_id_p = false; bool qualified_p = false; bool invalid_nested_name_p = false; bool invalid_explicit_specialization_p = false; tree pushed_scope = NULL_TREE; unsigned num_templates; /* Assume no nested-name-specifier will be present. */ *nested_name_specifier_p = false; /* Assume no template parameter lists will be used in defining the type. */ num_templates = 0; /* Look for the class-key. */ class_key = cp_parser_class_key (parser); if (class_key == none_type) return error_mark_node; /* Parse the attributes. */ attributes = cp_parser_attributes_opt (parser); /* If the next token is `::', that is invalid -- but sometimes people do try to write: struct ::S {}; Handle this gracefully by accepting the extra qualifier, and then issuing an error about it later if this really is a class-head. If it turns out just to be an elaborated type specifier, remain silent. */ if (cp_parser_global_scope_opt (parser, /*current_scope_valid_p=*/false)) qualified_p = true; push_deferring_access_checks (dk_no_check); /* Determine the name of the class. Begin by looking for an optional nested-name-specifier. */ nested_name_specifier = cp_parser_nested_name_specifier_opt (parser, /*typename_keyword_p=*/false, /*check_dependency_p=*/false, /*type_p=*/false, /*is_declaration=*/false); /* If there was a nested-name-specifier, then there *must* be an identifier. */ if (nested_name_specifier) { /* Although the grammar says `identifier', it really means `class-name' or `template-name'. You are only allowed to define a class that has already been declared with this syntax. The proposed resolution for Core Issue 180 says that wherever you see `class T::X' you should treat `X' as a type-name. It is OK to define an inaccessible class; for example: class A { class B; }; class A::B {}; We do not know if we will see a class-name, or a template-name. We look for a class-name first, in case the class-name is a template-id; if we looked for the template-name first we would stop after the template-name. */ cp_parser_parse_tentatively (parser); type = cp_parser_class_name (parser, /*typename_keyword_p=*/false, /*template_keyword_p=*/false, class_type, /*check_dependency_p=*/false, /*class_head_p=*/true, /*is_declaration=*/false); /* If that didn't work, ignore the nested-name-specifier. */ if (!cp_parser_parse_definitely (parser)) { invalid_nested_name_p = true; id = cp_parser_identifier (parser); if (id == error_mark_node) id = NULL_TREE; } /* If we could not find a corresponding TYPE, treat this declaration like an unqualified declaration. */ if (type == error_mark_node) nested_name_specifier = NULL_TREE; /* Otherwise, count the number of templates used in TYPE and its containing scopes. */ else { tree scope; for (scope = TREE_TYPE (type); scope && TREE_CODE (scope) != NAMESPACE_DECL; scope = (TYPE_P (scope) ? TYPE_CONTEXT (scope) : DECL_CONTEXT (scope))) if (TYPE_P (scope) && CLASS_TYPE_P (scope) && CLASSTYPE_TEMPLATE_INFO (scope) && PRIMARY_TEMPLATE_P (CLASSTYPE_TI_TEMPLATE (scope)) && !CLASSTYPE_TEMPLATE_SPECIALIZATION (scope)) ++num_templates; } } /* Otherwise, the identifier is optional. */ else { /* We don't know whether what comes next is a template-id, an identifier, or nothing at all. */ cp_parser_parse_tentatively (parser); /* Check for a template-id. */ id = cp_parser_template_id (parser, /*template_keyword_p=*/false, /*check_dependency_p=*/true, /*is_declaration=*/true); /* If that didn't work, it could still be an identifier. */ if (!cp_parser_parse_definitely (parser)) { if (cp_lexer_next_token_is (parser->lexer, CPP_NAME)) id = cp_parser_identifier (parser); else id = NULL_TREE; } else { template_id_p = true; ++num_templates; } } pop_deferring_access_checks (); if (id) cp_parser_check_for_invalid_template_id (parser, id); /* If it's not a `:' or a `{' then we can't really be looking at a class-head, since a class-head only appears as part of a class-specifier. We have to detect this situation before calling xref_tag, since that has irreversible side-effects. */ if (!cp_parser_next_token_starts_class_definition_p (parser)) { cp_parser_error (parser, "expected %<{%> or %<:%>"); return error_mark_node; } /* At this point, we're going ahead with the class-specifier, even if some other problem occurs. */ cp_parser_commit_to_tentative_parse (parser); /* Issue the error about the overly-qualified name now. */ if (qualified_p) cp_parser_error (parser, "global qualification of class name is invalid"); else if (invalid_nested_name_p) cp_parser_error (parser, "qualified name does not name a class"); else if (nested_name_specifier) { tree scope; /* Reject typedef-names in class heads. */ if (!DECL_IMPLICIT_TYPEDEF_P (type)) { error ("invalid class name in declaration of %qD", type); type = NULL_TREE; goto done; } /* Figure out in what scope the declaration is being placed. */ scope = current_scope (); /* If that scope does not contain the scope in which the class was originally declared, the program is invalid. */ if (scope && !is_ancestor (scope, nested_name_specifier)) { error ("declaration of %qD in %qD which does not enclose %qD", type, scope, nested_name_specifier); type = NULL_TREE; goto done; } /* [dcl.meaning] A declarator-id shall not be qualified exception of the definition of a ... nested class outside of its class ... [or] a the definition or explicit instantiation of a class member of a namespace outside of its namespace. */ if (scope == nested_name_specifier) { pedwarn ("extra qualification ignored"); nested_name_specifier = NULL_TREE; num_templates = 0; } } /* An explicit-specialization must be preceded by "template <>". If it is not, try to recover gracefully. */ if (at_namespace_scope_p () && parser->num_template_parameter_lists == 0 && template_id_p) { error ("an explicit specialization must be preceded by %<template <>%>"); invalid_explicit_specialization_p = true; /* Take the same action that would have been taken by cp_parser_explicit_specialization. */ ++parser->num_template_parameter_lists; begin_specialization (); } /* There must be no "return" statements between this point and the end of this function; set "type "to the correct return value and use "goto done;" to return. */ /* Make sure that the right number of template parameters were present. */ if (!cp_parser_check_template_parameters (parser, num_templates)) { /* If something went wrong, there is no point in even trying to process the class-definition. */ type = NULL_TREE; goto done; } /* Look up the type. */ if (template_id_p) { type = TREE_TYPE (id); type = maybe_process_partial_specialization (type); if (nested_name_specifier) pushed_scope = push_scope (nested_name_specifier); } else if (nested_name_specifier) { tree class_type; /* Given: template <typename T> struct S { struct T }; template <typename T> struct S<T>::T { }; we will get a TYPENAME_TYPE when processing the definition of `S::T'. We need to resolve it to the actual type before we try to define it. */ if (TREE_CODE (TREE_TYPE (type)) == TYPENAME_TYPE) { class_type = resolve_typename_type (TREE_TYPE (type), /*only_current_p=*/false); if (class_type != error_mark_node) type = TYPE_NAME (class_type); else { cp_parser_error (parser, "could not resolve typename type"); type = error_mark_node; } } maybe_process_partial_specialization (TREE_TYPE (type)); class_type = current_class_type; /* Enter the scope indicated by the nested-name-specifier. */ pushed_scope = push_scope (nested_name_specifier); /* Get the canonical version of this type. */ type = TYPE_MAIN_DECL (TREE_TYPE (type)); if (PROCESSING_REAL_TEMPLATE_DECL_P () && !CLASSTYPE_TEMPLATE_SPECIALIZATION (TREE_TYPE (type))) { type = push_template_decl (type); if (type == error_mark_node) { type = NULL_TREE; goto done; } } type = TREE_TYPE (type); *nested_name_specifier_p = true; } else /* The name is not a nested name. */ { /* If the class was unnamed, create a dummy name. */ if (!id) id = make_anon_name (); type = xref_tag (class_key, id, /*tag_scope=*/ts_current, parser->num_template_parameter_lists); } /* Indicate whether this class was declared as a `class' or as a `struct'. */ if (TREE_CODE (type) == RECORD_TYPE) CLASSTYPE_DECLARED_CLASS (type) = (class_key == class_type); cp_parser_check_class_key (class_key, type); /* If this type was already complete, and we see another definition, that's an error. */ if (type != error_mark_node && COMPLETE_TYPE_P (type)) { error ("redefinition of %q#T", type); error ("previous definition of %q+#T", type); type = NULL_TREE; goto done; } else if (type == error_mark_node) type = NULL_TREE; /* We will have entered the scope containing the class; the names of base classes should be looked up in that context. For example: struct A { struct B {}; struct C; }; struct A::C : B {}; is valid. */ *bases = NULL_TREE; /* Get the list of base-classes, if there is one. */ if (cp_lexer_next_token_is (parser->lexer, CPP_COLON)) *bases = cp_parser_base_clause (parser); done: /* Leave the scope given by the nested-name-specifier. We will enter the class scope itself while processing the members. */ if (pushed_scope) pop_scope (pushed_scope); if (invalid_explicit_specialization_p) { end_specialization (); --parser->num_template_parameter_lists; } *attributes_p = attributes; return type; } /* Parse a class-key. class-key: class struct union Returns the kind of class-key specified, or none_type to indicate error. */ static enum tag_types cp_parser_class_key (cp_parser* parser) { cp_token *token; enum tag_types tag_type; /* Look for the class-key. */ token = cp_parser_require (parser, CPP_KEYWORD, "class-key"); if (!token) return none_type; /* Check to see if the TOKEN is a class-key. */ tag_type = cp_parser_token_is_class_key (token); if (!tag_type) cp_parser_error (parser, "expected class-key"); return tag_type; } /* Parse an (optional) member-specification. member-specification: member-declaration member-specification [opt] access-specifier : member-specification [opt] */ static void cp_parser_member_specification_opt (cp_parser* parser) { while (true) { cp_token *token; enum rid keyword; /* Peek at the next token. */ token = cp_lexer_peek_token (parser->lexer); /* If it's a `}', or EOF then we've seen all the members. */ if (token->type == CPP_CLOSE_BRACE || token->type == CPP_EOF || token->type == CPP_PRAGMA_EOL) break; /* See if this token is a keyword. */ keyword = token->keyword; switch (keyword) { case RID_PUBLIC: case RID_PROTECTED: case RID_PRIVATE: /* Consume the access-specifier. */ cp_lexer_consume_token (parser->lexer); /* Remember which access-specifier is active. */ current_access_specifier = token->u.value; /* Look for the `:'. */ cp_parser_require (parser, CPP_COLON, "`:'"); break; default: /* Accept #pragmas at class scope. */ if (token->type == CPP_PRAGMA) { cp_parser_pragma (parser, pragma_external); break; } /* Otherwise, the next construction must be a member-declaration. */ cp_parser_member_declaration (parser); } } } /* Parse a member-declaration. member-declaration: decl-specifier-seq [opt] member-declarator-list [opt] ; function-definition ; [opt] :: [opt] nested-name-specifier template [opt] unqualified-id ; using-declaration template-declaration member-declarator-list: member-declarator member-declarator-list , member-declarator member-declarator: declarator pure-specifier [opt] declarator constant-initializer [opt] identifier [opt] : constant-expression GNU Extensions: member-declaration: __extension__ member-declaration member-declarator: declarator attributes [opt] pure-specifier [opt] declarator attributes [opt] constant-initializer [opt] identifier [opt] attributes [opt] : constant-expression */ static void cp_parser_member_declaration (cp_parser* parser) { cp_decl_specifier_seq decl_specifiers; tree prefix_attributes; tree decl; int declares_class_or_enum; bool friend_p; cp_token *token; int saved_pedantic; /* Check for the `__extension__' keyword. */ if (cp_parser_extension_opt (parser, &saved_pedantic)) { /* Recurse. */ cp_parser_member_declaration (parser); /* Restore the old value of the PEDANTIC flag. */ pedantic = saved_pedantic; return; } /* Check for a template-declaration. */ if (cp_lexer_next_token_is_keyword (parser->lexer, RID_TEMPLATE)) { /* An explicit specialization here is an error condition, and we expect the specialization handler to detect and report this. */ if (cp_lexer_peek_nth_token (parser->lexer, 2)->type == CPP_LESS && cp_lexer_peek_nth_token (parser->lexer, 3)->type == CPP_GREATER) cp_parser_explicit_specialization (parser); else cp_parser_template_declaration (parser, /*member_p=*/true); return; } /* Check for a using-declaration. */ if (cp_lexer_next_token_is_keyword (parser->lexer, RID_USING)) { /* Parse the using-declaration. */ cp_parser_using_declaration (parser, /*access_declaration_p=*/false); return; } /* Check for @defs. */ if (cp_lexer_next_token_is_keyword (parser->lexer, RID_AT_DEFS)) { tree ivar, member; tree ivar_chains = cp_parser_objc_defs_expression (parser); ivar = ivar_chains; while (ivar) { member = ivar; ivar = TREE_CHAIN (member); TREE_CHAIN (member) = NULL_TREE; finish_member_declaration (member); } return; } if (cp_parser_using_declaration (parser, /*access_declaration=*/true)) return; /* Parse the decl-specifier-seq. */ cp_parser_decl_specifier_seq (parser, CP_PARSER_FLAGS_OPTIONAL, &decl_specifiers, &declares_class_or_enum); prefix_attributes = decl_specifiers.attributes; decl_specifiers.attributes = NULL_TREE; /* Check for an invalid type-name. */ if (!decl_specifiers.type && cp_parser_parse_and_diagnose_invalid_type_name (parser)) return; /* If there is no declarator, then the decl-specifier-seq should specify a type. */ if (cp_lexer_next_token_is (parser->lexer, CPP_SEMICOLON)) { /* If there was no decl-specifier-seq, and the next token is a `;', then we have something like: struct S { ; }; [class.mem] Each member-declaration shall declare at least one member name of the class. */ if (!decl_specifiers.any_specifiers_p) { cp_token *token = cp_lexer_peek_token (parser->lexer); if (pedantic && !token->in_system_header) pedwarn ("%Hextra %<;%>", &token->location); } else { tree type; /* See if this declaration is a friend. */ friend_p = cp_parser_friend_p (&decl_specifiers); /* If there were decl-specifiers, check to see if there was a class-declaration. */ type = check_tag_decl (&decl_specifiers); /* Nested classes have already been added to the class, but a `friend' needs to be explicitly registered. */ if (friend_p) { /* If the `friend' keyword was present, the friend must be introduced with a class-key. */ if (!declares_class_or_enum) error ("a class-key must be used when declaring a friend"); /* In this case: template <typename T> struct A { friend struct A<T>::B; }; A<T>::B will be represented by a TYPENAME_TYPE, and therefore not recognized by check_tag_decl. */ if (!type && decl_specifiers.type && TYPE_P (decl_specifiers.type)) type = decl_specifiers.type; if (!type || !TYPE_P (type)) error ("friend declaration does not name a class or " "function"); else make_friend_class (current_class_type, type, /*complain=*/true); } /* If there is no TYPE, an error message will already have been issued. */ else if (!type || type == error_mark_node) ; /* An anonymous aggregate has to be handled specially; such a declaration really declares a data member (with a particular type), as opposed to a nested class. */ else if (ANON_AGGR_TYPE_P (type)) { /* Remove constructors and such from TYPE, now that we know it is an anonymous aggregate. */ fixup_anonymous_aggr (type); /* And make the corresponding data member. */ decl = build_decl (FIELD_DECL, NULL_TREE, type); /* Add it to the class. */ finish_member_declaration (decl); } else cp_parser_check_access_in_redeclaration (TYPE_NAME (type)); } } else { /* See if these declarations will be friends. */ friend_p = cp_parser_friend_p (&decl_specifiers); /* Keep going until we hit the `;' at the end of the declaration. */ while (cp_lexer_next_token_is_not (parser->lexer, CPP_SEMICOLON)) { tree attributes = NULL_TREE; tree first_attribute; /* Peek at the next token. */ token = cp_lexer_peek_token (parser->lexer); /* Check for a bitfield declaration. */ if (token->type == CPP_COLON || (token->type == CPP_NAME && cp_lexer_peek_nth_token (parser->lexer, 2)->type == CPP_COLON)) { tree identifier; tree width; /* Get the name of the bitfield. Note that we cannot just check TOKEN here because it may have been invalidated by the call to cp_lexer_peek_nth_token above. */ if (cp_lexer_peek_token (parser->lexer)->type != CPP_COLON) identifier = cp_parser_identifier (parser); else identifier = NULL_TREE; /* Consume the `:' token. */ cp_lexer_consume_token (parser->lexer); /* Get the width of the bitfield. */ width = cp_parser_constant_expression (parser, /*allow_non_constant=*/false, NULL); /* Look for attributes that apply to the bitfield. */ attributes = cp_parser_attributes_opt (parser); /* Remember which attributes are prefix attributes and which are not. */ first_attribute = attributes; /* Combine the attributes. */ attributes = chainon (prefix_attributes, attributes); /* Create the bitfield declaration. */ decl = grokbitfield (identifier ? make_id_declarator (NULL_TREE, identifier, sfk_none) : NULL, &decl_specifiers, width); /* Apply the attributes. */ cplus_decl_attributes (&decl, attributes, /*flags=*/0); } else { cp_declarator *declarator; tree initializer; tree asm_specification; int ctor_dtor_or_conv_p; /* Parse the declarator. */ declarator = cp_parser_declarator (parser, CP_PARSER_DECLARATOR_NAMED, &ctor_dtor_or_conv_p, /*parenthesized_p=*/NULL, /*member_p=*/true); /* If something went wrong parsing the declarator, make sure that we at least consume some tokens. */ if (declarator == cp_error_declarator) { /* Skip to the end of the statement. */ cp_parser_skip_to_end_of_statement (parser); /* If the next token is not a semicolon, that is probably because we just skipped over the body of a function. So, we consume a semicolon if present, but do not issue an error message if it is not present. */ if (cp_lexer_next_token_is (parser->lexer, CPP_SEMICOLON)) cp_lexer_consume_token (parser->lexer); return; } if (declares_class_or_enum & 2) cp_parser_check_for_definition_in_return_type (declarator, decl_specifiers.type); /* Look for an asm-specification. */ asm_specification = cp_parser_asm_specification_opt (parser); /* Look for attributes that apply to the declaration. */ attributes = cp_parser_attributes_opt (parser); /* Remember which attributes are prefix attributes and which are not. */ first_attribute = attributes; /* Combine the attributes. */ attributes = chainon (prefix_attributes, attributes); /* If it's an `=', then we have a constant-initializer or a pure-specifier. It is not correct to parse the initializer before registering the member declaration since the member declaration should be in scope while its initializer is processed. However, the rest of the front end does not yet provide an interface that allows us to handle this correctly. */ if (cp_lexer_next_token_is (parser->lexer, CPP_EQ)) { /* In [class.mem]: A pure-specifier shall be used only in the declaration of a virtual function. A member-declarator can contain a constant-initializer only if it declares a static member of integral or enumeration type. Therefore, if the DECLARATOR is for a function, we look for a pure-specifier; otherwise, we look for a constant-initializer. When we call `grokfield', it will perform more stringent semantics checks. */ if (function_declarator_p (declarator)) initializer = cp_parser_pure_specifier (parser); else /* Parse the initializer. */ initializer = cp_parser_constant_initializer (parser); } /* Otherwise, there is no initializer. */ else initializer = NULL_TREE; /* See if we are probably looking at a function definition. We are certainly not looking at a member-declarator. Calling `grokfield' has side-effects, so we must not do it unless we are sure that we are looking at a member-declarator. */ if (cp_parser_token_starts_function_definition_p (cp_lexer_peek_token (parser->lexer))) { /* The grammar does not allow a pure-specifier to be used when a member function is defined. (It is possible that this fact is an oversight in the standard, since a pure function may be defined outside of the class-specifier. */ if (initializer) error ("pure-specifier on function-definition"); decl = cp_parser_save_member_function_body (parser, &decl_specifiers, declarator, attributes); /* If the member was not a friend, declare it here. */ if (!friend_p) finish_member_declaration (decl); /* Peek at the next token. */ token = cp_lexer_peek_token (parser->lexer); /* If the next token is a semicolon, consume it. */ if (token->type == CPP_SEMICOLON) cp_lexer_consume_token (parser->lexer); return; } else /* Create the declaration. */ decl = grokfield (declarator, &decl_specifiers, initializer, /*init_const_expr_p=*/true, asm_specification, attributes); } /* Reset PREFIX_ATTRIBUTES. */ while (attributes && TREE_CHAIN (attributes) != first_attribute) attributes = TREE_CHAIN (attributes); if (attributes) TREE_CHAIN (attributes) = NULL_TREE; /* If there is any qualification still in effect, clear it now; we will be starting fresh with the next declarator. */ parser->scope = NULL_TREE; parser->qualifying_scope = NULL_TREE; parser->object_scope = NULL_TREE; /* If it's a `,', then there are more declarators. */ if (cp_lexer_next_token_is (parser->lexer, CPP_COMMA)) cp_lexer_consume_token (parser->lexer); /* If the next token isn't a `;', then we have a parse error. */ else if (cp_lexer_next_token_is_not (parser->lexer, CPP_SEMICOLON)) { cp_parser_error (parser, "expected %<;%>"); /* Skip tokens until we find a `;'. */ cp_parser_skip_to_end_of_statement (parser); break; } if (decl) { /* Add DECL to the list of members. */ if (!friend_p) finish_member_declaration (decl); if (TREE_CODE (decl) == FUNCTION_DECL) cp_parser_save_default_args (parser, decl); } } } cp_parser_require (parser, CPP_SEMICOLON, "`;'"); } /* Parse a pure-specifier. pure-specifier: = 0 Returns INTEGER_ZERO_NODE if a pure specifier is found. Otherwise, ERROR_MARK_NODE is returned. */ static tree cp_parser_pure_specifier (cp_parser* parser) { cp_token *token; /* Look for the `=' token. */ if (!cp_parser_require (parser, CPP_EQ, "`='")) return error_mark_node; /* Look for the `0' token. */ token = cp_lexer_consume_token (parser->lexer); /* c_lex_with_flags marks a single digit '0' with PURE_ZERO. */ if (token->type != CPP_NUMBER || !(token->flags & PURE_ZERO)) { cp_parser_error (parser, "invalid pure specifier (only `= 0' is allowed)"); cp_parser_skip_to_end_of_statement (parser); return error_mark_node; } if (PROCESSING_REAL_TEMPLATE_DECL_P ()) { error ("templates may not be %<virtual%>"); return error_mark_node; } return integer_zero_node; } /* Parse a constant-initializer. constant-initializer: = constant-expression Returns a representation of the constant-expression. */ static tree cp_parser_constant_initializer (cp_parser* parser) { /* Look for the `=' token. */ if (!cp_parser_require (parser, CPP_EQ, "`='")) return error_mark_node; /* It is invalid to write: struct S { static const int i = { 7 }; }; */ if (cp_lexer_next_token_is (parser->lexer, CPP_OPEN_BRACE)) { cp_parser_error (parser, "a brace-enclosed initializer is not allowed here"); /* Consume the opening brace. */ cp_lexer_consume_token (parser->lexer); /* Skip the initializer. */ cp_parser_skip_to_closing_brace (parser); /* Look for the trailing `}'. */ cp_parser_require (parser, CPP_CLOSE_BRACE, "`}'"); return error_mark_node; } return cp_parser_constant_expression (parser, /*allow_non_constant=*/false, NULL); } /* Derived classes [gram.class.derived] */ /* Parse a base-clause. base-clause: : base-specifier-list base-specifier-list: base-specifier base-specifier-list , base-specifier Returns a TREE_LIST representing the base-classes, in the order in which they were declared. The representation of each node is as described by cp_parser_base_specifier. In the case that no bases are specified, this function will return NULL_TREE, not ERROR_MARK_NODE. */ static tree cp_parser_base_clause (cp_parser* parser) { tree bases = NULL_TREE; /* Look for the `:' that begins the list. */ cp_parser_require (parser, CPP_COLON, "`:'"); /* Scan the base-specifier-list. */ while (true) { cp_token *token; tree base; /* Look for the base-specifier. */ base = cp_parser_base_specifier (parser); /* Add BASE to the front of the list. */ if (base != error_mark_node) { TREE_CHAIN (base) = bases; bases = base; } /* Peek at the next token. */ token = cp_lexer_peek_token (parser->lexer); /* If it's not a comma, then the list is complete. */ if (token->type != CPP_COMMA) break; /* Consume the `,'. */ cp_lexer_consume_token (parser->lexer); } /* PARSER->SCOPE may still be non-NULL at this point, if the last base class had a qualified name. However, the next name that appears is certainly not qualified. */ parser->scope = NULL_TREE; parser->qualifying_scope = NULL_TREE; parser->object_scope = NULL_TREE; return nreverse (bases); } /* Parse a base-specifier. base-specifier: :: [opt] nested-name-specifier [opt] class-name virtual access-specifier [opt] :: [opt] nested-name-specifier [opt] class-name access-specifier virtual [opt] :: [opt] nested-name-specifier [opt] class-name Returns a TREE_LIST. The TREE_PURPOSE will be one of ACCESS_{DEFAULT,PUBLIC,PROTECTED,PRIVATE}_[VIRTUAL]_NODE to indicate the specifiers provided. The TREE_VALUE will be a TYPE (or the ERROR_MARK_NODE) indicating the type that was specified. */ static tree cp_parser_base_specifier (cp_parser* parser) { cp_token *token; bool done = false; bool virtual_p = false; bool duplicate_virtual_error_issued_p = false; bool duplicate_access_error_issued_p = false; bool class_scope_p, template_p; tree access = access_default_node; tree type; /* Process the optional `virtual' and `access-specifier'. */ while (!done) { /* Peek at the next token. */ token = cp_lexer_peek_token (parser->lexer); /* Process `virtual'. */ switch (token->keyword) { case RID_VIRTUAL: /* If `virtual' appears more than once, issue an error. */ if (virtual_p && !duplicate_virtual_error_issued_p) { cp_parser_error (parser, "%<virtual%> specified more than once in base-specified"); duplicate_virtual_error_issued_p = true; } virtual_p = true; /* Consume the `virtual' token. */ cp_lexer_consume_token (parser->lexer); break; case RID_PUBLIC: case RID_PROTECTED: case RID_PRIVATE: /* If more than one access specifier appears, issue an error. */ if (access != access_default_node && !duplicate_access_error_issued_p) { cp_parser_error (parser, "more than one access specifier in base-specified"); duplicate_access_error_issued_p = true; } access = ridpointers[(int) token->keyword]; /* Consume the access-specifier. */ cp_lexer_consume_token (parser->lexer); break; default: done = true; break; } } /* It is not uncommon to see programs mechanically, erroneously, use the 'typename' keyword to denote (dependent) qualified types as base classes. */ if (cp_lexer_next_token_is_keyword (parser->lexer, RID_TYPENAME)) { if (!processing_template_decl) error ("keyword %<typename%> not allowed outside of templates"); else error ("keyword %<typename%> not allowed in this context " "(the base class is implicitly a type)"); cp_lexer_consume_token (parser->lexer); } /* Look for the optional `::' operator. */ cp_parser_global_scope_opt (parser, /*current_scope_valid_p=*/false); /* Look for the nested-name-specifier. The simplest way to implement: [temp.res] The keyword `typename' is not permitted in a base-specifier or mem-initializer; in these contexts a qualified name that depends on a template-parameter is implicitly assumed to be a type name. is to pretend that we have seen the `typename' keyword at this point. */ cp_parser_nested_name_specifier_opt (parser, /*typename_keyword_p=*/true, /*check_dependency_p=*/true, typename_type, /*is_declaration=*/true); /* If the base class is given by a qualified name, assume that names we see are type names or templates, as appropriate. */ class_scope_p = (parser->scope && TYPE_P (parser->scope)); template_p = class_scope_p && cp_parser_optional_template_keyword (parser); /* Finally, look for the class-name. */ type = cp_parser_class_name (parser, class_scope_p, template_p, typename_type, /*check_dependency_p=*/true, /*class_head_p=*/false, /*is_declaration=*/true); if (type == error_mark_node) return error_mark_node; return finish_base_specifier (TREE_TYPE (type), access, virtual_p); } /* Exception handling [gram.exception] */ /* Parse an (optional) exception-specification. exception-specification: throw ( type-id-list [opt] ) Returns a TREE_LIST representing the exception-specification. The TREE_VALUE of each node is a type. */ static tree cp_parser_exception_specification_opt (cp_parser* parser) { cp_token *token; tree type_id_list; /* Peek at the next token. */ token = cp_lexer_peek_token (parser->lexer); /* If it's not `throw', then there's no exception-specification. */ if (!cp_parser_is_keyword (token, RID_THROW)) return NULL_TREE; /* Consume the `throw'. */ cp_lexer_consume_token (parser->lexer); /* Look for the `('. */ cp_parser_require (parser, CPP_OPEN_PAREN, "`('"); /* Peek at the next token. */ token = cp_lexer_peek_token (parser->lexer); /* If it's not a `)', then there is a type-id-list. */ if (token->type != CPP_CLOSE_PAREN) { const char *saved_message; /* Types may not be defined in an exception-specification. */ saved_message = parser->type_definition_forbidden_message; parser->type_definition_forbidden_message = "types may not be defined in an exception-specification"; /* Parse the type-id-list. */ type_id_list = cp_parser_type_id_list (parser); /* Restore the saved message. */ parser->type_definition_forbidden_message = saved_message; } else type_id_list = empty_except_spec; /* Look for the `)'. */ cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'"); return type_id_list; } /* Parse an (optional) type-id-list. type-id-list: type-id type-id-list , type-id Returns a TREE_LIST. The TREE_VALUE of each node is a TYPE, in the order that the types were presented. */ static tree cp_parser_type_id_list (cp_parser* parser) { tree types = NULL_TREE; while (true) { cp_token *token; tree type; /* Get the next type-id. */ type = cp_parser_type_id (parser); /* Add it to the list. */ types = add_exception_specifier (types, type, /*complain=*/1); /* Peek at the next token. */ token = cp_lexer_peek_token (parser->lexer); /* If it is not a `,', we are done. */ if (token->type != CPP_COMMA) break; /* Consume the `,'. */ cp_lexer_consume_token (parser->lexer); } return nreverse (types); } /* Parse a try-block. try-block: try compound-statement handler-seq */ static tree cp_parser_try_block (cp_parser* parser) { tree try_block; cp_parser_require_keyword (parser, RID_TRY, "`try'"); try_block = begin_try_block (); cp_parser_compound_statement (parser, NULL, true); finish_try_block (try_block); cp_parser_handler_seq (parser); finish_handler_sequence (try_block); return try_block; } /* Parse a function-try-block. function-try-block: try ctor-initializer [opt] function-body handler-seq */ static bool cp_parser_function_try_block (cp_parser* parser) { tree compound_stmt; tree try_block; bool ctor_initializer_p; /* Look for the `try' keyword. */ if (!cp_parser_require_keyword (parser, RID_TRY, "`try'")) return false; /* Let the rest of the front-end know where we are. */ try_block = begin_function_try_block (&compound_stmt); /* Parse the function-body. */ ctor_initializer_p = cp_parser_ctor_initializer_opt_and_function_body (parser); /* We're done with the `try' part. */ finish_function_try_block (try_block); /* Parse the handlers. */ cp_parser_handler_seq (parser); /* We're done with the handlers. */ finish_function_handler_sequence (try_block, compound_stmt); return ctor_initializer_p; } /* Parse a handler-seq. handler-seq: handler handler-seq [opt] */ static void cp_parser_handler_seq (cp_parser* parser) { while (true) { cp_token *token; /* Parse the handler. */ cp_parser_handler (parser); /* Peek at the next token. */ token = cp_lexer_peek_token (parser->lexer); /* If it's not `catch' then there are no more handlers. */ if (!cp_parser_is_keyword (token, RID_CATCH)) break; } } /* Parse a handler. handler: catch ( exception-declaration ) compound-statement */ static void cp_parser_handler (cp_parser* parser) { tree handler; tree declaration; cp_parser_require_keyword (parser, RID_CATCH, "`catch'"); handler = begin_handler (); cp_parser_require (parser, CPP_OPEN_PAREN, "`('"); declaration = cp_parser_exception_declaration (parser); finish_handler_parms (declaration, handler); cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'"); cp_parser_compound_statement (parser, NULL, false); finish_handler (handler); } /* Parse an exception-declaration. exception-declaration: type-specifier-seq declarator type-specifier-seq abstract-declarator type-specifier-seq ... Returns a VAR_DECL for the declaration, or NULL_TREE if the ellipsis variant is used. */ static tree cp_parser_exception_declaration (cp_parser* parser) { cp_decl_specifier_seq type_specifiers; cp_declarator *declarator; const char *saved_message; /* If it's an ellipsis, it's easy to handle. */ if (cp_lexer_next_token_is (parser->lexer, CPP_ELLIPSIS)) { /* Consume the `...' token. */ cp_lexer_consume_token (parser->lexer); return NULL_TREE; } /* Types may not be defined in exception-declarations. */ saved_message = parser->type_definition_forbidden_message; parser->type_definition_forbidden_message = "types may not be defined in exception-declarations"; /* Parse the type-specifier-seq. */ cp_parser_type_specifier_seq (parser, /*is_condition=*/false, &type_specifiers); /* If it's a `)', then there is no declarator. */ if (cp_lexer_next_token_is (parser->lexer, CPP_CLOSE_PAREN)) declarator = NULL; else declarator = cp_parser_declarator (parser, CP_PARSER_DECLARATOR_EITHER, /*ctor_dtor_or_conv_p=*/NULL, /*parenthesized_p=*/NULL, /*member_p=*/false); /* Restore the saved message. */ parser->type_definition_forbidden_message = saved_message; if (!type_specifiers.any_specifiers_p) return error_mark_node; return grokdeclarator (declarator, &type_specifiers, CATCHPARM, 1, NULL); } /* Parse a throw-expression. throw-expression: throw assignment-expression [opt] Returns a THROW_EXPR representing the throw-expression. */ static tree cp_parser_throw_expression (cp_parser* parser) { tree expression; cp_token* token; cp_parser_require_keyword (parser, RID_THROW, "`throw'"); token = cp_lexer_peek_token (parser->lexer); /* Figure out whether or not there is an assignment-expression following the "throw" keyword. */ if (token->type == CPP_COMMA || token->type == CPP_SEMICOLON || token->type == CPP_CLOSE_PAREN || token->type == CPP_CLOSE_SQUARE || token->type == CPP_CLOSE_BRACE || token->type == CPP_COLON) expression = NULL_TREE; else expression = cp_parser_assignment_expression (parser, /*cast_p=*/false); return build_throw (expression); } /* GNU Extensions */ /* Parse an (optional) asm-specification. asm-specification: asm ( string-literal ) If the asm-specification is present, returns a STRING_CST corresponding to the string-literal. Otherwise, returns NULL_TREE. */ static tree cp_parser_asm_specification_opt (cp_parser* parser) { cp_token *token; tree asm_specification; /* Peek at the next token. */ token = cp_lexer_peek_token (parser->lexer); /* If the next token isn't the `asm' keyword, then there's no asm-specification. */ if (!cp_parser_is_keyword (token, RID_ASM)) return NULL_TREE; /* Consume the `asm' token. */ cp_lexer_consume_token (parser->lexer); /* Look for the `('. */ cp_parser_require (parser, CPP_OPEN_PAREN, "`('"); /* Look for the string-literal. */ asm_specification = cp_parser_string_literal (parser, false, false); /* Look for the `)'. */ cp_parser_require (parser, CPP_CLOSE_PAREN, "`('"); return asm_specification; } /* Parse an asm-operand-list. asm-operand-list: asm-operand asm-operand-list , asm-operand asm-operand: string-literal ( expression ) [ string-literal ] string-literal ( expression ) Returns a TREE_LIST representing the operands. The TREE_VALUE of each node is the expression. The TREE_PURPOSE is itself a TREE_LIST whose TREE_PURPOSE is a STRING_CST for the bracketed string-literal (or NULL_TREE if not present) and whose TREE_VALUE is a STRING_CST for the string literal before the parenthesis. */ static tree cp_parser_asm_operand_list (cp_parser* parser) { tree asm_operands = NULL_TREE; while (true) { tree string_literal; tree expression; tree name; if (cp_lexer_next_token_is (parser->lexer, CPP_OPEN_SQUARE)) { /* Consume the `[' token. */ cp_lexer_consume_token (parser->lexer); /* Read the operand name. */ name = cp_parser_identifier (parser); if (name != error_mark_node) name = build_string (IDENTIFIER_LENGTH (name), IDENTIFIER_POINTER (name)); /* Look for the closing `]'. */ cp_parser_require (parser, CPP_CLOSE_SQUARE, "`]'"); } else name = NULL_TREE; /* Look for the string-literal. */ string_literal = cp_parser_string_literal (parser, false, false); /* Look for the `('. */ cp_parser_require (parser, CPP_OPEN_PAREN, "`('"); /* Parse the expression. */ expression = cp_parser_expression (parser, /*cast_p=*/false); /* Look for the `)'. */ cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'"); /* Add this operand to the list. */ asm_operands = tree_cons (build_tree_list (name, string_literal), expression, asm_operands); /* If the next token is not a `,', there are no more operands. */ if (cp_lexer_next_token_is_not (parser->lexer, CPP_COMMA)) break; /* Consume the `,'. */ cp_lexer_consume_token (parser->lexer); } return nreverse (asm_operands); } /* Parse an asm-clobber-list. asm-clobber-list: string-literal asm-clobber-list , string-literal Returns a TREE_LIST, indicating the clobbers in the order that they appeared. The TREE_VALUE of each node is a STRING_CST. */ static tree cp_parser_asm_clobber_list (cp_parser* parser) { tree clobbers = NULL_TREE; while (true) { tree string_literal; /* Look for the string literal. */ string_literal = cp_parser_string_literal (parser, false, false); /* Add it to the list. */ clobbers = tree_cons (NULL_TREE, string_literal, clobbers); /* If the next token is not a `,', then the list is complete. */ if (cp_lexer_next_token_is_not (parser->lexer, CPP_COMMA)) break; /* Consume the `,' token. */ cp_lexer_consume_token (parser->lexer); } return clobbers; } /* Parse an (optional) series of attributes. attributes: attributes attribute attribute: __attribute__ (( attribute-list [opt] )) The return value is as for cp_parser_attribute_list. */ static tree cp_parser_attributes_opt (cp_parser* parser) { tree attributes = NULL_TREE; while (true) { cp_token *token; tree attribute_list; /* Peek at the next token. */ token = cp_lexer_peek_token (parser->lexer); /* If it's not `__attribute__', then we're done. */ if (token->keyword != RID_ATTRIBUTE) break; /* Consume the `__attribute__' keyword. */ cp_lexer_consume_token (parser->lexer); /* Look for the two `(' tokens. */ cp_parser_require (parser, CPP_OPEN_PAREN, "`('"); cp_parser_require (parser, CPP_OPEN_PAREN, "`('"); /* Peek at the next token. */ token = cp_lexer_peek_token (parser->lexer); if (token->type != CPP_CLOSE_PAREN) /* Parse the attribute-list. */ attribute_list = cp_parser_attribute_list (parser); else /* If the next token is a `)', then there is no attribute list. */ attribute_list = NULL; /* Look for the two `)' tokens. */ cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'"); cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'"); /* Add these new attributes to the list. */ attributes = chainon (attributes, attribute_list); } return attributes; } /* Parse an attribute-list. attribute-list: attribute attribute-list , attribute attribute: identifier identifier ( identifier ) identifier ( identifier , expression-list ) identifier ( expression-list ) Returns a TREE_LIST, or NULL_TREE on error. Each node corresponds to an attribute. The TREE_PURPOSE of each node is the identifier indicating which attribute is in use. The TREE_VALUE represents the arguments, if any. */ static tree cp_parser_attribute_list (cp_parser* parser) { tree attribute_list = NULL_TREE; bool save_translate_strings_p = parser->translate_strings_p; parser->translate_strings_p = false; while (true) { cp_token *token; tree identifier; tree attribute; /* Look for the identifier. We also allow keywords here; for example `__attribute__ ((const))' is legal. */ token = cp_lexer_peek_token (parser->lexer); if (token->type == CPP_NAME || token->type == CPP_KEYWORD) { tree arguments = NULL_TREE; /* Consume the token. */ token = cp_lexer_consume_token (parser->lexer); /* Save away the identifier that indicates which attribute this is. */ identifier = token->u.value; attribute = build_tree_list (identifier, NULL_TREE); /* Peek at the next token. */ token = cp_lexer_peek_token (parser->lexer); /* If it's an `(', then parse the attribute arguments. */ if (token->type == CPP_OPEN_PAREN) { arguments = cp_parser_parenthesized_expression_list (parser, true, /*cast_p=*/false, /*non_constant_p=*/NULL); /* Save the arguments away. */ TREE_VALUE (attribute) = arguments; } if (arguments != error_mark_node) { /* Add this attribute to the list. */ TREE_CHAIN (attribute) = attribute_list; attribute_list = attribute; } token = cp_lexer_peek_token (parser->lexer); } /* Now, look for more attributes. If the next token isn't a `,', we're done. */ if (token->type != CPP_COMMA) break; /* Consume the comma and keep going. */ cp_lexer_consume_token (parser->lexer); } parser->translate_strings_p = save_translate_strings_p; /* We built up the list in reverse order. */ return nreverse (attribute_list); } /* Parse an optional `__extension__' keyword. Returns TRUE if it is present, and FALSE otherwise. *SAVED_PEDANTIC is set to the current value of the PEDANTIC flag, regardless of whether or not the `__extension__' keyword is present. The caller is responsible for restoring the value of the PEDANTIC flag. */ static bool cp_parser_extension_opt (cp_parser* parser, int* saved_pedantic) { /* Save the old value of the PEDANTIC flag. */ *saved_pedantic = pedantic; if (cp_lexer_next_token_is_keyword (parser->lexer, RID_EXTENSION)) { /* Consume the `__extension__' token. */ cp_lexer_consume_token (parser->lexer); /* We're not being pedantic while the `__extension__' keyword is in effect. */ pedantic = 0; return true; } return false; } /* Parse a label declaration. label-declaration: __label__ label-declarator-seq ; label-declarator-seq: identifier , label-declarator-seq identifier */ static void cp_parser_label_declaration (cp_parser* parser) { /* Look for the `__label__' keyword. */ cp_parser_require_keyword (parser, RID_LABEL, "`__label__'"); while (true) { tree identifier; /* Look for an identifier. */ identifier = cp_parser_identifier (parser); /* If we failed, stop. */ if (identifier == error_mark_node) break; /* Declare it as a label. */ finish_label_decl (identifier); /* If the next token is a `;', stop. */ if (cp_lexer_next_token_is (parser->lexer, CPP_SEMICOLON)) break; /* Look for the `,' separating the label declarations. */ cp_parser_require (parser, CPP_COMMA, "`,'"); } /* Look for the final `;'. */ cp_parser_require (parser, CPP_SEMICOLON, "`;'"); } /* Support Functions */ /* Looks up NAME in the current scope, as given by PARSER->SCOPE. NAME should have one of the representations used for an id-expression. If NAME is the ERROR_MARK_NODE, the ERROR_MARK_NODE is returned. If PARSER->SCOPE is a dependent type, then a SCOPE_REF is returned. If NAME is a TEMPLATE_ID_EXPR, then it will be immediately returned; the name was already resolved when the TEMPLATE_ID_EXPR was formed. Abstractly, such entities should not be passed to this function, because they do not need to be looked up, but it is simpler to check for this special case here, rather than at the call-sites. In cases not explicitly covered above, this function returns a DECL, OVERLOAD, or baselink representing the result of the lookup. If there was no entity with the indicated NAME, the ERROR_MARK_NODE is returned. If TAG_TYPE is not NONE_TYPE, it indicates an explicit type keyword (e.g., "struct") that was used. In that case bindings that do not refer to types are ignored. If IS_TEMPLATE is TRUE, bindings that do not refer to templates are ignored. If IS_NAMESPACE is TRUE, bindings that do not refer to namespaces are ignored. If CHECK_DEPENDENCY is TRUE, names are not looked up in dependent types. If AMBIGUOUS_DECLS is non-NULL, *AMBIGUOUS_DECLS is set to a TREE_LIST of candidates if name-lookup results in an ambiguity, and NULL_TREE otherwise. */ static tree cp_parser_lookup_name (cp_parser *parser, tree name, enum tag_types tag_type, bool is_template, bool is_namespace, bool check_dependency, tree *ambiguous_decls) { int flags = 0; tree decl; tree object_type = parser->context->object_type; if (!cp_parser_uncommitted_to_tentative_parse_p (parser)) flags |= LOOKUP_COMPLAIN; /* Assume that the lookup will be unambiguous. */ if (ambiguous_decls) *ambiguous_decls = NULL_TREE; /* Now that we have looked up the name, the OBJECT_TYPE (if any) is no longer valid. Note that if we are parsing tentatively, and the parse fails, OBJECT_TYPE will be automatically restored. */ parser->context->object_type = NULL_TREE; if (name == error_mark_node) return error_mark_node; /* A template-id has already been resolved; there is no lookup to do. */ if (TREE_CODE (name) == TEMPLATE_ID_EXPR) return name; if (BASELINK_P (name)) { gcc_assert (TREE_CODE (BASELINK_FUNCTIONS (name)) == TEMPLATE_ID_EXPR); return name; } /* A BIT_NOT_EXPR is used to represent a destructor. By this point, it should already have been checked to make sure that the name used matches the type being destroyed. */ if (TREE_CODE (name) == BIT_NOT_EXPR) { tree type; /* Figure out to which type this destructor applies. */ if (parser->scope) type = parser->scope; else if (object_type) type = object_type; else type = current_class_type; /* If that's not a class type, there is no destructor. */ if (!type || !CLASS_TYPE_P (type)) return error_mark_node; if (CLASSTYPE_LAZY_DESTRUCTOR (type)) lazily_declare_fn (sfk_destructor, type); if (!CLASSTYPE_DESTRUCTORS (type)) return error_mark_node; /* If it was a class type, return the destructor. */ return CLASSTYPE_DESTRUCTORS (type); } /* By this point, the NAME should be an ordinary identifier. If the id-expression was a qualified name, the qualifying scope is stored in PARSER->SCOPE at this point. */ gcc_assert (TREE_CODE (name) == IDENTIFIER_NODE); /* Perform the lookup. */ if (parser->scope) { bool dependent_p; if (parser->scope == error_mark_node) return error_mark_node; /* If the SCOPE is dependent, the lookup must be deferred until the template is instantiated -- unless we are explicitly looking up names in uninstantiated templates. Even then, we cannot look up the name if the scope is not a class type; it might, for example, be a template type parameter. */ dependent_p = (TYPE_P (parser->scope) && !(parser->in_declarator_p && currently_open_class (parser->scope)) && dependent_type_p (parser->scope)); if ((check_dependency || !CLASS_TYPE_P (parser->scope)) && dependent_p) { if (tag_type) { tree type; /* The resolution to Core Issue 180 says that `struct A::B' should be considered a type-name, even if `A' is dependent. */ type = make_typename_type (parser->scope, name, tag_type, /*complain=*/tf_error); decl = TYPE_NAME (type); } else if (is_template && (cp_parser_next_token_ends_template_argument_p (parser) || cp_lexer_next_token_is (parser->lexer, CPP_CLOSE_PAREN))) decl = make_unbound_class_template (parser->scope, name, NULL_TREE, /*complain=*/tf_error); else decl = build_qualified_name (/*type=*/NULL_TREE, parser->scope, name, is_template); } else { tree pushed_scope = NULL_TREE; /* If PARSER->SCOPE is a dependent type, then it must be a class type, and we must not be checking dependencies; otherwise, we would have processed this lookup above. So that PARSER->SCOPE is not considered a dependent base by lookup_member, we must enter the scope here. */ if (dependent_p) pushed_scope = push_scope (parser->scope); /* If the PARSER->SCOPE is a template specialization, it may be instantiated during name lookup. In that case, errors may be issued. Even if we rollback the current tentative parse, those errors are valid. */ decl = lookup_qualified_name (parser->scope, name, tag_type != none_type, /*complain=*/true); if (pushed_scope) pop_scope (pushed_scope); } parser->qualifying_scope = parser->scope; parser->object_scope = NULL_TREE; } else if (object_type) { tree object_decl = NULL_TREE; /* Look up the name in the scope of the OBJECT_TYPE, unless the OBJECT_TYPE is not a class. */ if (CLASS_TYPE_P (object_type)) /* If the OBJECT_TYPE is a template specialization, it may be instantiated during name lookup. In that case, errors may be issued. Even if we rollback the current tentative parse, those errors are valid. */ object_decl = lookup_member (object_type, name, /*protect=*/0, tag_type != none_type); /* Look it up in the enclosing context, too. */ decl = lookup_name_real (name, tag_type != none_type, /*nonclass=*/0, /*block_p=*/true, is_namespace, flags); parser->object_scope = object_type; parser->qualifying_scope = NULL_TREE; if (object_decl) decl = object_decl; } else { decl = lookup_name_real (name, tag_type != none_type, /*nonclass=*/0, /*block_p=*/true, is_namespace, flags); parser->qualifying_scope = NULL_TREE; parser->object_scope = NULL_TREE; } /* If the lookup failed, let our caller know. */ if (!decl || decl == error_mark_node) return error_mark_node; /* If it's a TREE_LIST, the result of the lookup was ambiguous. */ if (TREE_CODE (decl) == TREE_LIST) { if (ambiguous_decls) *ambiguous_decls = decl; /* The error message we have to print is too complicated for cp_parser_error, so we incorporate its actions directly. */ if (!cp_parser_simulate_error (parser)) { error ("reference to %qD is ambiguous", name); print_candidates (decl); } return error_mark_node; } gcc_assert (DECL_P (decl) || TREE_CODE (decl) == OVERLOAD || TREE_CODE (decl) == SCOPE_REF || TREE_CODE (decl) == UNBOUND_CLASS_TEMPLATE || BASELINK_P (decl)); /* If we have resolved the name of a member declaration, check to see if the declaration is accessible. When the name resolves to set of overloaded functions, accessibility is checked when overload resolution is done. During an explicit instantiation, access is not checked at all, as per [temp.explicit]. */ if (DECL_P (decl)) check_accessibility_of_qualified_id (decl, object_type, parser->scope); return decl; } /* Like cp_parser_lookup_name, but for use in the typical case where CHECK_ACCESS is TRUE, IS_TYPE is FALSE, IS_TEMPLATE is FALSE, IS_NAMESPACE is FALSE, and CHECK_DEPENDENCY is TRUE. */ static tree cp_parser_lookup_name_simple (cp_parser* parser, tree name) { return cp_parser_lookup_name (parser, name, none_type, /*is_template=*/false, /*is_namespace=*/false, /*check_dependency=*/true, /*ambiguous_decls=*/NULL); } /* If DECL is a TEMPLATE_DECL that can be treated like a TYPE_DECL in the current context, return the TYPE_DECL. If TAG_NAME_P is true, the DECL indicates the class being defined in a class-head, or declared in an elaborated-type-specifier. Otherwise, return DECL. */ static tree cp_parser_maybe_treat_template_as_class (tree decl, bool tag_name_p) { /* If the TEMPLATE_DECL is being declared as part of a class-head, the translation from TEMPLATE_DECL to TYPE_DECL occurs: struct A { template <typename T> struct B; }; template <typename T> struct A::B {}; Similarly, in an elaborated-type-specifier: namespace N { struct X{}; } struct A { template <typename T> friend struct N::X; }; However, if the DECL refers to a class type, and we are in the scope of the class, then the name lookup automatically finds the TYPE_DECL created by build_self_reference rather than a TEMPLATE_DECL. For example, in: template <class T> struct S { S s; }; there is no need to handle such case. */ if (DECL_CLASS_TEMPLATE_P (decl) && tag_name_p) return DECL_TEMPLATE_RESULT (decl); return decl; } /* If too many, or too few, template-parameter lists apply to the declarator, issue an error message. Returns TRUE if all went well, and FALSE otherwise. */ static bool cp_parser_check_declarator_template_parameters (cp_parser* parser, cp_declarator *declarator) { unsigned num_templates; /* We haven't seen any classes that involve template parameters yet. */ num_templates = 0; switch (declarator->kind) { case cdk_id: if (declarator->u.id.qualifying_scope) { tree scope; tree member; scope = declarator->u.id.qualifying_scope; member = declarator->u.id.unqualified_name; while (scope && CLASS_TYPE_P (scope)) { /* You're supposed to have one `template <...>' for every template class, but you don't need one for a full specialization. For example: template <class T> struct S{}; template <> struct S<int> { void f(); }; void S<int>::f () {} is correct; there shouldn't be a `template <>' for the definition of `S<int>::f'. */ if (!CLASSTYPE_TEMPLATE_INFO (scope)) /* If SCOPE does not have template information of any kind, then it is not a template, nor is it nested within a template. */ break; if (explicit_class_specialization_p (scope)) break; if (PRIMARY_TEMPLATE_P (CLASSTYPE_TI_TEMPLATE (scope))) ++num_templates; scope = TYPE_CONTEXT (scope); } } else if (TREE_CODE (declarator->u.id.unqualified_name) == TEMPLATE_ID_EXPR) /* If the DECLARATOR has the form `X<y>' then it uses one additional level of template parameters. */ ++num_templates; return cp_parser_check_template_parameters (parser, num_templates); case cdk_function: case cdk_array: case cdk_pointer: case cdk_reference: case cdk_ptrmem: return (cp_parser_check_declarator_template_parameters (parser, declarator->declarator)); case cdk_error: return true; default: gcc_unreachable (); } return false; } /* NUM_TEMPLATES were used in the current declaration. If that is invalid, return FALSE and issue an error messages. Otherwise, return TRUE. */ static bool cp_parser_check_template_parameters (cp_parser* parser, unsigned num_templates) { /* If there are more template classes than parameter lists, we have something like: template <class T> void S<T>::R<T>::f (); */ if (parser->num_template_parameter_lists < num_templates) { error ("too few template-parameter-lists"); return false; } /* If there are the same number of template classes and parameter lists, that's OK. */ if (parser->num_template_parameter_lists == num_templates) return true; /* If there are more, but only one more, then we are referring to a member template. That's OK too. */ if (parser->num_template_parameter_lists == num_templates + 1) return true; /* Otherwise, there are too many template parameter lists. We have something like: template <class T> template <class U> void S::f(); */ error ("too many template-parameter-lists"); return false; } /* Parse an optional `::' token indicating that the following name is from the global namespace. If so, PARSER->SCOPE is set to the GLOBAL_NAMESPACE. Otherwise, PARSER->SCOPE is set to NULL_TREE, unless CURRENT_SCOPE_VALID_P is TRUE, in which case it is left alone. Returns the new value of PARSER->SCOPE, if the `::' token is present, and NULL_TREE otherwise. */ static tree cp_parser_global_scope_opt (cp_parser* parser, bool current_scope_valid_p) { cp_token *token; /* Peek at the next token. */ token = cp_lexer_peek_token (parser->lexer); /* If we're looking at a `::' token then we're starting from the global namespace, not our current location. */ if (token->type == CPP_SCOPE) { /* Consume the `::' token. */ cp_lexer_consume_token (parser->lexer); /* Set the SCOPE so that we know where to start the lookup. */ parser->scope = global_namespace; parser->qualifying_scope = global_namespace; parser->object_scope = NULL_TREE; return parser->scope; } else if (!current_scope_valid_p) { parser->scope = NULL_TREE; parser->qualifying_scope = NULL_TREE; parser->object_scope = NULL_TREE; } return NULL_TREE; } /* Returns TRUE if the upcoming token sequence is the start of a constructor declarator. If FRIEND_P is true, the declarator is preceded by the `friend' specifier. */ static bool cp_parser_constructor_declarator_p (cp_parser *parser, bool friend_p) { bool constructor_p; tree type_decl = NULL_TREE; bool nested_name_p; cp_token *next_token; /* The common case is that this is not a constructor declarator, so try to avoid doing lots of work if at all possible. It's not valid declare a constructor at function scope. */ if (parser->in_function_body) return false; /* And only certain tokens can begin a constructor declarator. */ next_token = cp_lexer_peek_token (parser->lexer); if (next_token->type != CPP_NAME && next_token->type != CPP_SCOPE && next_token->type != CPP_NESTED_NAME_SPECIFIER && next_token->type != CPP_TEMPLATE_ID) return false; /* Parse tentatively; we are going to roll back all of the tokens consumed here. */ cp_parser_parse_tentatively (parser); /* Assume that we are looking at a constructor declarator. */ constructor_p = true; /* Look for the optional `::' operator. */ cp_parser_global_scope_opt (parser, /*current_scope_valid_p=*/false); /* Look for the nested-name-specifier. */ nested_name_p = (cp_parser_nested_name_specifier_opt (parser, /*typename_keyword_p=*/false, /*check_dependency_p=*/false, /*type_p=*/false, /*is_declaration=*/false) != NULL_TREE); /* Outside of a class-specifier, there must be a nested-name-specifier. */ if (!nested_name_p && (!at_class_scope_p () || !TYPE_BEING_DEFINED (current_class_type) || friend_p)) constructor_p = false; /* If we still think that this might be a constructor-declarator, look for a class-name. */ if (constructor_p) { /* If we have: template <typename T> struct S { S(); }; template <typename T> S<T>::S (); we must recognize that the nested `S' names a class. Similarly, for: template <typename T> S<T>::S<T> (); we must recognize that the nested `S' names a template. */ type_decl = cp_parser_class_name (parser, /*typename_keyword_p=*/false, /*template_keyword_p=*/false, none_type, /*check_dependency_p=*/false, /*class_head_p=*/false, /*is_declaration=*/false); /* If there was no class-name, then this is not a constructor. */ constructor_p = !cp_parser_error_occurred (parser); } /* If we're still considering a constructor, we have to see a `(', to begin the parameter-declaration-clause, followed by either a `)', an `...', or a decl-specifier. We need to check for a type-specifier to avoid being fooled into thinking that: S::S (f) (int); is a constructor. (It is actually a function named `f' that takes one parameter (of type `int') and returns a value of type `S::S'. */ if (constructor_p && cp_parser_require (parser, CPP_OPEN_PAREN, "`('")) { if (cp_lexer_next_token_is_not (parser->lexer, CPP_CLOSE_PAREN) && cp_lexer_next_token_is_not (parser->lexer, CPP_ELLIPSIS) /* A parameter declaration begins with a decl-specifier, which is either the "attribute" keyword, a storage class specifier, or (usually) a type-specifier. */ && !cp_lexer_next_token_is_decl_specifier_keyword (parser->lexer)) { tree type; tree pushed_scope = NULL_TREE; unsigned saved_num_template_parameter_lists; /* Names appearing in the type-specifier should be looked up in the scope of the class. */ if (current_class_type) type = NULL_TREE; else { type = TREE_TYPE (type_decl); if (TREE_CODE (type) == TYPENAME_TYPE) { type = resolve_typename_type (type, /*only_current_p=*/false); if (type == error_mark_node) { cp_parser_abort_tentative_parse (parser); return false; } } pushed_scope = push_scope (type); } /* Inside the constructor parameter list, surrounding template-parameter-lists do not apply. */ saved_num_template_parameter_lists = parser->num_template_parameter_lists; parser->num_template_parameter_lists = 0; /* Look for the type-specifier. */ cp_parser_type_specifier (parser, CP_PARSER_FLAGS_NONE, /*decl_specs=*/NULL, /*is_declarator=*/true, /*declares_class_or_enum=*/NULL, /*is_cv_qualifier=*/NULL); parser->num_template_parameter_lists = saved_num_template_parameter_lists; /* Leave the scope of the class. */ if (pushed_scope) pop_scope (pushed_scope); constructor_p = !cp_parser_error_occurred (parser); } } else constructor_p = false; /* We did not really want to consume any tokens. */ cp_parser_abort_tentative_parse (parser); return constructor_p; } /* Parse the definition of the function given by the DECL_SPECIFIERS, ATTRIBUTES, and DECLARATOR. The access checks have been deferred; they must be performed once we are in the scope of the function. Returns the function defined. */ static tree cp_parser_function_definition_from_specifiers_and_declarator (cp_parser* parser, cp_decl_specifier_seq *decl_specifiers, tree attributes, const cp_declarator *declarator) { tree fn; bool success_p; /* Begin the function-definition. */ success_p = start_function (decl_specifiers, declarator, attributes); /* The things we're about to see are not directly qualified by any template headers we've seen thus far. */ reset_specialization (); /* If there were names looked up in the decl-specifier-seq that we did not check, check them now. We must wait until we are in the scope of the function to perform the checks, since the function might be a friend. */ perform_deferred_access_checks (); if (!success_p) { /* Skip the entire function. */ cp_parser_skip_to_end_of_block_or_statement (parser); fn = error_mark_node; } else fn = cp_parser_function_definition_after_declarator (parser, /*inline_p=*/false); return fn; } /* Parse the part of a function-definition that follows the declarator. INLINE_P is TRUE iff this function is an inline function defined with a class-specifier. Returns the function defined. */ static tree cp_parser_function_definition_after_declarator (cp_parser* parser, bool inline_p) { tree fn; bool ctor_initializer_p = false; bool saved_in_unbraced_linkage_specification_p; bool saved_in_function_body; unsigned saved_num_template_parameter_lists; saved_in_function_body = parser->in_function_body; parser->in_function_body = true; /* If the next token is `return', then the code may be trying to make use of the "named return value" extension that G++ used to support. */ if (cp_lexer_next_token_is_keyword (parser->lexer, RID_RETURN)) { /* Consume the `return' keyword. */ cp_lexer_consume_token (parser->lexer); /* Look for the identifier that indicates what value is to be returned. */ cp_parser_identifier (parser); /* Issue an error message. */ error ("named return values are no longer supported"); /* Skip tokens until we reach the start of the function body. */ while (true) { cp_token *token = cp_lexer_peek_token (parser->lexer); if (token->type == CPP_OPEN_BRACE || token->type == CPP_EOF || token->type == CPP_PRAGMA_EOL) break; cp_lexer_consume_token (parser->lexer); } } /* The `extern' in `extern "C" void f () { ... }' does not apply to anything declared inside `f'. */ saved_in_unbraced_linkage_specification_p = parser->in_unbraced_linkage_specification_p; parser->in_unbraced_linkage_specification_p = false; /* Inside the function, surrounding template-parameter-lists do not apply. */ saved_num_template_parameter_lists = parser->num_template_parameter_lists; parser->num_template_parameter_lists = 0; /* If the next token is `try', then we are looking at a function-try-block. */ if (cp_lexer_next_token_is_keyword (parser->lexer, RID_TRY)) ctor_initializer_p = cp_parser_function_try_block (parser); /* A function-try-block includes the function-body, so we only do this next part if we're not processing a function-try-block. */ else ctor_initializer_p = cp_parser_ctor_initializer_opt_and_function_body (parser); /* Finish the function. */ fn = finish_function ((ctor_initializer_p ? 1 : 0) | (inline_p ? 2 : 0)); /* Generate code for it, if necessary. */ expand_or_defer_fn (fn); /* Restore the saved values. */ parser->in_unbraced_linkage_specification_p = saved_in_unbraced_linkage_specification_p; parser->num_template_parameter_lists = saved_num_template_parameter_lists; parser->in_function_body = saved_in_function_body; return fn; } /* Parse a template-declaration, assuming that the `export' (and `extern') keywords, if present, has already been scanned. MEMBER_P is as for cp_parser_template_declaration. */ static void cp_parser_template_declaration_after_export (cp_parser* parser, bool member_p) { tree decl = NULL_TREE; VEC (deferred_access_check,gc) *checks; tree parameter_list; bool friend_p = false; bool need_lang_pop; /* Look for the `template' keyword. */ if (!cp_parser_require_keyword (parser, RID_TEMPLATE, "`template'")) return; /* And the `<'. */ if (!cp_parser_require (parser, CPP_LESS, "`<'")) return; if (at_class_scope_p () && current_function_decl) { /* 14.5.2.2 [temp.mem] A local class shall not have member templates. */ error ("invalid declaration of member template in local class"); cp_parser_skip_to_end_of_block_or_statement (parser); return; } /* [temp] A template ... shall not have C linkage. */ if (current_lang_name == lang_name_c) { error ("template with C linkage"); /* Give it C++ linkage to avoid confusing other parts of the front end. */ push_lang_context (lang_name_cplusplus); need_lang_pop = true; } else need_lang_pop = false; /* We cannot perform access checks on the template parameter declarations until we know what is being declared, just as we cannot check the decl-specifier list. */ push_deferring_access_checks (dk_deferred); /* If the next token is `>', then we have an invalid specialization. Rather than complain about an invalid template parameter, issue an error message here. */ if (cp_lexer_next_token_is (parser->lexer, CPP_GREATER)) { cp_parser_error (parser, "invalid explicit specialization"); begin_specialization (); parameter_list = NULL_TREE; } else /* Parse the template parameters. */ parameter_list = cp_parser_template_parameter_list (parser); /* Get the deferred access checks from the parameter list. These will be checked once we know what is being declared, as for a member template the checks must be performed in the scope of the class containing the member. */ checks = get_deferred_access_checks (); /* Look for the `>'. */ cp_parser_skip_to_end_of_template_parameter_list (parser); /* We just processed one more parameter list. */ ++parser->num_template_parameter_lists; /* If the next token is `template', there are more template parameters. */ if (cp_lexer_next_token_is_keyword (parser->lexer, RID_TEMPLATE)) cp_parser_template_declaration_after_export (parser, member_p); else { /* There are no access checks when parsing a template, as we do not know if a specialization will be a friend. */ push_deferring_access_checks (dk_no_check); decl = cp_parser_single_declaration (parser, checks, member_p, &friend_p); pop_deferring_access_checks (); /* If this is a member template declaration, let the front end know. */ if (member_p && !friend_p && decl) { if (TREE_CODE (decl) == TYPE_DECL) cp_parser_check_access_in_redeclaration (decl); decl = finish_member_template_decl (decl); } else if (friend_p && decl && TREE_CODE (decl) == TYPE_DECL) make_friend_class (current_class_type, TREE_TYPE (decl), /*complain=*/true); } /* We are done with the current parameter list. */ --parser->num_template_parameter_lists; pop_deferring_access_checks (); /* Finish up. */ finish_template_decl (parameter_list); /* Register member declarations. */ if (member_p && !friend_p && decl && !DECL_CLASS_TEMPLATE_P (decl)) finish_member_declaration (decl); /* For the erroneous case of a template with C linkage, we pushed an implicit C++ linkage scope; exit that scope now. */ if (need_lang_pop) pop_lang_context (); /* If DECL is a function template, we must return to parse it later. (Even though there is no definition, there might be default arguments that need handling.) */ if (member_p && decl && (TREE_CODE (decl) == FUNCTION_DECL || DECL_FUNCTION_TEMPLATE_P (decl))) TREE_VALUE (parser->unparsed_functions_queues) = tree_cons (NULL_TREE, decl, TREE_VALUE (parser->unparsed_functions_queues)); } /* Perform the deferred access checks from a template-parameter-list. CHECKS is a TREE_LIST of access checks, as returned by get_deferred_access_checks. */ static void cp_parser_perform_template_parameter_access_checks (VEC (deferred_access_check,gc)* checks) { ++processing_template_parmlist; perform_access_checks (checks); --processing_template_parmlist; } /* Parse a `decl-specifier-seq [opt] init-declarator [opt] ;' or `function-definition' sequence. MEMBER_P is true, this declaration appears in a class scope. Returns the DECL for the declared entity. If FRIEND_P is non-NULL, *FRIEND_P is set to TRUE iff the declaration is a friend. */ static tree cp_parser_single_declaration (cp_parser* parser, VEC (deferred_access_check,gc)* checks, bool member_p, bool* friend_p) { int declares_class_or_enum; tree decl = NULL_TREE; cp_decl_specifier_seq decl_specifiers; bool function_definition_p = false; /* This function is only used when processing a template declaration. */ gcc_assert (innermost_scope_kind () == sk_template_parms || innermost_scope_kind () == sk_template_spec); /* Defer access checks until we know what is being declared. */ push_deferring_access_checks (dk_deferred); /* Try the `decl-specifier-seq [opt] init-declarator [opt]' alternative. */ cp_parser_decl_specifier_seq (parser, CP_PARSER_FLAGS_OPTIONAL, &decl_specifiers, &declares_class_or_enum); if (friend_p) *friend_p = cp_parser_friend_p (&decl_specifiers); /* There are no template typedefs. */ if (decl_specifiers.specs[(int) ds_typedef]) { error ("template declaration of %qs", "typedef"); decl = error_mark_node; } /* Gather up the access checks that occurred the decl-specifier-seq. */ stop_deferring_access_checks (); /* Check for the declaration of a template class. */ if (declares_class_or_enum) { if (cp_parser_declares_only_class_p (parser)) { decl = shadow_tag (&decl_specifiers); /* In this case: struct C { friend template <typename T> struct A<T>::B; }; A<T>::B will be represented by a TYPENAME_TYPE, and therefore not recognized by shadow_tag. */ if (friend_p && *friend_p && !decl && decl_specifiers.type && TYPE_P (decl_specifiers.type)) decl = decl_specifiers.type; if (decl && decl != error_mark_node) decl = TYPE_NAME (decl); else decl = error_mark_node; /* Perform access checks for template parameters. */ cp_parser_perform_template_parameter_access_checks (checks); } } /* If it's not a template class, try for a template function. If the next token is a `;', then this declaration does not declare anything. But, if there were errors in the decl-specifiers, then the error might well have come from an attempted class-specifier. In that case, there's no need to warn about a missing declarator. */ if (!decl && (cp_lexer_next_token_is_not (parser->lexer, CPP_SEMICOLON) || decl_specifiers.type != error_mark_node)) decl = cp_parser_init_declarator (parser, &decl_specifiers, checks, /*function_definition_allowed_p=*/true, member_p, declares_class_or_enum, &function_definition_p); pop_deferring_access_checks (); /* Clear any current qualification; whatever comes next is the start of something new. */ parser->scope = NULL_TREE; parser->qualifying_scope = NULL_TREE; parser->object_scope = NULL_TREE; /* Look for a trailing `;' after the declaration. */ if (!function_definition_p && (decl == error_mark_node || !cp_parser_require (parser, CPP_SEMICOLON, "`;'"))) cp_parser_skip_to_end_of_block_or_statement (parser); return decl; } /* Parse a cast-expression that is not the operand of a unary "&". */ static tree cp_parser_simple_cast_expression (cp_parser *parser) { return cp_parser_cast_expression (parser, /*address_p=*/false, /*cast_p=*/false); } /* Parse a functional cast to TYPE. Returns an expression representing the cast. */ static tree cp_parser_functional_cast (cp_parser* parser, tree type) { tree expression_list; tree cast; expression_list = cp_parser_parenthesized_expression_list (parser, false, /*cast_p=*/true, /*non_constant_p=*/NULL); cast = build_functional_cast (type, expression_list); /* [expr.const]/1: In an integral constant expression "only type conversions to integral or enumeration type can be used". */ if (TREE_CODE (type) == TYPE_DECL) type = TREE_TYPE (type); if (cast != error_mark_node && !cast_valid_in_integral_constant_expression_p (type) && (cp_parser_non_integral_constant_expression (parser, "a call to a constructor"))) return error_mark_node; return cast; } /* Save the tokens that make up the body of a member function defined in a class-specifier. The DECL_SPECIFIERS and DECLARATOR have already been parsed. The ATTRIBUTES are any GNU "__attribute__" specifiers applied to the declaration. Returns the FUNCTION_DECL for the member function. */ static tree cp_parser_save_member_function_body (cp_parser* parser, cp_decl_specifier_seq *decl_specifiers, cp_declarator *declarator, tree attributes) { cp_token *first; cp_token *last; tree fn; /* Create the function-declaration. */ fn = start_method (decl_specifiers, declarator, attributes); /* If something went badly wrong, bail out now. */ if (fn == error_mark_node) { /* If there's a function-body, skip it. */ if (cp_parser_token_starts_function_definition_p (cp_lexer_peek_token (parser->lexer))) cp_parser_skip_to_end_of_block_or_statement (parser); return error_mark_node; } /* Remember it, if there default args to post process. */ cp_parser_save_default_args (parser, fn); /* Save away the tokens that make up the body of the function. */ first = parser->lexer->next_token; cp_parser_cache_group (parser, CPP_CLOSE_BRACE, /*depth=*/0); /* Handle function try blocks. */ while (cp_lexer_next_token_is_keyword (parser->lexer, RID_CATCH)) cp_parser_cache_group (parser, CPP_CLOSE_BRACE, /*depth=*/0); last = parser->lexer->next_token; /* Save away the inline definition; we will process it when the class is complete. */ DECL_PENDING_INLINE_INFO (fn) = cp_token_cache_new (first, last); DECL_PENDING_INLINE_P (fn) = 1; /* We need to know that this was defined in the class, so that friend templates are handled correctly. */ DECL_INITIALIZED_IN_CLASS_P (fn) = 1; /* We're done with the inline definition. */ finish_method (fn); /* Add FN to the queue of functions to be parsed later. */ TREE_VALUE (parser->unparsed_functions_queues) = tree_cons (NULL_TREE, fn, TREE_VALUE (parser->unparsed_functions_queues)); return fn; } /* Parse a template-argument-list, as well as the trailing ">" (but not the opening ">"). See cp_parser_template_argument_list for the return value. */ static tree cp_parser_enclosed_template_argument_list (cp_parser* parser) { tree arguments; tree saved_scope; tree saved_qualifying_scope; tree saved_object_scope; bool saved_greater_than_is_operator_p; bool saved_skip_evaluation; /* [temp.names] When parsing a template-id, the first non-nested `>' is taken as the end of the template-argument-list rather than a greater-than operator. */ saved_greater_than_is_operator_p = parser->greater_than_is_operator_p; parser->greater_than_is_operator_p = false; /* Parsing the argument list may modify SCOPE, so we save it here. */ saved_scope = parser->scope; saved_qualifying_scope = parser->qualifying_scope; saved_object_scope = parser->object_scope; /* We need to evaluate the template arguments, even though this template-id may be nested within a "sizeof". */ saved_skip_evaluation = skip_evaluation; skip_evaluation = false; /* Parse the template-argument-list itself. */ if (cp_lexer_next_token_is (parser->lexer, CPP_GREATER)) arguments = NULL_TREE; else arguments = cp_parser_template_argument_list (parser); /* Look for the `>' that ends the template-argument-list. If we find a '>>' instead, it's probably just a typo. */ if (cp_lexer_next_token_is (parser->lexer, CPP_RSHIFT)) { if (!saved_greater_than_is_operator_p) { /* If we're in a nested template argument list, the '>>' has to be a typo for '> >'. We emit the error message, but we continue parsing and we push a '>' as next token, so that the argument list will be parsed correctly. Note that the global source location is still on the token before the '>>', so we need to say explicitly where we want it. */ cp_token *token = cp_lexer_peek_token (parser->lexer); error ("%H%<>>%> should be %<> >%> " "within a nested template argument list", &token->location); /* ??? Proper recovery should terminate two levels of template argument list here. */ token->type = CPP_GREATER; } else { /* If this is not a nested template argument list, the '>>' is a typo for '>'. Emit an error message and continue. Same deal about the token location, but here we can get it right by consuming the '>>' before issuing the diagnostic. */ cp_lexer_consume_token (parser->lexer); error ("spurious %<>>%>, use %<>%> to terminate " "a template argument list"); } } else cp_parser_skip_to_end_of_template_parameter_list (parser); /* The `>' token might be a greater-than operator again now. */ parser->greater_than_is_operator_p = saved_greater_than_is_operator_p; /* Restore the SAVED_SCOPE. */ parser->scope = saved_scope; parser->qualifying_scope = saved_qualifying_scope; parser->object_scope = saved_object_scope; skip_evaluation = saved_skip_evaluation; return arguments; } /* MEMBER_FUNCTION is a member function, or a friend. If default arguments, or the body of the function have not yet been parsed, parse them now. */ static void cp_parser_late_parsing_for_member (cp_parser* parser, tree member_function) { /* If this member is a template, get the underlying FUNCTION_DECL. */ if (DECL_FUNCTION_TEMPLATE_P (member_function)) member_function = DECL_TEMPLATE_RESULT (member_function); /* There should not be any class definitions in progress at this point; the bodies of members are only parsed outside of all class definitions. */ gcc_assert (parser->num_classes_being_defined == 0); /* While we're parsing the member functions we might encounter more classes. We want to handle them right away, but we don't want them getting mixed up with functions that are currently in the queue. */ parser->unparsed_functions_queues = tree_cons (NULL_TREE, NULL_TREE, parser->unparsed_functions_queues); /* Make sure that any template parameters are in scope. */ maybe_begin_member_template_processing (member_function); /* If the body of the function has not yet been parsed, parse it now. */ if (DECL_PENDING_INLINE_P (member_function)) { tree function_scope; cp_token_cache *tokens; /* The function is no longer pending; we are processing it. */ tokens = DECL_PENDING_INLINE_INFO (member_function); DECL_PENDING_INLINE_INFO (member_function) = NULL; DECL_PENDING_INLINE_P (member_function) = 0; /* If this is a local class, enter the scope of the containing function. */ function_scope = current_function_decl; if (function_scope) push_function_context_to (function_scope); /* Push the body of the function onto the lexer stack. */ cp_parser_push_lexer_for_tokens (parser, tokens); /* Let the front end know that we going to be defining this function. */ start_preparsed_function (member_function, NULL_TREE, SF_PRE_PARSED | SF_INCLASS_INLINE); /* Don't do access checking if it is a templated function. */ if (processing_template_decl) push_deferring_access_checks (dk_no_check); /* Now, parse the body of the function. */ cp_parser_function_definition_after_declarator (parser, /*inline_p=*/true); if (processing_template_decl) pop_deferring_access_checks (); /* Leave the scope of the containing function. */ if (function_scope) pop_function_context_from (function_scope); cp_parser_pop_lexer (parser); } /* Remove any template parameters from the symbol table. */ maybe_end_member_template_processing (); /* Restore the queue. */ parser->unparsed_functions_queues = TREE_CHAIN (parser->unparsed_functions_queues); } /* If DECL contains any default args, remember it on the unparsed functions queue. */ static void cp_parser_save_default_args (cp_parser* parser, tree decl) { tree probe; for (probe = TYPE_ARG_TYPES (TREE_TYPE (decl)); probe; probe = TREE_CHAIN (probe)) if (TREE_PURPOSE (probe)) { TREE_PURPOSE (parser->unparsed_functions_queues) = tree_cons (current_class_type, decl, TREE_PURPOSE (parser->unparsed_functions_queues)); break; } } /* FN is a FUNCTION_DECL which may contains a parameter with an unparsed DEFAULT_ARG. Parse the default args now. This function assumes that the current scope is the scope in which the default argument should be processed. */ static void cp_parser_late_parsing_default_args (cp_parser *parser, tree fn) { bool saved_local_variables_forbidden_p; tree parm; /* While we're parsing the default args, we might (due to the statement expression extension) encounter more classes. We want to handle them right away, but we don't want them getting mixed up with default args that are currently in the queue. */ parser->unparsed_functions_queues = tree_cons (NULL_TREE, NULL_TREE, parser->unparsed_functions_queues); /* Local variable names (and the `this' keyword) may not appear in a default argument. */ saved_local_variables_forbidden_p = parser->local_variables_forbidden_p; parser->local_variables_forbidden_p = true; for (parm = TYPE_ARG_TYPES (TREE_TYPE (fn)); parm; parm = TREE_CHAIN (parm)) { cp_token_cache *tokens; tree default_arg = TREE_PURPOSE (parm); tree parsed_arg; VEC(tree,gc) *insts; tree copy; unsigned ix; if (!default_arg) continue; if (TREE_CODE (default_arg) != DEFAULT_ARG) /* This can happen for a friend declaration for a function already declared with default arguments. */ continue; /* Push the saved tokens for the default argument onto the parser's lexer stack. */ tokens = DEFARG_TOKENS (default_arg); cp_parser_push_lexer_for_tokens (parser, tokens); /* Parse the assignment-expression. */ parsed_arg = cp_parser_assignment_expression (parser, /*cast_p=*/false); if (!processing_template_decl) parsed_arg = check_default_argument (TREE_VALUE (parm), parsed_arg); TREE_PURPOSE (parm) = parsed_arg; /* Update any instantiations we've already created. */ for (insts = DEFARG_INSTANTIATIONS (default_arg), ix = 0; VEC_iterate (tree, insts, ix, copy); ix++) TREE_PURPOSE (copy) = parsed_arg; /* If the token stream has not been completely used up, then there was extra junk after the end of the default argument. */ if (!cp_lexer_next_token_is (parser->lexer, CPP_EOF)) cp_parser_error (parser, "expected %<,%>"); /* Revert to the main lexer. */ cp_parser_pop_lexer (parser); } /* Make sure no default arg is missing. */ check_default_args (fn); /* Restore the state of local_variables_forbidden_p. */ parser->local_variables_forbidden_p = saved_local_variables_forbidden_p; /* Restore the queue. */ parser->unparsed_functions_queues = TREE_CHAIN (parser->unparsed_functions_queues); } /* Parse the operand of `sizeof' (or a similar operator). Returns either a TYPE or an expression, depending on the form of the input. The KEYWORD indicates which kind of expression we have encountered. */ static tree cp_parser_sizeof_operand (cp_parser* parser, enum rid keyword) { static const char *format; tree expr = NULL_TREE; const char *saved_message; bool saved_integral_constant_expression_p; bool saved_non_integral_constant_expression_p; /* Initialize FORMAT the first time we get here. */ if (!format) format = "types may not be defined in '%s' expressions"; /* Types cannot be defined in a `sizeof' expression. Save away the old message. */ saved_message = parser->type_definition_forbidden_message; /* And create the new one. */ parser->type_definition_forbidden_message = XNEWVEC (const char, strlen (format) + strlen (IDENTIFIER_POINTER (ridpointers[keyword])) + 1 /* `\0' */); sprintf ((char *) parser->type_definition_forbidden_message, format, IDENTIFIER_POINTER (ridpointers[keyword])); /* The restrictions on constant-expressions do not apply inside sizeof expressions. */ saved_integral_constant_expression_p = parser->integral_constant_expression_p; saved_non_integral_constant_expression_p = parser->non_integral_constant_expression_p; parser->integral_constant_expression_p = false; /* Do not actually evaluate the expression. */ ++skip_evaluation; /* If it's a `(', then we might be looking at the type-id construction. */ if (cp_lexer_next_token_is (parser->lexer, CPP_OPEN_PAREN)) { tree type; bool saved_in_type_id_in_expr_p; /* We can't be sure yet whether we're looking at a type-id or an expression. */ cp_parser_parse_tentatively (parser); /* Consume the `('. */ cp_lexer_consume_token (parser->lexer); /* Parse the type-id. */ saved_in_type_id_in_expr_p = parser->in_type_id_in_expr_p; parser->in_type_id_in_expr_p = true; type = cp_parser_type_id (parser); parser->in_type_id_in_expr_p = saved_in_type_id_in_expr_p; /* Now, look for the trailing `)'. */ cp_parser_require (parser, CPP_CLOSE_PAREN, "%<)%>"); /* If all went well, then we're done. */ if (cp_parser_parse_definitely (parser)) { cp_decl_specifier_seq decl_specs; /* Build a trivial decl-specifier-seq. */ clear_decl_specs (&decl_specs); decl_specs.type = type; /* Call grokdeclarator to figure out what type this is. */ expr = grokdeclarator (NULL, &decl_specs, TYPENAME, /*initialized=*/0, /*attrlist=*/NULL); } } /* If the type-id production did not work out, then we must be looking at the unary-expression production. */ if (!expr) expr = cp_parser_unary_expression (parser, /*address_p=*/false, /*cast_p=*/false); /* Go back to evaluating expressions. */ --skip_evaluation; /* Free the message we created. */ free ((char *) parser->type_definition_forbidden_message); /* And restore the old one. */ parser->type_definition_forbidden_message = saved_message; parser->integral_constant_expression_p = saved_integral_constant_expression_p; parser->non_integral_constant_expression_p = saved_non_integral_constant_expression_p; return expr; } /* If the current declaration has no declarator, return true. */ static bool cp_parser_declares_only_class_p (cp_parser *parser) { /* If the next token is a `;' or a `,' then there is no declarator. */ return (cp_lexer_next_token_is (parser->lexer, CPP_SEMICOLON) || cp_lexer_next_token_is (parser->lexer, CPP_COMMA)); } /* Update the DECL_SPECS to reflect the storage class indicated by KEYWORD. */ static void cp_parser_set_storage_class (cp_parser *parser, cp_decl_specifier_seq *decl_specs, enum rid keyword) { cp_storage_class storage_class; if (parser->in_unbraced_linkage_specification_p) { error ("invalid use of %qD in linkage specification", ridpointers[keyword]); return; } else if (decl_specs->storage_class != sc_none) { decl_specs->conflicting_specifiers_p = true; return; } if ((keyword == RID_EXTERN || keyword == RID_STATIC) && decl_specs->specs[(int) ds_thread]) { error ("%<__thread%> before %qD", ridpointers[keyword]); decl_specs->specs[(int) ds_thread] = 0; } switch (keyword) { case RID_AUTO: storage_class = sc_auto; break; case RID_REGISTER: storage_class = sc_register; break; case RID_STATIC: storage_class = sc_static; break; case RID_EXTERN: storage_class = sc_extern; break; case RID_MUTABLE: storage_class = sc_mutable; break; default: gcc_unreachable (); } decl_specs->storage_class = storage_class; /* A storage class specifier cannot be applied alongside a typedef specifier. If there is a typedef specifier present then set conflicting_specifiers_p which will trigger an error later on in grokdeclarator. */ if (decl_specs->specs[(int)ds_typedef]) decl_specs->conflicting_specifiers_p = true; } /* Update the DECL_SPECS to reflect the TYPE_SPEC. If USER_DEFINED_P is true, the type is a user-defined type; otherwise it is a built-in type specified by a keyword. */ static void cp_parser_set_decl_spec_type (cp_decl_specifier_seq *decl_specs, tree type_spec, bool user_defined_p) { decl_specs->any_specifiers_p = true; /* If the user tries to redeclare bool or wchar_t (with, for example, in "typedef int wchar_t;") we remember that this is what happened. In system headers, we ignore these declarations so that G++ can work with system headers that are not C++-safe. */ if (decl_specs->specs[(int) ds_typedef] && !user_defined_p && (type_spec == boolean_type_node || type_spec == wchar_type_node) && (decl_specs->type || decl_specs->specs[(int) ds_long] || decl_specs->specs[(int) ds_short] || decl_specs->specs[(int) ds_unsigned] || decl_specs->specs[(int) ds_signed])) { decl_specs->redefined_builtin_type = type_spec; if (!decl_specs->type) { decl_specs->type = type_spec; decl_specs->user_defined_type_p = false; } } else if (decl_specs->type) decl_specs->multiple_types_p = true; else { decl_specs->type = type_spec; decl_specs->user_defined_type_p = user_defined_p; decl_specs->redefined_builtin_type = NULL_TREE; } } /* DECL_SPECIFIERS is the representation of a decl-specifier-seq. Returns TRUE iff `friend' appears among the DECL_SPECIFIERS. */ static bool cp_parser_friend_p (const cp_decl_specifier_seq *decl_specifiers) { return decl_specifiers->specs[(int) ds_friend] != 0; } /* If the next token is of the indicated TYPE, consume it. Otherwise, issue an error message indicating that TOKEN_DESC was expected. Returns the token consumed, if the token had the appropriate type. Otherwise, returns NULL. */ static cp_token * cp_parser_require (cp_parser* parser, enum cpp_ttype type, const char* token_desc) { if (cp_lexer_next_token_is (parser->lexer, type)) return cp_lexer_consume_token (parser->lexer); else { /* Output the MESSAGE -- unless we're parsing tentatively. */ if (!cp_parser_simulate_error (parser)) { char *message = concat ("expected ", token_desc, NULL); cp_parser_error (parser, message); free (message); } return NULL; } } /* An error message is produced if the next token is not '>'. All further tokens are skipped until the desired token is found or '{', '}', ';' or an unbalanced ')' or ']'. */ static void cp_parser_skip_to_end_of_template_parameter_list (cp_parser* parser) { /* Current level of '< ... >'. */ unsigned level = 0; /* Ignore '<' and '>' nested inside '( ... )' or '[ ... ]'. */ unsigned nesting_depth = 0; /* Are we ready, yet? If not, issue error message. */ if (cp_parser_require (parser, CPP_GREATER, "%<>%>")) return; /* Skip tokens until the desired token is found. */ while (true) { /* Peek at the next token. */ switch (cp_lexer_peek_token (parser->lexer)->type) { case CPP_LESS: if (!nesting_depth) ++level; break; case CPP_GREATER: if (!nesting_depth && level-- == 0) { /* We've reached the token we want, consume it and stop. */ cp_lexer_consume_token (parser->lexer); return; } break; case CPP_OPEN_PAREN: case CPP_OPEN_SQUARE: ++nesting_depth; break; case CPP_CLOSE_PAREN: case CPP_CLOSE_SQUARE: if (nesting_depth-- == 0) return; break; case CPP_EOF: case CPP_PRAGMA_EOL: case CPP_SEMICOLON: case CPP_OPEN_BRACE: case CPP_CLOSE_BRACE: /* The '>' was probably forgotten, don't look further. */ return; default: break; } /* Consume this token. */ cp_lexer_consume_token (parser->lexer); } } /* If the next token is the indicated keyword, consume it. Otherwise, issue an error message indicating that TOKEN_DESC was expected. Returns the token consumed, if the token had the appropriate type. Otherwise, returns NULL. */ static cp_token * cp_parser_require_keyword (cp_parser* parser, enum rid keyword, const char* token_desc) { cp_token *token = cp_parser_require (parser, CPP_KEYWORD, token_desc); if (token && token->keyword != keyword) { dyn_string_t error_msg; /* Format the error message. */ error_msg = dyn_string_new (0); dyn_string_append_cstr (error_msg, "expected "); dyn_string_append_cstr (error_msg, token_desc); cp_parser_error (parser, error_msg->s); dyn_string_delete (error_msg); return NULL; } return token; } /* Returns TRUE iff TOKEN is a token that can begin the body of a function-definition. */ static bool cp_parser_token_starts_function_definition_p (cp_token* token) { return (/* An ordinary function-body begins with an `{'. */ token->type == CPP_OPEN_BRACE /* A ctor-initializer begins with a `:'. */ || token->type == CPP_COLON /* A function-try-block begins with `try'. */ || token->keyword == RID_TRY /* The named return value extension begins with `return'. */ || token->keyword == RID_RETURN); } /* Returns TRUE iff the next token is the ":" or "{" beginning a class definition. */ static bool cp_parser_next_token_starts_class_definition_p (cp_parser *parser) { cp_token *token; token = cp_lexer_peek_token (parser->lexer); return (token->type == CPP_OPEN_BRACE || token->type == CPP_COLON); } /* Returns TRUE iff the next token is the "," or ">" ending a template-argument. */ static bool cp_parser_next_token_ends_template_argument_p (cp_parser *parser) { cp_token *token; token = cp_lexer_peek_token (parser->lexer); return (token->type == CPP_COMMA || token->type == CPP_GREATER); } /* Returns TRUE iff the n-th token is a "<", or the n-th is a "[" and the (n+1)-th is a ":" (which is a possible digraph typo for "< ::"). */ static bool cp_parser_nth_token_starts_template_argument_list_p (cp_parser * parser, size_t n) { cp_token *token; token = cp_lexer_peek_nth_token (parser->lexer, n); if (token->type == CPP_LESS) return true; /* Check for the sequence `<::' in the original code. It would be lexed as `[:', where `[' is a digraph, and there is no whitespace before `:'. */ if (token->type == CPP_OPEN_SQUARE && token->flags & DIGRAPH) { cp_token *token2; token2 = cp_lexer_peek_nth_token (parser->lexer, n+1); if (token2->type == CPP_COLON && !(token2->flags & PREV_WHITE)) return true; } return false; } /* Returns the kind of tag indicated by TOKEN, if it is a class-key, or none_type otherwise. */ static enum tag_types cp_parser_token_is_class_key (cp_token* token) { switch (token->keyword) { case RID_CLASS: return class_type; case RID_STRUCT: return record_type; case RID_UNION: return union_type; default: return none_type; } } /* Issue an error message if the CLASS_KEY does not match the TYPE. */ static void cp_parser_check_class_key (enum tag_types class_key, tree type) { if ((TREE_CODE (type) == UNION_TYPE) != (class_key == union_type)) pedwarn ("%qs tag used in naming %q#T", class_key == union_type ? "union" : class_key == record_type ? "struct" : "class", type); } /* Issue an error message if DECL is redeclared with different access than its original declaration [class.access.spec/3]. This applies to nested classes and nested class templates. [class.mem/1]. */ static void cp_parser_check_access_in_redeclaration (tree decl) { if (!CLASS_TYPE_P (TREE_TYPE (decl))) return; if ((TREE_PRIVATE (decl) != (current_access_specifier == access_private_node)) || (TREE_PROTECTED (decl) != (current_access_specifier == access_protected_node))) error ("%qD redeclared with different access", decl); } /* Look for the `template' keyword, as a syntactic disambiguator. Return TRUE iff it is present, in which case it will be consumed. */ static bool cp_parser_optional_template_keyword (cp_parser *parser) { if (cp_lexer_next_token_is_keyword (parser->lexer, RID_TEMPLATE)) { /* The `template' keyword can only be used within templates; outside templates the parser can always figure out what is a template and what is not. */ if (!processing_template_decl) { error ("%<template%> (as a disambiguator) is only allowed " "within templates"); /* If this part of the token stream is rescanned, the same error message would be generated. So, we purge the token from the stream. */ cp_lexer_purge_token (parser->lexer); return false; } else { /* Consume the `template' keyword. */ cp_lexer_consume_token (parser->lexer); return true; } } return false; } /* The next token is a CPP_NESTED_NAME_SPECIFIER. Consume the token, set PARSER->SCOPE, and perform other related actions. */ static void cp_parser_pre_parsed_nested_name_specifier (cp_parser *parser) { int i; struct tree_check *check_value; deferred_access_check *chk; VEC (deferred_access_check,gc) *checks; /* Get the stored value. */ check_value = cp_lexer_consume_token (parser->lexer)->u.tree_check_value; /* Perform any access checks that were deferred. */ checks = check_value->checks; if (checks) { for (i = 0 ; VEC_iterate (deferred_access_check, checks, i, chk) ; ++i) { perform_or_defer_access_check (chk->binfo, chk->decl, chk->diag_decl); } } /* Set the scope from the stored value. */ parser->scope = check_value->value; parser->qualifying_scope = check_value->qualifying_scope; parser->object_scope = NULL_TREE; } /* Consume tokens up through a non-nested END token. */ static void cp_parser_cache_group (cp_parser *parser, enum cpp_ttype end, unsigned depth) { while (true) { cp_token *token; /* Abort a parenthesized expression if we encounter a brace. */ if ((end == CPP_CLOSE_PAREN || depth == 0) && cp_lexer_next_token_is (parser->lexer, CPP_SEMICOLON)) return; /* If we've reached the end of the file, stop. */ if (cp_lexer_next_token_is (parser->lexer, CPP_EOF) || (end != CPP_PRAGMA_EOL && cp_lexer_next_token_is (parser->lexer, CPP_PRAGMA_EOL))) return; /* Consume the next token. */ token = cp_lexer_consume_token (parser->lexer); /* See if it starts a new group. */ if (token->type == CPP_OPEN_BRACE) { cp_parser_cache_group (parser, CPP_CLOSE_BRACE, depth + 1); if (depth == 0) return; } else if (token->type == CPP_OPEN_PAREN) cp_parser_cache_group (parser, CPP_CLOSE_PAREN, depth + 1); else if (token->type == CPP_PRAGMA) cp_parser_cache_group (parser, CPP_PRAGMA_EOL, depth + 1); else if (token->type == end) return; } } /* Begin parsing tentatively. We always save tokens while parsing tentatively so that if the tentative parsing fails we can restore the tokens. */ static void cp_parser_parse_tentatively (cp_parser* parser) { /* Enter a new parsing context. */ parser->context = cp_parser_context_new (parser->context); /* Begin saving tokens. */ cp_lexer_save_tokens (parser->lexer); /* In order to avoid repetitive access control error messages, access checks are queued up until we are no longer parsing tentatively. */ push_deferring_access_checks (dk_deferred); } /* Commit to the currently active tentative parse. */ static void cp_parser_commit_to_tentative_parse (cp_parser* parser) { cp_parser_context *context; cp_lexer *lexer; /* Mark all of the levels as committed. */ lexer = parser->lexer; for (context = parser->context; context->next; context = context->next) { if (context->status == CP_PARSER_STATUS_KIND_COMMITTED) break; context->status = CP_PARSER_STATUS_KIND_COMMITTED; while (!cp_lexer_saving_tokens (lexer)) lexer = lexer->next; cp_lexer_commit_tokens (lexer); } } /* Abort the currently active tentative parse. All consumed tokens will be rolled back, and no diagnostics will be issued. */ static void cp_parser_abort_tentative_parse (cp_parser* parser) { cp_parser_simulate_error (parser); /* Now, pretend that we want to see if the construct was successfully parsed. */ cp_parser_parse_definitely (parser); } /* Stop parsing tentatively. If a parse error has occurred, restore the token stream. Otherwise, commit to the tokens we have consumed. Returns true if no error occurred; false otherwise. */ static bool cp_parser_parse_definitely (cp_parser* parser) { bool error_occurred; cp_parser_context *context; /* Remember whether or not an error occurred, since we are about to destroy that information. */ error_occurred = cp_parser_error_occurred (parser); /* Remove the topmost context from the stack. */ context = parser->context; parser->context = context->next; /* If no parse errors occurred, commit to the tentative parse. */ if (!error_occurred) { /* Commit to the tokens read tentatively, unless that was already done. */ if (context->status != CP_PARSER_STATUS_KIND_COMMITTED) cp_lexer_commit_tokens (parser->lexer); pop_to_parent_deferring_access_checks (); } /* Otherwise, if errors occurred, roll back our state so that things are just as they were before we began the tentative parse. */ else { cp_lexer_rollback_tokens (parser->lexer); pop_deferring_access_checks (); } /* Add the context to the front of the free list. */ context->next = cp_parser_context_free_list; cp_parser_context_free_list = context; return !error_occurred; } /* Returns true if we are parsing tentatively and are not committed to this tentative parse. */ static bool cp_parser_uncommitted_to_tentative_parse_p (cp_parser* parser) { return (cp_parser_parsing_tentatively (parser) && parser->context->status != CP_PARSER_STATUS_KIND_COMMITTED); } /* Returns nonzero iff an error has occurred during the most recent tentative parse. */ static bool cp_parser_error_occurred (cp_parser* parser) { return (cp_parser_parsing_tentatively (parser) && parser->context->status == CP_PARSER_STATUS_KIND_ERROR); } /* Returns nonzero if GNU extensions are allowed. */ static bool cp_parser_allow_gnu_extensions_p (cp_parser* parser) { return parser->allow_gnu_extensions_p; } /* Objective-C++ Productions */ /* Parse an Objective-C expression, which feeds into a primary-expression above. objc-expression: objc-message-expression objc-string-literal objc-encode-expression objc-protocol-expression objc-selector-expression Returns a tree representation of the expression. */ static tree cp_parser_objc_expression (cp_parser* parser) { /* Try to figure out what kind of declaration is present. */ cp_token *kwd = cp_lexer_peek_token (parser->lexer); switch (kwd->type) { case CPP_OPEN_SQUARE: return cp_parser_objc_message_expression (parser); case CPP_OBJC_STRING: kwd = cp_lexer_consume_token (parser->lexer); return objc_build_string_object (kwd->u.value); case CPP_KEYWORD: switch (kwd->keyword) { case RID_AT_ENCODE: return cp_parser_objc_encode_expression (parser); case RID_AT_PROTOCOL: return cp_parser_objc_protocol_expression (parser); case RID_AT_SELECTOR: return cp_parser_objc_selector_expression (parser); default: break; } default: error ("misplaced %<@%D%> Objective-C++ construct", kwd->u.value); cp_parser_skip_to_end_of_block_or_statement (parser); } return error_mark_node; } /* Parse an Objective-C message expression. objc-message-expression: [ objc-message-receiver objc-message-args ] Returns a representation of an Objective-C message. */ static tree cp_parser_objc_message_expression (cp_parser* parser) { tree receiver, messageargs; cp_lexer_consume_token (parser->lexer); /* Eat '['. */ receiver = cp_parser_objc_message_receiver (parser); messageargs = cp_parser_objc_message_args (parser); cp_parser_require (parser, CPP_CLOSE_SQUARE, "`]'"); return objc_build_message_expr (build_tree_list (receiver, messageargs)); } /* Parse an objc-message-receiver. objc-message-receiver: expression simple-type-specifier Returns a representation of the type or expression. */ static tree cp_parser_objc_message_receiver (cp_parser* parser) { tree rcv; /* An Objective-C message receiver may be either (1) a type or (2) an expression. */ cp_parser_parse_tentatively (parser); rcv = cp_parser_expression (parser, false); if (cp_parser_parse_definitely (parser)) return rcv; rcv = cp_parser_simple_type_specifier (parser, /*decl_specs=*/NULL, CP_PARSER_FLAGS_NONE); return objc_get_class_reference (rcv); } /* Parse the arguments and selectors comprising an Objective-C message. objc-message-args: objc-selector objc-selector-args objc-selector-args , objc-comma-args objc-selector-args: objc-selector [opt] : assignment-expression objc-selector-args objc-selector [opt] : assignment-expression objc-comma-args: assignment-expression objc-comma-args , assignment-expression Returns a TREE_LIST, with TREE_PURPOSE containing a list of selector arguments and TREE_VALUE containing a list of comma arguments. */ static tree cp_parser_objc_message_args (cp_parser* parser) { tree sel_args = NULL_TREE, addl_args = NULL_TREE; bool maybe_unary_selector_p = true; cp_token *token = cp_lexer_peek_token (parser->lexer); while (cp_parser_objc_selector_p (token->type) || token->type == CPP_COLON) { tree selector = NULL_TREE, arg; if (token->type != CPP_COLON) selector = cp_parser_objc_selector (parser); /* Detect if we have a unary selector. */ if (maybe_unary_selector_p && cp_lexer_next_token_is_not (parser->lexer, CPP_COLON)) return build_tree_list (selector, NULL_TREE); maybe_unary_selector_p = false; cp_parser_require (parser, CPP_COLON, "`:'"); arg = cp_parser_assignment_expression (parser, false); sel_args = chainon (sel_args, build_tree_list (selector, arg)); token = cp_lexer_peek_token (parser->lexer); } /* Handle non-selector arguments, if any. */ while (token->type == CPP_COMMA) { tree arg; cp_lexer_consume_token (parser->lexer); arg = cp_parser_assignment_expression (parser, false); addl_args = chainon (addl_args, build_tree_list (NULL_TREE, arg)); token = cp_lexer_peek_token (parser->lexer); } return build_tree_list (sel_args, addl_args); } /* Parse an Objective-C encode expression. objc-encode-expression: @encode objc-typename Returns an encoded representation of the type argument. */ static tree cp_parser_objc_encode_expression (cp_parser* parser) { tree type; cp_lexer_consume_token (parser->lexer); /* Eat '@encode'. */ cp_parser_require (parser, CPP_OPEN_PAREN, "`('"); type = complete_type (cp_parser_type_id (parser)); cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'"); if (!type) { error ("%<@encode%> must specify a type as an argument"); return error_mark_node; } return objc_build_encode_expr (type); } /* Parse an Objective-C @defs expression. */ static tree cp_parser_objc_defs_expression (cp_parser *parser) { tree name; cp_lexer_consume_token (parser->lexer); /* Eat '@defs'. */ cp_parser_require (parser, CPP_OPEN_PAREN, "`('"); name = cp_parser_identifier (parser); cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'"); return objc_get_class_ivars (name); } /* Parse an Objective-C protocol expression. objc-protocol-expression: @protocol ( identifier ) Returns a representation of the protocol expression. */ static tree cp_parser_objc_protocol_expression (cp_parser* parser) { tree proto; cp_lexer_consume_token (parser->lexer); /* Eat '@protocol'. */ cp_parser_require (parser, CPP_OPEN_PAREN, "`('"); proto = cp_parser_identifier (parser); cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'"); return objc_build_protocol_expr (proto); } /* Parse an Objective-C selector expression. objc-selector-expression: @selector ( objc-method-signature ) objc-method-signature: objc-selector objc-selector-seq objc-selector-seq: objc-selector : objc-selector-seq objc-selector : Returns a representation of the method selector. */ static tree cp_parser_objc_selector_expression (cp_parser* parser) { tree sel_seq = NULL_TREE; bool maybe_unary_selector_p = true; cp_token *token; cp_lexer_consume_token (parser->lexer); /* Eat '@selector'. */ cp_parser_require (parser, CPP_OPEN_PAREN, "`('"); token = cp_lexer_peek_token (parser->lexer); while (cp_parser_objc_selector_p (token->type) || token->type == CPP_COLON || token->type == CPP_SCOPE) { tree selector = NULL_TREE; if (token->type != CPP_COLON || token->type == CPP_SCOPE) selector = cp_parser_objc_selector (parser); if (cp_lexer_next_token_is_not (parser->lexer, CPP_COLON) && cp_lexer_next_token_is_not (parser->lexer, CPP_SCOPE)) { /* Detect if we have a unary selector. */ if (maybe_unary_selector_p) { sel_seq = selector; goto finish_selector; } else { cp_parser_error (parser, "expected %<:%>"); } } maybe_unary_selector_p = false; token = cp_lexer_consume_token (parser->lexer); if (token->type == CPP_SCOPE) { sel_seq = chainon (sel_seq, build_tree_list (selector, NULL_TREE)); sel_seq = chainon (sel_seq, build_tree_list (NULL_TREE, NULL_TREE)); } else sel_seq = chainon (sel_seq, build_tree_list (selector, NULL_TREE)); token = cp_lexer_peek_token (parser->lexer); } finish_selector: cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'"); return objc_build_selector_expr (sel_seq); } /* Parse a list of identifiers. objc-identifier-list: identifier objc-identifier-list , identifier Returns a TREE_LIST of identifier nodes. */ static tree cp_parser_objc_identifier_list (cp_parser* parser) { tree list = build_tree_list (NULL_TREE, cp_parser_identifier (parser)); cp_token *sep = cp_lexer_peek_token (parser->lexer); while (sep->type == CPP_COMMA) { cp_lexer_consume_token (parser->lexer); /* Eat ','. */ list = chainon (list, build_tree_list (NULL_TREE, cp_parser_identifier (parser))); sep = cp_lexer_peek_token (parser->lexer); } return list; } /* Parse an Objective-C alias declaration. objc-alias-declaration: @compatibility_alias identifier identifier ; This function registers the alias mapping with the Objective-C front-end. It returns nothing. */ static void cp_parser_objc_alias_declaration (cp_parser* parser) { tree alias, orig; cp_lexer_consume_token (parser->lexer); /* Eat '@compatibility_alias'. */ alias = cp_parser_identifier (parser); orig = cp_parser_identifier (parser); objc_declare_alias (alias, orig); cp_parser_consume_semicolon_at_end_of_statement (parser); } /* Parse an Objective-C class forward-declaration. objc-class-declaration: @class objc-identifier-list ; The function registers the forward declarations with the Objective-C front-end. It returns nothing. */ static void cp_parser_objc_class_declaration (cp_parser* parser) { cp_lexer_consume_token (parser->lexer); /* Eat '@class'. */ objc_declare_class (cp_parser_objc_identifier_list (parser)); cp_parser_consume_semicolon_at_end_of_statement (parser); } /* Parse a list of Objective-C protocol references. objc-protocol-refs-opt: objc-protocol-refs [opt] objc-protocol-refs: < objc-identifier-list > Returns a TREE_LIST of identifiers, if any. */ static tree cp_parser_objc_protocol_refs_opt (cp_parser* parser) { tree protorefs = NULL_TREE; if(cp_lexer_next_token_is (parser->lexer, CPP_LESS)) { cp_lexer_consume_token (parser->lexer); /* Eat '<'. */ protorefs = cp_parser_objc_identifier_list (parser); cp_parser_require (parser, CPP_GREATER, "`>'"); } return protorefs; } /* Parse a Objective-C visibility specification. */ static void cp_parser_objc_visibility_spec (cp_parser* parser) { cp_token *vis = cp_lexer_peek_token (parser->lexer); switch (vis->keyword) { case RID_AT_PRIVATE: objc_set_visibility (2); break; case RID_AT_PROTECTED: objc_set_visibility (0); break; case RID_AT_PUBLIC: objc_set_visibility (1); break; default: return; } /* Eat '@private'/'@protected'/'@public'. */ cp_lexer_consume_token (parser->lexer); } /* Parse an Objective-C method type. */ static void cp_parser_objc_method_type (cp_parser* parser) { objc_set_method_type (cp_lexer_consume_token (parser->lexer)->type == CPP_PLUS ? PLUS_EXPR : MINUS_EXPR); } /* Parse an Objective-C protocol qualifier. */ static tree cp_parser_objc_protocol_qualifiers (cp_parser* parser) { tree quals = NULL_TREE, node; cp_token *token = cp_lexer_peek_token (parser->lexer); node = token->u.value; while (node && TREE_CODE (node) == IDENTIFIER_NODE && (node == ridpointers [(int) RID_IN] || node == ridpointers [(int) RID_OUT] || node == ridpointers [(int) RID_INOUT] || node == ridpointers [(int) RID_BYCOPY] || node == ridpointers [(int) RID_BYREF] || node == ridpointers [(int) RID_ONEWAY])) { quals = tree_cons (NULL_TREE, node, quals); cp_lexer_consume_token (parser->lexer); token = cp_lexer_peek_token (parser->lexer); node = token->u.value; } return quals; } /* Parse an Objective-C typename. */ static tree cp_parser_objc_typename (cp_parser* parser) { tree typename = NULL_TREE; if (cp_lexer_next_token_is (parser->lexer, CPP_OPEN_PAREN)) { tree proto_quals, cp_type = NULL_TREE; cp_lexer_consume_token (parser->lexer); /* Eat '('. */ proto_quals = cp_parser_objc_protocol_qualifiers (parser); /* An ObjC type name may consist of just protocol qualifiers, in which case the type shall default to 'id'. */ if (cp_lexer_next_token_is_not (parser->lexer, CPP_CLOSE_PAREN)) cp_type = cp_parser_type_id (parser); cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'"); typename = build_tree_list (proto_quals, cp_type); } return typename; } /* Check to see if TYPE refers to an Objective-C selector name. */ static bool cp_parser_objc_selector_p (enum cpp_ttype type) { return (type == CPP_NAME || type == CPP_KEYWORD || type == CPP_AND_AND || type == CPP_AND_EQ || type == CPP_AND || type == CPP_OR || type == CPP_COMPL || type == CPP_NOT || type == CPP_NOT_EQ || type == CPP_OR_OR || type == CPP_OR_EQ || type == CPP_XOR || type == CPP_XOR_EQ); } /* Parse an Objective-C selector. */ static tree cp_parser_objc_selector (cp_parser* parser) { cp_token *token = cp_lexer_consume_token (parser->lexer); if (!cp_parser_objc_selector_p (token->type)) { error ("invalid Objective-C++ selector name"); return error_mark_node; } /* C++ operator names are allowed to appear in ObjC selectors. */ switch (token->type) { case CPP_AND_AND: return get_identifier ("and"); case CPP_AND_EQ: return get_identifier ("and_eq"); case CPP_AND: return get_identifier ("bitand"); case CPP_OR: return get_identifier ("bitor"); case CPP_COMPL: return get_identifier ("compl"); case CPP_NOT: return get_identifier ("not"); case CPP_NOT_EQ: return get_identifier ("not_eq"); case CPP_OR_OR: return get_identifier ("or"); case CPP_OR_EQ: return get_identifier ("or_eq"); case CPP_XOR: return get_identifier ("xor"); case CPP_XOR_EQ: return get_identifier ("xor_eq"); default: return token->u.value; } } /* Parse an Objective-C params list. */ static tree cp_parser_objc_method_keyword_params (cp_parser* parser) { tree params = NULL_TREE; bool maybe_unary_selector_p = true; cp_token *token = cp_lexer_peek_token (parser->lexer); while (cp_parser_objc_selector_p (token->type) || token->type == CPP_COLON) { tree selector = NULL_TREE, typename, identifier; if (token->type != CPP_COLON) selector = cp_parser_objc_selector (parser); /* Detect if we have a unary selector. */ if (maybe_unary_selector_p && cp_lexer_next_token_is_not (parser->lexer, CPP_COLON)) return selector; maybe_unary_selector_p = false; cp_parser_require (parser, CPP_COLON, "`:'"); typename = cp_parser_objc_typename (parser); identifier = cp_parser_identifier (parser); params = chainon (params, objc_build_keyword_decl (selector, typename, identifier)); token = cp_lexer_peek_token (parser->lexer); } return params; } /* Parse the non-keyword Objective-C params. */ static tree cp_parser_objc_method_tail_params_opt (cp_parser* parser, bool *ellipsisp) { tree params = make_node (TREE_LIST); cp_token *token = cp_lexer_peek_token (parser->lexer); *ellipsisp = false; /* Initially, assume no ellipsis. */ while (token->type == CPP_COMMA) { cp_parameter_declarator *parmdecl; tree parm; cp_lexer_consume_token (parser->lexer); /* Eat ','. */ token = cp_lexer_peek_token (parser->lexer); if (token->type == CPP_ELLIPSIS) { cp_lexer_consume_token (parser->lexer); /* Eat '...'. */ *ellipsisp = true; break; } parmdecl = cp_parser_parameter_declaration (parser, false, NULL); parm = grokdeclarator (parmdecl->declarator, &parmdecl->decl_specifiers, PARM, /*initialized=*/0, /*attrlist=*/NULL); chainon (params, build_tree_list (NULL_TREE, parm)); token = cp_lexer_peek_token (parser->lexer); } return params; } /* Parse a linkage specification, a pragma, an extra semicolon or a block. */ static void cp_parser_objc_interstitial_code (cp_parser* parser) { cp_token *token = cp_lexer_peek_token (parser->lexer); /* If the next token is `extern' and the following token is a string literal, then we have a linkage specification. */ if (token->keyword == RID_EXTERN && cp_parser_is_string_literal (cp_lexer_peek_nth_token (parser->lexer, 2))) cp_parser_linkage_specification (parser); /* Handle #pragma, if any. */ else if (token->type == CPP_PRAGMA) cp_parser_pragma (parser, pragma_external); /* Allow stray semicolons. */ else if (token->type == CPP_SEMICOLON) cp_lexer_consume_token (parser->lexer); /* Finally, try to parse a block-declaration, or a function-definition. */ else cp_parser_block_declaration (parser, /*statement_p=*/false); } /* Parse a method signature. */ static tree cp_parser_objc_method_signature (cp_parser* parser) { tree rettype, kwdparms, optparms; bool ellipsis = false; cp_parser_objc_method_type (parser); rettype = cp_parser_objc_typename (parser); kwdparms = cp_parser_objc_method_keyword_params (parser); optparms = cp_parser_objc_method_tail_params_opt (parser, &ellipsis); return objc_build_method_signature (rettype, kwdparms, optparms, ellipsis); } /* Pars an Objective-C method prototype list. */ static void cp_parser_objc_method_prototype_list (cp_parser* parser) { cp_token *token = cp_lexer_peek_token (parser->lexer); while (token->keyword != RID_AT_END) { if (token->type == CPP_PLUS || token->type == CPP_MINUS) { objc_add_method_declaration (cp_parser_objc_method_signature (parser)); cp_parser_consume_semicolon_at_end_of_statement (parser); } else /* Allow for interspersed non-ObjC++ code. */ cp_parser_objc_interstitial_code (parser); token = cp_lexer_peek_token (parser->lexer); } cp_lexer_consume_token (parser->lexer); /* Eat '@end'. */ objc_finish_interface (); } /* Parse an Objective-C method definition list. */ static void cp_parser_objc_method_definition_list (cp_parser* parser) { cp_token *token = cp_lexer_peek_token (parser->lexer); while (token->keyword != RID_AT_END) { tree meth; if (token->type == CPP_PLUS || token->type == CPP_MINUS) { push_deferring_access_checks (dk_deferred); objc_start_method_definition (cp_parser_objc_method_signature (parser)); /* For historical reasons, we accept an optional semicolon. */ if (cp_lexer_next_token_is (parser->lexer, CPP_SEMICOLON)) cp_lexer_consume_token (parser->lexer); perform_deferred_access_checks (); stop_deferring_access_checks (); meth = cp_parser_function_definition_after_declarator (parser, false); pop_deferring_access_checks (); objc_finish_method_definition (meth); } else /* Allow for interspersed non-ObjC++ code. */ cp_parser_objc_interstitial_code (parser); token = cp_lexer_peek_token (parser->lexer); } cp_lexer_consume_token (parser->lexer); /* Eat '@end'. */ objc_finish_implementation (); } /* Parse Objective-C ivars. */ static void cp_parser_objc_class_ivars (cp_parser* parser) { cp_token *token = cp_lexer_peek_token (parser->lexer); if (token->type != CPP_OPEN_BRACE) return; /* No ivars specified. */ cp_lexer_consume_token (parser->lexer); /* Eat '{'. */ token = cp_lexer_peek_token (parser->lexer); while (token->type != CPP_CLOSE_BRACE) { cp_decl_specifier_seq declspecs; int decl_class_or_enum_p; tree prefix_attributes; cp_parser_objc_visibility_spec (parser); if (cp_lexer_next_token_is (parser->lexer, CPP_CLOSE_BRACE)) break; cp_parser_decl_specifier_seq (parser, CP_PARSER_FLAGS_OPTIONAL, &declspecs, &decl_class_or_enum_p); prefix_attributes = declspecs.attributes; declspecs.attributes = NULL_TREE; /* Keep going until we hit the `;' at the end of the declaration. */ while (cp_lexer_next_token_is_not (parser->lexer, CPP_SEMICOLON)) { tree width = NULL_TREE, attributes, first_attribute, decl; cp_declarator *declarator = NULL; int ctor_dtor_or_conv_p; /* Check for a (possibly unnamed) bitfield declaration. */ token = cp_lexer_peek_token (parser->lexer); if (token->type == CPP_COLON) goto eat_colon; if (token->type == CPP_NAME && (cp_lexer_peek_nth_token (parser->lexer, 2)->type == CPP_COLON)) { /* Get the name of the bitfield. */ declarator = make_id_declarator (NULL_TREE, cp_parser_identifier (parser), sfk_none); eat_colon: cp_lexer_consume_token (parser->lexer); /* Eat ':'. */ /* Get the width of the bitfield. */ width = cp_parser_constant_expression (parser, /*allow_non_constant=*/false, NULL); } else { /* Parse the declarator. */ declarator = cp_parser_declarator (parser, CP_PARSER_DECLARATOR_NAMED, &ctor_dtor_or_conv_p, /*parenthesized_p=*/NULL, /*member_p=*/false); } /* Look for attributes that apply to the ivar. */ attributes = cp_parser_attributes_opt (parser); /* Remember which attributes are prefix attributes and which are not. */ first_attribute = attributes; /* Combine the attributes. */ attributes = chainon (prefix_attributes, attributes); if (width) { /* Create the bitfield declaration. */ decl = grokbitfield (declarator, &declspecs, width); cplus_decl_attributes (&decl, attributes, /*flags=*/0); } else decl = grokfield (declarator, &declspecs, NULL_TREE, /*init_const_expr_p=*/false, NULL_TREE, attributes); /* Add the instance variable. */ objc_add_instance_variable (decl); /* Reset PREFIX_ATTRIBUTES. */ while (attributes && TREE_CHAIN (attributes) != first_attribute) attributes = TREE_CHAIN (attributes); if (attributes) TREE_CHAIN (attributes) = NULL_TREE; token = cp_lexer_peek_token (parser->lexer); if (token->type == CPP_COMMA) { cp_lexer_consume_token (parser->lexer); /* Eat ','. */ continue; } break; } cp_parser_consume_semicolon_at_end_of_statement (parser); token = cp_lexer_peek_token (parser->lexer); } cp_lexer_consume_token (parser->lexer); /* Eat '}'. */ /* For historical reasons, we accept an optional semicolon. */ if (cp_lexer_next_token_is (parser->lexer, CPP_SEMICOLON)) cp_lexer_consume_token (parser->lexer); } /* Parse an Objective-C protocol declaration. */ static void cp_parser_objc_protocol_declaration (cp_parser* parser) { tree proto, protorefs; cp_token *tok; cp_lexer_consume_token (parser->lexer); /* Eat '@protocol'. */ if (cp_lexer_next_token_is_not (parser->lexer, CPP_NAME)) { error ("identifier expected after %<@protocol%>"); goto finish; } /* See if we have a forward declaration or a definition. */ tok = cp_lexer_peek_nth_token (parser->lexer, 2); /* Try a forward declaration first. */ if (tok->type == CPP_COMMA || tok->type == CPP_SEMICOLON) { objc_declare_protocols (cp_parser_objc_identifier_list (parser)); finish: cp_parser_consume_semicolon_at_end_of_statement (parser); } /* Ok, we got a full-fledged definition (or at least should). */ else { proto = cp_parser_identifier (parser); protorefs = cp_parser_objc_protocol_refs_opt (parser); objc_start_protocol (proto, protorefs); cp_parser_objc_method_prototype_list (parser); } } /* Parse an Objective-C superclass or category. */ static void cp_parser_objc_superclass_or_category (cp_parser *parser, tree *super, tree *categ) { cp_token *next = cp_lexer_peek_token (parser->lexer); *super = *categ = NULL_TREE; if (next->type == CPP_COLON) { cp_lexer_consume_token (parser->lexer); /* Eat ':'. */ *super = cp_parser_identifier (parser); } else if (next->type == CPP_OPEN_PAREN) { cp_lexer_consume_token (parser->lexer); /* Eat '('. */ *categ = cp_parser_identifier (parser); cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'"); } } /* Parse an Objective-C class interface. */ static void cp_parser_objc_class_interface (cp_parser* parser) { tree name, super, categ, protos; cp_lexer_consume_token (parser->lexer); /* Eat '@interface'. */ name = cp_parser_identifier (parser); cp_parser_objc_superclass_or_category (parser, &super, &categ); protos = cp_parser_objc_protocol_refs_opt (parser); /* We have either a class or a category on our hands. */ if (categ) objc_start_category_interface (name, categ, protos); else { objc_start_class_interface (name, super, protos); /* Handle instance variable declarations, if any. */ cp_parser_objc_class_ivars (parser); objc_continue_interface (); } cp_parser_objc_method_prototype_list (parser); } /* Parse an Objective-C class implementation. */ static void cp_parser_objc_class_implementation (cp_parser* parser) { tree name, super, categ; cp_lexer_consume_token (parser->lexer); /* Eat '@implementation'. */ name = cp_parser_identifier (parser); cp_parser_objc_superclass_or_category (parser, &super, &categ); /* We have either a class or a category on our hands. */ if (categ) objc_start_category_implementation (name, categ); else { objc_start_class_implementation (name, super); /* Handle instance variable declarations, if any. */ cp_parser_objc_class_ivars (parser); objc_continue_implementation (); } cp_parser_objc_method_definition_list (parser); } /* Consume the @end token and finish off the implementation. */ static void cp_parser_objc_end_implementation (cp_parser* parser) { cp_lexer_consume_token (parser->lexer); /* Eat '@end'. */ objc_finish_implementation (); } /* Parse an Objective-C declaration. */ static void cp_parser_objc_declaration (cp_parser* parser) { /* Try to figure out what kind of declaration is present. */ cp_token *kwd = cp_lexer_peek_token (parser->lexer); switch (kwd->keyword) { case RID_AT_ALIAS: cp_parser_objc_alias_declaration (parser); break; case RID_AT_CLASS: cp_parser_objc_class_declaration (parser); break; case RID_AT_PROTOCOL: cp_parser_objc_protocol_declaration (parser); break; case RID_AT_INTERFACE: cp_parser_objc_class_interface (parser); break; case RID_AT_IMPLEMENTATION: cp_parser_objc_class_implementation (parser); break; case RID_AT_END: cp_parser_objc_end_implementation (parser); break; default: error ("misplaced %<@%D%> Objective-C++ construct", kwd->u.value); cp_parser_skip_to_end_of_block_or_statement (parser); } } /* Parse an Objective-C try-catch-finally statement. objc-try-catch-finally-stmt: @try compound-statement objc-catch-clause-seq [opt] objc-finally-clause [opt] objc-catch-clause-seq: objc-catch-clause objc-catch-clause-seq [opt] objc-catch-clause: @catch ( exception-declaration ) compound-statement objc-finally-clause @finally compound-statement Returns NULL_TREE. */ static tree cp_parser_objc_try_catch_finally_statement (cp_parser *parser) { location_t location; tree stmt; cp_parser_require_keyword (parser, RID_AT_TRY, "`@try'"); location = cp_lexer_peek_token (parser->lexer)->location; /* NB: The @try block needs to be wrapped in its own STATEMENT_LIST node, lest it get absorbed into the surrounding block. */ stmt = push_stmt_list (); cp_parser_compound_statement (parser, NULL, false); objc_begin_try_stmt (location, pop_stmt_list (stmt)); while (cp_lexer_next_token_is_keyword (parser->lexer, RID_AT_CATCH)) { cp_parameter_declarator *parmdecl; tree parm; cp_lexer_consume_token (parser->lexer); cp_parser_require (parser, CPP_OPEN_PAREN, "`('"); parmdecl = cp_parser_parameter_declaration (parser, false, NULL); parm = grokdeclarator (parmdecl->declarator, &parmdecl->decl_specifiers, PARM, /*initialized=*/0, /*attrlist=*/NULL); cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'"); objc_begin_catch_clause (parm); cp_parser_compound_statement (parser, NULL, false); objc_finish_catch_clause (); } if (cp_lexer_next_token_is_keyword (parser->lexer, RID_AT_FINALLY)) { cp_lexer_consume_token (parser->lexer); location = cp_lexer_peek_token (parser->lexer)->location; /* NB: The @finally block needs to be wrapped in its own STATEMENT_LIST node, lest it get absorbed into the surrounding block. */ stmt = push_stmt_list (); cp_parser_compound_statement (parser, NULL, false); objc_build_finally_clause (location, pop_stmt_list (stmt)); } return objc_finish_try_stmt (); } /* Parse an Objective-C synchronized statement. objc-synchronized-stmt: @synchronized ( expression ) compound-statement Returns NULL_TREE. */ static tree cp_parser_objc_synchronized_statement (cp_parser *parser) { location_t location; tree lock, stmt; cp_parser_require_keyword (parser, RID_AT_SYNCHRONIZED, "`@synchronized'"); location = cp_lexer_peek_token (parser->lexer)->location; cp_parser_require (parser, CPP_OPEN_PAREN, "`('"); lock = cp_parser_expression (parser, false); cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'"); /* NB: The @synchronized block needs to be wrapped in its own STATEMENT_LIST node, lest it get absorbed into the surrounding block. */ stmt = push_stmt_list (); cp_parser_compound_statement (parser, NULL, false); return objc_build_synchronized (location, lock, pop_stmt_list (stmt)); } /* Parse an Objective-C throw statement. objc-throw-stmt: @throw assignment-expression [opt] ; Returns a constructed '@throw' statement. */ static tree cp_parser_objc_throw_statement (cp_parser *parser) { tree expr = NULL_TREE; cp_parser_require_keyword (parser, RID_AT_THROW, "`@throw'"); if (cp_lexer_next_token_is_not (parser->lexer, CPP_SEMICOLON)) expr = cp_parser_assignment_expression (parser, false); cp_parser_consume_semicolon_at_end_of_statement (parser); return objc_build_throw_stmt (expr); } /* Parse an Objective-C statement. */ static tree cp_parser_objc_statement (cp_parser * parser) { /* Try to figure out what kind of declaration is present. */ cp_token *kwd = cp_lexer_peek_token (parser->lexer); switch (kwd->keyword) { case RID_AT_TRY: return cp_parser_objc_try_catch_finally_statement (parser); case RID_AT_SYNCHRONIZED: return cp_parser_objc_synchronized_statement (parser); case RID_AT_THROW: return cp_parser_objc_throw_statement (parser); default: error ("misplaced %<@%D%> Objective-C++ construct", kwd->u.value); cp_parser_skip_to_end_of_block_or_statement (parser); } return error_mark_node; } /* OpenMP 2.5 parsing routines. */ /* All OpenMP clauses. OpenMP 2.5. */ typedef enum pragma_omp_clause { PRAGMA_OMP_CLAUSE_NONE = 0, PRAGMA_OMP_CLAUSE_COPYIN, PRAGMA_OMP_CLAUSE_COPYPRIVATE, PRAGMA_OMP_CLAUSE_DEFAULT, PRAGMA_OMP_CLAUSE_FIRSTPRIVATE, PRAGMA_OMP_CLAUSE_IF, PRAGMA_OMP_CLAUSE_LASTPRIVATE, PRAGMA_OMP_CLAUSE_NOWAIT, PRAGMA_OMP_CLAUSE_NUM_THREADS, PRAGMA_OMP_CLAUSE_ORDERED, PRAGMA_OMP_CLAUSE_PRIVATE, PRAGMA_OMP_CLAUSE_REDUCTION, PRAGMA_OMP_CLAUSE_SCHEDULE, PRAGMA_OMP_CLAUSE_SHARED } pragma_omp_clause; /* Returns name of the next clause. If the clause is not recognized PRAGMA_OMP_CLAUSE_NONE is returned and the token is not consumed. Otherwise appropriate pragma_omp_clause is returned and the token is consumed. */ static pragma_omp_clause cp_parser_omp_clause_name (cp_parser *parser) { pragma_omp_clause result = PRAGMA_OMP_CLAUSE_NONE; if (cp_lexer_next_token_is_keyword (parser->lexer, RID_IF)) result = PRAGMA_OMP_CLAUSE_IF; else if (cp_lexer_next_token_is_keyword (parser->lexer, RID_DEFAULT)) result = PRAGMA_OMP_CLAUSE_DEFAULT; else if (cp_lexer_next_token_is_keyword (parser->lexer, RID_PRIVATE)) result = PRAGMA_OMP_CLAUSE_PRIVATE; else if (cp_lexer_next_token_is (parser->lexer, CPP_NAME)) { tree id = cp_lexer_peek_token (parser->lexer)->u.value; const char *p = IDENTIFIER_POINTER (id); switch (p[0]) { case 'c': if (!strcmp ("copyin", p)) result = PRAGMA_OMP_CLAUSE_COPYIN; else if (!strcmp ("copyprivate", p)) result = PRAGMA_OMP_CLAUSE_COPYPRIVATE; break; case 'f': if (!strcmp ("firstprivate", p)) result = PRAGMA_OMP_CLAUSE_FIRSTPRIVATE; break; case 'l': if (!strcmp ("lastprivate", p)) result = PRAGMA_OMP_CLAUSE_LASTPRIVATE; break; case 'n': if (!strcmp ("nowait", p)) result = PRAGMA_OMP_CLAUSE_NOWAIT; else if (!strcmp ("num_threads", p)) result = PRAGMA_OMP_CLAUSE_NUM_THREADS; break; case 'o': if (!strcmp ("ordered", p)) result = PRAGMA_OMP_CLAUSE_ORDERED; break; case 'r': if (!strcmp ("reduction", p)) result = PRAGMA_OMP_CLAUSE_REDUCTION; break; case 's': if (!strcmp ("schedule", p)) result = PRAGMA_OMP_CLAUSE_SCHEDULE; else if (!strcmp ("shared", p)) result = PRAGMA_OMP_CLAUSE_SHARED; break; } } if (result != PRAGMA_OMP_CLAUSE_NONE) cp_lexer_consume_token (parser->lexer); return result; } /* Validate that a clause of the given type does not already exist. */ static void check_no_duplicate_clause (tree clauses, enum tree_code code, const char *name) { tree c; for (c = clauses; c ; c = OMP_CLAUSE_CHAIN (c)) if (OMP_CLAUSE_CODE (c) == code) { error ("too many %qs clauses", name); break; } } /* OpenMP 2.5: variable-list: identifier variable-list , identifier In addition, we match a closing parenthesis. An opening parenthesis will have been consumed by the caller. If KIND is nonzero, create the appropriate node and install the decl in OMP_CLAUSE_DECL and add the node to the head of the list. If KIND is zero, create a TREE_LIST with the decl in TREE_PURPOSE; return the list created. */ static tree cp_parser_omp_var_list_no_open (cp_parser *parser, enum omp_clause_code kind, tree list) { while (1) { tree name, decl; name = cp_parser_id_expression (parser, /*template_p=*/false, /*check_dependency_p=*/true, /*template_p=*/NULL, /*declarator_p=*/false, /*optional_p=*/false); if (name == error_mark_node) goto skip_comma; decl = cp_parser_lookup_name_simple (parser, name); if (decl == error_mark_node) cp_parser_name_lookup_error (parser, name, decl, NULL); else if (kind != 0) { tree u = build_omp_clause (kind); OMP_CLAUSE_DECL (u) = decl; OMP_CLAUSE_CHAIN (u) = list; list = u; } else list = tree_cons (decl, NULL_TREE, list); get_comma: if (cp_lexer_next_token_is_not (parser->lexer, CPP_COMMA)) break; cp_lexer_consume_token (parser->lexer); } if (!cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'")) { int ending; /* Try to resync to an unnested comma. Copied from cp_parser_parenthesized_expression_list. */ skip_comma: ending = cp_parser_skip_to_closing_parenthesis (parser, /*recovering=*/true, /*or_comma=*/true, /*consume_paren=*/true); if (ending < 0) goto get_comma; } return list; } /* Similarly, but expect leading and trailing parenthesis. This is a very common case for omp clauses. */ static tree cp_parser_omp_var_list (cp_parser *parser, enum omp_clause_code kind, tree list) { if (cp_parser_require (parser, CPP_OPEN_PAREN, "`('")) return cp_parser_omp_var_list_no_open (parser, kind, list); return list; } /* OpenMP 2.5: default ( shared | none ) */ static tree cp_parser_omp_clause_default (cp_parser *parser, tree list) { enum omp_clause_default_kind kind = OMP_CLAUSE_DEFAULT_UNSPECIFIED; tree c; if (!cp_parser_require (parser, CPP_OPEN_PAREN, "`('")) return list; if (cp_lexer_next_token_is (parser->lexer, CPP_NAME)) { tree id = cp_lexer_peek_token (parser->lexer)->u.value; const char *p = IDENTIFIER_POINTER (id); switch (p[0]) { case 'n': if (strcmp ("none", p) != 0) goto invalid_kind; kind = OMP_CLAUSE_DEFAULT_NONE; break; case 's': if (strcmp ("shared", p) != 0) goto invalid_kind; kind = OMP_CLAUSE_DEFAULT_SHARED; break; default: goto invalid_kind; } cp_lexer_consume_token (parser->lexer); } else { invalid_kind: cp_parser_error (parser, "expected %<none%> or %<shared%>"); } if (!cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'")) cp_parser_skip_to_closing_parenthesis (parser, /*recovering=*/true, /*or_comma=*/false, /*consume_paren=*/true); if (kind == OMP_CLAUSE_DEFAULT_UNSPECIFIED) return list; check_no_duplicate_clause (list, OMP_CLAUSE_DEFAULT, "default"); c = build_omp_clause (OMP_CLAUSE_DEFAULT); OMP_CLAUSE_CHAIN (c) = list; OMP_CLAUSE_DEFAULT_KIND (c) = kind; return c; } /* OpenMP 2.5: if ( expression ) */ static tree cp_parser_omp_clause_if (cp_parser *parser, tree list) { tree t, c; if (!cp_parser_require (parser, CPP_OPEN_PAREN, "`('")) return list; t = cp_parser_condition (parser); if (t == error_mark_node || !cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'")) cp_parser_skip_to_closing_parenthesis (parser, /*recovering=*/true, /*or_comma=*/false, /*consume_paren=*/true); check_no_duplicate_clause (list, OMP_CLAUSE_IF, "if"); c = build_omp_clause (OMP_CLAUSE_IF); OMP_CLAUSE_IF_EXPR (c) = t; OMP_CLAUSE_CHAIN (c) = list; return c; } /* OpenMP 2.5: nowait */ static tree cp_parser_omp_clause_nowait (cp_parser *parser ATTRIBUTE_UNUSED, tree list) { tree c; check_no_duplicate_clause (list, OMP_CLAUSE_NOWAIT, "nowait"); c = build_omp_clause (OMP_CLAUSE_NOWAIT); OMP_CLAUSE_CHAIN (c) = list; return c; } /* OpenMP 2.5: num_threads ( expression ) */ static tree cp_parser_omp_clause_num_threads (cp_parser *parser, tree list) { tree t, c; if (!cp_parser_require (parser, CPP_OPEN_PAREN, "`('")) return list; t = cp_parser_expression (parser, false); if (t == error_mark_node || !cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'")) cp_parser_skip_to_closing_parenthesis (parser, /*recovering=*/true, /*or_comma=*/false, /*consume_paren=*/true); check_no_duplicate_clause (list, OMP_CLAUSE_NUM_THREADS, "num_threads"); c = build_omp_clause (OMP_CLAUSE_NUM_THREADS); OMP_CLAUSE_NUM_THREADS_EXPR (c) = t; OMP_CLAUSE_CHAIN (c) = list; return c; } /* OpenMP 2.5: ordered */ static tree cp_parser_omp_clause_ordered (cp_parser *parser ATTRIBUTE_UNUSED, tree list) { tree c; check_no_duplicate_clause (list, OMP_CLAUSE_ORDERED, "ordered"); c = build_omp_clause (OMP_CLAUSE_ORDERED); OMP_CLAUSE_CHAIN (c) = list; return c; } /* OpenMP 2.5: reduction ( reduction-operator : variable-list ) reduction-operator: One of: + * - & ^ | && || */ static tree cp_parser_omp_clause_reduction (cp_parser *parser, tree list) { enum tree_code code; tree nlist, c; if (!cp_parser_require (parser, CPP_OPEN_PAREN, "`('")) return list; switch (cp_lexer_peek_token (parser->lexer)->type) { case CPP_PLUS: code = PLUS_EXPR; break; case CPP_MULT: code = MULT_EXPR; break; case CPP_MINUS: code = MINUS_EXPR; break; case CPP_AND: code = BIT_AND_EXPR; break; case CPP_XOR: code = BIT_XOR_EXPR; break; case CPP_OR: code = BIT_IOR_EXPR; break; case CPP_AND_AND: code = TRUTH_ANDIF_EXPR; break; case CPP_OR_OR: code = TRUTH_ORIF_EXPR; break; default: cp_parser_error (parser, "`+', `*', `-', `&', `^', `|', `&&', or `||'"); resync_fail: cp_parser_skip_to_closing_parenthesis (parser, /*recovering=*/true, /*or_comma=*/false, /*consume_paren=*/true); return list; } cp_lexer_consume_token (parser->lexer); if (!cp_parser_require (parser, CPP_COLON, "`:'")) goto resync_fail; nlist = cp_parser_omp_var_list_no_open (parser, OMP_CLAUSE_REDUCTION, list); for (c = nlist; c != list; c = OMP_CLAUSE_CHAIN (c)) OMP_CLAUSE_REDUCTION_CODE (c) = code; return nlist; } /* OpenMP 2.5: schedule ( schedule-kind ) schedule ( schedule-kind , expression ) schedule-kind: static | dynamic | guided | runtime */ static tree cp_parser_omp_clause_schedule (cp_parser *parser, tree list) { tree c, t; if (!cp_parser_require (parser, CPP_OPEN_PAREN, "expected %<(%>")) return list; c = build_omp_clause (OMP_CLAUSE_SCHEDULE); if (cp_lexer_next_token_is (parser->lexer, CPP_NAME)) { tree id = cp_lexer_peek_token (parser->lexer)->u.value; const char *p = IDENTIFIER_POINTER (id); switch (p[0]) { case 'd': if (strcmp ("dynamic", p) != 0) goto invalid_kind; OMP_CLAUSE_SCHEDULE_KIND (c) = OMP_CLAUSE_SCHEDULE_DYNAMIC; break; case 'g': if (strcmp ("guided", p) != 0) goto invalid_kind; OMP_CLAUSE_SCHEDULE_KIND (c) = OMP_CLAUSE_SCHEDULE_GUIDED; break; case 'r': if (strcmp ("runtime", p) != 0) goto invalid_kind; OMP_CLAUSE_SCHEDULE_KIND (c) = OMP_CLAUSE_SCHEDULE_RUNTIME; break; default: goto invalid_kind; } } else if (cp_lexer_next_token_is_keyword (parser->lexer, RID_STATIC)) OMP_CLAUSE_SCHEDULE_KIND (c) = OMP_CLAUSE_SCHEDULE_STATIC; else goto invalid_kind; cp_lexer_consume_token (parser->lexer); if (cp_lexer_next_token_is (parser->lexer, CPP_COMMA)) { cp_lexer_consume_token (parser->lexer); t = cp_parser_assignment_expression (parser, false); if (t == error_mark_node) goto resync_fail; else if (OMP_CLAUSE_SCHEDULE_KIND (c) == OMP_CLAUSE_SCHEDULE_RUNTIME) error ("schedule %<runtime%> does not take " "a %<chunk_size%> parameter"); else OMP_CLAUSE_SCHEDULE_CHUNK_EXPR (c) = t; if (!cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'")) goto resync_fail; } else if (!cp_parser_require (parser, CPP_CLOSE_PAREN, "`,' or `)'")) goto resync_fail; check_no_duplicate_clause (list, OMP_CLAUSE_SCHEDULE, "schedule"); OMP_CLAUSE_CHAIN (c) = list; return c; invalid_kind: cp_parser_error (parser, "invalid schedule kind"); resync_fail: cp_parser_skip_to_closing_parenthesis (parser, /*recovering=*/true, /*or_comma=*/false, /*consume_paren=*/true); return list; } /* Parse all OpenMP clauses. The set clauses allowed by the directive is a bitmask in MASK. Return the list of clauses found; the result of clause default goes in *pdefault. */ static tree cp_parser_omp_all_clauses (cp_parser *parser, unsigned int mask, const char *where, cp_token *pragma_tok) { tree clauses = NULL; while (cp_lexer_next_token_is_not (parser->lexer, CPP_PRAGMA_EOL)) { pragma_omp_clause c_kind = cp_parser_omp_clause_name (parser); const char *c_name; tree prev = clauses; switch (c_kind) { case PRAGMA_OMP_CLAUSE_COPYIN: clauses = cp_parser_omp_var_list (parser, OMP_CLAUSE_COPYIN, clauses); c_name = "copyin"; break; case PRAGMA_OMP_CLAUSE_COPYPRIVATE: clauses = cp_parser_omp_var_list (parser, OMP_CLAUSE_COPYPRIVATE, clauses); c_name = "copyprivate"; break; case PRAGMA_OMP_CLAUSE_DEFAULT: clauses = cp_parser_omp_clause_default (parser, clauses); c_name = "default"; break; case PRAGMA_OMP_CLAUSE_FIRSTPRIVATE: clauses = cp_parser_omp_var_list (parser, OMP_CLAUSE_FIRSTPRIVATE, clauses); c_name = "firstprivate"; break; case PRAGMA_OMP_CLAUSE_IF: clauses = cp_parser_omp_clause_if (parser, clauses); c_name = "if"; break; case PRAGMA_OMP_CLAUSE_LASTPRIVATE: clauses = cp_parser_omp_var_list (parser, OMP_CLAUSE_LASTPRIVATE, clauses); c_name = "lastprivate"; break; case PRAGMA_OMP_CLAUSE_NOWAIT: clauses = cp_parser_omp_clause_nowait (parser, clauses); c_name = "nowait"; break; case PRAGMA_OMP_CLAUSE_NUM_THREADS: clauses = cp_parser_omp_clause_num_threads (parser, clauses); c_name = "num_threads"; break; case PRAGMA_OMP_CLAUSE_ORDERED: clauses = cp_parser_omp_clause_ordered (parser, clauses); c_name = "ordered"; break; case PRAGMA_OMP_CLAUSE_PRIVATE: clauses = cp_parser_omp_var_list (parser, OMP_CLAUSE_PRIVATE, clauses); c_name = "private"; break; case PRAGMA_OMP_CLAUSE_REDUCTION: clauses = cp_parser_omp_clause_reduction (parser, clauses); c_name = "reduction"; break; case PRAGMA_OMP_CLAUSE_SCHEDULE: clauses = cp_parser_omp_clause_schedule (parser, clauses); c_name = "schedule"; break; case PRAGMA_OMP_CLAUSE_SHARED: clauses = cp_parser_omp_var_list (parser, OMP_CLAUSE_SHARED, clauses); c_name = "shared"; break; default: cp_parser_error (parser, "expected %<#pragma omp%> clause"); goto saw_error; } if (((mask >> c_kind) & 1) == 0) { /* Remove the invalid clause(s) from the list to avoid confusing the rest of the compiler. */ clauses = prev; error ("%qs is not valid for %qs", c_name, where); } } saw_error: cp_parser_skip_to_pragma_eol (parser, pragma_tok); return finish_omp_clauses (clauses); } /* OpenMP 2.5: structured-block: statement In practice, we're also interested in adding the statement to an outer node. So it is convenient if we work around the fact that cp_parser_statement calls add_stmt. */ static unsigned cp_parser_begin_omp_structured_block (cp_parser *parser) { unsigned save = parser->in_statement; /* Only move the values to IN_OMP_BLOCK if they weren't false. This preserves the "not within loop or switch" style error messages for nonsense cases like void foo() { #pragma omp single break; } */ if (parser->in_statement) parser->in_statement = IN_OMP_BLOCK; return save; } static void cp_parser_end_omp_structured_block (cp_parser *parser, unsigned save) { parser->in_statement = save; } static tree cp_parser_omp_structured_block (cp_parser *parser) { tree stmt = begin_omp_structured_block (); unsigned int save = cp_parser_begin_omp_structured_block (parser); cp_parser_statement (parser, NULL_TREE, false); cp_parser_end_omp_structured_block (parser, save); return finish_omp_structured_block (stmt); } /* OpenMP 2.5: # pragma omp atomic new-line expression-stmt expression-stmt: x binop= expr | x++ | ++x | x-- | --x binop: +, *, -, /, &, ^, |, <<, >> where x is an lvalue expression with scalar type. */ static void cp_parser_omp_atomic (cp_parser *parser, cp_token *pragma_tok) { tree lhs, rhs; enum tree_code code; cp_parser_require_pragma_eol (parser, pragma_tok); lhs = cp_parser_unary_expression (parser, /*address_p=*/false, /*cast_p=*/false); switch (TREE_CODE (lhs)) { case ERROR_MARK: goto saw_error; case PREINCREMENT_EXPR: case POSTINCREMENT_EXPR: lhs = TREE_OPERAND (lhs, 0); code = PLUS_EXPR; rhs = integer_one_node; break; case PREDECREMENT_EXPR: case POSTDECREMENT_EXPR: lhs = TREE_OPERAND (lhs, 0); code = MINUS_EXPR; rhs = integer_one_node; break; default: switch (cp_lexer_peek_token (parser->lexer)->type) { case CPP_MULT_EQ: code = MULT_EXPR; break; case CPP_DIV_EQ: code = TRUNC_DIV_EXPR; break; case CPP_PLUS_EQ: code = PLUS_EXPR; break; case CPP_MINUS_EQ: code = MINUS_EXPR; break; case CPP_LSHIFT_EQ: code = LSHIFT_EXPR; break; case CPP_RSHIFT_EQ: code = RSHIFT_EXPR; break; case CPP_AND_EQ: code = BIT_AND_EXPR; break; case CPP_OR_EQ: code = BIT_IOR_EXPR; break; case CPP_XOR_EQ: code = BIT_XOR_EXPR; break; default: cp_parser_error (parser, "invalid operator for %<#pragma omp atomic%>"); goto saw_error; } cp_lexer_consume_token (parser->lexer); rhs = cp_parser_expression (parser, false); if (rhs == error_mark_node) goto saw_error; break; } finish_omp_atomic (code, lhs, rhs); cp_parser_consume_semicolon_at_end_of_statement (parser); return; saw_error: cp_parser_skip_to_end_of_block_or_statement (parser); } /* OpenMP 2.5: # pragma omp barrier new-line */ static void cp_parser_omp_barrier (cp_parser *parser, cp_token *pragma_tok) { cp_parser_require_pragma_eol (parser, pragma_tok); finish_omp_barrier (); } /* OpenMP 2.5: # pragma omp critical [(name)] new-line structured-block */ static tree cp_parser_omp_critical (cp_parser *parser, cp_token *pragma_tok) { tree stmt, name = NULL; if (cp_lexer_next_token_is (parser->lexer, CPP_OPEN_PAREN)) { cp_lexer_consume_token (parser->lexer); name = cp_parser_identifier (parser); if (name == error_mark_node || !cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'")) cp_parser_skip_to_closing_parenthesis (parser, /*recovering=*/true, /*or_comma=*/false, /*consume_paren=*/true); if (name == error_mark_node) name = NULL; } cp_parser_require_pragma_eol (parser, pragma_tok); stmt = cp_parser_omp_structured_block (parser); return c_finish_omp_critical (stmt, name); } /* OpenMP 2.5: # pragma omp flush flush-vars[opt] new-line flush-vars: ( variable-list ) */ static void cp_parser_omp_flush (cp_parser *parser, cp_token *pragma_tok) { if (cp_lexer_next_token_is (parser->lexer, CPP_OPEN_PAREN)) (void) cp_parser_omp_var_list (parser, 0, NULL); cp_parser_require_pragma_eol (parser, pragma_tok); finish_omp_flush (); } /* Parse the restricted form of the for statment allowed by OpenMP. */ static tree cp_parser_omp_for_loop (cp_parser *parser) { tree init, cond, incr, body, decl, pre_body; location_t loc; if (!cp_lexer_next_token_is_keyword (parser->lexer, RID_FOR)) { cp_parser_error (parser, "for statement expected"); return NULL; } loc = cp_lexer_consume_token (parser->lexer)->location; if (!cp_parser_require (parser, CPP_OPEN_PAREN, "`('")) return NULL; init = decl = NULL; pre_body = push_stmt_list (); if (cp_lexer_next_token_is_not (parser->lexer, CPP_SEMICOLON)) { cp_decl_specifier_seq type_specifiers; /* First, try to parse as an initialized declaration. See cp_parser_condition, from whence the bulk of this is copied. */ cp_parser_parse_tentatively (parser); cp_parser_type_specifier_seq (parser, /*is_condition=*/false, &type_specifiers); if (!cp_parser_error_occurred (parser)) { tree asm_specification, attributes; cp_declarator *declarator; declarator = cp_parser_declarator (parser, CP_PARSER_DECLARATOR_NAMED, /*ctor_dtor_or_conv_p=*/NULL, /*parenthesized_p=*/NULL, /*member_p=*/false); attributes = cp_parser_attributes_opt (parser); asm_specification = cp_parser_asm_specification_opt (parser); cp_parser_require (parser, CPP_EQ, "`='"); if (cp_parser_parse_definitely (parser)) { tree pushed_scope; decl = start_decl (declarator, &type_specifiers, /*initialized_p=*/false, attributes, /*prefix_attributes=*/NULL_TREE, &pushed_scope); init = cp_parser_assignment_expression (parser, false); cp_finish_decl (decl, NULL_TREE, /*init_const_expr_p=*/false, asm_specification, LOOKUP_ONLYCONVERTING); if (pushed_scope) pop_scope (pushed_scope); } } else cp_parser_abort_tentative_parse (parser); /* If parsing as an initialized declaration failed, try again as a simple expression. */ if (decl == NULL) init = cp_parser_expression (parser, false); } cp_parser_require (parser, CPP_SEMICOLON, "`;'"); pre_body = pop_stmt_list (pre_body); cond = NULL; if (cp_lexer_next_token_is_not (parser->lexer, CPP_SEMICOLON)) cond = cp_parser_condition (parser); cp_parser_require (parser, CPP_SEMICOLON, "`;'"); incr = NULL; if (cp_lexer_next_token_is_not (parser->lexer, CPP_CLOSE_PAREN)) incr = cp_parser_expression (parser, false); if (!cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'")) cp_parser_skip_to_closing_parenthesis (parser, /*recovering=*/true, /*or_comma=*/false, /*consume_paren=*/true); /* Note that we saved the original contents of this flag when we entered the structured block, and so we don't need to re-save it here. */ parser->in_statement = IN_OMP_FOR; /* Note that the grammar doesn't call for a structured block here, though the loop as a whole is a structured block. */ body = push_stmt_list (); cp_parser_statement (parser, NULL_TREE, false); body = pop_stmt_list (body); return finish_omp_for (loc, decl, init, cond, incr, body, pre_body); } /* OpenMP 2.5: #pragma omp for for-clause[optseq] new-line for-loop */ #define OMP_FOR_CLAUSE_MASK \ ( (1u << PRAGMA_OMP_CLAUSE_PRIVATE) \ | (1u << PRAGMA_OMP_CLAUSE_FIRSTPRIVATE) \ | (1u << PRAGMA_OMP_CLAUSE_LASTPRIVATE) \ | (1u << PRAGMA_OMP_CLAUSE_REDUCTION) \ | (1u << PRAGMA_OMP_CLAUSE_ORDERED) \ | (1u << PRAGMA_OMP_CLAUSE_SCHEDULE) \ | (1u << PRAGMA_OMP_CLAUSE_NOWAIT)) static tree cp_parser_omp_for (cp_parser *parser, cp_token *pragma_tok) { tree clauses, sb, ret; unsigned int save; clauses = cp_parser_omp_all_clauses (parser, OMP_FOR_CLAUSE_MASK, "#pragma omp for", pragma_tok); sb = begin_omp_structured_block (); save = cp_parser_begin_omp_structured_block (parser); ret = cp_parser_omp_for_loop (parser); if (ret) OMP_FOR_CLAUSES (ret) = clauses; cp_parser_end_omp_structured_block (parser, save); add_stmt (finish_omp_structured_block (sb)); return ret; } /* OpenMP 2.5: # pragma omp master new-line structured-block */ static tree cp_parser_omp_master (cp_parser *parser, cp_token *pragma_tok) { cp_parser_require_pragma_eol (parser, pragma_tok); return c_finish_omp_master (cp_parser_omp_structured_block (parser)); } /* OpenMP 2.5: # pragma omp ordered new-line structured-block */ static tree cp_parser_omp_ordered (cp_parser *parser, cp_token *pragma_tok) { cp_parser_require_pragma_eol (parser, pragma_tok); return c_finish_omp_ordered (cp_parser_omp_structured_block (parser)); } /* OpenMP 2.5: section-scope: { section-sequence } section-sequence: section-directive[opt] structured-block section-sequence section-directive structured-block */ static tree cp_parser_omp_sections_scope (cp_parser *parser) { tree stmt, substmt; bool error_suppress = false; cp_token *tok; if (!cp_parser_require (parser, CPP_OPEN_BRACE, "`{'")) return NULL_TREE; stmt = push_stmt_list (); if (cp_lexer_peek_token (parser->lexer)->pragma_kind != PRAGMA_OMP_SECTION) { unsigned save; substmt = begin_omp_structured_block (); save = cp_parser_begin_omp_structured_block (parser); while (1) { cp_parser_statement (parser, NULL_TREE, false); tok = cp_lexer_peek_token (parser->lexer); if (tok->pragma_kind == PRAGMA_OMP_SECTION) break; if (tok->type == CPP_CLOSE_BRACE) break; if (tok->type == CPP_EOF) break; } cp_parser_end_omp_structured_block (parser, save); substmt = finish_omp_structured_block (substmt); substmt = build1 (OMP_SECTION, void_type_node, substmt); add_stmt (substmt); } while (1) { tok = cp_lexer_peek_token (parser->lexer); if (tok->type == CPP_CLOSE_BRACE) break; if (tok->type == CPP_EOF) break; if (tok->pragma_kind == PRAGMA_OMP_SECTION) { cp_lexer_consume_token (parser->lexer); cp_parser_require_pragma_eol (parser, tok); error_suppress = false; } else if (!error_suppress) { cp_parser_error (parser, "expected %<#pragma omp section%> or %<}%>"); error_suppress = true; } substmt = cp_parser_omp_structured_block (parser); substmt = build1 (OMP_SECTION, void_type_node, substmt); add_stmt (substmt); } cp_parser_require (parser, CPP_CLOSE_BRACE, "`}'"); substmt = pop_stmt_list (stmt); stmt = make_node (OMP_SECTIONS); TREE_TYPE (stmt) = void_type_node; OMP_SECTIONS_BODY (stmt) = substmt; add_stmt (stmt); return stmt; } /* OpenMP 2.5: # pragma omp sections sections-clause[optseq] newline sections-scope */ #define OMP_SECTIONS_CLAUSE_MASK \ ( (1u << PRAGMA_OMP_CLAUSE_PRIVATE) \ | (1u << PRAGMA_OMP_CLAUSE_FIRSTPRIVATE) \ | (1u << PRAGMA_OMP_CLAUSE_LASTPRIVATE) \ | (1u << PRAGMA_OMP_CLAUSE_REDUCTION) \ | (1u << PRAGMA_OMP_CLAUSE_NOWAIT)) static tree cp_parser_omp_sections (cp_parser *parser, cp_token *pragma_tok) { tree clauses, ret; clauses = cp_parser_omp_all_clauses (parser, OMP_SECTIONS_CLAUSE_MASK, "#pragma omp sections", pragma_tok); ret = cp_parser_omp_sections_scope (parser); if (ret) OMP_SECTIONS_CLAUSES (ret) = clauses; return ret; } /* OpenMP 2.5: # pragma parallel parallel-clause new-line # pragma parallel for parallel-for-clause new-line # pragma parallel sections parallel-sections-clause new-line */ #define OMP_PARALLEL_CLAUSE_MASK \ ( (1u << PRAGMA_OMP_CLAUSE_IF) \ | (1u << PRAGMA_OMP_CLAUSE_PRIVATE) \ | (1u << PRAGMA_OMP_CLAUSE_FIRSTPRIVATE) \ | (1u << PRAGMA_OMP_CLAUSE_DEFAULT) \ | (1u << PRAGMA_OMP_CLAUSE_SHARED) \ | (1u << PRAGMA_OMP_CLAUSE_COPYIN) \ | (1u << PRAGMA_OMP_CLAUSE_REDUCTION) \ | (1u << PRAGMA_OMP_CLAUSE_NUM_THREADS)) static tree cp_parser_omp_parallel (cp_parser *parser, cp_token *pragma_tok) { enum pragma_kind p_kind = PRAGMA_OMP_PARALLEL; const char *p_name = "#pragma omp parallel"; tree stmt, clauses, par_clause, ws_clause, block; unsigned int mask = OMP_PARALLEL_CLAUSE_MASK; unsigned int save; if (cp_lexer_next_token_is_keyword (parser->lexer, RID_FOR)) { cp_lexer_consume_token (parser->lexer); p_kind = PRAGMA_OMP_PARALLEL_FOR; p_name = "#pragma omp parallel for"; mask |= OMP_FOR_CLAUSE_MASK; mask &= ~(1u << PRAGMA_OMP_CLAUSE_NOWAIT); } else if (cp_lexer_next_token_is (parser->lexer, CPP_NAME)) { tree id = cp_lexer_peek_token (parser->lexer)->u.value; const char *p = IDENTIFIER_POINTER (id); if (strcmp (p, "sections") == 0) { cp_lexer_consume_token (parser->lexer); p_kind = PRAGMA_OMP_PARALLEL_SECTIONS; p_name = "#pragma omp parallel sections"; mask |= OMP_SECTIONS_CLAUSE_MASK; mask &= ~(1u << PRAGMA_OMP_CLAUSE_NOWAIT); } } clauses = cp_parser_omp_all_clauses (parser, mask, p_name, pragma_tok); block = begin_omp_parallel (); save = cp_parser_begin_omp_structured_block (parser); switch (p_kind) { case PRAGMA_OMP_PARALLEL: cp_parser_already_scoped_statement (parser); par_clause = clauses; break; case PRAGMA_OMP_PARALLEL_FOR: c_split_parallel_clauses (clauses, &par_clause, &ws_clause); stmt = cp_parser_omp_for_loop (parser); if (stmt) OMP_FOR_CLAUSES (stmt) = ws_clause; break; case PRAGMA_OMP_PARALLEL_SECTIONS: c_split_parallel_clauses (clauses, &par_clause, &ws_clause); stmt = cp_parser_omp_sections_scope (parser); if (stmt) OMP_SECTIONS_CLAUSES (stmt) = ws_clause; break; default: gcc_unreachable (); } cp_parser_end_omp_structured_block (parser, save); stmt = finish_omp_parallel (par_clause, block); if (p_kind != PRAGMA_OMP_PARALLEL) OMP_PARALLEL_COMBINED (stmt) = 1; return stmt; } /* OpenMP 2.5: # pragma omp single single-clause[optseq] new-line structured-block */ #define OMP_SINGLE_CLAUSE_MASK \ ( (1u << PRAGMA_OMP_CLAUSE_PRIVATE) \ | (1u << PRAGMA_OMP_CLAUSE_FIRSTPRIVATE) \ | (1u << PRAGMA_OMP_CLAUSE_COPYPRIVATE) \ | (1u << PRAGMA_OMP_CLAUSE_NOWAIT)) static tree cp_parser_omp_single (cp_parser *parser, cp_token *pragma_tok) { tree stmt = make_node (OMP_SINGLE); TREE_TYPE (stmt) = void_type_node; OMP_SINGLE_CLAUSES (stmt) = cp_parser_omp_all_clauses (parser, OMP_SINGLE_CLAUSE_MASK, "#pragma omp single", pragma_tok); OMP_SINGLE_BODY (stmt) = cp_parser_omp_structured_block (parser); return add_stmt (stmt); } /* OpenMP 2.5: # pragma omp threadprivate (variable-list) */ static void cp_parser_omp_threadprivate (cp_parser *parser, cp_token *pragma_tok) { tree vars; vars = cp_parser_omp_var_list (parser, 0, NULL); cp_parser_require_pragma_eol (parser, pragma_tok); if (!targetm.have_tls) sorry ("threadprivate variables not supported in this target"); finish_omp_threadprivate (vars); } /* Main entry point to OpenMP statement pragmas. */ static void cp_parser_omp_construct (cp_parser *parser, cp_token *pragma_tok) { tree stmt; switch (pragma_tok->pragma_kind) { case PRAGMA_OMP_ATOMIC: cp_parser_omp_atomic (parser, pragma_tok); return; case PRAGMA_OMP_CRITICAL: stmt = cp_parser_omp_critical (parser, pragma_tok); break; case PRAGMA_OMP_FOR: stmt = cp_parser_omp_for (parser, pragma_tok); break; case PRAGMA_OMP_MASTER: stmt = cp_parser_omp_master (parser, pragma_tok); break; case PRAGMA_OMP_ORDERED: stmt = cp_parser_omp_ordered (parser, pragma_tok); break; case PRAGMA_OMP_PARALLEL: stmt = cp_parser_omp_parallel (parser, pragma_tok); break; case PRAGMA_OMP_SECTIONS: stmt = cp_parser_omp_sections (parser, pragma_tok); break; case PRAGMA_OMP_SINGLE: stmt = cp_parser_omp_single (parser, pragma_tok); break; default: gcc_unreachable (); } if (stmt) SET_EXPR_LOCATION (stmt, pragma_tok->location); } /* The parser. */ static GTY (()) cp_parser *the_parser; /* Special handling for the first token or line in the file. The first thing in the file might be #pragma GCC pch_preprocess, which loads a PCH file, which is a GC collection point. So we need to handle this first pragma without benefit of an existing lexer structure. Always returns one token to the caller in *FIRST_TOKEN. This is either the true first token of the file, or the first token after the initial pragma. */ static void cp_parser_initial_pragma (cp_token *first_token) { tree name = NULL; cp_lexer_get_preprocessor_token (NULL, first_token); if (first_token->pragma_kind != PRAGMA_GCC_PCH_PREPROCESS) return; cp_lexer_get_preprocessor_token (NULL, first_token); if (first_token->type == CPP_STRING) { name = first_token->u.value; cp_lexer_get_preprocessor_token (NULL, first_token); if (first_token->type != CPP_PRAGMA_EOL) error ("junk at end of %<#pragma GCC pch_preprocess%>"); } else error ("expected string literal"); /* Skip to the end of the pragma. */ while (first_token->type != CPP_PRAGMA_EOL && first_token->type != CPP_EOF) cp_lexer_get_preprocessor_token (NULL, first_token); /* Now actually load the PCH file. */ if (name) c_common_pch_pragma (parse_in, TREE_STRING_POINTER (name)); /* Read one more token to return to our caller. We have to do this after reading the PCH file in, since its pointers have to be live. */ cp_lexer_get_preprocessor_token (NULL, first_token); } /* Normal parsing of a pragma token. Here we can (and must) use the regular lexer. */ static bool cp_parser_pragma (cp_parser *parser, enum pragma_context context) { cp_token *pragma_tok; unsigned int id; pragma_tok = cp_lexer_consume_token (parser->lexer); gcc_assert (pragma_tok->type == CPP_PRAGMA); parser->lexer->in_pragma = true; id = pragma_tok->pragma_kind; switch (id) { case PRAGMA_GCC_PCH_PREPROCESS: error ("%<#pragma GCC pch_preprocess%> must be first"); break; case PRAGMA_OMP_BARRIER: switch (context) { case pragma_compound: cp_parser_omp_barrier (parser, pragma_tok); return false; case pragma_stmt: error ("%<#pragma omp barrier%> may only be " "used in compound statements"); break; default: goto bad_stmt; } break; case PRAGMA_OMP_FLUSH: switch (context) { case pragma_compound: cp_parser_omp_flush (parser, pragma_tok); return false; case pragma_stmt: error ("%<#pragma omp flush%> may only be " "used in compound statements"); break; default: goto bad_stmt; } break; case PRAGMA_OMP_THREADPRIVATE: cp_parser_omp_threadprivate (parser, pragma_tok); return false; case PRAGMA_OMP_ATOMIC: case PRAGMA_OMP_CRITICAL: case PRAGMA_OMP_FOR: case PRAGMA_OMP_MASTER: case PRAGMA_OMP_ORDERED: case PRAGMA_OMP_PARALLEL: case PRAGMA_OMP_SECTIONS: case PRAGMA_OMP_SINGLE: if (context == pragma_external) goto bad_stmt; cp_parser_omp_construct (parser, pragma_tok); return true; case PRAGMA_OMP_SECTION: error ("%<#pragma omp section%> may only be used in " "%<#pragma omp sections%> construct"); break; default: gcc_assert (id >= PRAGMA_FIRST_EXTERNAL); c_invoke_pragma_handler (id); break; bad_stmt: cp_parser_error (parser, "expected declaration specifiers"); break; } cp_parser_skip_to_pragma_eol (parser, pragma_tok); return false; } /* The interface the pragma parsers have to the lexer. */ enum cpp_ttype pragma_lex (tree *value) { cp_token *tok; enum cpp_ttype ret; tok = cp_lexer_peek_token (the_parser->lexer); ret = tok->type; *value = tok->u.value; if (ret == CPP_PRAGMA_EOL || ret == CPP_EOF) ret = CPP_EOF; else if (ret == CPP_STRING) *value = cp_parser_string_literal (the_parser, false, false); else { cp_lexer_consume_token (the_parser->lexer); if (ret == CPP_KEYWORD) ret = CPP_NAME; } return ret; } /* External interface. */ /* Parse one entire translation unit. */ void c_parse_file (void) { bool error_occurred; static bool already_called = false; if (already_called) { sorry ("inter-module optimizations not implemented for C++"); return; } already_called = true; the_parser = cp_parser_new (); push_deferring_access_checks (flag_access_control ? dk_no_deferred : dk_no_check); error_occurred = cp_parser_translation_unit (the_parser); the_parser = NULL; } /* This variable must be provided by every front end. */ int yydebug; #include "gt-cp-parser.h"

test_nest_lock_parallel.c

// RUN: %libomp-compile-and-run | %sort-threads | FileCheck %s // REQUIRES: ompt // UNSUPPORTED: gcc-4, gcc-5, gcc-6, gcc-7 #include "callback.h" #include <omp.h> int main() { omp_nest_lock_t nest_lock; omp_init_nest_lock(&nest_lock); #pragma omp parallel num_threads(2) { #pragma omp master { omp_set_nest_lock(&nest_lock); print_fuzzy_address(1); } #pragma omp barrier omp_test_nest_lock(&nest_lock); //should fail for non-master print_fuzzy_address(2); #pragma omp barrier #pragma omp master { omp_unset_nest_lock(&nest_lock); print_fuzzy_address(3); omp_unset_nest_lock(&nest_lock); print_fuzzy_address(4); } } omp_destroy_nest_lock(&nest_lock); // Check if libomp supports the callbacks for this test. // 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-NOT: {{^}}0: Could not register callback 'ompt_callback_nest_lock' // CHECK: 0: NULL_POINTER=[[NULL:.*$]] // CHECK: {{^}}[[MASTER_ID:[0-9]+]]: ompt_event_wait_nest_lock: wait_id=[[WAIT_ID:[0-9]+]], hint=0, impl={{[0-9]+}}, codeptr_ra=[[RETURN_ADDRESS:0x[0-f]+]]{{[0-f][0-f]}} // CHECK: {{^}}[[MASTER_ID]]: ompt_event_acquired_nest_lock_first: wait_id=[[WAIT_ID]], codeptr_ra=[[RETURN_ADDRESS]]{{[0-f][0-f]}} // CHECK-NEXT: {{^}}[[MASTER_ID]]: fuzzy_address={{.*}}[[RETURN_ADDRESS]] // CHECK: {{^}}[[MASTER_ID]]: ompt_event_wait_nest_lock: wait_id=[[WAIT_ID]], hint=0, impl={{[0-9]+}}, codeptr_ra=[[RETURN_ADDRESS:0x[0-f]+]]{{[0-f][0-f]}} // CHECK: {{^}}[[MASTER_ID]]: ompt_event_acquired_nest_lock_next: wait_id=[[WAIT_ID]], codeptr_ra=[[RETURN_ADDRESS]]{{[0-f][0-f]}} // CHECK-NEXT: {{^}}[[MASTER_ID]]: fuzzy_address={{.*}}[[RETURN_ADDRESS]] // CHECK: {{^}}[[MASTER_ID]]: ompt_event_release_nest_lock_prev: wait_id=[[WAIT_ID]], codeptr_ra=[[RETURN_ADDRESS:0x[0-f]+]]{{[0-f][0-f]}} // CHECK-NEXT: {{^}}[[MASTER_ID]]: fuzzy_address={{.*}}[[RETURN_ADDRESS]] // CHECK: {{^}}[[MASTER_ID]]: ompt_event_release_nest_lock_last: wait_id=[[WAIT_ID]], codeptr_ra=[[RETURN_ADDRESS:0x[0-f]+]]{{[0-f][0-f]}} // CHECK-NEXT: {{^}}[[MASTER_ID]]: fuzzy_address={{.*}}[[RETURN_ADDRESS]] // CHECK: {{^}}[[MASTER_ID]]: ompt_event_destroy_nest_lock: wait_id=[[WAIT_ID]] // CHECK: {{^}}[[THREAD_ID:[0-9]+]]: ompt_event_wait_nest_lock: wait_id=[[WAIT_ID]], hint=0, impl={{[0-9]+}}, codeptr_ra=[[RETURN_ADDRESS:0x[0-f]+]]{{[0-f][0-f]}} // CHECK-NOT: {{^}}[[THREAD_ID]]: ompt_event_acquired_nest_lock_next: wait_id=[[WAIT_ID]] // CHECK-NEXT: {{^}}[[THREAD_ID]]: fuzzy_address={{.*}}[[RETURN_ADDRESS]] return 0; }

GB_unaryop__abs_int32_uint8.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__abs_int32_uint8 // op(A') function: GB_tran__abs_int32_uint8 // C type: int32_t // A type: uint8_t // cast: int32_t cij = (int32_t) aij // unaryop: cij = GB_IABS (aij) #define GB_ATYPE \ uint8_t #define GB_CTYPE \ int32_t // aij = Ax [pA] #define GB_GETA(aij,Ax,pA) \ uint8_t aij = Ax [pA] #define GB_CX(p) Cx [p] // unary operator #define GB_OP(z, x) \ z = GB_IABS (x) ; // casting #define GB_CASTING(z, aij) \ int32_t z = (int32_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_ABS || GxB_NO_INT32 || GxB_NO_UINT8) //------------------------------------------------------------------------------ // Cx = op (cast (Ax)): apply a unary operator //------------------------------------------------------------------------------ GrB_Info GB_unop__abs_int32_uint8 ( int32_t *Cx, // Cx and Ax may be aliased uint8_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__abs_int32_uint8 ( 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

fox_floats_timer_caching_omp_fileIO_benchmark.c

/* fox_floats_timer_caching_omp_fileIO_benchmark.c -- uses Fox's algorithm to multiply two square matrices * * Implementation of parallel matrix multiplication: * LaTeX: $C_{i,j} = \sum_{k} A_{i,k}B_{k,j}$ * * Input: * Input Matrix file name: A.dat, B.dat * * Output: * Output Matrix file name: C.dat * Output Sub-matrices file name: SubMatrices.dat * * Notes: * 1. Assumes the number of processes is a perfect square * 2. The array member of the matrices is statically allocated * * See Chap 7, pp. 113 & ff and pp. 125 & ff in PPMPI */ /* Compiler command: * mpiicc -O3 -qopenmp -qopt-report-phase=vec -qopt-report=3 fox_floats_timer_caching_omp_fileIO_benchmark.c * -o fox_floats_timer_caching_omp_fileIO_benchmark * * Run command: * mpirun -n -4 ./fox_floats_timer_caching_omp */ /* Head files */ #include <stdio.h> #include <math.h> #include <stdlib.h> #include <mpi.h> #include <omp.h> // define problem scale, matrix row/col size #define PROBLEM_SCALE 4096 // define whether or not Print Matices in the Command Line #define PRINT_A 0 #define PRINT_B 0 #define PRINT_C 0 #define PRINT_LOCAL_A 0 #define PRINT_LOCAL_B 0 #define PRINT_LOCAL_C 0 // define float precision, 4 byte single-precision float or 8 byte double-precision float #define FLOAT double #define FLOAT_MPI MPI_DOUBLE // Define threads speed-up affnity in the computing #define NUM_THREADS 8 // Define threads affinity "scatter" or "compact" #define AFFINITY "KMP_AFFINITY = compact" /* Type define structure of process grid */ typedef struct { int p; /* Total number of processes */ MPI_Comm comm; /* Communicator for entire grid */ MPI_Comm row_comm; /* Communicator for my row */ MPI_Comm col_comm; /* Communicator for my col */ int q; /* Order of grid */ int my_row; /* My row number */ int my_col; /* My column number */ int my_rank; /* My rank in the grid comm */ } GRID_INFO_T; /* Type define structure of local matrix */ #define MAX 2097152 // Maximum number of elements in the array that store the local matrix (2^21) typedef struct { int n_bar; #define Order(A) ((A)->n_bar) // defination with parameters FLOAT entries[MAX]; #define Entry(A,i,j) (*(((A)->entries) + ((A)->n_bar)*(i) + (j))) // defination with parameters, Array dereference } LOCAL_MATRIX_T; /* Function Declarations */ LOCAL_MATRIX_T* Local_matrix_allocate(int n_bar); void Free_local_matrix(LOCAL_MATRIX_T** local_A); void Read_matrix_A(char* prompt, LOCAL_MATRIX_T* local_A, GRID_INFO_T* grid, int n); // Read matrix A from a file void Read_matrix_B(char* prompt, LOCAL_MATRIX_T* local_B, // for continuous memory access, local A(i,k)*B(k,j) = A(i,k)*B^{T}(j,k) GRID_INFO_T* grid, int n); // Read matrix B from a file void Print_matrix_A(char* title, LOCAL_MATRIX_T* local_A, GRID_INFO_T* grid, int n); // Print matrix A in the command line void Print_matrix_B(char* title, LOCAL_MATRIX_T* local_B, // Speical print function for local matrix B^{T}(j,k) GRID_INFO_T* grid, int n); // Print matrix B in the command line void Print_matrix_C(char* title, LOCAL_MATRIX_T* local_C, GRID_INFO_T* grid, int n); // Print matrix C in the command line void Set_to_zero(LOCAL_MATRIX_T* local_A); void Local_matrix_multiply(LOCAL_MATRIX_T* local_A, LOCAL_MATRIX_T* local_B, LOCAL_MATRIX_T* local_C); void Build_matrix_type(LOCAL_MATRIX_T* local_A); MPI_Datatype local_matrix_mpi_t; LOCAL_MATRIX_T* temp_mat; // global LOCAL_MATRIX_T* type pointer void Print_local_matrices_A(char* title, LOCAL_MATRIX_T* local_A, GRID_INFO_T* grid); void Print_local_matrices_B(char* title, LOCAL_MATRIX_T* local_B, // Speical print function for local matrix B^{T}(j,k) GRID_INFO_T* grid); void Print_local_matrices_C(char* title, LOCAL_MATRIX_T* local_B, GRID_INFO_T* grid); void Write_matrix_C(char* title, LOCAL_MATRIX_T* local_C, GRID_INFO_T* grid, int n); // Write matrix multiplication to a file void Write_local_matrices_A(char* title, LOCAL_MATRIX_T* local_A, GRID_INFO_T* grid); // Write local matrix A to a file void Write_local_matrices_B(char* title, LOCAL_MATRIX_T* local_B, // Speical print function for local matrix B^{T}(j,k) GRID_INFO_T* grid); // Write local matrix B to a file void Write_local_matrices_C(char* title, LOCAL_MATRIX_T* local_A, GRID_INFO_T* grid); // Write local matrix C to a file /*********************************************************/ main(int argc, char* argv[]) { FILE *fp; int p; int my_rank; GRID_INFO_T grid; LOCAL_MATRIX_T* local_A; LOCAL_MATRIX_T* local_B; LOCAL_MATRIX_T* local_C; int n; int n_bar; double timer_start; double timer_end; int content; int i; int j; void Setup_grid(GRID_INFO_T* grid); void Fox(int n, GRID_INFO_T* grid, LOCAL_MATRIX_T* local_A, LOCAL_MATRIX_T* local_B, LOCAL_MATRIX_T* local_C); // Matrix Generator fp = fopen("A.dat", "w"); // Generate and print matrix A into a file for (i = 0; i < PROBLEM_SCALE; i++) { for (j = 0; j < PROBLEM_SCALE; j++) if(i == j){ fprintf(fp,"%d ", 1); } else { fprintf(fp,"%d ", 0); } fprintf(fp,"\n"); } fclose(fp); fp = fopen("B.dat", "w"); // Generate and print matrix B into a file for (i = 0; i < PROBLEM_SCALE; i++){ for (j = 0; j < PROBLEM_SCALE; j++) fprintf(fp,"%d ", (i*PROBLEM_SCALE)+j); fprintf(fp, "\n"); } fclose(fp); // SPMD Mode start from here (Processess fork from here) MPI_Init(&argc, &argv); // MPI initializing MPI_Comm_rank(MPI_COMM_WORLD, &my_rank); // Get my process id in the MPI communicator // Initial OpenMP Environment omp_set_num_threads(NUM_THREADS); kmp_set_defaults(AFFINITY); Setup_grid(&grid); // Set up Processess grid if (my_rank == 0) { fp = fopen("A.dat","r"); n = 0; while((content = fgetc(fp)) != EOF) { //printf("fgetc = %d\n", content); if(content != 0x20 && content != 0x0A) n++; } fclose(fp); n = (int) sqrt((double) n); printf("We read the order of the matrices from A.dat is\n %d\n", n); // while(fgetc(fp) != EOF) n++; // printf("What's the order of the matrices?\n"); // scanf("%d", &n); // Overall Matrix's Order } MPI_Bcast(&n, 1, MPI_INT, 0, MPI_COMM_WORLD); // MPI broadcast the overall matrix's order n_bar = n/grid.q; // \bar n is the local matrix's order local_A = Local_matrix_allocate(n_bar); // Allocate local matrix A Order(local_A) = n_bar; // Local matrix A's order Read_matrix_A("Read A from A.dat", local_A, &grid, n); // Read local matrices A from process 0 by using stdin, and send them to each process (Procedure) if (PRINT_A == 1) Print_matrix_A("We read A =", local_A, &grid, n);// Print local matrices A from process 0 by using stdout, and send them to each process (Procedure) local_B = Local_matrix_allocate(n_bar); // Allocate local matrix Order(local_B) = n_bar; // Local matrix B's order Read_matrix_B("Read B from B.dat", local_B, &grid, n); // Read local matrix B as it's local transpose from process 0 by using stdin, and send them to each process (Procedure) if (PRINT_B == 1) Print_matrix_B("We read B =", local_B, &grid, n);// Print local matrix B as it's local transpose from process 0 by using stdout, and send them to each process (Procedure) Build_matrix_type(local_A); // Buid local_A's MPI matrix data type temp_mat = Local_matrix_allocate(n_bar); // Allocate temporary matrix of order n $\time$ n local_C = Local_matrix_allocate(n_bar); // Allocate matrix local_C Order(local_C) = n_bar; // Set matrix local_C's order MPI_Barrier(MPI_COMM_WORLD); // Set the MPI process barrier timer_start = MPI_Wtime(); // Get the MPI wall time Fox(n, &grid, local_A, local_B, local_C); // FOX parallel matrix multiplication Algorithm implement function timer_end = MPI_Wtime(); // Get the MPI wall time MPI_Barrier(MPI_COMM_WORLD); // Set the MPI process barrier Write_matrix_C("Write C into the C.dat", local_C, &grid, n); // Print matrix local_C (parallel matrix multiplication result) if (PRINT_C == 1) Print_matrix_C("The product is", local_C, &grid, n); // Print matrix local_C (parallel matrix multiplication result) Write_local_matrices_A("Write split of local matrix A into local_A.dat", local_A, &grid); // Write local matrix A into file if (PRINT_LOCAL_A == 1) Print_local_matrices_A("Split of local matrix A", local_A, &grid); // Print matrix A split in processess Write_local_matrices_B("Write split of local matrix B into local_B.dat", local_B, &grid); // Write local matrix B into file, special for row-major storage if (PRINT_LOCAL_B == 1) Print_local_matrices_B("Split of local matrix B", local_B, &grid); // Print matrix B split in processess, special for row-major storage Write_local_matrices_C("Write split of local matrix C into local_C.dat", local_C, &grid); // Print matrix C split in processess if (PRINT_LOCAL_C == 1) Print_local_matrices_C("Split of local matrix C", local_C, &grid); // Print matrix C split in processess Free_local_matrix(&local_A); // Free local matrix local_A Free_local_matrix(&local_B); // Free local matrix local_B Free_local_matrix(&local_C); // Free local matrix local_C if(my_rank == 0) printf("Parallel Fox Matrix Multiplication Elapsed time:\n %30.20E seconds\n", timer_end-timer_start); MPI_Finalize(); // MPI finalize, processes join and resource recycle } /* main */ /*********************************************************/ void Setup_grid( GRID_INFO_T* grid /* out */) { int old_rank; int dimensions[2]; int wrap_around[2]; int coordinates[2]; int free_coords[2]; /* Set up Global Grid Information */ MPI_Comm_size(MPI_COMM_WORLD, &(grid->p)); MPI_Comm_rank(MPI_COMM_WORLD, &old_rank); /* We assume p is a perfect square */ // but what if it's not a perfect square grid->q = (int) sqrt((double) grid->p); dimensions[0] = dimensions[1] = grid->q; /* We want a circular shift in second dimension. */ /* Don't care about first */ wrap_around[0] = wrap_around[1] = 1; MPI_Cart_create(MPI_COMM_WORLD, 2, dimensions, wrap_around, 1, &(grid->comm)); MPI_Comm_rank(grid->comm, &(grid->my_rank)); MPI_Cart_coords(grid->comm, grid->my_rank, 2, coordinates); grid->my_row = coordinates[0]; grid->my_col = coordinates[1]; /* Set up row communicators */ free_coords[0] = 0; free_coords[1] = 1; MPI_Cart_sub(grid->comm, free_coords, &(grid->row_comm)); /* Set up column communicators */ free_coords[0] = 1; free_coords[1] = 0; MPI_Cart_sub(grid->comm, free_coords, &(grid->col_comm)); } /* Setup_grid */ /*********************************************************/ void Fox( int n /* in */, GRID_INFO_T* grid /* in */, LOCAL_MATRIX_T* local_A /* in */, LOCAL_MATRIX_T* local_B /* in */, LOCAL_MATRIX_T* local_C /* out */) { LOCAL_MATRIX_T* temp_A; /* Storage for the sub- */ /* matrix of A used during */ /* the current stage */ int stage; int bcast_root; int n_bar; /* n/sqrt(p) */ int source; int dest; MPI_Status status; n_bar = n/grid->q; Set_to_zero(local_C); /* Calculate addresses for row circular shift of B */ source = (grid->my_row + 1) % grid->q; dest = (grid->my_row + grid->q - 1) % grid->q; /* Set aside storage for the broadcast block of A */ temp_A = Local_matrix_allocate(n_bar); for (stage = 0; stage < grid->q; stage++) { bcast_root = (grid->my_row + stage) % grid->q; if (bcast_root == grid->my_col) { // Process P_{ii} broadcast A_{ii} in process gird's row commnunicator MPI_Bcast(local_A, 1, local_matrix_mpi_t, bcast_root, grid->row_comm); Local_matrix_multiply(local_A, local_B, local_C); } else { // temp_A is a buffer for process P_{ij} to store A_{ij} MPI_Bcast(temp_A, 1, local_matrix_mpi_t, bcast_root, grid->row_comm); Local_matrix_multiply(temp_A, local_B, local_C); } MPI_Sendrecv_replace(local_B, 1, local_matrix_mpi_t, // MPI send and receive with single buffer dest, 0, source, 0, grid->col_comm, &status); // Circular shift of process grid B's row, after local multiplication operation } /* for */ } /* Fox */ /*********************************************************/ LOCAL_MATRIX_T* Local_matrix_allocate(int local_order) { LOCAL_MATRIX_T* temp; temp = (LOCAL_MATRIX_T*) malloc(sizeof(LOCAL_MATRIX_T)); return temp; } /* Local_matrix_allocate */ /*********************************************************/ void Free_local_matrix( LOCAL_MATRIX_T** local_A_ptr /* in/out */) { free(*local_A_ptr); } /* Free_local_matrix */ /*********************************************************/ /* Read and distribute matrix for matrix A: * foreach global row of the matrix, * foreach grid column * read a block of n_bar floats on process 0 * and send them to the appropriate process. */ void Read_matrix_A( char* prompt /* in */, LOCAL_MATRIX_T* local_A /* out */, GRID_INFO_T* grid /* in */, int n /* in */) { FILE *fp; int mat_row, mat_col; int grid_row, grid_col; int dest; int coords[2]; FLOAT* temp; MPI_Status status; if (grid->my_rank == 0) { // Process 0 read matrix input from stdin and send them to other processess fp = fopen("A.dat","r"); temp = (FLOAT*) malloc(Order(local_A)*sizeof(FLOAT)); printf("%s\n", prompt); fflush(stdout); for (mat_row = 0; mat_row < n; mat_row++) { grid_row = mat_row/Order(local_A); coords[0] = grid_row; for (grid_col = 0; grid_col < grid->q; grid_col++) { coords[1] = grid_col; MPI_Cart_rank(grid->comm, coords, &dest); if (dest == 0) { for (mat_col = 0; mat_col < Order(local_A); mat_col++) fscanf(fp, "%lf", (local_A->entries)+mat_row*Order(local_A)+mat_col); /* scanf("%lf", (local_A->entries)+mat_row*Order(local_A)+mat_col); */ } else { for(mat_col = 0; mat_col < Order(local_A); mat_col++) fscanf(fp,"%lf", temp + mat_col); // scanf("%lf", temp + mat_col); MPI_Send(temp, Order(local_A), FLOAT_MPI, dest, 0, grid->comm); } } } free(temp); fclose(fp); } else { // Other processess receive matrix from process 0 for (mat_row = 0; mat_row < Order(local_A); mat_row++) MPI_Recv(&Entry(local_A, mat_row, 0), Order(local_A), FLOAT_MPI, 0, 0, grid->comm, &status); } } /* Read_matrix */ /*********************************************************/ /* Read and distribute matrix for local matrix B's transpose: * foreach global row of the matrix, * foreach grid column * read a block of n_bar floats on process 0 * and send them to the appropriate process. */ void Read_matrix_B( char* prompt /* in */, LOCAL_MATRIX_T* local_B /* out */, GRID_INFO_T* grid /* in */, int n /* in */) { FILE *fp; int mat_row, mat_col; int grid_row, grid_col; int dest; int coords[2]; FLOAT *temp; MPI_Status status; if (grid->my_rank == 0) { // Process 0 read matrix input from stdin and send them to other processess fp = fopen("B.dat","r"); temp = (FLOAT*) malloc(Order(local_B)*sizeof(FLOAT)); printf("%s\n", prompt); fflush(stdout); for (mat_row = 0; mat_row < n; mat_row++) { grid_row = mat_row/Order(local_B); coords[0] = grid_row; for (grid_col = 0; grid_col < grid->q; grid_col++) { coords[1] = grid_col; MPI_Cart_rank(grid->comm, coords, &dest); if (dest == 0) { // process 0 (local) for (mat_col = 0; mat_col < Order(local_B); mat_col++) fscanf(fp, "%lf", (local_B->entries)+mat_col*Order(local_B)+mat_row); // switch rows and colums in local_B, for column major storage /* scanf("%lf", (local_B->entries)+mat_col*Order(local_B)+mat_row); // switch rows and colums in local_B, for column major storage */ /* scanf("%lf", (local_A->entries)+mat_row*Order(local_A)+mat_col); */ } else { for(mat_col = 0; mat_col < Order(local_B); mat_col++) fscanf(fp, "%lf", temp + mat_col); // scanf("%lf", temp + mat_col); MPI_Send(temp, Order(local_B), FLOAT_MPI, dest, 0, grid->comm); } } } free(temp); fclose(fp); } else { // Other processess receive matrix from process 0 temp = (FLOAT*) malloc(Order(local_B)*sizeof(FLOAT)); // switch rows and colums in local_B, for column major storage for (mat_col = 0; mat_col < Order(local_B); mat_col++) { MPI_Recv(temp, Order(local_B), FLOAT_MPI, 0, 0, grid->comm, &status); // switch rows and colums in local_B, for column major storage for(mat_row = 0; mat_row < Order(local_B); mat_row++) Entry(local_B, mat_row, mat_col) = *(temp + mat_row); // switch rows and colums in local_B, for column major storage /* MPI_Recv(&Entry(local_A, mat_row, 0), Order(local_A), FLOAT_MPI, 0, 0, grid->comm, &status); */ } free(temp); } } /* Read_matrix_B */ /*********************************************************/ /* Recive and Print Matrix A: * foreach global row of the matrix, * foreach grid column * send n_bar floats to process 0 from each other process * receive a block of n_bar floats on process 0 from other processes and print them */ void Print_matrix_A( char* title /* in */, LOCAL_MATRIX_T* local_A /* out */, GRID_INFO_T* grid /* in */, int n /* in */) { int mat_row, mat_col; int grid_row, grid_col; int source; int coords[2]; FLOAT* temp; MPI_Status status; if (grid->my_rank == 0) { temp = (FLOAT*) malloc(Order(local_A)*sizeof(FLOAT)); printf("%s\n", title); for (mat_row = 0; mat_row < n; mat_row++) { grid_row = mat_row/Order(local_A); coords[0] = grid_row; for (grid_col = 0; grid_col < grid->q; grid_col++) { coords[1] = grid_col; MPI_Cart_rank(grid->comm, coords, &source); if (source == 0) { for(mat_col = 0; mat_col < Order(local_A); mat_col++) printf("%20.15E ", Entry(local_A, mat_row, mat_col)); } else { MPI_Recv(temp, Order(local_A), FLOAT_MPI, source, 0, grid->comm, &status); for(mat_col = 0; mat_col < Order(local_A); mat_col++) printf("%20.15E ", temp[mat_col]); } } printf("\n"); } free(temp); } else { for (mat_row = 0; mat_row < Order(local_A); mat_row++) MPI_Send(&Entry(local_A, mat_row, 0), Order(local_A), FLOAT_MPI, 0, 0, grid->comm); } } /* Print_matrix_A */ /*********************************************************/ /* Recive and Print Matrix for local matrix B's transpose: * foreach global row of the matrix, * foreach grid column * send n_bar floats to process 0 from each other process * receive a block of n_bar floats on process 0 from other processes and print them */ void Print_matrix_B( char* title /* in */, LOCAL_MATRIX_T* local_B /* out */, GRID_INFO_T* grid /* in */, int n /* in */) { int mat_row, mat_col; int grid_row, grid_col; int source; int coords[2]; FLOAT* temp; MPI_Status status; if (grid->my_rank == 0) { temp = (FLOAT*) malloc(Order(local_B)*sizeof(FLOAT)); printf("%s\n", title); for (mat_row = 0; mat_row < n; mat_row++) { grid_row = mat_row/Order(local_B); coords[0] = grid_row; for (grid_col = 0; grid_col < grid->q; grid_col++) { coords[1] = grid_col; MPI_Cart_rank(grid->comm, coords, &source); if (source == 0) { for(mat_col = 0; mat_col < Order(local_B); mat_col++) printf("%20.15E ", Entry(local_B, mat_col, mat_row)); // switch rows and colums in local_B, for column major storage // printf("%20.15E ", Entry(local_A, mat_row, mat_col)); } else { MPI_Recv(temp, Order(local_B), FLOAT_MPI, source, 0, grid->comm, &status); for(mat_col = 0; mat_col < Order(local_B); mat_col++) printf("%20.15E ", temp[mat_col]); } } printf("\n"); } free(temp); } else { temp = (FLOAT*) malloc(Order(local_B)*sizeof(FLOAT)); for (mat_col = 0; mat_col < Order(local_B); mat_col++) { for(mat_row = 0; mat_row < Order(local_B); mat_row++) *(temp+mat_row) = Entry(local_B, mat_row, mat_col); // switch rows and colums in local_B, for column major storage MPI_Send(temp, Order(local_B), FLOAT_MPI, 0, 0, grid->comm); } free(temp); } } /* Print_matrix_B */ /*********************************************************/ /* Recive and Print Matrix A: * foreach global row of the matrix, * foreach grid column * send n_bar floats to process 0 from each other process * receive a block of n_bar floats on process 0 from other processes and print them */ void Print_matrix_C( char* title /* in */, LOCAL_MATRIX_T* local_C /* out */, GRID_INFO_T* grid /* in */, int n /* in */) { int mat_row, mat_col; int grid_row, grid_col; int source; int coords[2]; FLOAT* temp; MPI_Status status; if (grid->my_rank == 0) { temp = (FLOAT*) malloc(Order(local_C)*sizeof(FLOAT)); printf("%s\n", title); for (mat_row = 0; mat_row < n; mat_row++) { grid_row = mat_row/Order(local_C); coords[0] = grid_row; for (grid_col = 0; grid_col < grid->q; grid_col++) { coords[1] = grid_col; MPI_Cart_rank(grid->comm, coords, &source); if (source == 0) { for(mat_col = 0; mat_col < Order(local_C); mat_col++) printf("%20.15E ", Entry(local_C, mat_row, mat_col)); } else { MPI_Recv(temp, Order(local_C), FLOAT_MPI, source, 0, grid->comm, &status); for(mat_col = 0; mat_col < Order(local_C); mat_col++) printf("%20.15E ", temp[mat_col]); } } printf("\n"); } free(temp); } else { for (mat_row = 0; mat_row < Order(local_C); mat_row++) MPI_Send(&Entry(local_C, mat_row, 0), Order(local_C), FLOAT_MPI, 0, 0, grid->comm); } } /* Print_matrix_C */ /*********************************************************/ /* Recive and Write Matrix C into a file: * foreach global row of the matrix, * foreach grid column * send n_bar floats to process 0 from each other process * receive a block of n_bar floats on process 0 from other processes and print them */ void Write_matrix_C( char* title /* in */, LOCAL_MATRIX_T* local_C /* out */, GRID_INFO_T* grid /* in */, int n /* in */) { FILE *fp; int mat_row, mat_col; int grid_row, grid_col; int source; int coords[2]; FLOAT* temp; MPI_Status status; if (grid->my_rank == 0) { fp = fopen("C.dat", "w+"); temp = (FLOAT*) malloc(Order(local_C)*sizeof(FLOAT)); printf("%s\n", title); for (mat_row = 0; mat_row < n; mat_row++) { grid_row = mat_row/Order(local_C); coords[0] = grid_row; for (grid_col = 0; grid_col < grid->q; grid_col++) { coords[1] = grid_col; MPI_Cart_rank(grid->comm, coords, &source); if (source == 0) { for(mat_col = 0; mat_col < Order(local_C); mat_col++) fprintf(fp, "%20.15E ", Entry(local_C, mat_row, mat_col)); // printf("%20.15E ", Entry(local_A, mat_row, mat_col)); } else { MPI_Recv(temp, Order(local_C), FLOAT_MPI, source, 0, grid->comm, &status); for(mat_col = 0; mat_col < Order(local_C); mat_col++) fprintf(fp, "%20.15E ", temp[mat_col]); // printf("%20.15E ", temp[mat_col]); } } fprintf(fp,"\n"); } free(temp); fclose(fp); } else { for (mat_row = 0; mat_row < Order(local_C); mat_row++) MPI_Send(&Entry(local_C, mat_row, 0), Order(local_C), FLOAT_MPI, 0, 0, grid->comm); } } /* Write_matrix_C */ /*********************************************************/ /* * Set local matrix's element to zero */ void Set_to_zero( LOCAL_MATRIX_T* local_A /* out */) { int i, j; for (i = 0; i < Order(local_A); i++) for (j = 0; j < Order(local_A); j++) Entry(local_A,i,j) = 0.0E0; } /* Set_to_zero */ /*********************************************************/ void Build_matrix_type( LOCAL_MATRIX_T* local_A /* in */) { MPI_Datatype temp_mpi_t; int block_lengths[2]; MPI_Aint displacements[2]; MPI_Datatype typelist[2]; MPI_Aint start_address; MPI_Aint address; MPI_Type_contiguous(Order(local_A)*Order(local_A), FLOAT_MPI, &temp_mpi_t); // Creates a contiguous datatype /* Synopsis int MPI_Type_contiguous(int count, MPI_Datatype oldtype, MPI_Datatype *newtype) Input Parameters count replication count (nonnegative integer) oldtype old datatype (handle) */ block_lengths[0] = block_lengths[1] = 1; typelist[0] = MPI_INT; typelist[1] = temp_mpi_t; MPI_Address(local_A, &start_address); // Gets the address of a location in caller's memory MPI_Address(&(local_A->n_bar), &address); /* Synopsis int MPI_Address(const void *location, MPI_Aint *address) Input Parameters location location in caller memory (choice) Output Parameters address address of location (address integer) */ displacements[0] = address - start_address; MPI_Address(local_A->entries, &address); displacements[1] = address - start_address; MPI_Type_struct(2, block_lengths, displacements, typelist, &local_matrix_mpi_t); // Creates a struct datatype /* Synopsis int MPI_Type_struct(int count, const int *array_of_blocklengths, const MPI_Aint *array_of_displacements, const MPI_Datatype *array_of_types, MPI_Datatype *newtype) Input Parameters count number of blocks (integer) -- also number of entries in arrays array_of_types , array_of_displacements and array_of_blocklengths array_of_blocklengths number of elements in each block (array) array_of_displacements byte displacement of each block (array) array_of_types type of elements in each block (array of handles to datatype objects) Output Parameters newtype new datatype (handle) */ MPI_Type_commit(&local_matrix_mpi_t); // Commits the datatype /* Synopsis int MPI_Type_commit(MPI_Datatype *datatype) Input Parameters datatype datatype (handle) */ } /* Build_matrix_type */ /*********************************************************/ /* local matrix multiplication function * withing OpenMP Thread Acceleration */ void Local_matrix_multiply( LOCAL_MATRIX_T* local_A /* in */, LOCAL_MATRIX_T* local_B /* in */, LOCAL_MATRIX_T* local_C /* out */) { int i, j, k; // int my_rank; // MPI_Comm_rank(MPI_COMM_WORLD, &my_rank); // Get my process id in the MPI communicator #pragma omp parallel for private(i, j, k) shared(local_A, local_B, local_C) num_threads(NUM_THREADS) // Threads acceleration upgrade, parallel task split for (i = 0; i < Order(local_A); i++) { // printf("Current in the Fox Kernel:\n my process id is %d, my thread id is %d\n",my_rank,omp_get_thread_num()); for (j = 0; j < Order(local_A); j++) for (k = 0; k < Order(local_B); k++) Entry(local_C,i,j) = Entry(local_C,i,j) // switch rows and colums in local_B, for column major storage + Entry(local_A,i,k)*Entry(local_B,j,k); // continuous memory access, local matrix multiplication A(i,k)*B^T(j,k) /* Entry(local_C,i,j) = Entry(local_C,i,j) + Entry(local_A,i,k)*Entry(local_B,k,j); // non-continuous memory access, A(i,k)*B^T(j,k) is more proper */ } } /* Local_matrix_multiply */ /*********************************************************/ /* Recive and Print Local Matrix A: * Process 0 print local matrix local_A * Other Processess send local matrix local_A to process 0 * And process 0 receive local matrix local_A from other processess */ void Print_local_matrices_A( char* title /* in */, LOCAL_MATRIX_T* local_A /* in */, GRID_INFO_T* grid /* in */) { int coords[2]; int i, j; int source; MPI_Status status; // print by process No.0 in process mesh if (grid->my_rank == 0) { printf("%s\n", title); printf("Process %d > grid_row = %d, grid_col = %d\n", grid->my_rank, grid->my_row, grid->my_col); for (i = 0; i < Order(local_A); i++) { for (j = 0; j < Order(local_A); j++) printf("%20.15E ", Entry(local_A,i,j)); printf("\n"); } for (source = 1; source < grid->p; source++) { MPI_Recv(temp_mat, 1, local_matrix_mpi_t, source, 0, grid->comm, &status); MPI_Cart_coords(grid->comm, source, 2, coords); printf("Process %d > grid_row = %d, grid_col = %d\n", source, coords[0], coords[1]); for (i = 0; i < Order(temp_mat); i++) { for (j = 0; j < Order(temp_mat); j++) printf("%20.15E ", Entry(temp_mat,i,j)); printf("\n"); } } fflush(stdout); } else { MPI_Send(local_A, 1, local_matrix_mpi_t, 0, 0, grid->comm); } } /* Print_local_matrices_A */ /*********************************************************/ /* Recive and Print Local Matrix for local matrix B's transpose: * Process 0 print local matrix local_A * Other Processess send local matrix local_A to process 0 * And process 0 receive local matrix local_A from other processess */ void Print_local_matrices_B( char* title /* in */, LOCAL_MATRIX_T* local_B /* in */, GRID_INFO_T* grid /* in */) { int coords[2]; int i, j; int source; MPI_Status status; // print by process No.0 in process mesh if (grid->my_rank == 0) { printf("%s\n", title); printf("Process %d > grid_row = %d, grid_col = %d\n", grid->my_rank, grid->my_row, grid->my_col); for (i = 0; i < Order(local_B); i++) { for (j = 0; j < Order(local_B); j++) printf("%20.15E ", Entry(local_B,j,i)); // switch rows and colums in local_B, for column major storage printf("\n"); } for (source = 1; source < grid->p; source++) { MPI_Recv(temp_mat, 1, local_matrix_mpi_t, source, 0, grid->comm, &status); MPI_Cart_coords(grid->comm, source, 2, coords); printf("Process %d > grid_row = %d, grid_col = %d\n", source, coords[0], coords[1]); for (i = 0; i < Order(temp_mat); i++) { for (j = 0; j < Order(temp_mat); j++) printf("%20.15E ", Entry(temp_mat,j,i)); // switch rows and colums in local_B, for column major storage printf("\n"); } } fflush(stdout); } else { MPI_Send(local_B, 1, local_matrix_mpi_t, 0, 0, grid->comm); } } /* Print_local_matrices_B */ /*********************************************************/ /* Recive and Print Local Matrix A: * Process 0 print local matrix local_A * Other Processess send local matrix local_A to process 0 * And process 0 receive local matrix local_A from other processess */ void Print_local_matrices_C( char* title /* in */, LOCAL_MATRIX_T* local_C /* in */, GRID_INFO_T* grid /* in */) { int coords[2]; int i, j; int source; MPI_Status status; // print by process No.0 in process mesh if (grid->my_rank == 0) { printf("%s\n", title); printf("Process %d > grid_row = %d, grid_col = %d\n", grid->my_rank, grid->my_row, grid->my_col); for (i = 0; i < Order(local_C); i++) { for (j = 0; j < Order(local_C); j++) printf("%20.15E ", Entry(local_C,i,j)); printf("\n"); } for (source = 1; source < grid->p; source++) { MPI_Recv(temp_mat, 1, local_matrix_mpi_t, source, 0, grid->comm, &status); MPI_Cart_coords(grid->comm, source, 2, coords); printf("Process %d > grid_row = %d, grid_col = %d\n", source, coords[0], coords[1]); for (i = 0; i < Order(temp_mat); i++) { for (j = 0; j < Order(temp_mat); j++) printf("%20.15E ", Entry(temp_mat,i,j)); printf("\n"); } } fflush(stdout); } else { MPI_Send(local_C, 1, local_matrix_mpi_t, 0, 0, grid->comm); } } /* Print_local_matrices_C */ /*********************************************************/ /* Recive and Write Local Matrix A: * Process 0 print local matrix local_A * Other Processess send local matrix local_A to process 0 * And process 0 receive local matrix local_A from other processess */ void Write_local_matrices_A( char* title /* in */, LOCAL_MATRIX_T* local_A /* in */, GRID_INFO_T* grid /* in */) { FILE *fp; int coords[2]; int i, j; int source; MPI_Status status; // print by process No.0 in process mesh if (grid->my_rank == 0) { fp = fopen("local_A.dat","w+"); printf("%s\n", title); fprintf(fp,"Process %d > grid_row = %d, grid_col = %d\n", grid->my_rank, grid->my_row, grid->my_col); for (i = 0; i < Order(local_A); i++) { for (j = 0; j < Order(local_A); j++) fprintf(fp,"%20.15E ", Entry(local_A,i,j)); fprintf(fp, "\n"); } for (source = 1; source < grid->p; source++) { MPI_Recv(temp_mat, 1, local_matrix_mpi_t, source, 0, grid->comm, &status); MPI_Cart_coords(grid->comm, source, 2, coords); fprintf(fp, "Process %d > grid_row = %d, grid_col = %d\n", source, coords[0], coords[1]); for (i = 0; i < Order(temp_mat); i++) { for (j = 0; j < Order(temp_mat); j++) fprintf(fp, "%20.15E ", Entry(temp_mat,i,j)); fprintf(fp, "\n"); } } fflush(stdout); fclose(fp); } else { MPI_Send(local_A, 1, local_matrix_mpi_t, 0, 0, grid->comm); } } /* Write_local_matrices_A */ /*********************************************************/ /* Recive and Write Local Matrix for local matrix B's transpose: * Process 0 print local matrix local_A * Other Processess send local matrix local_A to process 0 * And process 0 receive local matrix local_A from other processess */ void Write_local_matrices_B( char* title /* in */, LOCAL_MATRIX_T* local_B /* in */, GRID_INFO_T* grid /* in */) { FILE *fp; int coords[2]; int i, j; int source; MPI_Status status; // print by process No.0 in process mesh if (grid->my_rank == 0) { fp = fopen("local_B.dat","w+"); printf("%s\n", title); fprintf(fp, "Process %d > grid_row = %d, grid_col = %d\n", grid->my_rank, grid->my_row, grid->my_col); for (i = 0; i < Order(local_B); i++) { for (j = 0; j < Order(local_B); j++) fprintf(fp, "%20.15E ", Entry(local_B,j,i)); // switch rows and colums in local_B, for column major storage fprintf(fp, "\n"); } for (source = 1; source < grid->p; source++) { MPI_Recv(temp_mat, 1, local_matrix_mpi_t, source, 0, grid->comm, &status); MPI_Cart_coords(grid->comm, source, 2, coords); fprintf(fp, "Process %d > grid_row = %d, grid_col = %d\n", source, coords[0], coords[1]); for (i = 0; i < Order(temp_mat); i++) { for (j = 0; j < Order(temp_mat); j++) fprintf(fp, "%20.15E ", Entry(temp_mat,j,i)); // switch rows and colums in local_B, for column major storage fprintf(fp, "\n"); } } fflush(stdout); fclose(fp); } else { MPI_Send(local_B, 1, local_matrix_mpi_t, 0, 0, grid->comm); } } /* Write_local_matrices_B */ /*********************************************************/ /* Recive and Write Local Matrix C: * Process 0 print local matrix local_C * Other Processess send local matrix local_C to process 0 * And process 0 receive local matrix local_C from other processess */ void Write_local_matrices_C( char* title /* in */, LOCAL_MATRIX_T* local_C /* in */, GRID_INFO_T* grid /* in */) { FILE *fp; int coords[2]; int i, j; int source; MPI_Status status; // print by process No.0 in process mesh if (grid->my_rank == 0) { fp = fopen("local_C.dat","w+"); printf("%s\n", title); fprintf(fp, "Process %d > grid_row = %d, grid_col = %d\n", grid->my_rank, grid->my_row, grid->my_col); for (i = 0; i < Order(local_C); i++) { for (j = 0; j < Order(local_C); j++) fprintf(fp, "%20.15E ", Entry(local_C,i,j)); fprintf(fp, "\n"); } for (source = 1; source < grid->p; source++) { MPI_Recv(temp_mat, 1, local_matrix_mpi_t, source, 0, grid->comm, &status); MPI_Cart_coords(grid->comm, source, 2, coords); fprintf(fp, "Process %d > grid_row = %d, grid_col = %d\n", source, coords[0], coords[1]); for (i = 0; i < Order(temp_mat); i++) { for (j = 0; j < Order(temp_mat); j++) fprintf(fp, "%20.15E ", Entry(temp_mat,i,j)); fprintf(fp, "\n"); } } fflush(stdout); fclose(fp); } else { MPI_Send(local_C, 1, local_matrix_mpi_t, 0, 0, grid->comm); } } /* Write_local_matrices_C */

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 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 "magick/studio.h" #include "magick/artifact.h" #include "magick/attribute.h" #include "magick/blob.h" #include "magick/cache.h" #include "magick/image.h" #include "magick/image-private.h" #include "magick/list.h" #include "magick/fourier.h" #include "magick/log.h" #include "magick/memory_.h" #include "magick/monitor.h" #include "magick/monitor-private.h" #include "magick/pixel-accessor.h" #include "magick/pixel-private.h" #include "magick/property.h" #include "magick/quantum-private.h" #include "magick/resource_.h" #include "magick/string-private.h" #include "magick/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 { ChannelType 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, 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) == 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); } if (SetImageStorageClass(image,DirectClass) == MagickFalse) { image=DestroyImageList(image); return(image); } image->depth=32UL; AppendImageToList(&complex_images,image); /* Apply complex mathematics to image pixels. */ artifact=GetImageArtifact(image,"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; 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++) { register const PixelPacket *magick_restrict Ai, *magick_restrict Ar, *magick_restrict Bi, *magick_restrict Br; register PixelPacket *magick_restrict Ci, *magick_restrict Cr; register 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 PixelPacket *) NULL) || (Ai == (const PixelPacket *) NULL) || (Br == (const PixelPacket *) NULL) || (Bi == (const PixelPacket *) NULL) || (Cr == (PixelPacket *) NULL) || (Ci == (PixelPacket *) NULL)) { status=MagickFalse; continue; } for (x=0; x < (ssize_t) columns; x++) { switch (op) { case AddComplexOperator: { Cr->red=Ar->red+Br->red; Ci->red=Ai->red+Bi->red; Cr->green=Ar->green+Br->green; Ci->green=Ai->green+Bi->green; Cr->blue=Ar->blue+Br->blue; Ci->blue=Ai->blue+Bi->blue; if (images->matte != MagickFalse) { Cr->opacity=Ar->opacity+Br->opacity; Ci->opacity=Ai->opacity+Bi->opacity; } break; } case ConjugateComplexOperator: default: { Cr->red=Ar->red; Ci->red=(-Bi->red); Cr->green=Ar->green; Ci->green=(-Bi->green); Cr->blue=Ar->blue; Ci->blue=(-Bi->blue); if (images->matte != MagickFalse) { Cr->opacity=Ar->opacity; Ci->opacity=(-Bi->opacity); } break; } case DivideComplexOperator: { double gamma; gamma=QuantumRange*PerceptibleReciprocal(QuantumScale*Br->red*Br->red+ QuantumScale*Bi->red*Bi->red+snr); Cr->red=gamma*(QuantumScale*Ar->red*Br->red+QuantumScale*Ai->red* Bi->red); Ci->red=gamma*(QuantumScale*Ai->red*Br->red-QuantumScale*Ar->red* Bi->red); gamma=QuantumRange*PerceptibleReciprocal(QuantumScale*Br->green* Br->green+QuantumScale*Bi->green*Bi->green+snr); Cr->green=gamma*(QuantumScale*Ar->green*Br->green+QuantumScale* Ai->green*Bi->green); Ci->green=gamma*(QuantumScale*Ai->green*Br->green-QuantumScale* Ar->green*Bi->green); gamma=QuantumRange*PerceptibleReciprocal(QuantumScale*Br->blue* Br->blue+QuantumScale*Bi->blue*Bi->blue+snr); Cr->blue=gamma*(QuantumScale*Ar->blue*Br->blue+QuantumScale* Ai->blue*Bi->blue); Ci->blue=gamma*(QuantumScale*Ai->blue*Br->blue-QuantumScale* Ar->blue*Bi->blue); if (images->matte != MagickFalse) { gamma=QuantumRange*PerceptibleReciprocal(QuantumScale*Br->opacity* Br->opacity+QuantumScale*Bi->opacity*Bi->opacity+snr); Cr->opacity=gamma*(QuantumScale*Ar->opacity*Br->opacity+ QuantumScale*Ai->opacity*Bi->opacity); Ci->opacity=gamma*(QuantumScale*Ai->opacity*Br->opacity- QuantumScale*Ar->opacity*Bi->opacity); } break; } case MagnitudePhaseComplexOperator: { Cr->red=sqrt(QuantumScale*Ar->red*Ar->red+QuantumScale* Ai->red*Ai->red); Ci->red=atan2((double) Ai->red,(double) Ar->red)/(2.0*MagickPI)+0.5; Cr->green=sqrt(QuantumScale*Ar->green*Ar->green+QuantumScale* Ai->green*Ai->green); Ci->green=atan2((double) Ai->green,(double) Ar->green)/ (2.0*MagickPI)+0.5; Cr->blue=sqrt(QuantumScale*Ar->blue*Ar->blue+QuantumScale* Ai->blue*Ai->blue); Ci->blue=atan2(Ai->blue,Ar->blue)/(2.0*MagickPI)+0.5; if (images->matte != MagickFalse) { Cr->opacity=sqrt(QuantumScale*Ar->opacity*Ar->opacity+ QuantumScale*Ai->opacity*Ai->opacity); Ci->opacity=atan2((double) Ai->opacity,(double) Ar->opacity)/ (2.0*MagickPI)+0.5; } break; } case MultiplyComplexOperator: { Cr->red=(QuantumScale*Ar->red*Br->red-(double) Ai->red*Bi->red); Ci->red=(QuantumScale*Ai->red*Br->red+(double) Ar->red*Bi->red); Cr->green=(QuantumScale*Ar->green*Br->green-(double) Ai->green*Bi->green); Ci->green=(QuantumScale*Ai->green*Br->green+(double) Ar->green*Bi->green); Cr->blue=(QuantumScale*Ar->blue*Br->blue-(double) Ai->blue*Bi->blue); Ci->blue=(QuantumScale*Ai->blue*Br->blue+(double) Ar->blue*Bi->blue); if (images->matte != MagickFalse) { Cr->opacity=(QuantumScale*Ar->opacity*Br->opacity- QuantumScale*Ai->opacity*Bi->opacity); Ci->opacity=(QuantumScale*Ai->opacity*Br->opacity+ QuantumScale*Ar->opacity*Bi->opacity); } break; } case RealImaginaryComplexOperator: { Cr->red=Ar->red*cos(2.0*MagickPI*(Ai->red-0.5)); Ci->red=Ar->red*sin(2.0*MagickPI*(Ai->red-0.5)); Cr->green=Ar->green*cos(2.0*MagickPI*(Ai->green-0.5)); Ci->green=Ar->green*sin(2.0*MagickPI*(Ai->green-0.5)); Cr->blue=Ar->blue*cos(2.0*MagickPI*(Ai->blue-0.5)); Ci->blue=Ar->blue*sin(2.0*MagickPI*(Ai->blue-0.5)); if (images->matte != MagickFalse) { Cr->opacity=Ar->opacity*cos(2.0*MagickPI*(Ai->opacity-0.5)); Ci->opacity=Ar->opacity*sin(2.0*MagickPI*(Ai->opacity-0.5)); } break; } case SubtractComplexOperator: { Cr->red=Ar->red-Br->red; Ci->red=Ai->red-Bi->red; Cr->green=Ar->green-Br->green; Ci->green=Ai->green-Bi->green; Cr->blue=Ar->blue-Br->blue; Ci->blue=Ai->blue-Bi->blue; if (Cr_image->matte != MagickFalse) { Cr->opacity=Ar->opacity-Br->opacity; Ci->opacity=Ai->opacity-Bi->opacity; } break; } } Ar++; Ai++; Br++; Bi++; Cr++; Ci++; } 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; register 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; register 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) { register 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; register IndexPacket *indexes; register PixelPacket *q; register 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 == (PixelPacket *) NULL) break; indexes=GetCacheViewAuthenticIndexQueue(magnitude_view); for (x=0L; x < (ssize_t) fourier_info->width; x++) { switch (fourier_info->channel) { case RedChannel: default: { SetPixelRed(q,ClampToQuantum(QuantumRange*magnitude_pixels[i])); break; } case GreenChannel: { SetPixelGreen(q,ClampToQuantum(QuantumRange*magnitude_pixels[i])); break; } case BlueChannel: { SetPixelBlue(q,ClampToQuantum(QuantumRange*magnitude_pixels[i])); break; } case OpacityChannel: { SetPixelOpacity(q,ClampToQuantum(QuantumRange*magnitude_pixels[i])); break; } case IndexChannel: { SetPixelIndex(indexes+x,ClampToQuantum(QuantumRange* magnitude_pixels[i])); break; } case GrayChannels: { SetPixelGray(q,ClampToQuantum(QuantumRange*magnitude_pixels[i])); break; } } i++; q++; } 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 == (PixelPacket *) NULL) break; indexes=GetCacheViewAuthenticIndexQueue(phase_view); for (x=0L; x < (ssize_t) fourier_info->width; x++) { switch (fourier_info->channel) { case RedChannel: default: { SetPixelRed(q,ClampToQuantum(QuantumRange*phase_pixels[i])); break; } case GreenChannel: { SetPixelGreen(q,ClampToQuantum(QuantumRange*phase_pixels[i])); break; } case BlueChannel: { SetPixelBlue(q,ClampToQuantum(QuantumRange*phase_pixels[i])); break; } case OpacityChannel: { SetPixelOpacity(q,ClampToQuantum(QuantumRange*phase_pixels[i])); break; } case IndexChannel: { SetPixelIndex(indexes+x,ClampToQuantum(QuantumRange*phase_pixels[i])); break; } case GrayChannels: { SetPixelGray(q,ClampToQuantum(QuantumRange*phase_pixels[i])); break; } } i++; q++; } 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; register const IndexPacket *indexes; register const PixelPacket *p; register 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 PixelPacket *) NULL) break; indexes=GetCacheViewVirtualIndexQueue(image_view); for (x=0L; x < (ssize_t) fourier_info->width; x++) { switch (fourier_info->channel) { case RedChannel: default: { source_pixels[i]=QuantumScale*GetPixelRed(p); break; } case GreenChannel: { source_pixels[i]=QuantumScale*GetPixelGreen(p); break; } case BlueChannel: { source_pixels[i]=QuantumScale*GetPixelBlue(p); break; } case OpacityChannel: { source_pixels[i]=QuantumScale*GetPixelOpacity(p); break; } case IndexChannel: { source_pixels[i]=QuantumScale*GetPixelIndex(indexes+x); break; } case GrayChannels: { source_pixels[i]=QuantumScale*GetPixelGray(p); break; } } i++; p++; } } 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 Fourier 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 ChannelType 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=IsGrayImage(image,exception); #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, GrayChannels,modulus,fourier_image,exception); else thread_status=ForwardFourierTransformChannel(image,RedChannel, 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, GreenChannel,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, BlueChannel,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->matte != MagickFalse) thread_status=ForwardFourierTransformChannel(image, OpacityChannel,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, IndexChannel,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) { register 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; register const IndexPacket *indexes; register const PixelPacket *p; register 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 PixelPacket *) NULL) break; indexes=GetCacheViewAuthenticIndexQueue(magnitude_view); for (x=0L; x < (ssize_t) fourier_info->width; x++) { switch (fourier_info->channel) { case RedChannel: default: { magnitude_pixels[i]=QuantumScale*GetPixelRed(p); break; } case GreenChannel: { magnitude_pixels[i]=QuantumScale*GetPixelGreen(p); break; } case BlueChannel: { magnitude_pixels[i]=QuantumScale*GetPixelBlue(p); break; } case OpacityChannel: { magnitude_pixels[i]=QuantumScale*GetPixelOpacity(p); break; } case IndexChannel: { magnitude_pixels[i]=QuantumScale*GetPixelIndex(indexes+x); break; } case GrayChannels: { magnitude_pixels[i]=QuantumScale*GetPixelGray(p); break; } } i++; p++; } } 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 PixelPacket *) NULL) break; indexes=GetCacheViewAuthenticIndexQueue(phase_view); for (x=0L; x < (ssize_t) fourier_info->width; x++) { switch (fourier_info->channel) { case RedChannel: default: { phase_pixels[i]=QuantumScale*GetPixelRed(p); break; } case GreenChannel: { phase_pixels[i]=QuantumScale*GetPixelGreen(p); break; } case BlueChannel: { phase_pixels[i]=QuantumScale*GetPixelBlue(p); break; } case OpacityChannel: { phase_pixels[i]=QuantumScale*GetPixelOpacity(p); break; } case IndexChannel: { phase_pixels[i]=QuantumScale*GetPixelIndex(indexes+x); break; } case GrayChannels: { phase_pixels[i]=QuantumScale*GetPixelGray(p); break; } } i++; p++; } } 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; double *source_pixels; const char *value; fftw_plan fftw_c2r_plan; MemoryInfo *source_info; register IndexPacket *indexes; register PixelPacket *q; register 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 == (PixelPacket *) NULL) break; indexes=GetCacheViewAuthenticIndexQueue(image_view); for (x=0L; x < (ssize_t) fourier_info->width; x++) { if (x < (ssize_t) image->columns) switch (fourier_info->channel) { case RedChannel: default: { SetPixelRed(q,ClampToQuantum(QuantumRange*source_pixels[i])); break; } case GreenChannel: { SetPixelGreen(q,ClampToQuantum(QuantumRange*source_pixels[i])); break; } case BlueChannel: { SetPixelBlue(q,ClampToQuantum(QuantumRange*source_pixels[i])); break; } case OpacityChannel: { SetPixelOpacity(q,ClampToQuantum(QuantumRange*source_pixels[i])); break; } case IndexChannel: { SetPixelIndex(indexes+x,ClampToQuantum(QuantumRange* source_pixels[i])); break; } case GrayChannels: { SetPixelGray(q,ClampToQuantum(QuantumRange*source_pixels[i])); break; } } i++; q++; } 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 ChannelType 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=IsGrayImage(magnitude_image,exception); if (is_gray != MagickFalse) is_gray=IsGrayImage(phase_image,exception); #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,GrayChannels,modulus,fourier_image,exception); else thread_status=InverseFourierTransformChannel(magnitude_image, phase_image,RedChannel,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,GreenChannel,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,BlueChannel,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->matte != MagickFalse) thread_status=InverseFourierTransformChannel(magnitude_image, phase_image,OpacityChannel,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,IndexChannel,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); }

for_misc_messages.c

// RUN: %clang_cc1 -fsyntax-only -fopenmp -triple x86_64-unknown-unknown -verify %s // expected-error@+1 {{unexpected OpenMP directive '#pragma omp for'}} #pragma omp for // expected-error@+1 {{unexpected OpenMP directive '#pragma omp for'}} #pragma omp for foo void test_no_clause() { int i; #pragma omp for for (i = 0; i < 16; ++i) ; // expected-error@+2 {{statement after '#pragma omp for' must be a for loop}} #pragma omp for ++i; } void test_branch_protected_scope() { int i = 0; L1: ++i; int x[24]; #pragma omp parallel #pragma omp for for (i = 0; i < 16; ++i) { if (i == 5) goto L1; // expected-error {{use of undeclared label 'L1'}} else if (i == 6) return; // expected-error {{cannot return from OpenMP region}} else if (i == 7) goto L2; else if (i == 8) { L2: x[i]++; } } if (x[0] == 0) goto L2; // expected-error {{use of undeclared label 'L2'}} else if (x[1] == 1) goto L1; } void test_invalid_clause() { int i; #pragma omp parallel // expected-warning@+1 {{extra tokens at the end of '#pragma omp for' are ignored}} #pragma omp for foo bar for (i = 0; i < 16; ++i) ; } void test_non_identifiers() { int i, x; #pragma omp parallel // expected-warning@+1 {{extra tokens at the end of '#pragma omp for' are ignored}} #pragma omp for; for (i = 0; i < 16; ++i) ; // expected-warning@+2 {{extra tokens at the end of '#pragma omp for' are ignored}} #pragma omp parallel #pragma omp for linear(x); for (i = 0; i < 16; ++i) ; #pragma omp parallel // expected-warning@+1 {{extra tokens at the end of '#pragma omp for' are ignored}} #pragma omp for private(x); for (i = 0; i < 16; ++i) ; #pragma omp parallel // expected-warning@+1 {{extra tokens at the end of '#pragma omp for' are ignored}} #pragma omp for, private(x); for (i = 0; i < 16; ++i) ; } extern int foo(); void test_collapse() { int i; #pragma omp parallel // expected-error@+1 {{expected '('}} #pragma omp for collapse for (i = 0; i < 16; ++i) ; #pragma omp parallel // expected-error@+1 {{expected expression}} expected-error@+1 {{expected ')'}} expected-note@+1 {{to match this '('}} #pragma omp for collapse( for (i = 0; i < 16; ++i) ; #pragma omp parallel // expected-error@+1 {{expected expression}} #pragma omp for collapse() for (i = 0; i < 16; ++i) ; #pragma omp parallel // expected-error@+1 {{expected expression}} expected-error@+1 {{expected ')'}} expected-note@+1 {{to match this '('}} #pragma omp for collapse(, for (i = 0; i < 16; ++i) ; #pragma omp parallel // expected-error@+1 {{expected expression}} expected-error@+1 {{expected ')'}} expected-note@+1 {{to match this '('}} #pragma omp for collapse(, ) for (i = 0; i < 16; ++i) ; #pragma omp parallel // expected-warning@+2 {{extra tokens at the end of '#pragma omp for' are ignored}} // expected-error@+1 {{expected '('}} #pragma omp for collapse 4) for (i = 0; i < 16; ++i) ; #pragma omp parallel // expected-error@+2 {{expected ')'}} // expected-note@+1 {{to match this '('}} expected-note@+1 {{as specified in 'collapse' clause}} #pragma omp for collapse(4 for (i = 0; i < 16; ++i) ; // expected-error {{expected 4 for loops after '#pragma omp for', but found only 1}} #pragma omp parallel // expected-error@+2 {{expected ')'}} // expected-note@+1 {{to match this '('}} expected-note@+1 {{as specified in 'collapse' clause}} #pragma omp for collapse(4, for (i = 0; i < 16; ++i) ; // expected-error {{expected 4 for loops after '#pragma omp for', but found only 1}} #pragma omp parallel // expected-error@+2 {{expected ')'}} // expected-note@+1 {{to match this '('}} expected-note@+1 {{as specified in 'collapse' clause}} #pragma omp for collapse(4, ) for (i = 0; i < 16; ++i) ; // expected-error {{expected 4 for loops after '#pragma omp for', but found only 1}} #pragma omp parallel // expected-note@+1 {{as specified in 'collapse' clause}} #pragma omp for collapse(4) for (i = 0; i < 16; ++i) ; // expected-error {{expected 4 for loops after '#pragma omp for', but found only 1}} #pragma omp parallel // expected-error@+2 {{expected ')'}} // expected-note@+1 {{to match this '('}} expected-note@+1 {{as specified in 'collapse' clause}} #pragma omp for collapse(4 4) for (i = 0; i < 16; ++i) ; // expected-error {{expected 4 for loops after '#pragma omp for', but found only 1}} #pragma omp parallel // expected-error@+2 {{expected ')'}} // expected-note@+1 {{to match this '('}} expected-note@+1 {{as specified in 'collapse' clause}} #pragma omp for collapse(4, , 4) for (i = 0; i < 16; ++i) ; // expected-error {{expected 4 for loops after '#pragma omp for', but found only 1}} #pragma omp parallel #pragma omp for collapse(4) for (int i1 = 0; i1 < 16; ++i1) for (int i2 = 0; i2 < 16; ++i2) for (int i3 = 0; i3 < 16; ++i3) for (int i4 = 0; i4 < 16; ++i4) foo(); #pragma omp parallel // expected-error@+2 {{expected ')'}} // expected-note@+1 {{to match this '('}} expected-note@+1 {{as specified in 'collapse' clause}} #pragma omp for collapse(4, 8) for (i = 0; i < 16; ++i) ; // expected-error {{expected 4 for loops after '#pragma omp for', but found only 1}} #pragma omp parallel // expected-error@+1 {{expression is not an integer constant expression}} #pragma omp for collapse(2.5) for (i = 0; i < 16; ++i) ; #pragma omp parallel // expected-error@+1 {{expression is not an integer constant expression}} #pragma omp for collapse(foo()) for (i = 0; i < 16; ++i) ; #pragma omp parallel // expected-error@+1 {{argument to 'collapse' clause must be a strictly positive integer value}} #pragma omp for collapse(-5) for (i = 0; i < 16; ++i) ; #pragma omp parallel // expected-error@+1 {{argument to 'collapse' clause must be a strictly positive integer value}} #pragma omp for collapse(0) for (i = 0; i < 16; ++i) ; #pragma omp parallel // expected-error@+1 {{argument to 'collapse' clause must be a strictly positive integer value}} #pragma omp for collapse(5 - 5) for (i = 0; i < 16; ++i) ; #pragma omp parallel #pragma omp for collapse(2) for (i = 0; i < 16; ++i) // expected-note@+1 {{variable with automatic storage duration is predetermined as private; perhaps you forget to enclose 'omp for' directive into a parallel or another task region?}} for (int j = 0; j < 16; ++j) // expected-error@+2 {{reduction variable must be shared}} // expected-error@+1 {{region cannot be closely nested inside 'for' region; perhaps you forget to enclose 'omp for' directive into a parallel region?}} #pragma omp for reduction(+ : i, j) for (int k = 0; k < 16; ++k) i += j; } void test_private() { int i; #pragma omp parallel // expected-error@+2 {{expected expression}} // expected-error@+1 {{expected ')'}} expected-note@+1 {{to match this '('}} #pragma omp for private( for (i = 0; i < 16; ++i) ; #pragma omp parallel // expected-error@+2 {{expected ')'}} expected-note@+2 {{to match this '('}} // expected-error@+1 2 {{expected expression}} #pragma omp for private(, for (i = 0; i < 16; ++i) ; #pragma omp parallel // expected-error@+1 2 {{expected expression}} #pragma omp for private(, ) for (i = 0; i < 16; ++i) ; #pragma omp parallel // expected-error@+1 {{expected expression}} #pragma omp for private() for (i = 0; i < 16; ++i) ; #pragma omp parallel // expected-error@+1 {{expected expression}} #pragma omp for private(int) for (i = 0; i < 16; ++i) ; #pragma omp parallel // expected-error@+1 {{expected variable name}} #pragma omp for private(0) for (i = 0; i < 16; ++i) ; int x, y, z; #pragma omp parallel #pragma omp for private(x) for (i = 0; i < 16; ++i) ; #pragma omp parallel #pragma omp for private(x, y) for (i = 0; i < 16; ++i) ; #pragma omp parallel #pragma omp for private(x, y, z) for (i = 0; i < 16; ++i) { x = y * i + z; } } void test_lastprivate() { int i; #pragma omp parallel // expected-error@+2 {{expected ')'}} expected-note@+2 {{to match this '('}} // expected-error@+1 {{expected expression}} #pragma omp for lastprivate( for (i = 0; i < 16; ++i) ; #pragma omp parallel // expected-error@+2 {{expected ')'}} expected-note@+2 {{to match this '('}} // expected-error@+1 2 {{expected expression}} #pragma omp for lastprivate(, for (i = 0; i < 16; ++i) ; #pragma omp parallel // expected-error@+1 2 {{expected expression}} #pragma omp for lastprivate(, ) for (i = 0; i < 16; ++i) ; #pragma omp parallel // expected-error@+1 {{expected expression}} #pragma omp for lastprivate() for (i = 0; i < 16; ++i) ; #pragma omp parallel // expected-error@+1 {{expected expression}} #pragma omp for lastprivate(int) for (i = 0; i < 16; ++i) ; #pragma omp parallel // expected-error@+1 {{expected variable name}} #pragma omp for lastprivate(0) for (i = 0; i < 16; ++i) ; int x, y, z; #pragma omp parallel #pragma omp for lastprivate(x) for (i = 0; i < 16; ++i) ; #pragma omp parallel #pragma omp for lastprivate(x, y) for (i = 0; i < 16; ++i) ; #pragma omp parallel #pragma omp for lastprivate(x, y, z) for (i = 0; i < 16; ++i) ; } void test_firstprivate() { int i; #pragma omp parallel // expected-error@+2 {{expected ')'}} expected-note@+2 {{to match this '('}} // expected-error@+1 {{expected expression}} #pragma omp for firstprivate( for (i = 0; i < 16; ++i) ; #pragma omp parallel // expected-error@+2 {{expected ')'}} expected-note@+2 {{to match this '('}} // expected-error@+1 2 {{expected expression}} #pragma omp for firstprivate(, for (i = 0; i < 16; ++i) ; #pragma omp parallel // expected-error@+1 2 {{expected expression}} #pragma omp for firstprivate(, ) for (i = 0; i < 16; ++i) ; #pragma omp parallel // expected-error@+1 {{expected expression}} #pragma omp for firstprivate() for (i = 0; i < 16; ++i) ; #pragma omp parallel // expected-error@+1 {{expected expression}} #pragma omp for firstprivate(int) for (i = 0; i < 16; ++i) ; #pragma omp parallel // expected-error@+1 {{expected variable name}} #pragma omp for firstprivate(0) for (i = 0; i < 16; ++i) ; int x, y, z; #pragma omp parallel #pragma omp for lastprivate(x) firstprivate(x) for (i = 0; i < 16; ++i) ; #pragma omp parallel #pragma omp for lastprivate(x, y) firstprivate(x, y) for (i = 0; i < 16; ++i) ; #pragma omp parallel #pragma omp for lastprivate(x, y, z) firstprivate(x, y, z) for (i = 0; i < 16; ++i) ; } void test_loop_messages() { float a[100], b[100], c[100]; #pragma omp parallel // expected-error@+2 {{variable must be of integer or pointer type}} #pragma omp for for (float fi = 0; fi < 10.0; fi++) { c[(int)fi] = a[(int)fi] + b[(int)fi]; } #pragma omp parallel // expected-error@+2 {{variable must be of integer or pointer type}} #pragma omp for for (double fi = 0; fi < 10.0; fi++) { c[(int)fi] = a[(int)fi] + b[(int)fi]; } // expected-warning@+2 {{OpenMP loop iteration variable cannot have more than 64 bits size and will be narrowed}} #pragma omp for for (__int128 ii = 0; ii < 10; ii++) { c[ii] = a[ii] + b[ii]; } }

pr39591-1.c

/* PR other/39591 */ /* { dg-do run } */ extern void abort (void); int err; int main (void) { #pragma omp parallel { int array[40]; int i; for (i = 0; i < sizeof array / sizeof array[0]; i++) array[i] = 0x55555555; #pragma omp for schedule(dynamic) for (i = 0; i < 50; i++) #pragma omp task shared(array) { int j; for (j = 0; j < sizeof array / sizeof array[0]; j++) if (array[j] != 0x55555555) #pragma omp atomic err++; } } if (err) abort (); return 0; }

rawSHA224_fmt_plug.c

/* * This file is part of John the Ripper password cracker, * Copyright (c) 2010 by Solar Designer * based on rawMD4_fmt.c code, with trivial changes by groszek. * * Rewritten Spring 2013, JimF. SSE code added and released with the following terms: * No copyright is claimed, and the software is hereby placed in the public domain. * In case this attempt to disclaim copyright and place the software in the public * domain is deemed null and void, then the software is Copyright (c) 2011 JimF * and it is hereby released to the general public under the following * terms: * * This software may be modified, redistributed, and used for any * purpose, in source and binary forms, with or without modification. */ #if FMT_EXTERNS_H extern struct fmt_main fmt_rawSHA224; #elif FMT_REGISTERS_H john_register_one(&fmt_rawSHA224); #else #include "arch.h" #include "sha2.h" #include "stdint.h" #include "params.h" #include "common.h" #include "johnswap.h" #include "formats.h" #include "simd-intrinsics.h" //#undef SIMD_COEF_32 //#undef SIMD_PARA_SHA256 /* * Only effective for SIMD. * Undef to disable reversing steps for benchmarking. */ #define REVERSE_STEPS #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 "memdbg.h" #define FORMAT_LABEL "Raw-SHA224" #define FORMAT_NAME "" #define FORMAT_TAG "$SHA224$" #define TAG_LENGTH 8 #ifdef SIMD_COEF_32 #define ALGORITHM_NAME SHA256_ALGORITHM_NAME #else #define ALGORITHM_NAME "32/" ARCH_BITS_STR " " SHA2_LIB #endif #define BENCHMARK_COMMENT "" #define BENCHMARK_LENGTH -1 #ifdef SIMD_COEF_32 #define PLAINTEXT_LENGTH 55 #else #define PLAINTEXT_LENGTH 125 #endif #define CIPHERTEXT_LENGTH 56 #define BINARY_SIZE DIGEST_SIZE #define DIGEST_SIZE 28 #define DIGEST_SIZE_256 32 #define BINARY_ALIGN MEM_ALIGN_WORD #define SALT_SIZE 0 #define SALT_ALIGN 1 #ifdef SIMD_COEF_32 #define MIN_KEYS_PER_CRYPT (SIMD_COEF_32*SIMD_PARA_SHA256) #define MAX_KEYS_PER_CRYPT (SIMD_COEF_32*SIMD_PARA_SHA256) #else #define MIN_KEYS_PER_CRYPT 1 #define MAX_KEYS_PER_CRYPT 1 #endif static struct fmt_tests tests[] = { {"d63dc919e201d7bc4c825630d2cf25fdc93d4b2f0d46706d29038d01", "password"}, {"$SHA224$d63dc919e201d7bc4c825630d2cf25fdc93d4b2f0d46706d29038d01", "password"}, {"$SHA224$7e6a4309ddf6e8866679f61ace4f621b0e3455ebac2e831a60f13cd1", "12345678"}, {"$SHA224$d14a028c2a3a2bc9476102bb288234c415a2b01f828ea62ac5b3e42f", ""}, {"b93ff16271aa688dbf671120817d75b895b874ab2b9bb9f71481d88d", "UPPERCASE"}, {NULL} }; #ifdef SIMD_COEF_32 #define GETPOS(i, index) ( (index&(SIMD_COEF_32-1))*4 + ((i)&(0xffffffff-3))*SIMD_COEF_32 + (3-((i)&3)) + (unsigned int)index/SIMD_COEF_32*SHA_BUF_SIZ*SIMD_COEF_32*4 ) static uint32_t (*saved_key); static uint32_t (*crypt_out); #else static int (*saved_len); static char (*saved_key)[PLAINTEXT_LENGTH + 1]; static ARCH_WORD_32 (*crypt_out) [(DIGEST_SIZE + sizeof(ARCH_WORD_32) - 1) / sizeof(ARCH_WORD_32)]; #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 #ifndef SIMD_COEF_32 saved_len = mem_calloc(self->params.max_keys_per_crypt, sizeof(*saved_len)); saved_key = mem_calloc(self->params.max_keys_per_crypt, sizeof(*saved_key)); crypt_out = mem_calloc(self->params.max_keys_per_crypt, sizeof(*crypt_out)); #else saved_key = mem_calloc_align(self->params.max_keys_per_crypt * SHA_BUF_SIZ, sizeof(*saved_key), MEM_ALIGN_SIMD); crypt_out = mem_calloc_align(self->params.max_keys_per_crypt * DIGEST_SIZE_256 / sizeof(uint32_t), sizeof(*crypt_out), MEM_ALIGN_SIMD); #endif } static void done(void) { MEM_FREE(crypt_out); MEM_FREE(saved_key); #ifndef SIMD_COEF_32 MEM_FREE(saved_len); #endif } static int valid(char *ciphertext, struct fmt_main *self) { char *p, *q; p = ciphertext; if (!strncmp(p, FORMAT_TAG, TAG_LENGTH)) p += 8; q = p; while (atoi16[ARCH_INDEX(*q)] != 0x7F) 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)) ciphertext += TAG_LENGTH; memcpy(out, FORMAT_TAG, TAG_LENGTH); memcpy(out + TAG_LENGTH, ciphertext, CIPHERTEXT_LENGTH + 1); strlwr(out + TAG_LENGTH); return out; } static void *get_binary(char *ciphertext) { static unsigned int *outw; unsigned char *out; char *p; int i; if (!outw) outw = mem_calloc_tiny(DIGEST_SIZE, MEM_ALIGN_WORD); out = (unsigned char*)outw; 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; } #ifdef SIMD_COEF_32 alter_endianity (out, DIGEST_SIZE); #ifdef REVERSE_STEPS sha224_reverse(outw); #endif #endif return out; } #ifdef SIMD_COEF_32 #define HASH_IDX (((unsigned int)index&(SIMD_COEF_32-1))+(unsigned int)index/SIMD_COEF_32*8*SIMD_COEF_32 + 3*SIMD_COEF_32) static int get_hash_0 (int index) { return crypt_out[HASH_IDX] & PH_MASK_0; } static int get_hash_1 (int index) { return crypt_out[HASH_IDX] & PH_MASK_1; } static int get_hash_2 (int index) { return crypt_out[HASH_IDX] & PH_MASK_2; } static int get_hash_3 (int index) { return crypt_out[HASH_IDX] & PH_MASK_3; } static int get_hash_4 (int index) { return crypt_out[HASH_IDX] & PH_MASK_4; } static int get_hash_5 (int index) { return crypt_out[HASH_IDX] & PH_MASK_5; } static int get_hash_6 (int index) { return crypt_out[HASH_IDX] & PH_MASK_6; } #else static int get_hash_0(int index) { return crypt_out[index][3] & PH_MASK_0; } static int get_hash_1(int index) { return crypt_out[index][3] & PH_MASK_1; } static int get_hash_2(int index) { return crypt_out[index][3] & PH_MASK_2; } static int get_hash_3(int index) { return crypt_out[index][3] & PH_MASK_3; } static int get_hash_4(int index) { return crypt_out[index][3] & PH_MASK_4; } static int get_hash_5(int index) { return crypt_out[index][3] & PH_MASK_5; } static int get_hash_6(int index) { return crypt_out[index][3] & PH_MASK_6; } #endif static int binary_hash_0(void *binary) { return ((ARCH_WORD_32*)binary)[3] & PH_MASK_0; } static int binary_hash_1(void *binary) { return ((ARCH_WORD_32*)binary)[3] & PH_MASK_1; } static int binary_hash_2(void *binary) { return ((ARCH_WORD_32*)binary)[3] & PH_MASK_2; } static int binary_hash_3(void *binary) { return ((ARCH_WORD_32*)binary)[3] & PH_MASK_3; } static int binary_hash_4(void *binary) { return ((ARCH_WORD_32*)binary)[3] & PH_MASK_4; } static int binary_hash_5(void *binary) { return ((ARCH_WORD_32*)binary)[3] & PH_MASK_5; } static int binary_hash_6(void *binary) { return ((ARCH_WORD_32*)binary)[3] & PH_MASK_6; } #ifdef SIMD_COEF_32 static void set_key(char *key, int index) { #if ARCH_ALLOWS_UNALIGNED const ARCH_WORD_32 *wkey = (ARCH_WORD_32*)key; #else char buf_aligned[PLAINTEXT_LENGTH + 1] JTR_ALIGN(sizeof(uint32_t)); const ARCH_WORD_32 *wkey = (uint32_t*)(is_aligned(key, sizeof(uint32_t)) ? key : strcpy(buf_aligned, key)); #endif ARCH_WORD_32 *keybuffer = &((ARCH_WORD_32 *)saved_key)[(index&(SIMD_COEF_32-1)) + (unsigned int)index/SIMD_COEF_32*SHA_BUF_SIZ*SIMD_COEF_32]; ARCH_WORD_32 *keybuf_word = keybuffer; unsigned int len; ARCH_WORD_32 temp; len = 0; while((unsigned char)(temp = *wkey++)) { if (!(temp & 0xff00)) { *keybuf_word = JOHNSWAP((temp & 0xff) | (0x80 << 8)); len++; goto key_cleaning; } if (!(temp & 0xff0000)) { *keybuf_word = JOHNSWAP((temp & 0xffff) | (0x80 << 16)); len+=2; goto key_cleaning; } if (!(temp & 0xff000000)) { *keybuf_word = JOHNSWAP(temp | (0x80U << 24)); len+=3; goto key_cleaning; } *keybuf_word = JOHNSWAP(temp); len += 4; keybuf_word += SIMD_COEF_32; } *keybuf_word = 0x80000000; key_cleaning: keybuf_word += SIMD_COEF_32; while(*keybuf_word) { *keybuf_word = 0; keybuf_word += SIMD_COEF_32; } keybuffer[15*SIMD_COEF_32] = len << 3; } #else static void set_key(char *key, int index) { int len = strlen(key); saved_len[index] = len; if (len > PLAINTEXT_LENGTH) len = saved_len[index] = PLAINTEXT_LENGTH; memcpy(saved_key[index], key, len); } #endif #ifdef SIMD_COEF_32 static char *get_key(int index) { unsigned int i,s; static char out[PLAINTEXT_LENGTH+1]; unsigned char *wucp = (unsigned char*)saved_key; s = ((ARCH_WORD_32 *)saved_key)[15*SIMD_COEF_32 + (index&(SIMD_COEF_32-1)) + (unsigned int)index/SIMD_COEF_32*SHA_BUF_SIZ*SIMD_COEF_32] >> 3; for(i=0;i<s;i++) out[i] = wucp[ GETPOS(i, index) ]; out[i] = 0; return (char*) out; } #else static char *get_key(int index) { saved_key[index][saved_len[index]] = 0; return saved_key[index]; } #endif #ifndef REVERSE_STEPS #undef SSEi_REVERSE_STEPS #define SSEi_REVERSE_STEPS 0 #endif static int crypt_all(int *pcount, struct db_salt *salt) { const int count = *pcount; int index = 0; #ifdef _OPENMP #pragma omp parallel for for (index = 0; index < count; index += MAX_KEYS_PER_CRYPT) #endif { #ifdef SIMD_COEF_32 SIMDSHA256body(&saved_key[(unsigned int)index/SIMD_COEF_32*SHA_BUF_SIZ*SIMD_COEF_32], &crypt_out[(unsigned int)index/SIMD_COEF_32*8*SIMD_COEF_32], NULL, SSEi_REVERSE_STEPS|SSEi_MIXED_IN|SSEi_CRYPT_SHA224); #else SHA256_CTX ctx; SHA224_Init(&ctx); SHA224_Update(&ctx, saved_key[index], saved_len[index]); SHA224_Final((unsigned char *)crypt_out[index], &ctx); #endif } return count; } static int cmp_all(void *binary, int count) { unsigned int index; for (index = 0; index < count; index++) #ifdef SIMD_COEF_32 if (((ARCH_WORD_32*) binary)[3] == crypt_out[HASH_IDX]) #else if ( ((ARCH_WORD_32*)binary)[0] == crypt_out[index][0] ) #endif return 1; return 0; } static int cmp_one(void *binary, int index) { #ifdef SIMD_COEF_32 return ((ARCH_WORD_32*)binary)[3] == crypt_out[HASH_IDX]; #else return *(ARCH_WORD_32*)binary == crypt_out[index][0]; #endif } static int cmp_exact(char *source, int index) { ARCH_WORD_32 *binary = get_binary(source); char *key = get_key(index); SHA256_CTX ctx; ARCH_WORD_32 crypt_out[DIGEST_SIZE / sizeof(ARCH_WORD_32)]; SHA224_Init(&ctx); SHA224_Update(&ctx, key, strlen(key)); SHA224_Final((unsigned char*)crypt_out, &ctx); #ifdef SIMD_COEF_32 alter_endianity(crypt_out, DIGEST_SIZE); #ifdef REVERSE_STEPS sha224_reverse(crypt_out); #endif #endif return !memcmp(binary, crypt_out, DIGEST_SIZE); } struct fmt_main fmt_rawSHA224 = { { FORMAT_LABEL, FORMAT_NAME, "SHA224 " 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_OMP | FMT_OMP_BAD | FMT_SPLIT_UNIFIES_CASE, { NULL }, tests }, { init, done, fmt_default_reset, fmt_default_prepare, valid, split, get_binary, fmt_default_salt, { NULL }, 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, 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 */

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] = 32; tile_size[3] = 2048; 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(t1-6,8),ceild(8*t2-Nz-19,32));t3<=min(floord(4*Nt+Ny-9,32),floord(4*t1+Ny-1,32));t3++) { for (t4=max(max(ceild(t1-510,512),ceild(8*t2-Nz-2035,2048)),ceild(32*t3-Ny-2035,2048));t4<=min(min(floord(4*Nt+Nx-9,2048),floord(4*t1+Nx-1,2048)),floord(32*t3+Nx+19,2048));t4++) { for (t5=max(max(max(max(0,ceild(8*t2-Nz+5,4)),ceild(32*t3-Ny+5,4)),ceild(2048*t4-Nx+5,4)),t1);t5<=min(min(min(Nt-1,t1+1),8*t3+6),512*t4+510);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(32*t3,4*t5+4);t7<=min(32*t3+31,4*t5+Ny-5);t7++) { lbv=max(2048*t4,4*t5+4); ubv=min(2048*t4+2047,4*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; }

chunks.c

/************************************************************************* * chunks.c - * * $Id$ * * Copyright (c) INRIA 2012 * * AUTHOR: * Gregoire Malandain (gregoire.malandain@inria.fr) * * CREATION DATE: * Fri Nov 16 22:45:44 CET 2012 * * * ADDITIONS, CHANGES * * * * */ #include <stdlib.h> #include <stdio.h> #include <math.h> #ifdef MAC #include <sys/types.h> #include <sys/sysctl.h> #else #include <unistd.h> #endif #ifdef _OPENMP #include <omp.h> #endif #include <pthread.h> #include <vtmalloc.h> #include <chunks.h> /* debug / verbose variables */ static int _verbose_ = 1; static int _debug_ = 0; void setVerboseInChunks( int v ) { _verbose_ = v; } void incrementVerboseInChunks( ) { _verbose_ ++; } void decrementVerboseInChunks( ) { _verbose_ --; if ( _verbose_ < 0 ) _verbose_ = 0; } void setDebugInChunks( int v ) { _debug_ = v; } void incrementDebugInChunks( ) { _debug_ ++; } void decrementDebugInChunks( ) { _debug_ --; if ( _debug_ < 0 ) _debug_ = 0; } /* parallelism, scheduling */ static parallelismType _parallelism_ = _DEFAULT_PARALLELISM_; static ompSchedulingType _omp_scheduling_ = _DYNAMIC_OMP_SCHEDULING_; void setParallelism( parallelismType p ) { _parallelism_ = p; } parallelismType getParallelism( ) { return( _parallelism_ ); } void setOmpScheduling( ompSchedulingType s ) { _omp_scheduling_ = s; } ompSchedulingType getOmpScheduling( ) { return( _omp_scheduling_ ); } /* chunk related variable */ static int _max_chunks_ = -1; static int _min_elements_ = 100; void setMaxChunks( int c ) { _max_chunks_ = c; } int getMaxChunks( ) { return( _max_chunks_ ); } void setMinElementsInChunks( int e ) { _min_elements_ = e; } int getMinElementsInChunks( ) { return( _min_elements_); } /************************************************************ * * chunks processing * ************************************************************/ #ifdef _OPENMP static int _ompProcessChunks( _chunk_callfunction ftn, typeChunks *chunks, char *from ) { int n; if ( chunks->n_allocated_chunks > 1 ) { switch( chunks->ompScheduling ) { default : case _DEFAULT_OMP_SCHEDULING_ : if ( _debug_ >= 3 ) fprintf( stderr, "%s: default openmp scheduling\n", from ); #pragma omp parallel for for ( n=0; n<chunks->n_allocated_chunks; n++ ) { if ( _debug_ >=2 ) { fprintf( stderr, "%s: processing chunk #%d/%d", from, n+1, chunks->n_allocated_chunks ); fprintf( stderr, " attributed to thread #%d", omp_get_thread_num() ); fprintf( stderr, "\n" ); } (void)(*ftn)( &(chunks->data[n]) ); } break; case _DYNAMIC_OMP_SCHEDULING_ : if ( _debug_ >= 3 ) fprintf( stderr, "%s: dynamic openmp scheduling\n", from ); #pragma omp parallel for schedule(dynamic) for ( n=0; n<chunks->n_allocated_chunks; n++ ) { if ( _debug_ >=2 ) { fprintf( stderr, "%s: processing chunk #%d/%d", from, n+1, chunks->n_allocated_chunks ); fprintf( stderr, " attributed to thread #%d", omp_get_thread_num() ); fprintf( stderr, "\n" ); } (void)(*ftn)( &(chunks->data[n]) ); } break; case _DYNAMIC_ONE_OMP_SCHEDULING_ : if ( _debug_ >= 3 ) fprintf( stderr, "%s: (dynamic,1) openmp scheduling\n", from ); #pragma omp parallel for schedule(dynamic,1) for ( n=0; n<chunks->n_allocated_chunks; n++ ) { if ( _debug_ >=2 ) { fprintf( stderr, "%s: processing chunk #%d/%d", from, n+1, chunks->n_allocated_chunks ); fprintf( stderr, " attributed to thread #%d", omp_get_thread_num() ); fprintf( stderr, "\n" ); } (void)(*ftn)( &(chunks->data[n]) ); } break; case _GUIDED_OMP_SCHEDULING_ : if ( _debug_ >= 3 ) fprintf( stderr, "%s: (guided) openmp scheduling\n", from ); #pragma omp parallel for schedule(guided) for ( n=0; n<chunks->n_allocated_chunks; n++ ) { if ( _debug_ >=2 ) { fprintf( stderr, "%s: processing chunk #%d/%d", from, n+1, chunks->n_allocated_chunks ); fprintf( stderr, " attributed to thread #%d", omp_get_thread_num() ); fprintf( stderr, "\n" ); } (void)(*ftn)( &(chunks->data[n]) ); } break; case _STATIC_OMP_SCHEDULING_ : if ( _debug_ >= 3 ) fprintf( stderr, "%s: (static) openmp scheduling\n", from ); #pragma omp parallel for schedule(static) for ( n=0; n<chunks->n_allocated_chunks; n++ ) { if ( _debug_ >=2 ) { fprintf( stderr, "%s: processing chunk #%d/%d", from, n+1, chunks->n_allocated_chunks ); fprintf( stderr, " attributed to thread #%d", omp_get_thread_num() ); fprintf( stderr, "\n" ); } (void)(*ftn)( &(chunks->data[n]) ); } break; } } else { if ( _debug_ >= 3 ) fprintf( stderr, "%s: sequential loop\n", from ); for ( n=0; n<chunks->n_allocated_chunks; n++ ) { if ( _debug_ >= 4 ) { fprintf( stderr, "%s: processing chunk #%d/%d", from, n+1, chunks->n_allocated_chunks ); fprintf( stderr, " in a sequential way" ); fprintf( stderr, "\n" ); } (void)(*ftn)( &(chunks->data[n]) ); } } /* check the returned values in case of error */ for ( n=0; n<chunks->n_allocated_chunks; n++ ) { if ( chunks->data[n].ret != 1 ) { if ( _verbose_ ) { fprintf( stderr, "%s: error when computing chunk #%d\n", from, n ); } return( -1 ); } } return( 1 ); } #endif static int _pthreadProcessChunks( _chunk_callfunction ftn, typeChunks *chunks, char *from ) { char *proc = "_pthreadProcessChunks"; int n; int rc; void *status; pthread_t *thread; pthread_attr_t attr; if ( _debug_ >= 3 ) fprintf( stderr, "%s: pthread scheduling\n", from ); thread = (pthread_t*)vtmalloc( chunks->n_allocated_chunks * sizeof( pthread_t ), "thread", proc ); if ( thread == (pthread_t*)NULL ) { if ( _verbose_ ) fprintf( stderr, "%s: unable to allocate array of %d threads\n", proc, chunks->n_allocated_chunks ); return( -1 ); } pthread_attr_init( &attr ); pthread_attr_setdetachstate( &attr, PTHREAD_CREATE_JOINABLE ); for ( n=0; n<chunks->n_allocated_chunks; n++ ) { rc = pthread_create( &thread[n], &attr, ftn, &(chunks->data[n]) ); if ( rc ) { if ( _verbose_ ) fprintf( stderr, "%s: error when creating threads #%d/%d (returned code = %d)\n", proc, n, chunks->n_allocated_chunks, rc ); vtfree( thread ); return( -1 ); } } pthread_attr_destroy(&attr); for ( n=0; n<chunks->n_allocated_chunks; n++ ) { rc = pthread_join( thread[n], &status ); if ( rc ) { if ( _verbose_ ) fprintf( stderr, "%s: error when joining threads #%d/%d (returned code = %d)\n", proc, n, chunks->n_allocated_chunks, rc ); vtfree( thread ); return( -1 ); } } vtfree( thread ); return( 1 ); } int processChunks( _chunk_callfunction ftn, typeChunks *chunks, char *from ) { char *proc = "processChunks"; int n; switch( _parallelism_ ) { case _NO_PARALLELISM_ : if ( _debug_ >= 3 ) fprintf( stderr, "%s: _NO_PARALLELISM_ case\n", proc ); for ( n=0; n<chunks->n_allocated_chunks; n++ ) { (void)(*ftn)( &(chunks->data[n]) ); } break; default : case _DEFAULT_PARALLELISM_ : if ( _debug_ >= 3 ) fprintf( stderr, "%s: _DEFAULT_PARALLELISM_ case\n", proc ); #ifdef _OPENMP case _OMP_PARALLELISM_ : if ( _debug_ >= 3 ) fprintf( stderr, "%s: _OMP_PARALLELISM_ case\n", proc ); return ( _ompProcessChunks( ftn, chunks, from ) ); break; #endif case _PTHREAD_PARALLELISM_ : if ( _debug_ >= 3 ) fprintf( stderr, "%s: _PTHREAD_PARALLELISM_ case\n", proc ); return ( _pthreadProcessChunks( ftn, chunks, from ) ); break; } return( 1 ); } /************************************************************ * * chunks construction (ad hoc function) * ************************************************************/ #ifdef MAC static int _getNCPU() { int n=1; int mib[4]; size_t lmib = 4; int ncpu; size_t lncpu = sizeof( ncpu ); int nactivecpu; size_t lnactivecpu = sizeof( nactivecpu ); int nphysicalcpu; size_t lnphysicalcpu = sizeof( nphysicalcpu ); int nphysicalcpumax; size_t lnphysicalcpumax = sizeof( nphysicalcpumax ); int nlogicalcpu; size_t lnlogicalcpu = sizeof( nlogicalcpu ); int nlogicalcpumax; size_t lnlogicalcpumax = sizeof( nlogicalcpumax ); int navailablecpu; size_t lnavailablecpu = sizeof( ncpu ); switch( _parallelism_ ) { case _NO_PARALLELISM_ : return( 1 ); default : case _DEFAULT_PARALLELISM_ : #ifdef _OPENMP case _OMP_PARALLELISM_ : return( omp_get_max_threads() ); #endif case _PTHREAD_PARALLELISM_ : mib[0] = CTL_HW; mib[1] = HW_NCPU; sysctl( mib, 2, &ncpu, &lncpu, NULL, 0); mib[0] = CTL_HW; mib[1] = HW_AVAILCPU; sysctl( mib, 2, &navailablecpu, &lnavailablecpu, NULL, 0); sysctlnametomib( "hw.ncpu", mib, &lmib ); sysctl( mib, 2, &ncpu, &lncpu, NULL, 0); sysctlnametomib( "hw.activecpu", mib, &lmib ); sysctl( mib, 2, &nactivecpu, &lnactivecpu, NULL, 0); sysctlnametomib( "hw.physicalcpu", mib, &lmib ); sysctl( mib, 2, &nphysicalcpu, &lnphysicalcpu, NULL, 0); sysctlnametomib( "hw.physicalcpu_max", mib, &lmib ); sysctl( mib, 2, &nphysicalcpumax, &lnphysicalcpumax, NULL, 0); sysctlnametomib( "hw.logicalcpu", mib, &lmib ); sysctl( mib, 2, &nlogicalcpu, &lnlogicalcpu, NULL, 0); sysctlnametomib( "hw.logicalcpu_max", mib, &lmib ); sysctl( mib, 2, &nlogicalcpumax, &lnlogicalcpumax, NULL, 0); if ( _debug_ >= 4 ) { fprintf( stderr, "ncpu = %d\n", ncpu ); fprintf( stderr, "navailablecpu = %d\n", navailablecpu ); fprintf( stderr, "nactivecpu = %d\n", nactivecpu ); fprintf( stderr, "nphysicalcpu = %d\n", nphysicalcpu ); fprintf( stderr, "nphysicalcpumax = %d\n", nphysicalcpumax ); fprintf( stderr, "nlogicalcpu = %d\n", nlogicalcpu ); fprintf( stderr, "nlogicalcpumax = %d\n", nlogicalcpumax ); } if ( n < ncpu ) n = ncpu; if ( n < nactivecpu ) n = nactivecpu; if ( n < nphysicalcpu ) n = nphysicalcpu; if ( n < nphysicalcpumax ) n = nphysicalcpumax; if ( n < nlogicalcpu ) n = nlogicalcpu; if ( n < nlogicalcpumax ) n = nlogicalcpumax; if ( n < navailablecpu ) n = navailablecpu; return( n ); } return( 1 ); } #else static int _getNCPU() { return( sysconf( _SC_NPROCESSORS_ONLN ) ); } #endif static void _setMaxChunks( ) { switch( _parallelism_ ) { case _NO_PARALLELISM_ : _max_chunks_ = 1; break; default : case _DEFAULT_PARALLELISM_ : #ifdef _OPENMP case _OMP_PARALLELISM_ : if ( omp_get_max_threads() == 1 ) { _max_chunks_ = 1; } else { if ( _max_chunks_ <= 0 ) _max_chunks_ = 100; } break; #endif case _PTHREAD_PARALLELISM_ : if ( _max_chunks_ <= 0 ) _max_chunks_ = _getNCPU(); break; } if ( _max_chunks_ == 1 ) _parallelism_ = _NO_PARALLELISM_; } int buildChunks( typeChunks *chunks, size_t first, size_t last, char *from ) { char *proc = "buildChunks"; size_t size = last-first+1; int n; _setMaxChunks( ); n = _max_chunks_; chunks->ompScheduling = _omp_scheduling_; /* only one chunk */ if ( n == 1 ) { if ( allocBuildOneChunk( chunks, first, last ) != 1 ) { if ( _verbose_ ) fprintf( stderr, "%s: error when allocating one chunk\n", proc ); return( -1 ); } return( 1 ); } /* what to do when there are too few elements ? */ if ( size < (size_t)n*_min_elements_ ) { n = size / _min_elements_; if ( size % _min_elements_ > 0 ) n ++; if ( n == 1 ) { if ( allocBuildOneChunk( chunks, first, last ) != 1 ) { if ( _verbose_ ) fprintf( stderr, "%s: error when allocating one chunk (too few element case)\n", proc ); return( -1 ); } return( 1 ); } } if ( allocBuildEqualChunks( chunks, first, last, n ) != 1 ) { if ( _verbose_ ) fprintf( stderr, "%s: error when building %d chunks (call from %s)\n", proc, n, from ); return( -1 ); } if ( _debug_ >= 3 ) { fprintf( stderr, "\n" ); if ( from != (char*)NULL ) fprintf( stderr, "%s: has computed %d chunks from '%s'\n", proc, chunks->n_allocated_chunks, from ); else fprintf( stderr, "%s: has computed %d chunks from '%s'\n", proc, chunks->n_allocated_chunks, from ); } return( 1 ); } /************************************************************ * * chunks construction (generic functions) * ************************************************************/ int allocBuildOneChunk( typeChunks *chunks, size_t first, size_t last ) { char *proc = "oneChunk"; if ( allocChunks( chunks, 1 ) <= 0 ) { if ( _verbose_ ) fprintf( stderr, "%s: error when allocating one chunk\n", proc ); return( -1 ); } chunks->data[0].first = first; chunks->data[0].last = last; return( 1 ); } int buildEqualChunks( typeChunk *chunk, size_t first, size_t last, int n ) { char *proc = "buildEqualChunks"; size_t totalSize = last+1-first; size_t f = first; size_t i, chunkSize; if ( n <= 0 ) { if ( _verbose_ ) fprintf( stderr, "%s: negative number of chunks\n", proc ); return( -1 ); } chunkSize = totalSize / n; if ( chunkSize <= 0 ) { if ( _verbose_ ) fprintf( stderr, "%s: negative or null chunk size (too many chunks ?)\n", proc ); return( -1 ); } for ( i=0; i<(size_t)n; i++, f+=chunkSize ) { /* chunk of size chunkSize+1 */ if ( chunkSize * (n-i) < totalSize ) { totalSize -= chunkSize + 1; chunk[ i ].first = f; chunk[ i ].last = f+(chunkSize+1)-1; f++; } /* chunk of size chunkSize */ else { totalSize -= chunkSize; chunk[ i ].first = f; chunk[ i ].last = f+chunkSize-1; } } return( 1 ); } int allocBuildEqualChunks( typeChunks *chunks, size_t first, size_t last, int nchunks ) { char *proc = "allocBuildEqualChunks"; size_t size = last - first + 1; int n = nchunks; if ( n <= 0 ) { if ( _verbose_ ) fprintf( stderr, "%s: negative number of chunks\n", proc ); return( -1 ); } if ( size < (size_t)n ) { n = size; } if ( allocChunks( chunks, n ) != 1 ) { if ( _verbose_ ) fprintf( stderr, "%s: error when allocating chunks\n", proc ); return( -1 ); } if ( buildEqualChunks( &(chunks->data[0]), first, last, n ) != 1 ) { freeChunks( chunks ); if ( _verbose_ ) fprintf( stderr, "%s: error when calculating chunks\n", proc ); return( -1 ); } return( 1 ); } int allocBuildInequalChunks( typeChunks *chunks, size_t first, size_t last, double fraction, /* fraction of data to be put in one bucket */ int chunks_bucket, /* number of chunks for one bucket */ size_t minimal_chunk_size, int maximal_chunk_number ) { char *proc = "allocBuildInequalChunks"; size_t totalSize = last+1-first; size_t f = first; size_t i, chunkSize; int maxchunks; int n, nchunks; if ( maximal_chunk_number <= 0 ) { if ( _verbose_ ) fprintf( stderr, "%s: negative maximal number of chunks\n", proc ); return( -1 ); } if ( chunks_bucket <= 0 ) { if ( _verbose_ ) fprintf( stderr, "%s: negative number of chunks in a bucket\n", proc ); return( -1 ); } if ( fraction < 0.0 || 1.0 <= fraction ) { if ( _verbose_ ) fprintf( stderr, "%s: fraction should be in ]0,1[\n", proc ); return( -1 ); } /* calculating the number of chunks */ for ( nchunks=0, maxchunks=maximal_chunk_number, totalSize=last+1-first; totalSize > 0 && maxchunks > 0; ) { /* put the remaining data in the remaining chunks -> equal repartition in maxchunks chunks */ if ( maxchunks <= chunks_bucket ) { nchunks += maxchunks; totalSize = 0; if ( _debug_ >= 3 ) fprintf( stderr, "(1) add %d chunks -> %d\n", maxchunks, nchunks ); continue; } /* the remaining data fits in one bucket -> equal repartition in chunks_bucket chunks */ if ( totalSize / chunks_bucket < minimal_chunk_size ) { nchunks += chunks_bucket; totalSize = 0; if ( _debug_ >= 3 ) fprintf( stderr, "(2) add %d chunks -> %d\n", chunks_bucket, nchunks ); continue; } /* the considered fraction of data in the bucket yield too small chunks -> equal repartition in min( totalSize / minimal_chunk_size, maxchunks) */ if ( (fraction * totalSize) / chunks_bucket < minimal_chunk_size ) { n = totalSize / minimal_chunk_size; if ( n > maxchunks ) n = maxchunks; nchunks += n; totalSize = 0; if ( _debug_ >= 3 ) fprintf( stderr, "(3) add %d chunks -> %d\n", n, nchunks ); continue; } /* after filling the bucket, there will be too much remaining data -> equal repartition in maxchunks */ if ( (maxchunks <= 2*chunks_bucket) && (fraction * totalSize) / chunks_bucket < ((1-fraction) * totalSize) / (maxchunks-chunks_bucket) ) { nchunks += maxchunks; totalSize = 0; if ( _debug_ >= 3 ) fprintf( stderr, "(4) add %d chunks -> %d\n", maxchunks, nchunks ); continue; } /* generic case */ chunkSize = (fraction * totalSize) / chunks_bucket; nchunks += chunks_bucket; maxchunks -= chunks_bucket; totalSize -= chunks_bucket * chunkSize; if ( _debug_ >= 3 ) fprintf( stderr, "(5) add %d chunks -> %d\n", chunks_bucket, nchunks ); } /* allocating the chunks */ if ( allocChunks( chunks, nchunks ) <= 0 ) { if ( _verbose_ ) fprintf( stderr, "%s: error when allocating chunks\n", proc ); return( -1 ); } /* filling chunks */ for ( nchunks=0, maxchunks=maximal_chunk_number, totalSize=last+1-first, f=first; totalSize > 0 && maxchunks > 0; ) { /* put the remaining data in the remaining chunks -> equal repartition in maxchunks chunks */ if ( maxchunks <= chunks_bucket ) { if ( buildEqualChunks( &(chunks->data[nchunks]), f, last, maxchunks ) != 1 ) { freeChunks( chunks ); if ( _verbose_ ) fprintf( stderr, "%s: error when calculating chunks\n", proc ); return( -1 ); } totalSize = 0; continue; } /* the remaining data fits in one bucket -> equal repartition in chunks_bucket chunks */ if ( totalSize / chunks_bucket < minimal_chunk_size ) { if ( buildEqualChunks( &(chunks->data[nchunks]), f, last, chunks_bucket ) != 1 ) { freeChunks( chunks ); if ( _verbose_ ) fprintf( stderr, "%s: error when calculating chunks\n", proc ); return( -1 ); } totalSize = 0; continue; } /* the considered fraction of data in the bucket yield too small chunks -> equal repartition in min( totalSize / minimal_chunk_size, maxchunks) */ if ( (fraction * totalSize) / chunks_bucket < minimal_chunk_size ) { n = totalSize / minimal_chunk_size; if ( n > maxchunks ) n = maxchunks; if ( buildEqualChunks( &(chunks->data[nchunks]), f, last, n ) != 1 ) { freeChunks( chunks ); if ( _verbose_ ) fprintf( stderr, "%s: error when calculating chunks\n", proc ); return( -1 ); } totalSize = 0; continue; } /* after filling the bucket, there will be too much remaining data -> equal repartition in maxchunks */ if ( (maxchunks <= 2*chunks_bucket) && (fraction * totalSize) / chunks_bucket < ((1-fraction) * totalSize) / (maxchunks-chunks_bucket) ) { if ( buildEqualChunks( &(chunks->data[nchunks]), f, last, maxchunks ) != 1 ) { freeChunks( chunks ); if ( _verbose_ ) fprintf( stderr, "%s: error when calculating chunks\n", proc ); return( -1 ); } totalSize = 0; continue; } /* generic case */ chunkSize = (fraction * totalSize) / chunks_bucket; for (i=0; i<(size_t)chunks_bucket; i++, f+=chunkSize, totalSize-=chunkSize, nchunks++, maxchunks-- ) { chunks->data[ nchunks ].first = f; chunks->data[ nchunks ].last = f+chunkSize-1; } } return( 1 ); } /************************************************************ * * management * ************************************************************/ void initChunk( typeChunk *chunk ) { chunk->first = 1; chunk->last = 0; chunk->parameters = (void*)NULL; chunk->ret = 0; } void initChunks( typeChunks *chunks ) { chunks->data = (typeChunk*)NULL; chunks->n_allocated_chunks = 0; chunks->ompScheduling = _DEFAULT_OMP_SCHEDULING_; } void freeChunks( typeChunks *chunks ) { if ( chunks->data != (typeChunk*)NULL ) vtfree( chunks->data ); initChunks( chunks ); } int allocChunks( typeChunks *chunks, int n ) { char *proc = "allocChunks"; int i; if ( n <= 0 ) { if ( _verbose_ ) fprintf( stderr, "%s: negative or null number of chunks\n", proc ); return( -1 ); } chunks->data = (typeChunk*)vtmalloc( n *sizeof(typeChunk), "chunks->data", proc ); if ( chunks->data == (typeChunk*)NULL ) { if ( _verbose_ ) fprintf( stderr, "%s: error when allocating %d chunks\n", proc, n ); return( -1 ); } for ( i=0; i<n; i++ ) initChunk( &(chunks->data[i] ) ); chunks->n_allocated_chunks = n; return( 1 ); } void printChunks( FILE *theFile, typeChunks *chunks, char *s ) { char *proc = "printChunks"; int i; FILE *f = theFile; if ( f == NULL ) f = stdout; if ( s != (char *)NULL ) fprintf( f, "%s: information on '%s'\n", proc, s ); if ( chunks->n_allocated_chunks <= 0 || chunks->data == (typeChunk*)NULL ) { fprintf( f, "empty chunks\n" ); return; } for ( i=0; i<chunks->n_allocated_chunks; i++ ) fprintf( f, "#%3d [%12lu %12lu] = %12lu\n", i, chunks->data[i].first, chunks->data[i].last, chunks->data[i].last + 1 - chunks->data[i].first ); fprintf( f, "\n" ); } /************************************************************ * * test * ************************************************************/

GB_emult_01_template.c

//------------------------------------------------------------------------------ // GB_emult_01_template: C=A.*B, C<M or !M>=A.*B when C is sparse/hyper //------------------------------------------------------------------------------ // SuiteSparse:GraphBLAS, Timothy A. Davis, (c) 2017-2021, All Rights Reserved. // SPDX-License-Identifier: Apache-2.0 //------------------------------------------------------------------------------ // Computes C=A.*B, C<M>=A.*B, or C<!M>=A.*B when C is sparse or hypersparse: // phase1: does not compute C itself, but just counts the # of entries in each // vector of C. Fine tasks compute the # of entries in their slice of a // single vector of C, and the results are cumsum'd. // phase2: computes C, using the counts computed by phase1. // No input matrix can be jumbled, and C is constructed as unjumbled. // The following cases are handled: // ------------------------------------------ // C = A .* B // ------------------------------------------ // sparse . sparse sparse (method: 01) // ------------------------------------------ // C <M>= A .* B // ------------------------------------------ // sparse sparse sparse sparse (method: 01) // sparse bitmap sparse sparse (method: 01) // sparse full sparse sparse (method: 01) // sparse sparse sparse bitmap (04a or 02a) // sparse sparse sparse full (04a or 02a) // sparse sparse bitmap sparse (04b or 02b) // sparse sparse full sparse (04b or 02b) // ------------------------------------------ // C <!M>= A .* B // ------------------------------------------ // sparse sparse sparse sparse (01: M later) // sparse bitmap sparse sparse (method: 01) // sparse full sparse sparse (method: 01) // The 04a and 04b methods are not yet implemented. This method handles // those cases. Methods 02a and 02b can be used as well, but only if M is // applied later. See GB_emult_sparsity for this decision. { int taskid ; #pragma omp parallel for num_threads(C_nthreads) schedule(dynamic,1) for (taskid = 0 ; taskid < C_ntasks ; taskid++) { //---------------------------------------------------------------------- // get the task descriptor //---------------------------------------------------------------------- int64_t kfirst = TaskList [taskid].kfirst ; int64_t klast = TaskList [taskid].klast ; bool fine_task = (klast == -1) ; int64_t len ; if (fine_task) { // a fine task operates on a slice of a single vector klast = kfirst ; len = TaskList [taskid].len ; } else { // a coarse task operates on one or more whole vectors len = vlen ; } //---------------------------------------------------------------------- // compute all vectors in this task //---------------------------------------------------------------------- for (int64_t k = kfirst ; k <= klast ; k++) { //------------------------------------------------------------------ // get j, the kth vector of C //------------------------------------------------------------------ int64_t j = GBH (Ch, k) ; #if defined ( GB_PHASE_1_OF_2 ) int64_t cjnz = 0 ; #else int64_t pC, pC_end ; if (fine_task) { // A fine task computes a slice of C(:,j) pC = TaskList [taskid ].pC ; pC_end = TaskList [taskid+1].pC ; ASSERT (Cp [k] <= pC && pC <= pC_end && pC_end <= Cp [k+1]) ; } else { // The vectors of C are never sliced for a coarse task. pC = Cp [k] ; pC_end = Cp [k+1] ; } int64_t cjnz = pC_end - pC ; if (cjnz == 0) continue ; #endif //------------------------------------------------------------------ // get A(:,j) //------------------------------------------------------------------ int64_t pA = -1, pA_end = -1 ; if (fine_task) { // A fine task operates on Ai,Ax [pA...pA_end-1], which is // a subset of the vector A(:,j) pA = TaskList [taskid].pA ; pA_end = TaskList [taskid].pA_end ; } else { // A coarse task operates on the entire vector A (:,j) int64_t kA = (Ch == Ah) ? k : ((C_to_A == NULL) ? j : C_to_A [k]) ; if (kA >= 0) { pA = GBP (Ap, kA, vlen) ; pA_end = GBP (Ap, kA+1, vlen) ; } } int64_t ajnz = pA_end - pA ; // nnz in A(:,j) for this slice int64_t pA_start = pA ; bool adense = (ajnz == len) ; // get the first and last indices in A(:,j) for this vector int64_t iA_first = -1 ; if (ajnz > 0) { iA_first = GBI (Ai, pA, vlen) ; } #if defined ( GB_PHASE_1_OF_2 ) || defined ( GB_DEBUG ) int64_t iA_last = -1 ; if (ajnz > 0) { iA_last = GBI (Ai, pA_end-1, vlen) ; } #endif //------------------------------------------------------------------ // get B(:,j) //------------------------------------------------------------------ int64_t pB = -1, pB_end = -1 ; if (fine_task) { // A fine task operates on Bi,Bx [pB...pB_end-1], which is // a subset of the vector B(:,j) pB = TaskList [taskid].pB ; pB_end = TaskList [taskid].pB_end ; } else { // A coarse task operates on the entire vector B (:,j) int64_t kB = (Ch == Bh) ? k : ((C_to_B == NULL) ? j : C_to_B [k]) ; if (kB >= 0) { pB = GBP (Bp, kB, vlen) ; pB_end = GBP (Bp, kB+1, vlen) ; } } int64_t bjnz = pB_end - pB ; // nnz in B(:,j) for this slice int64_t pB_start = pB ; bool bdense = (bjnz == len) ; // get the first and last indices in B(:,j) for this vector int64_t iB_first = -1 ; if (bjnz > 0) { iB_first = GBI (Bi, pB, vlen) ; } #if defined ( GB_PHASE_1_OF_2 ) || defined ( GB_DEBUG ) int64_t iB_last = -1 ; if (bjnz > 0) { iB_last = GBI (Bi, pB_end-1, vlen) ; } #endif //------------------------------------------------------------------ // get M(:,j) if M is sparse or hypersparse //------------------------------------------------------------------ int64_t pM = -1 ; int64_t pM_end = -1 ; if (M_is_sparse_or_hyper) { if (fine_task) { // A fine task operates on Mi,Mx [pM...pM_end-1], which is // a subset of the vector M(:,j) pM = TaskList [taskid].pM ; pM_end = TaskList [taskid].pM_end ; } else { int64_t kM = -1 ; if (Ch == Mh) { // Ch is the same as Mh (a shallow copy), or both NULL kM = k ; } else { kM = (C_to_M == NULL) ? j : C_to_M [k] ; } if (kM >= 0) { pM = GBP (Mp, kM, vlen) ; pM_end = GBP (Mp, kM+1, vlen) ; } } } //------------------------------------------------------------------ // C(:,j)<optional mask> = A (:,j) .* B (:,j) or subvector //------------------------------------------------------------------ #if defined ( GB_PHASE_1_OF_2 ) if (ajnz == 0 || bjnz == 0) { //-------------------------------------------------------------- // A(:,j) and/or B(:,j) are empty //-------------------------------------------------------------- ; } else if (iA_last < iB_first || iB_last < iA_first) { //-------------------------------------------------------------- // intersection of A(:,j) and B(:,j) is empty //-------------------------------------------------------------- // the last entry of A(:,j) comes before the first entry // of B(:,j), or visa versa ; } else #endif if (M == NULL) { //-------------------------------------------------------------- // C = A.*B //-------------------------------------------------------------- // ------------------------------------------ // C = A .* B // ------------------------------------------ // sparse . sparse sparse (method: 01) // sparse sparse sparse sparse (01 M later) // both A and B are sparse/hyper ASSERT (A_is_sparse || A_is_hyper) ; ASSERT (B_is_sparse || B_is_hyper) ; if (ajnz > 32 * bjnz) { //---------------------------------------------------------- // A(:,j) is much denser than B(:,j) //---------------------------------------------------------- for ( ; pB < pB_end ; pB++) { int64_t i = Bi [pB] ; // find i in A(:,j) int64_t pright = pA_end - 1 ; bool found ; GB_BINARY_SEARCH (i, Ai, pA, pright, found) ; if (found) { // C (i,j) = A (i,j) .* B (i,j) #if defined ( GB_PHASE_1_OF_2 ) cjnz++ ; #else ASSERT (pC < pC_end) ; Ci [pC] = i ; GB_GETA (aij, Ax, pA) ; GB_GETB (bij, Bx, pB) ; GB_BINOP (GB_CX (pC), aij, bij, i, j) ; pC++ ; #endif } } #if defined ( GB_PHASE_2_OF_2 ) ASSERT (pC == pC_end) ; #endif } else if (bjnz > 32 * ajnz) { //---------------------------------------------------------- // B(:,j) is much denser than A(:,j) //---------------------------------------------------------- for ( ; pA < pA_end ; pA++) { int64_t i = Ai [pA] ; // find i in B(:,j) int64_t pright = pB_end - 1 ; bool found ; GB_BINARY_SEARCH (i, Bi, pB, pright, found) ; if (found) { // C (i,j) = A (i,j) .* B (i,j) #if defined ( GB_PHASE_1_OF_2 ) cjnz++ ; #else ASSERT (pC < pC_end) ; Ci [pC] = i ; GB_GETA (aij, Ax, pA) ; GB_GETB (bij, Bx, pB) ; GB_BINOP (GB_CX (pC), aij, bij, i, j) ; pC++ ; #endif } } #if defined ( GB_PHASE_2_OF_2 ) ASSERT (pC == pC_end) ; #endif } else { //---------------------------------------------------------- // A(:,j) and B(:,j) about the sparsity //---------------------------------------------------------- // linear-time scan of A(:,j) and B(:,j) while (pA < pA_end && pB < pB_end) { int64_t iA = Ai [pA] ; int64_t iB = Bi [pB] ; if (iA < iB) { // A(i,j) exists but not B(i,j) pA++ ; } else if (iB < iA) { // B(i,j) exists but not A(i,j) pB++ ; } else { // both A(i,j) and B(i,j) exist // C (i,j) = A (i,j) .* B (i,j) #if defined ( GB_PHASE_1_OF_2 ) cjnz++ ; #else ASSERT (pC < pC_end) ; Ci [pC] = iB ; GB_GETA (aij, Ax, pA) ; GB_GETB (bij, Bx, pB) ; GB_BINOP (GB_CX (pC), aij, bij, iB, j) ; pC++ ; #endif pA++ ; pB++ ; } } #if defined ( GB_PHASE_2_OF_2 ) ASSERT (pC == pC_end) ; #endif } } else if (M_is_sparse_or_hyper) { //-------------------------------------------------------------- // C and M are sparse or hypersparse //-------------------------------------------------------------- // ------------------------------------------ // C <M>= A .* B // ------------------------------------------ // sparse sparse sparse sparse (method: 01) // sparse sparse sparse bitmap (04a or 02a) // sparse sparse sparse full (04a or 02a) // sparse sparse bitmap sparse (04b or 02b) // sparse sparse full sparse (04b or 02b) // Method 04 is not yet implemented; using this method // (GB_emult_01) instead. // ether A or B are sparse/hyper ASSERT (A_is_sparse || A_is_hyper || B_is_sparse || B_is_hyper); for ( ; pM < pM_end ; pM++) { //---------------------------------------------------------- // get M(i,j) for A(i,j) .* B (i,j) //---------------------------------------------------------- int64_t i = GBI (Mi, pM, vlen) ; bool mij = GB_mcast (Mx, pM, msize) ; if (!mij) continue ; //---------------------------------------------------------- // get A(i,j) //---------------------------------------------------------- bool afound ; if (adense) { // A(:,j) is dense, bitmap, or full; use quick lookup pA = pA_start + i - iA_first ; afound = GBB (Ab, pA) ; } else { // A(:,j) is sparse; use binary search for A(i,j) int64_t apright = pA_end - 1 ; GB_BINARY_SEARCH (i, Ai, pA, apright, afound) ; } if (!afound) continue ; ASSERT (GBI (Ai, pA, vlen) == i) ; //---------------------------------------------------------- // get B(i,j) //---------------------------------------------------------- bool bfound ; if (bdense) { // B(:,j) is dense; use direct lookup for B(i,j) pB = pB_start + i - iB_first ; bfound = GBB (Bb, pB) ; } else { // B(:,j) is sparse; use binary search for B(i,j) int64_t bpright = pB_end - 1 ; GB_BINARY_SEARCH (i, Bi, pB, bpright, bfound) ; } if (!bfound) continue ; ASSERT (GBI (Bi, pB, vlen) == i) ; //---------------------------------------------------------- // C(i,j) = A(i,j) .* B(i,j) //---------------------------------------------------------- // C (i,j) = A (i,j) .* B (i,j) #if defined ( GB_PHASE_1_OF_2 ) cjnz++ ; #else Ci [pC] = i ; GB_GETA (aij, Ax, pA) ; GB_GETB (bij, Bx, pB) ; GB_BINOP (GB_CX (pC), aij, bij, i, j) ; pC++ ; #endif } #if defined ( GB_PHASE_2_OF_2 ) ASSERT (pC == pC_end) ; #endif } else { //-------------------------------------------------------------- // M is bitmap or full, for either C<M>=A.*B or C<!M>=A.*B //-------------------------------------------------------------- // ------------------------------------------ // C <M>= A .* B // ------------------------------------------ // sparse bitmap sparse sparse (method: 01) // sparse full sparse sparse (method: 01) // ------------------------------------------ // C <!M>= A .* B // ------------------------------------------ // sparse bitmap sparse sparse (method: 01) // sparse full sparse sparse (method: 01) // GB_GET_MIJ: get M(i,j) where M is bitmap or full #undef GB_GET_MIJ #define GB_GET_MIJ(i) \ int64_t pM = pM_start + i ; \ bool mij = GBB (Mb, pM) && GB_mcast (Mx, pM, msize) ; \ if (Mask_comp) mij = !mij ; // both A and B are sparse/hyper ASSERT (A_is_sparse || A_is_hyper) ; ASSERT (B_is_sparse || B_is_hyper) ; int64_t pM_start = j * vlen ; if (ajnz > 32 * bjnz) { //---------------------------------------------------------- // A(:,j) much denser than B(:,j), M bitmap/full //---------------------------------------------------------- for ( ; pB < pB_end ; pB++) { int64_t i = Bi [pB] ; GB_GET_MIJ (i) ; if (mij) { // find i in A(:,j) int64_t pright = pA_end - 1 ; bool found ; GB_BINARY_SEARCH (i, Ai, pA, pright, found) ; if (found) { // C (i,j) = A (i,j) .* B (i,j) #if defined ( GB_PHASE_1_OF_2 ) cjnz++ ; #else ASSERT (pC < pC_end) ; Ci [pC] = i ; GB_GETA (aij, Ax, pA) ; GB_GETB (bij, Bx, pB) ; GB_BINOP (GB_CX (pC), aij, bij, i, j) ; pC++ ; #endif } } } #if defined ( GB_PHASE_2_OF_2 ) ASSERT (pC == pC_end) ; #endif } else if (bjnz > 32 * ajnz) { //---------------------------------------------------------- // B(:,j) much denser than A(:,j), M bitmap/full //---------------------------------------------------------- for ( ; pA < pA_end ; pA++) { int64_t i = Ai [pA] ; GB_GET_MIJ (i) ; if (mij) { // find i in B(:,j) int64_t pright = pB_end - 1 ; bool found ; GB_BINARY_SEARCH (i, Bi, pB, pright, found) ; if (found) { // C (i,j) = A (i,j) .* B (i,j) #if defined ( GB_PHASE_1_OF_2 ) cjnz++ ; #else ASSERT (pC < pC_end) ; Ci [pC] = i ; GB_GETA (aij, Ax, pA) ; GB_GETB (bij, Bx, pB) ; GB_BINOP (GB_CX (pC), aij, bij, i, j) ; pC++ ; #endif } } } #if defined ( GB_PHASE_2_OF_2 ) ASSERT (pC == pC_end) ; #endif } else { //---------------------------------------------------------- // A(:,j) and B(:,j) about the same, M bitmap/full //---------------------------------------------------------- // linear-time scan of A(:,j) and B(:,j) while (pA < pA_end && pB < pB_end) { int64_t iA = Ai [pA] ; int64_t iB = Bi [pB] ; if (iA < iB) { // A(i,j) exists but not B(i,j) pA++ ; } else if (iB < iA) { // B(i,j) exists but not A(i,j) pB++ ; } else { // both A(i,j) and B(i,j) exist int64_t i = iA ; GB_GET_MIJ (i) ; if (mij) { // C (i,j) = A (i,j) .* B (i,j) #if defined ( GB_PHASE_1_OF_2 ) cjnz++ ; #else ASSERT (pC < pC_end) ; Ci [pC] = i ; GB_GETA (aij, Ax, pA) ; GB_GETB (bij, Bx, pB) ; GB_BINOP (GB_CX (pC), aij, bij, iB, j) ; pC++ ; #endif } pA++ ; pB++ ; } } #if defined ( GB_PHASE_2_OF_2 ) ASSERT (pC == pC_end) ; #endif } } //------------------------------------------------------------------ // final count of nnz (C (:,j)) //------------------------------------------------------------------ #if defined ( GB_PHASE_1_OF_2 ) if (fine_task) { TaskList [taskid].pC = cjnz ; } else { Cp [k] = cjnz ; } #endif } } }

GB_binop__times_int64.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__times_int64) // A.*B function (eWiseMult): GB (_AemultB_08__times_int64) // A.*B function (eWiseMult): GB (_AemultB_02__times_int64) // A.*B function (eWiseMult): GB (_AemultB_04__times_int64) // A.*B function (eWiseMult): GB (_AemultB_bitmap__times_int64) // A*D function (colscale): GB (_AxD__times_int64) // D*A function (rowscale): GB (_DxB__times_int64) // C+=B function (dense accum): GB (_Cdense_accumB__times_int64) // C+=b function (dense accum): GB (_Cdense_accumb__times_int64) // C+=A+B function (dense ewise3): GB (_Cdense_ewise3_accum__times_int64) // C=A+B function (dense ewise3): GB (_Cdense_ewise3_noaccum__times_int64) // C=scalar+B GB (_bind1st__times_int64) // C=scalar+B' GB (_bind1st_tran__times_int64) // C=A+scalar GB (_bind2nd__times_int64) // C=A'+scalar GB (_bind2nd_tran__times_int64) // C type: int64_t // A type: int64_t // A pattern? 0 // B type: int64_t // B pattern? 0 // BinaryOp: cij = (aij * bij) #define GB_ATYPE \ int64_t #define GB_BTYPE \ int64_t #define GB_CTYPE \ int64_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) \ int64_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) \ int64_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) \ int64_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_TIMES || GxB_NO_INT64 || GxB_NO_TIMES_INT64) //------------------------------------------------------------------------------ // 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__times_int64) ( 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 //------------------------------------------------------------------------------ void GB (_Cdense_ewise3_noaccum__times_int64) ( 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__times_int64) ( 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__times_int64) ( 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 int64_t int64_t bwork = (*((int64_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__times_int64) ( 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 int64_t *restrict Cx = (int64_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__times_int64) ( GrB_Matrix C, const GrB_Matrix D, const GrB_Matrix B, int nthreads ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else int64_t *restrict Cx = (int64_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__times_int64) ( 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) ; int64_t alpha_scalar ; int64_t beta_scalar ; if (is_eWiseUnion) { alpha_scalar = (*((int64_t *) alpha_scalar_in)) ; beta_scalar = (*((int64_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__times_int64) ( 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__times_int64) ( 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__times_int64) ( 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__times_int64) ( 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__times_int64) ( 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 int64_t *Cx = (int64_t *) Cx_output ; int64_t x = (*((int64_t *) x_input)) ; int64_t *Bx = (int64_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 ; int64_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__times_int64) ( 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 ; int64_t *Cx = (int64_t *) Cx_output ; int64_t *Ax = (int64_t *) Ax_input ; int64_t y = (*((int64_t *) y_input)) ; #pragma omp parallel for num_threads(nthreads) schedule(static) for (p = 0 ; p < anz ; p++) { if (!GBB (Ab, p)) continue ; int64_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) \ { \ int64_t aij = GBX (Ax, pA, false) ; \ Cx [pC] = (x * aij) ; \ } GrB_Info GB (_bind1st_tran__times_int64) ( 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 \ int64_t #if GB_DISABLE return (GrB_NO_VALUE) ; #else int64_t x = (*((const int64_t *) x_input)) ; #include "GB_unop_transpose.c" return (GrB_SUCCESS) ; #endif #undef GB_ATYPE #define GB_ATYPE \ int64_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) \ { \ int64_t aij = GBX (Ax, pA, false) ; \ Cx [pC] = (aij * y) ; \ } GrB_Info GB (_bind2nd_tran__times_int64) ( 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 int64_t y = (*((const int64_t *) y_input)) ; #include "GB_unop_transpose.c" return (GrB_SUCCESS) ; #endif } #endif

paint.c

/* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % PPPP AAA IIIII N N TTTTT % % P P A A I NN N T % % PPPP AAAAA I N N N T % % P A A I N NN T % % P A A IIIII N N T % % % % % % Methods to Paint on an Image % % % % Software Design % % Cristy % % July 1998 % % % % % % 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/artifact.h" #include "MagickCore/channel.h" #include "MagickCore/color.h" #include "MagickCore/color-private.h" #include "MagickCore/colorspace-private.h" #include "MagickCore/composite.h" #include "MagickCore/composite-private.h" #include "MagickCore/draw.h" #include "MagickCore/draw-private.h" #include "MagickCore/exception.h" #include "MagickCore/exception-private.h" #include "MagickCore/gem.h" #include "MagickCore/gem-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/resource_.h" #include "MagickCore/statistic.h" #include "MagickCore/string_.h" #include "MagickCore/string-private.h" #include "MagickCore/thread-private.h" /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % F l o o d f i l l P a i n t I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % FloodfillPaintImage() changes the color value of any pixel that matches % target and is an immediate neighbor. If the method FillToBorderMethod is % specified, the color value is changed for any neighbor pixel that does not % match the bordercolor member of image. % % By default target must match a particular pixel color exactly. However, % in many cases two colors may differ by a small amount. The fuzz member of % image defines how much tolerance is acceptable to consider two colors as % the same. For example, set fuzz to 10 and the color red at intensities of % 100 and 102 respectively are now interpreted as the same color for the % purposes of the floodfill. % % The format of the FloodfillPaintImage method is: % % MagickBooleanType FloodfillPaintImage(Image *image, % const DrawInfo *draw_info,const PixelInfo target, % const ssize_t x_offset,const ssize_t y_offset, % const MagickBooleanType invert,ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o draw_info: the draw info. % % o target: the RGB value of the target color. % % o x_offset,y_offset: the starting location of the operation. % % o invert: paint any pixel that does not match the target color. % % o exception: return any errors or warnings in this structure. % */ MagickExport MagickBooleanType FloodfillPaintImage(Image *image, const DrawInfo *draw_info,const PixelInfo *target,const ssize_t x_offset, const ssize_t y_offset,const MagickBooleanType invert, ExceptionInfo *exception) { #define MaxStacksize 524288UL #define PushSegmentStack(up,left,right,delta) \ { \ if (s >= (segment_stack+MaxStacksize)) \ { \ segment_info=RelinquishVirtualMemory(segment_info); \ image_view=DestroyCacheView(image_view); \ floodplane_view=DestroyCacheView(floodplane_view); \ floodplane_image=DestroyImage(floodplane_image); \ ThrowBinaryException(DrawError,"SegmentStackOverflow",image->filename) \ } \ else \ { \ if ((((up)+(delta)) >= 0) && (((up)+(delta)) < (ssize_t) image->rows)) \ { \ s->x1=(double) (left); \ s->y1=(double) (up); \ s->x2=(double) (right); \ s->y2=(double) (delta); \ s++; \ } \ } \ } CacheView *floodplane_view, *image_view; Image *floodplane_image; MagickBooleanType skip, status; MemoryInfo *segment_info; PixelInfo fill_color, pixel; SegmentInfo *s; SegmentInfo *segment_stack; ssize_t offset, start, x1, x2, y; /* Check boundary conditions. */ 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 ((x_offset < 0) || (x_offset >= (ssize_t) image->columns)) return(MagickFalse); if ((y_offset < 0) || (y_offset >= (ssize_t) image->rows)) return(MagickFalse); if (SetImageStorageClass(image,DirectClass,exception) == MagickFalse) return(MagickFalse); if (IsGrayColorspace(image->colorspace) != MagickFalse) (void) SetImageColorspace(image,sRGBColorspace,exception); if ((image->alpha_trait == UndefinedPixelTrait) && (draw_info->fill.alpha_trait != UndefinedPixelTrait)) (void) SetImageAlpha(image,OpaqueAlpha,exception); /* Set floodfill state. */ floodplane_image=CloneImage(image,0,0,MagickTrue,exception); if (floodplane_image == (Image *) NULL) return(MagickFalse); floodplane_image->alpha_trait=UndefinedPixelTrait; floodplane_image->colorspace=GRAYColorspace; (void) QueryColorCompliance("#000",AllCompliance, &floodplane_image->background_color,exception); (void) SetImageBackgroundColor(floodplane_image,exception); segment_info=AcquireVirtualMemory(MaxStacksize,sizeof(*segment_stack)); if (segment_info == (MemoryInfo *) NULL) { floodplane_image=DestroyImage(floodplane_image); ThrowBinaryException(ResourceLimitError,"MemoryAllocationFailed", image->filename); } segment_stack=(SegmentInfo *) GetVirtualMemoryBlob(segment_info); /* Push initial segment on stack. */ status=MagickTrue; start=0; s=segment_stack; GetPixelInfo(image,&pixel); image_view=AcquireVirtualCacheView(image,exception); floodplane_view=AcquireAuthenticCacheView(floodplane_image,exception); PushSegmentStack(y_offset,x_offset,x_offset,1); PushSegmentStack(y_offset+1,x_offset,x_offset,-1); while (s > segment_stack) { const Quantum *magick_restrict p; Quantum *magick_restrict q; ssize_t x; /* Pop segment off stack. */ s--; x1=(ssize_t) s->x1; x2=(ssize_t) s->x2; offset=(ssize_t) s->y2; y=(ssize_t) s->y1+offset; /* Recolor neighboring pixels. */ p=GetCacheViewVirtualPixels(image_view,0,y,(size_t) (x1+1),1,exception); q=GetCacheViewAuthenticPixels(floodplane_view,0,y,(size_t) (x1+1),1, exception); if ((p == (const Quantum *) NULL) || (q == (Quantum *) NULL)) break; p+=x1*GetPixelChannels(image); q+=x1*GetPixelChannels(floodplane_image); for (x=x1; x >= 0; x--) { if (GetPixelGray(floodplane_image,q) != 0) break; GetPixelInfoPixel(image,p,&pixel); if (IsFuzzyEquivalencePixelInfo(&pixel,target) == invert) break; SetPixelGray(floodplane_image,QuantumRange,q); p-=GetPixelChannels(image); q-=GetPixelChannels(floodplane_image); } if (SyncCacheViewAuthenticPixels(floodplane_view,exception) == MagickFalse) break; skip=x >= x1 ? MagickTrue : MagickFalse; if (skip == MagickFalse) { start=x+1; if (start < x1) PushSegmentStack(y,start,x1-1,-offset); x=x1+1; } do { if (skip == MagickFalse) { if (x < (ssize_t) image->columns) { p=GetCacheViewVirtualPixels(image_view,x,y,image->columns-x,1, exception); q=GetCacheViewAuthenticPixels(floodplane_view,x,y,image->columns- x,1,exception); if ((p == (const Quantum *) NULL) || (q == (Quantum *) NULL)) break; for ( ; x < (ssize_t) image->columns; x++) { if (GetPixelGray(floodplane_image,q) != 0) break; GetPixelInfoPixel(image,p,&pixel); if (IsFuzzyEquivalencePixelInfo(&pixel,target) == invert) break; SetPixelGray(floodplane_image,QuantumRange,q); p+=GetPixelChannels(image); q+=GetPixelChannels(floodplane_image); } status=SyncCacheViewAuthenticPixels(floodplane_view,exception); if (status == MagickFalse) break; } PushSegmentStack(y,start,x-1,offset); if (x > (x2+1)) PushSegmentStack(y,x2+1,x-1,-offset); } skip=MagickFalse; x++; if (x <= x2) { p=GetCacheViewVirtualPixels(image_view,x,y,(size_t) (x2-x+1),1, exception); q=GetCacheViewAuthenticPixels(floodplane_view,x,y,(size_t) (x2-x+1),1, exception); if ((p == (const Quantum *) NULL) || (q == (Quantum *) NULL)) break; for ( ; x <= x2; x++) { if (GetPixelGray(floodplane_image,q) != 0) break; GetPixelInfoPixel(image,p,&pixel); if (IsFuzzyEquivalencePixelInfo(&pixel,target) != invert) break; p+=GetPixelChannels(image); q+=GetPixelChannels(floodplane_image); } } start=x; } while (x <= x2); } status=MagickTrue; for (y=0; y < (ssize_t) image->rows; y++) { const Quantum *magick_restrict p; Quantum *magick_restrict q; ssize_t x; /* Tile fill color onto floodplane. */ if (status == MagickFalse) continue; p=GetCacheViewVirtualPixels(floodplane_view,0,y,image->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++) { if (GetPixelGray(floodplane_image,p) != 0) { GetFillColor(draw_info,x,y,&fill_color,exception); SetPixelViaPixelInfo(image,&fill_color,q); } p+=GetPixelChannels(floodplane_image); q+=GetPixelChannels(image); } if (SyncCacheViewAuthenticPixels(image_view,exception) == MagickFalse) status=MagickFalse; } floodplane_view=DestroyCacheView(floodplane_view); image_view=DestroyCacheView(image_view); segment_info=RelinquishVirtualMemory(segment_info); floodplane_image=DestroyImage(floodplane_image); return(status); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + G r a d i e n t I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GradientImage() applies a continuously smooth color transitions along a % vector from one color to another. % % Note, the interface of this method will change in the future to support % more than one transistion. % % The format of the GradientImage method is: % % MagickBooleanType GradientImage(Image *image,const GradientType type, % const SpreadMethod method,const PixelInfo *start_color, % const PixelInfo *stop_color,ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o type: the gradient type: linear or radial. % % o spread: the gradient spread meathod: pad, reflect, or repeat. % % o start_color: the start color. % % o stop_color: the stop color. % % o exception: return any errors or warnings in this structure. % */ MagickExport MagickBooleanType GradientImage(Image *image, const GradientType type,const SpreadMethod method,const StopInfo *stops, const size_t number_stops,ExceptionInfo *exception) { const char *artifact; DrawInfo *draw_info; GradientInfo *gradient; MagickBooleanType status; /* Set gradient start-stop end points. */ assert(image != (const Image *) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(stops != (const StopInfo *) NULL); assert(number_stops > 0); draw_info=AcquireDrawInfo(); gradient=(&draw_info->gradient); gradient->type=type; gradient->bounding_box.width=image->columns; gradient->bounding_box.height=image->rows; artifact=GetImageArtifact(image,"gradient:bounding-box"); if (artifact != (const char *) NULL) (void) ParseAbsoluteGeometry(artifact,&gradient->bounding_box); gradient->gradient_vector.x2=(double) image->columns-1; gradient->gradient_vector.y2=(double) image->rows-1; artifact=GetImageArtifact(image,"gradient:direction"); if (artifact != (const char *) NULL) { GravityType direction; direction=(GravityType) ParseCommandOption(MagickGravityOptions, MagickFalse,artifact); switch (direction) { case NorthWestGravity: { gradient->gradient_vector.x1=(double) image->columns-1; gradient->gradient_vector.y1=(double) image->rows-1; gradient->gradient_vector.x2=0.0; gradient->gradient_vector.y2=0.0; break; } case NorthGravity: { gradient->gradient_vector.x1=0.0; gradient->gradient_vector.y1=(double) image->rows-1; gradient->gradient_vector.x2=0.0; gradient->gradient_vector.y2=0.0; break; } case NorthEastGravity: { gradient->gradient_vector.x1=0.0; gradient->gradient_vector.y1=(double) image->rows-1; gradient->gradient_vector.x2=(double) image->columns-1; gradient->gradient_vector.y2=0.0; break; } case WestGravity: { gradient->gradient_vector.x1=(double) image->columns-1; gradient->gradient_vector.y1=0.0; gradient->gradient_vector.x2=0.0; gradient->gradient_vector.y2=0.0; break; } case EastGravity: { gradient->gradient_vector.x1=0.0; gradient->gradient_vector.y1=0.0; gradient->gradient_vector.x2=(double) image->columns-1; gradient->gradient_vector.y2=0.0; break; } case SouthWestGravity: { gradient->gradient_vector.x1=(double) image->columns-1; gradient->gradient_vector.y1=0.0; gradient->gradient_vector.x2=0.0; gradient->gradient_vector.y2=(double) image->rows-1; break; } case SouthGravity: { gradient->gradient_vector.x1=0.0; gradient->gradient_vector.y1=0.0; gradient->gradient_vector.x2=0.0; gradient->gradient_vector.y2=(double) image->columns-1; break; } case SouthEastGravity: { gradient->gradient_vector.x1=0.0; gradient->gradient_vector.y1=0.0; gradient->gradient_vector.x2=(double) image->columns-1; gradient->gradient_vector.y2=(double) image->rows-1; break; } default: break; } } artifact=GetImageArtifact(image,"gradient:angle"); if (artifact != (const char *) NULL) gradient->angle=StringToDouble(artifact,(char **) NULL); artifact=GetImageArtifact(image,"gradient:vector"); if (artifact != (const char *) NULL) (void) sscanf(artifact,"%lf%*[ ,]%lf%*[ ,]%lf%*[ ,]%lf", &gradient->gradient_vector.x1,&gradient->gradient_vector.y1, &gradient->gradient_vector.x2,&gradient->gradient_vector.y2); if ((GetImageArtifact(image,"gradient:angle") == (const char *) NULL) && (GetImageArtifact(image,"gradient:direction") == (const char *) NULL) && (GetImageArtifact(image,"gradient:extent") == (const char *) NULL) && (GetImageArtifact(image,"gradient:vector") == (const char *) NULL)) if ((type == LinearGradient) && (gradient->gradient_vector.y2 != 0.0)) gradient->gradient_vector.x2=0.0; gradient->center.x=(double) gradient->gradient_vector.x2/2.0; gradient->center.y=(double) gradient->gradient_vector.y2/2.0; artifact=GetImageArtifact(image,"gradient:center"); if (artifact != (const char *) NULL) (void) sscanf(artifact,"%lf%*[ ,]%lf",&gradient->center.x, &gradient->center.y); artifact=GetImageArtifact(image,"gradient:angle"); if ((type == LinearGradient) && (artifact != (const char *) NULL)) { double sine, cosine, distance; /* Reference https://drafts.csswg.org/css-images-3/#linear-gradients. */ sine=sin((double) DegreesToRadians(gradient->angle-90.0)); cosine=cos((double) DegreesToRadians(gradient->angle-90.0)); distance=fabs((double) (image->columns-1.0)*cosine)+ fabs((double) (image->rows-1.0)*sine); gradient->gradient_vector.x1=0.5*((image->columns-1.0)-distance*cosine); gradient->gradient_vector.y1=0.5*((image->rows-1.0)-distance*sine); gradient->gradient_vector.x2=0.5*((image->columns-1.0)+distance*cosine); gradient->gradient_vector.y2=0.5*((image->rows-1.0)+distance*sine); } gradient->radii.x=(double) MagickMax((image->columns-1.0),(image->rows-1.0))/ 2.0; gradient->radii.y=gradient->radii.x; artifact=GetImageArtifact(image,"gradient:extent"); if (artifact != (const char *) NULL) { if (LocaleCompare(artifact,"Circle") == 0) { gradient->radii.x=(double) MagickMax((image->columns-1.0), (image->rows-1.0))/2.0; gradient->radii.y=gradient->radii.x; } if (LocaleCompare(artifact,"Diagonal") == 0) { gradient->radii.x=(double) (sqrt((double) (image->columns-1.0)* (image->columns-1.0)+(image->rows-1.0)*(image->rows-1.0)))/2.0; gradient->radii.y=gradient->radii.x; } if (LocaleCompare(artifact,"Ellipse") == 0) { gradient->radii.x=(double) (image->columns-1.0)/2.0; gradient->radii.y=(double) (image->rows-1.0)/2.0; } if (LocaleCompare(artifact,"Maximum") == 0) { gradient->radii.x=(double) MagickMax((image->columns-1.0), (image->rows-1.0))/2.0; gradient->radii.y=gradient->radii.x; } if (LocaleCompare(artifact,"Minimum") == 0) { gradient->radii.x=(double) (MagickMin((image->columns-1.0), (image->rows-1.0)))/2.0; gradient->radii.y=gradient->radii.x; } } artifact=GetImageArtifact(image,"gradient:radii"); if (artifact != (const char *) NULL) (void) sscanf(artifact,"%lf%*[ ,]%lf",&gradient->radii.x, &gradient->radii.y); gradient->radius=MagickMax(gradient->radii.x,gradient->radii.y); gradient->spread=method; /* Define the gradient to fill between the stops. */ gradient->number_stops=number_stops; gradient->stops=(StopInfo *) AcquireQuantumMemory(gradient->number_stops, sizeof(*gradient->stops)); if (gradient->stops == (StopInfo *) NULL) ThrowBinaryException(ResourceLimitError,"MemoryAllocationFailed", image->filename); (void) memcpy(gradient->stops,stops,(size_t) number_stops*sizeof(*stops)); /* Draw a gradient on the image. */ status=DrawGradientImage(image,draw_info,exception); draw_info=DestroyDrawInfo(draw_info); return(status); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % O i l P a i n t I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % OilPaintImage() applies a special effect filter that simulates an oil % painting. Each pixel is replaced by the most frequent color occurring % in a circular region defined by radius. % % The format of the OilPaintImage method is: % % Image *OilPaintImage(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 circular neighborhood. % % o sigma: the standard deviation of the Gaussian, in pixels. % % o exception: return any errors or warnings in this structure. % */ static size_t **DestroyHistogramThreadSet(size_t **histogram) { ssize_t i; assert(histogram != (size_t **) NULL); for (i=0; i < (ssize_t) GetMagickResourceLimit(ThreadResource); i++) if (histogram[i] != (size_t *) NULL) histogram[i]=(size_t *) RelinquishMagickMemory(histogram[i]); histogram=(size_t **) RelinquishMagickMemory(histogram); return(histogram); } static size_t **AcquireHistogramThreadSet(const size_t count) { ssize_t i; size_t **histogram, number_threads; number_threads=(size_t) GetMagickResourceLimit(ThreadResource); histogram=(size_t **) AcquireQuantumMemory(number_threads,sizeof(*histogram)); if (histogram == (size_t **) NULL) return((size_t **) NULL); (void) memset(histogram,0,number_threads*sizeof(*histogram)); for (i=0; i < (ssize_t) number_threads; i++) { histogram[i]=(size_t *) AcquireQuantumMemory(count,sizeof(**histogram)); if (histogram[i] == (size_t *) NULL) return(DestroyHistogramThreadSet(histogram)); } return(histogram); } MagickExport Image *OilPaintImage(const Image *image,const double radius, const double sigma,ExceptionInfo *exception) { #define NumberPaintBins 256 #define OilPaintImageTag "OilPaint/Image" CacheView *image_view, *paint_view; Image *linear_image, *paint_image; MagickBooleanType status; MagickOffsetType progress; size_t **histograms, width; ssize_t center, y; /* Initialize painted 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); width=GetOptimalKernelWidth2D(radius,sigma); linear_image=CloneImage(image,0,0,MagickTrue,exception); paint_image=CloneImage(image,0,0,MagickTrue,exception); if ((linear_image == (Image *) NULL) || (paint_image == (Image *) NULL)) { if (linear_image != (Image *) NULL) linear_image=DestroyImage(linear_image); if (paint_image != (Image *) NULL) linear_image=DestroyImage(paint_image); return((Image *) NULL); } if (SetImageStorageClass(paint_image,DirectClass,exception) == MagickFalse) { linear_image=DestroyImage(linear_image); paint_image=DestroyImage(paint_image); return((Image *) NULL); } histograms=AcquireHistogramThreadSet(NumberPaintBins); if (histograms == (size_t **) NULL) { linear_image=DestroyImage(linear_image); paint_image=DestroyImage(paint_image); ThrowImageException(ResourceLimitError,"MemoryAllocationFailed"); } /* Oil paint image. */ status=MagickTrue; progress=0; center=(ssize_t) GetPixelChannels(linear_image)*(linear_image->columns+width)* (width/2L)+GetPixelChannels(linear_image)*(width/2L); image_view=AcquireVirtualCacheView(linear_image,exception); paint_view=AcquireAuthenticCacheView(paint_image,exception); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(progress,status) \ magick_number_threads(linear_image,paint_image,linear_image->rows,1) #endif for (y=0; y < (ssize_t) linear_image->rows; y++) { const Quantum *magick_restrict p; Quantum *magick_restrict q; size_t *histogram; ssize_t x; if (status == MagickFalse) continue; p=GetCacheViewVirtualPixels(image_view,-((ssize_t) width/2L),y-(ssize_t) (width/2L),linear_image->columns+width,width,exception); q=QueueCacheViewAuthenticPixels(paint_view,0,y,paint_image->columns,1, exception); if ((p == (const Quantum *) NULL) || (q == (Quantum *) NULL)) { status=MagickFalse; continue; } histogram=histograms[GetOpenMPThreadId()]; for (x=0; x < (ssize_t) linear_image->columns; x++) { ssize_t i, u; size_t count; ssize_t j, k, n, v; /* Assign most frequent color. */ k=0; j=0; count=0; (void) memset(histogram,0,NumberPaintBins* sizeof(*histogram)); for (v=0; v < (ssize_t) width; v++) { for (u=0; u < (ssize_t) width; u++) { n=(ssize_t) ScaleQuantumToChar(ClampToQuantum(GetPixelIntensity( linear_image,p+GetPixelChannels(linear_image)*(u+k)))); histogram[n]++; if (histogram[n] > count) { j=k+u; count=histogram[n]; } } k+=(ssize_t) (linear_image->columns+width); } for (i=0; i < (ssize_t) GetPixelChannels(linear_image); i++) { PixelChannel channel = GetPixelChannelChannel(linear_image,i); PixelTrait traits = GetPixelChannelTraits(linear_image,channel); PixelTrait paint_traits=GetPixelChannelTraits(paint_image,channel); if ((traits == UndefinedPixelTrait) || (paint_traits == UndefinedPixelTrait)) continue; if ((paint_traits & CopyPixelTrait) != 0) { SetPixelChannel(paint_image,channel,p[center+i],q); continue; } SetPixelChannel(paint_image,channel,p[j*GetPixelChannels(linear_image)+ i],q); } p+=GetPixelChannels(linear_image); q+=GetPixelChannels(paint_image); } if (SyncCacheViewAuthenticPixels(paint_view,exception) == MagickFalse) status=MagickFalse; if (linear_image->progress_monitor != (MagickProgressMonitor) NULL) { MagickBooleanType proceed; #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp atomic #endif progress++; proceed=SetImageProgress(linear_image,OilPaintImageTag,progress, linear_image->rows); if (proceed == MagickFalse) status=MagickFalse; } } paint_view=DestroyCacheView(paint_view); image_view=DestroyCacheView(image_view); histograms=DestroyHistogramThreadSet(histograms); linear_image=DestroyImage(linear_image); if (status == MagickFalse) paint_image=DestroyImage(paint_image); return(paint_image); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % O p a q u e P a i n t I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % OpaquePaintImage() changes any pixel that matches color with the color % defined by fill argument. % % By default color must match a particular pixel color exactly. However, in % many cases two colors may differ by a small amount. Fuzz defines how much % tolerance is acceptable to consider two colors as the same. For example, % set fuzz to 10 and the color red at intensities of 100 and 102 respectively % are now interpreted as the same color. % % The format of the OpaquePaintImage method is: % % MagickBooleanType OpaquePaintImage(Image *image,const PixelInfo *target, % const PixelInfo *fill,const MagickBooleanType invert, % ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o target: the RGB value of the target color. % % o fill: the replacement color. % % o invert: paint any pixel that does not match the target color. % % o exception: return any errors or warnings in this structure. % */ MagickExport MagickBooleanType OpaquePaintImage(Image *image, const PixelInfo *target,const PixelInfo *fill,const MagickBooleanType invert, ExceptionInfo *exception) { #define OpaquePaintImageTag "Opaque/Image" CacheView *image_view; MagickBooleanType status; MagickOffsetType progress; PixelInfo conform_fill, conform_target, zero; ssize_t y; assert(image != (Image *) NULL); assert(image->signature == MagickCoreSignature); assert(target != (PixelInfo *) NULL); assert(fill != (PixelInfo *) NULL); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); if (SetImageStorageClass(image,DirectClass,exception) == MagickFalse) return(MagickFalse); ConformPixelInfo(image,fill,&conform_fill,exception); ConformPixelInfo(image,target,&conform_target,exception); /* Make image color opaque. */ status=MagickTrue; progress=0; GetPixelInfo(image,&zero); 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++) { PixelInfo pixel; 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; } pixel=zero; for (x=0; x < (ssize_t) image->columns; x++) { GetPixelInfoPixel(image,q,&pixel); if (IsFuzzyEquivalencePixelInfo(&pixel,&conform_target) != invert) { PixelTrait traits; traits=GetPixelChannelTraits(image,RedPixelChannel); if ((traits & UpdatePixelTrait) != 0) SetPixelRed(image,(Quantum) conform_fill.red,q); traits=GetPixelChannelTraits(image,GreenPixelChannel); if ((traits & UpdatePixelTrait) != 0) SetPixelGreen(image,(Quantum) conform_fill.green,q); traits=GetPixelChannelTraits(image,BluePixelChannel); if ((traits & UpdatePixelTrait) != 0) SetPixelBlue(image,(Quantum) conform_fill.blue,q); traits=GetPixelChannelTraits(image,BlackPixelChannel); if ((traits & UpdatePixelTrait) != 0) SetPixelBlack(image,(Quantum) conform_fill.black,q); traits=GetPixelChannelTraits(image,AlphaPixelChannel); if ((traits & UpdatePixelTrait) != 0) SetPixelAlpha(image,(Quantum) conform_fill.alpha,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,OpaquePaintImageTag,progress, image->rows); if (proceed == MagickFalse) status=MagickFalse; } } image_view=DestroyCacheView(image_view); return(status); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % T r a n s p a r e n t P a i n t I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % TransparentPaintImage() changes the opacity value associated with any pixel % that matches color to the value defined by opacity. % % By default color must match a particular pixel color exactly. However, in % many cases two colors may differ by a small amount. Fuzz defines how much % tolerance is acceptable to consider two colors as the same. For example, % set fuzz to 10 and the color red at intensities of 100 and 102 respectively % are now interpreted as the same color. % % The format of the TransparentPaintImage method is: % % MagickBooleanType TransparentPaintImage(Image *image, % const PixelInfo *target,const Quantum opacity, % const MagickBooleanType invert,ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o target: the target color. % % o opacity: the replacement opacity value. % % o invert: paint any pixel that does not match the target color. % % o exception: return any errors or warnings in this structure. % */ MagickExport MagickBooleanType TransparentPaintImage(Image *image, const PixelInfo *target,const Quantum opacity,const MagickBooleanType invert, ExceptionInfo *exception) { #define TransparentPaintImageTag "Transparent/Image" CacheView *image_view; MagickBooleanType status; MagickOffsetType progress; PixelInfo zero; ssize_t y; assert(image != (Image *) NULL); assert(image->signature == MagickCoreSignature); assert(target != (PixelInfo *) NULL); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); if (SetImageStorageClass(image,DirectClass,exception) == MagickFalse) return(MagickFalse); if (image->alpha_trait == UndefinedPixelTrait) (void) SetImageAlphaChannel(image,OpaqueAlphaChannel,exception); /* Make image color transparent. */ status=MagickTrue; progress=0; GetPixelInfo(image,&zero); 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++) { PixelInfo pixel; ssize_t x; Quantum *magick_restrict q; if (status == MagickFalse) continue; q=GetCacheViewAuthenticPixels(image_view,0,y,image->columns,1,exception); if (q == (Quantum *) NULL) { status=MagickFalse; continue; } pixel=zero; for (x=0; x < (ssize_t) image->columns; x++) { GetPixelInfoPixel(image,q,&pixel); if (IsFuzzyEquivalencePixelInfo(&pixel,target) != invert) SetPixelAlpha(image,opacity,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,TransparentPaintImageTag,progress, image->rows); if (proceed == MagickFalse) status=MagickFalse; } } image_view=DestroyCacheView(image_view); return(status); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % T r a n s p a r e n t P a i n t I m a g e C h r o m a % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % TransparentPaintImageChroma() changes the opacity value associated with any % pixel that matches color to the value defined by opacity. % % As there is one fuzz value for the all the channels, TransparentPaintImage() % is not suitable for the operations like chroma, where the tolerance for % similarity of two color component (RGB) can be different. Thus we define % this method to take two target pixels (one low and one high) and all the % pixels of an image which are lying between these two pixels are made % transparent. % % The format of the TransparentPaintImageChroma method is: % % MagickBooleanType TransparentPaintImageChroma(Image *image, % const PixelInfo *low,const PixelInfo *high,const Quantum opacity, % const MagickBooleanType invert,ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o low: the low target color. % % o high: the high target color. % % o opacity: the replacement opacity value. % % o invert: paint any pixel that does not match the target color. % % o exception: return any errors or warnings in this structure. % */ MagickExport MagickBooleanType TransparentPaintImageChroma(Image *image, const PixelInfo *low,const PixelInfo *high,const Quantum opacity, const MagickBooleanType invert,ExceptionInfo *exception) { #define TransparentPaintImageTag "Transparent/Image" CacheView *image_view; MagickBooleanType status; MagickOffsetType progress; ssize_t y; assert(image != (Image *) NULL); assert(image->signature == MagickCoreSignature); assert(high != (PixelInfo *) NULL); assert(low != (PixelInfo *) NULL); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); if (SetImageStorageClass(image,DirectClass,exception) == MagickFalse) return(MagickFalse); if (image->alpha_trait == UndefinedPixelTrait) (void) SetImageAlphaChannel(image,OpaqueAlphaChannel,exception); /* Make image color transparent. */ 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++) { MagickBooleanType match; PixelInfo pixel; 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; } GetPixelInfo(image,&pixel); for (x=0; x < (ssize_t) image->columns; x++) { GetPixelInfoPixel(image,q,&pixel); match=((pixel.red >= low->red) && (pixel.red <= high->red) && (pixel.green >= low->green) && (pixel.green <= high->green) && (pixel.blue >= low->blue) && (pixel.blue <= high->blue)) ? MagickTrue : MagickFalse; if (match != invert) SetPixelAlpha(image,opacity,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,TransparentPaintImageTag,progress, image->rows); if (proceed == MagickFalse) status=MagickFalse; } } image_view=DestroyCacheView(image_view); return(status); }

dacemath.c

/****************************************************************************** * * * DIFFERENTIAL ALGEBRA CORE ENGINE * * * ******************************************************************************* * * * Copyright 2016 Politecnico di Milano (2014 Dinamica Srl) * * 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. * * * *******************************************************************************/ /* * dacemath.c * * Created on: November 18, 2016 * Author: Politecnico di Milano */ /** \addtogroup DACE Core * @{ */ // MS C library needs this to trigger it to define math constants #define _USE_MATH_DEFINES #include <math.h> #include <stdlib.h> #include "dace/config.h" #include "dace/dacebase.h" #include "dace/daceaux.h" #include "dacecontrib.h" // define various math constants in case they have not been defined by math.h // these are non-standard C, but most C libraries have them #ifndef M_PI #define M_PI (3.14159265358979323846) #endif #ifndef M_PI_2 #define M_PI_2 (1.57079632679489661923) #endif /******************************************************************************** * Basic DACE arithmetic operations *********************************************************************************/ /*! Perform addition of two DA objects. \param[in] ina Pointer to the first DA object to operate on \param[in] inb Pointer to the first DA object to operate on \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina or inb. */ void daceAdd(const DACEDA *ina, const DACEDA *inb, DACEDA *inc) { if(!daceIsSameObject(ina, inc) && !daceIsSameObject(inb, inc)) { daceWeightedSum(ina, 1.0, inb, 1.0, inc); } else { DACEDA idaadd; daceAllocateDA(&idaadd, 0); daceWeightedSum(ina, 1.0, inb, 1.0, &idaadd); daceCopy(&idaadd, inc); daceFreeDA(&idaadd); } } /*! Perform subtraction of two DA objects. \param[in] ina Pointer to the first DA object to operate on \param[in] inb Pointer to the first DA object to operate on \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina or inb. */ void daceSubtract(const DACEDA *ina, const DACEDA *inb, DACEDA *inc) { if(!daceIsSameObject(ina, inc) && !daceIsSameObject(inb, inc)) { daceWeightedSum(ina, 1.0, inb, -1.0, inc); } else { DACEDA idasub; daceAllocateDA(&idasub, 0); daceWeightedSum(ina, 1.0, inb, -1.0, &idasub); daceCopy(&idasub, inc); daceFreeDA(&idasub); } } /*! Perform multiplication of two DA objects. \param[in] ina Pointer to the first DA object to operate on \param[in] inb Pointer to the first DA object to operate on \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina or inb. */ void daceMultiply(const DACEDA *ina, const DACEDA *inb, DACEDA *inc) { // These should use thread local storage (TLS) for multithread safe implementations // see https://en.wikipedia.org/wiki/Thread-local_storage #if DACE_MEMORY_MODEL == DACE_MEMORY_STATIC static DACE_THREAD_LOCAL double cc[DACE_STATIC_NMMAX] = {0}; static DACE_THREAD_LOCAL extended_monomial emb[DACE_STATIC_NMMAX]; static DACE_THREAD_LOCAL extended_monomial *ipbeg[DACE_STATIC_NOMAX+1]; static DACE_THREAD_LOCAL extended_monomial *ipend[DACE_STATIC_NOMAX+1]; static DACE_THREAD_LOCAL unsigned int nomax = 0; static DACE_THREAD_LOCAL unsigned int nvmax = 0; // make sure static memory is correctly allocated if(UNLIKELY(nomax != DACECom.nomax || nvmax != DACECom.nvmax)) { nomax = DACECom.nomax; nvmax = DACECom.nvmax; ipbeg[0] = &emb[0]; for(unsigned int i = 1; i <= DACECom.nomax; i++) ipbeg[i] = emb + daceCountMonomials(i - 1, DACECom.nvmax); } #else static DACE_THREAD_LOCAL double *cc = NULL; static DACE_THREAD_LOCAL extended_monomial *emb = NULL; static DACE_THREAD_LOCAL extended_monomial **ipbeg = NULL; static DACE_THREAD_LOCAL extended_monomial **ipend = NULL; static DACE_THREAD_LOCAL unsigned int nomax = 0; static DACE_THREAD_LOCAL unsigned int nvmax = 0; // make sure static memory is correctly allocated if(UNLIKELY(nomax != DACECom.nomax || nvmax != DACECom.nvmax)) { nomax = DACECom.nomax; nvmax = DACECom.nvmax; dacefree(cc); dacefree(emb); dacefree(ipbeg); dacefree(ipend); cc = (double*) dacecalloc(DACECom.nmmax, sizeof(double)); emb = (extended_monomial*) dacecalloc(DACECom.nmmax, sizeof(extended_monomial)); ipbeg = (extended_monomial**) dacecalloc(DACECom.nomax+1, sizeof(extended_monomial*)); ipend = (extended_monomial**) dacecalloc(DACECom.nomax+1, sizeof(extended_monomial*)); ipbeg[0] = &emb[0]; for(unsigned int i = 1; i <= DACECom.nomax; i++) ipbeg[i] = emb + daceCountMonomials(i - 1, DACECom.nvmax); } #endif monomial *ipoa; unsigned int ilma, illa; monomial *ipob; unsigned int ilmb, illb; daceVariableInformation(ina, &ipoa, &ilma, &illa); daceVariableInformation(inb, &ipob, &ilmb, &illb); // sort so that ina is the short DA vector if(illa>illb) { unsigned int t1; t1 = illb; illb = illa; illa = t1; t1 = ilmb; ilmb = ilma; ilma = t1; monomial* t2; t2 = ipoa; ipoa = ipob; ipob = t2; } for(unsigned int i = 0; i <= DACECom_t.nocut; i++) ipend[i] = ipbeg[i]; // sort vector b by order for(monomial *ib = ipob; ib < ipob+illb; ib++) { const unsigned int noib = DACECom.ieo[ib->ii]; if(noib > DACECom_t.nocut) continue; ipend[noib]->i1 = DACECom.ie1[ib->ii]; ipend[noib]->i2 = DACECom.ie2[ib->ii]; ipend[noib]->cc = ib->cc; ipend[noib]++; } // perform actual multiplication for(monomial *ia = ipoa; ia < ipoa+illa; ia++) { const unsigned int i1ia = DACECom.ie1[ia->ii]; const unsigned int i2ia = DACECom.ie2[ia->ii]; const double ccia = ia->cc; // Note: all of these inner loops can safely be run in parallel //#pragma omp parallel for for(int noib = DACECom_t.nocut-DACECom.ieo[ia->ii]; noib >= 0; noib--) { for(extended_monomial *ib = ipbeg[noib]; ib < ipend[noib]; ib++) { const unsigned int ic = DACECom.ia1[i1ia+ib->i1] + DACECom.ia2[i2ia+ib->i2]; cc[ic] += ccia*ib->cc; } } } dacePack(cc, inc); } /*! Multiply two DA vectors component-wise, i.e. each monomial of ina with the corresponding monomial of inb \param[in] ina Pointer to the first DA object to operate on \param[in] inb Pointer to the first DA object to operate on \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina or inb. \sa daceEvalMonomials */ void daceMultiplyMonomials(const DACEDA *ina, const DACEDA *inb, DACEDA *inc) { monomial *ipoa; unsigned int ilma, illa; monomial *ipob; unsigned int ilmb, illb; monomial *ipoc; unsigned int ilmc, illc; daceVariableInformation(ina, &ipoa, &ilma, &illa); daceVariableInformation(inb, &ipob, &ilmb, &illb); daceVariableInformation(inc, &ipoc, &ilmc, &illc); monomial *ib = ipob, *ic = ipoc; monomial *const ibmax = ipob + ilmb, *const icmax = ipoc + ilmc; for (monomial *i = ipoa; i < ipoa + illa; i++) { while (ib->ii < i->ii && ib < ibmax) ib++; if (ib == ibmax) break; if (ib->ii == i->ii) { if (ic >= icmax) { daceSetError(__func__, DACE_ERROR, 21); break; } ic->cc = i->cc*ib->cc; ic->ii = i->ii; ic++; } } } /*! Perform division of two DA objects. \param[in] ina Pointer to the first DA object to operate on \param[in] inb Pointer to the first DA object to operate on \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina or inb. */ void daceDivide(const DACEDA *ina, const DACEDA *inb, DACEDA *inc) { DACEDA idadiv; daceAllocateDA(&idadiv, 0); daceMultiplicativeInverse(inb, &idadiv); daceMultiply(ina, &idadiv, inc); daceFreeDA(&idadiv); } /*! Square a DA object. \param[in] ina Pointer to the DA object to square \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. */ void daceSquare(const DACEDA *ina, DACEDA *inb) { daceMultiply(ina, ina, inb); } /*! Add constant to a DA object. \param[in] ina Pointer to the first DA object to operate on \param[in] ckon Constant value to add \param[out] inb Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inb can be the same as ina. */ void daceAddDouble(const DACEDA *ina, const double ckon, DACEDA *inb) { if(!daceIsSameObject(ina, inb)) daceCopy(ina, inb); daceSetCoefficient0(inb, 0, daceGetConstant(inb)+ckon); } /*! Subtract DA object from constant. \param[in] ina Pointer to the first DA object to operate on \param[in] ckon Constant value to subtract from \param[out] inb Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inb can be the same as ina. */ void daceDoubleSubtract(const DACEDA *ina, const double ckon, DACEDA *inb) { daceMultiplyDouble(ina, -1.0, inb); daceSetCoefficient0(inb, 0, daceGetConstant(inb)+ckon); } /*! Subtract constant from a DA object. \param[in] ina Pointer to the first DA object to operate on \param[in] ckon Constant value to subtract \param[out] inb Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inb can be the same as ina. */ void daceSubtractDouble(const DACEDA *ina, const double ckon, DACEDA *inb) { daceAddDouble(ina, -ckon, inb); } /*! Multiply constant and DA object. \param[in] ina Pointer to the first DA object to operate on \param[in] ckon Constant value to multiply by \param[out] inb Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inb can be the same as ina. */ void daceMultiplyDouble(const DACEDA *ina, const double ckon, DACEDA *inb) { monomial *ipoa; unsigned int ilma, illa; monomial *ipob; unsigned int ilmb, illb; daceVariableInformation(ina, &ipoa, &ilma, &illa); daceVariableInformation(inb, &ipob, &ilmb, &illb); monomial *ib = ipob; if(illa <= ilmb) { for(monomial *ia = ipoa; ia < ipoa+illa; ia++) { if(DACECom.ieo[ia->ii] > DACECom_t.nocut) continue; const double c = ia->cc*ckon; if(fabs(c) < DACECom_t.eps) continue; ib->cc = c; ib->ii = ia->ii; ib++; } } else { monomial *const ibmax = ipob+ilmb; for(monomial *ia = ipoa; ia < ipoa+illa; ia++) { if(DACECom.ieo[ia->ii] > DACECom_t.nocut) continue; const double c = ia->cc*ckon; if(fabs(c) < DACECom_t.eps) continue; if(ib >= ibmax) { daceSetError(__func__, DACE_ERROR, 21); break; } ib->cc = c; ib->ii = ia->ii; ib++; } } daceSetLength(inb, ib-ipob); } /*! Divide DA object by a constant. \param[in] ina Pointer to the first DA object to operate on \param[in] ckon Constant value to divide by \param[out] inb Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inb can be the same as ina. */ void daceDivideDouble(const DACEDA *ina, const double ckon, DACEDA *inb) { if(ckon == 0.0) { daceSetError(__func__, DACE_ERROR, 41); daceCreateConstant(inb, 0.0); return; } daceMultiplyDouble(ina, 1.0/ckon, inb); } /*! Divide constant by DA object. \param[in] ina Pointer to the first DA object to operate on \param[in] ckon Constant value to divide \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. */ void daceDoubleDivide(const DACEDA *ina, const double ckon, DACEDA *inc) { daceMultiplicativeInverse(ina, inc); daceMultiplyDouble(inc, ckon, inc); } /*! Divide a DA vector by a single variable to some power, if possible. \param[in] ina Pointer to the DA object to operate on \param[in] var Number of the independent variable by which to divide \param[in] p Power of independent variable \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. */ void daceDivideByVariable(const DACEDA *ina, const unsigned int var, const unsigned int p, DACEDA *inc) { monomial *ipoa; unsigned int ilma, illa; monomial *ipoc; unsigned int ilmc, illc; daceVariableInformation(ina, &ipoa, &ilma, &illa); daceVariableInformation(inc, &ipoc, &ilmc, &illc); if(var < 1 || var > DACECom.nvmax) { daceSetError(__func__, DACE_ERROR, 24); daceCreateConstant(inc, 0.0); return; } // treat a few special cases if(p == 0) { // dividing by 1 daceCopy(ina, inc); return; } else if(illa == 0) { // dividing 0 by anything daceCreateConstant(inc, 0.0); return; } else if(p > DACECom.nomax) { // dividing non-zero DA by too high a power daceSetError(__func__, DACE_ERROR, 42); daceCreateConstant(inc, 0.0); return; } const unsigned int ibase = DACECom.nomax+1; unsigned int j = var-1; if(var > DACECom.nv1) j = j-DACECom.nv1; const unsigned int idiv = npown(ibase, j); monomial *ic = ipoc; monomial *const icmax = ipoc+ilmc; if(var > DACECom.nv1) { for(monomial *i = ipoa; i < ipoa+illa; i++) { const unsigned int ic1 = DACECom.ie1[i->ii]; const unsigned int ic2 = DACECom.ie2[i->ii]; const unsigned int ipow = (ic2/idiv)%ibase; if(ipow < p) { daceSetError(__func__, DACE_ERROR, 42); daceCreateConstant(inc, 0.0); return; } if(ic >= icmax) { daceSetError(__func__, DACE_ERROR, 21); break; } ic->ii = DACECom.ia1[ic1] + DACECom.ia2[ic2-p*idiv]; ic->cc = i->cc; ic++; } } else { for(monomial *i = ipoa; i < ipoa+illa; i++) { const unsigned int ic1 = DACECom.ie1[i->ii]; const unsigned int ic2 = DACECom.ie2[i->ii]; const unsigned int ipow = (ic1/idiv)%ibase; if(ipow < p) { daceSetError(__func__, DACE_ERROR, 42); daceCreateConstant(inc, 0.0); return; } if(ic >= icmax) { daceSetError(__func__, DACE_ERROR, 21); break; } ic->ii = DACECom.ia1[ic1-p*idiv] + DACECom.ia2[ic2]; ic->cc = i->cc; ic++; } } daceSetLength(inc, ic-ipoc); } /*! Derivative of DA object with respect to a given independent variable. \param[in] idif Number of the independent variable with respect to which the derivative is taken \param[in] ina Pointer to the DA object to operate on \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. */ void daceDifferentiate(const unsigned int idif, const DACEDA *ina, DACEDA *inc) { monomial *ipoa; unsigned int ilma, illa; monomial *ipoc; unsigned int ilmc, illc; daceVariableInformation(ina, &ipoa, &ilma, &illa); daceVariableInformation(inc, &ipoc, &ilmc, &illc); if(idif < 1 || idif > DACECom.nvmax) { daceSetError(__func__, DACE_ERROR, 24); daceCreateConstant(inc, 0.0); return; } const unsigned int ibase = DACECom.nomax+1; unsigned int j = idif-1; if(idif > DACECom.nv1) j = j-DACECom.nv1; const unsigned int idiv = npown(ibase, j); monomial *ic = ipoc; monomial *const icmax = ipoc+ilmc; if(idif > DACECom.nv1) { for(monomial *i = ipoa; i < ipoa+illa; i++) { const unsigned int ic1 = DACECom.ie1[i->ii]; const unsigned int ic2 = DACECom.ie2[i->ii]; const unsigned int ipow = (ic2/idiv)%ibase; if(ipow == 0 || DACECom.ieo[i->ii] > DACECom_t.nocut+1) continue; if(ic >= icmax) { daceSetError(__func__, DACE_ERROR, 21); break; } ic->ii = DACECom.ia1[ic1] + DACECom.ia2[ic2-idiv]; ic->cc = i->cc*ipow; ic++; } } else { for(monomial *i = ipoa; i < ipoa+illa; i++) { const unsigned int ic1 = DACECom.ie1[i->ii]; const unsigned int ic2 = DACECom.ie2[i->ii]; const unsigned int ipow = (ic1/idiv)%ibase; if(ipow == 0 || DACECom.ieo[i->ii] > DACECom_t.nocut+1) continue; if(ic >= icmax) { daceSetError(__func__, DACE_ERROR, 21); break; } ic->ii = DACECom.ia1[ic1-idiv] + DACECom.ia2[ic2]; ic->cc = i->cc*ipow; ic++; } } daceSetLength(inc, ic-ipoc); } /*! Integral of DA object with respect to a given independent variable. \param[in] idif Number of the independent variable with respect to which the integral is taken \param[in] ina Pointer to the DA object to operate on \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. */ void daceIntegrate(const unsigned int iint, const DACEDA *ina, DACEDA *inc) { monomial *ipoa; unsigned int ilma, illa; monomial *ipoc; unsigned int ilmc, illc; daceVariableInformation(ina, &ipoa, &ilma, &illa); daceVariableInformation(inc, &ipoc, &ilmc, &illc); if(iint < 1 || iint > DACECom.nvmax) { daceSetError(__func__, DACE_ERROR, 24); daceCreateConstant(inc, 0.0); return; } const unsigned int ibase = DACECom.nomax+1; unsigned int j = iint-1; if(iint > DACECom.nv1) j = j-DACECom.nv1; const unsigned int idiv = npown(ibase, j); monomial *ic = ipoc; monomial *const icmax = ipoc+ilmc; if(iint > DACECom.nv1) { for(monomial *i = ipoa; i < ipoa+illa; i++) { if(DACECom.ieo[i->ii] >= DACECom_t.nocut) continue; const unsigned int ic1 = DACECom.ie1[i->ii]; const unsigned int ic2 = DACECom.ie2[i->ii]; const unsigned int ipow = (ic2/idiv)%ibase; const double ccc = i->cc/(ipow+1); if(fabs(ccc) < DACECom_t.eps) continue; if(ic >= icmax) { daceSetError(__func__, DACE_ERROR, 21); break; } ic->ii = DACECom.ia1[ic1] + DACECom.ia2[ic2+idiv]; ic->cc = ccc; ic = ic+1; } } else { for(monomial *i = ipoa; i < ipoa+illa; i++) { if(DACECom.ieo[i->ii] >= DACECom_t.nocut) continue; const unsigned int ic1 = DACECom.ie1[i->ii]; const unsigned int ic2 = DACECom.ie2[i->ii]; const unsigned int ipow = (ic1/idiv)%ibase; const double ccc = i->cc/(ipow+1); if(fabs(ccc) < DACECom_t.eps) continue; if(ic >= icmax) { daceSetError(__func__, DACE_ERROR, 21); break; } ic->ii = DACECom.ia1[ic1+idiv] + DACECom.ia2[ic2]; ic->cc = ccc; ic = ic+1; } } daceSetLength(inc, ic-ipoc); } /******************************************************************************** * DACE intrinsic function routines *********************************************************************************/ /*! Truncate the constant part of a DA object to an integer. \param[in] ina Pointer to the DA object to operate on \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. */ void daceTruncate(const DACEDA *ina, DACEDA *inc) { daceCopy(ina, inc); daceSetCoefficient0(inc, 0, rint(daceGetConstant(inc))); } /*! Round the constant part of a DA object to an integer. \param[in] ina Pointer to the DA object to operate on \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. */ void daceRound(const DACEDA *ina, DACEDA *inc) { daceCopy(ina, inc); daceSetCoefficient0(inc, 0, round(daceGetConstant(inc))); } /*! Modulo the constant part of a DA object by p. \param[in] ina Pointer to the DA object to operate on \param[in] p Value with respect to which to compute the modulo \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. */ void daceModulo(const DACEDA *ina, const double p, DACEDA *inc) { daceCopy(ina, inc); daceSetCoefficient0(inc, 0, fmod(daceGetConstant(inc),p)); } /*! Raise a DA object to the p-th power. \param[in] ina Pointer to the DA object to operate on \param[in] p Power to which to raise the DA object \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. */ void dacePowerDouble(const DACEDA *ina, const double p, DACEDA *inc) { // check simple cases if(p == 0.0) { daceCreateConstant(inc, 1.0); return; } else if(p == (int)p) { dacePower(ina, (int)p, inc); return; } const double a0 = daceGetConstant(ina); if(a0 <= 0.0) { daceSetError(__func__, DACE_ERROR, 43); daceCreateConstant(inc, 0.0); return; } #if DACE_MEMORY_MODEL == DACE_MEMORY_STATIC double xf[DACE_STATIC_NOMAX+1]; #else double *xf = (double*) dacecalloc(DACECom_t.nocut+1, sizeof(double)); #endif xf[0] = pow(a0, p); for(unsigned int i = 1; i < DACECom_t.nocut+1; i++) xf[i] = xf[i-1]/i*(p-(i-1)); daceDivideDouble(ina, a0, inc); // more accurate than including a0 in series (uses non-linear part in EvaluateSeries) daceEvaluateSeries(inc, xf, inc); #if DACE_MEMORY_MODEL != DACE_MEMORY_STATIC dacefree(xf); #endif } /*! Raise a DA object to the p-th integer power. \param[in] ina Pointer to the DA object to operate on \param[in] p Power to which to raise the DA object \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. */ void dacePower(const DACEDA *ina, const int np, DACEDA *inc) { DACEDA itemp; // handle some common simple cases directly switch(np) { case 0: daceCreateConstant(inc, 1.0); return; case 1: daceCopy(ina, inc); return; case -1: daceMultiplicativeInverse(ina, inc); return; } // handle all other cases, again with common special cases hard coded switch(abs(np)) { case 2: daceSquare(ina, inc); break; case 3: daceAllocateDA(&itemp, 0); daceSquare(ina, &itemp); daceMultiply(ina, &itemp, inc); daceFreeDA(&itemp); break; case 4: daceAllocateDA(&itemp, 0); daceSquare(ina, &itemp); daceSquare(&itemp, inc); daceFreeDA(&itemp); break; default: daceAllocateDA(&itemp, 0); daceCopy(ina, &itemp); daceCreateConstant(inc, 1.0); unsigned int inp = abs(np); while(inp) { if(inp & 1u) daceMultiply(inc, &itemp, inc); inp >>= 1; if(inp) daceSquare(&itemp, &itemp); } daceFreeDA(&itemp); } if(np < 0) daceMultiplicativeInverse(inc, inc); } /*! Take the np-th root of a DA object. \param[in] ina Pointer to the DA object to operate on \param[in] np Root to take of the DA object \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. */ void daceRoot(const DACEDA *ina, const int np, DACEDA *inc) { if(np == 0) { daceSetError(__func__, DACE_ERROR, 44); daceCreateConstant(inc, 0.0); return; } const double a0 = daceGetConstant(ina); const unsigned int iodd = abs(np) & 1u; if((iodd == 0) && (a0 <= 0.0)) { daceSetError(__func__, DACE_ERROR, 45); daceCreateConstant(inc, 0.0); return; } else if((iodd == 1) && (a0 == 0.0)) { daceSetError(__func__, DACE_ERROR, 46); daceCreateConstant(inc, 0.0); return; } double cr = 1.0/np; #if DACE_MEMORY_MODEL == DACE_MEMORY_STATIC double xf[DACE_STATIC_NOMAX+1]; #else double *xf = (double*) dacecalloc(DACECom_t.nocut+1, sizeof(double)); #endif xf[0] = copysign(pow(fabs(a0), cr), a0); for(unsigned int i = 1; i < DACECom_t.nocut+1; i++) { xf[i] = xf[i-1]/i*cr; cr--; } daceDivideDouble(ina, a0, inc); // more accurate than including a0 in series (uses non-linear part in EvaluateSeries) daceEvaluateSeries(inc, xf, inc); #if DACE_MEMORY_MODEL != DACE_MEMORY_STATIC dacefree(xf); #endif } /*! Compute the multiplicative inverse of a DA object. \param[in] ina Pointer to the DA object to operate on \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. */ void daceMultiplicativeInverse(const DACEDA *ina, DACEDA *inc) { const double a0 = daceGetConstant(ina); if(a0 == 0.0) { daceSetError(__func__, DACE_ERROR, 41); daceCreateConstant(inc, 0.0); return; } if(DACECom_t.nocut < 5) { // lower orders: compute series directly daceMultiplicativeInverse0(ina, inc, a0); } else { // higher orders: use iteration const unsigned int nocut = DACECom_t.nocut; DACECom_t.nocut = 2; daceMultiplicativeInverse0(ina, inc, a0); DACEDA temp; daceAllocateDA(&temp, 0); for(unsigned int ord = 3; ord <= nocut; ord *= 2) { DACECom_t.nocut = umin(nocut, 2*ord-1); daceMultiply(ina, inc, &temp); daceDoubleSubtract(&temp, 2.0, &temp); daceMultiply(inc, &temp, inc); } daceFreeDA(&temp); } } /*! Compute the multiplicative inverse of a DA object using series expansion. \param[in] ina Pointer to the DA object to operate on \param[out] inc Pointer to the DA object to store the result in \param[in] a0 Constant part of ina \note This routine is aliasing safe, i.e. inc can be the same as ina. */ void daceMultiplicativeInverse0(const DACEDA *ina, DACEDA *inc, const double a0) { daceDivideDouble(ina, a0, inc); #if DACE_MEMORY_MODEL == DACE_MEMORY_STATIC double xf[DACE_STATIC_NOMAX+1]; #else double *xf = (double*) dacecalloc(DACECom_t.nocut+1, sizeof(double)); #endif xf[0] = 1.0/a0; for(unsigned int i = 1; i < DACECom_t.nocut+1; i++) xf[i] = -xf[i-1]; daceEvaluateSeries(inc, xf, inc); #if DACE_MEMORY_MODEL != DACE_MEMORY_STATIC dacefree(xf); #endif } /*! Compute the square root of a DA object. \param[in] ina Pointer to the DA object to operate on \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. */ void daceSquareRoot(const DACEDA *ina, DACEDA *inc) { daceRoot(ina, 2, inc); } /*! Compute the inverse square root of a DA object. \param[in] ina Pointer to the DA object to operate on \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. */ void daceInverseSquareRoot(const DACEDA *ina, DACEDA *inc) { daceRoot(ina, -2, inc); } /*! Compute the cubic root of a DA object. \param[in] ina Pointer to the DA object to operate on \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. */ void daceCubicRoot(const DACEDA *ina, DACEDA *inc) { daceRoot(ina, 3, inc); } /*! Compute the inverse cubic root of a DA object. \param[in] ina Pointer to the DA object to operate on \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. */ void daceInverseCubicRoot(const DACEDA *ina, DACEDA *inc) { daceRoot(ina, -3, inc); } /*! Compute the hypothenuse of two DA objects. \param[in] ina Pointer to the first DA object to operate on \param[in] inb Pointer to the second DA object to operate on \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina or inb. */ void daceHypotenuse(const DACEDA *ina, const DACEDA *inb, DACEDA *inc) { DACEDA itemp1, itemp2; daceAllocateDA(&itemp1, 0); daceAllocateDA(&itemp2, 0); daceSquare(ina, &itemp1); daceSquare(inb, &itemp2); daceAdd(&itemp1, &itemp2, inc); daceRoot(inc, 2, inc); daceFreeDA(&itemp2); daceFreeDA(&itemp1); } /*! Compute the exponential of a DA object. \param[in] ina Pointer to the DA object to operate on \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. */ void daceExponential(const DACEDA *ina, DACEDA *inc) { #if DACE_MEMORY_MODEL == DACE_MEMORY_STATIC double xf[DACE_STATIC_NOMAX+1]; #else double* xf = (double*) dacecalloc(DACECom_t.nocut+1, sizeof(double)); #endif xf[0] = exp(daceGetConstant(ina)); for(unsigned int i = 1; i < DACECom_t.nocut+1; i++) xf[i] = xf[i-1]/i; daceEvaluateSeries(ina, xf, inc); #if DACE_MEMORY_MODEL != DACE_MEMORY_STATIC dacefree(xf); #endif } /*! Compute the natural logarithm root of a DA object. \param[in] ina Pointer to the DA object to operate on \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. */ void daceLogarithm(const DACEDA *ina, DACEDA *inc) { const double a0 = daceGetConstant(ina); if(a0 <= 0) { daceSetError(__func__, DACE_ERROR, 47); daceCreateConstant(inc, 0.0); return; } #if DACE_MEMORY_MODEL == DACE_MEMORY_STATIC double xf[DACE_STATIC_NOMAX+1]; #else double* xf = (double*) dacecalloc(DACECom_t.nocut+1, sizeof(double)); #endif daceDivideDouble(ina, a0, inc); xf[0] = log(a0); xf[1] = 1.0; for(unsigned int i = 2; i < DACECom_t.nocut+1; i++) { xf[i] = -xf[i-1]/i*(i-1); } daceEvaluateSeries(inc, xf, inc); #if DACE_MEMORY_MODEL != DACE_MEMORY_STATIC dacefree(xf); #endif } /*! Compute the logarithm with respect to base b of a DA object. \param[in] ina Pointer to the DA object to operate on \param[in] b Base of the logarithm to use \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. */ void daceLogarithmBase(const DACEDA *ina, const double b, DACEDA *inc) { if(b <= 0) { daceSetError(__func__, DACE_ERROR, 48); daceCreateConstant(inc, 0.0); return; } daceLogarithm(ina, inc); daceMultiplyDouble(inc, 1.0/log(b), inc); } /*! Compute the decadic logarithm of a DA object. \param[in] ina Pointer to the DA object to operate on \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. */ void daceLogarithm10(const DACEDA *ina, DACEDA *inc) { daceLogarithmBase(ina, 10.0, inc); } /*! Compute the binary logarithm of a DA object. \param[in] ina Pointer to the DA object to operate on \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. */ void daceLogarithm2(const DACEDA *ina, DACEDA *inc) { daceLogarithmBase(ina, 2.0, inc); } /*! Compute the sine of a DA object. \param[in] ina Pointer to the DA object to operate on \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. */ void daceSine(const DACEDA *ina, DACEDA *inc) { #if DACE_MEMORY_MODEL == DACE_MEMORY_STATIC double xf[DACE_STATIC_NOMAX+1]; #else double* xf = (double*) dacecalloc(DACECom_t.nocut+1, sizeof(double)); #endif const double a0 = daceGetConstant(ina); xf[0] = sin(a0); xf[1] = cos(a0); for(unsigned int i = 2; i < DACECom_t.nocut+1; i++) { xf[i] = -xf[i-2]/(i*(i-1)); } daceEvaluateSeries(ina, xf, inc); #if DACE_MEMORY_MODEL != DACE_MEMORY_STATIC dacefree(xf); #endif } /*! Compute the cosine of a DA object. \param[in] ina Pointer to the DA object to operate on \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. */ void daceCosine(const DACEDA *ina, DACEDA *inc) { #if DACE_MEMORY_MODEL == DACE_MEMORY_STATIC double xf[DACE_STATIC_NOMAX+1]; #else double* xf = (double*) dacecalloc(DACECom_t.nocut+1, sizeof(double)); #endif const double a0 = daceGetConstant(ina); xf[0] = cos(a0); xf[1] = -sin(a0); for(unsigned int i = 2; i < DACECom_t.nocut+1; i++) { xf[i] = -xf[i-2]/(i*(i-1)); } daceEvaluateSeries(ina, xf, inc); #if DACE_MEMORY_MODEL != DACE_MEMORY_STATIC dacefree(xf); #endif } /*! Compute the tangent of a DA object. \param[in] ina Pointer to the DA object to operate on \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. */ void daceTangent(const DACEDA *ina, DACEDA *inc) { DACEDA itemp; if(cos(daceGetConstant(ina)) == 0.0) { daceSetError(__func__, DACE_ERROR, 49); daceCreateConstant(inc, 0.0); return; } daceAllocateDA(&itemp, 0); daceSine(ina, &itemp); daceCosine(ina, inc); daceDivide(&itemp, inc, inc); daceFreeDA(&itemp); } /*! Compute the arcsine of a DA object. \param[in] ina Pointer to the DA object to operate on \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. */ void daceArcSine(const DACEDA *ina, DACEDA *inc) { DACEDA itemp; if(fabs(daceGetConstant(ina)) >= 1.0) { daceSetError(__func__, DACE_ERROR, 50); daceCreateConstant(inc, 0.0); return; } daceAllocateDA(&itemp, 0); daceSquare(ina, &itemp); daceDoubleSubtract(&itemp, 1.0, &itemp); daceSquareRoot(&itemp, &itemp); daceDivide(ina, &itemp, inc); daceArcTangent(inc, inc); daceFreeDA(&itemp); } /*! Compute the arccosine of a DA object. \param[in] ina Pointer to the DA object to operate on \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. */ void daceArcCosine(const DACEDA *ina, DACEDA *inc) { if(fabs(daceGetConstant(ina)) >= 1.0) { daceSetError(__func__, DACE_ERROR, 50); daceCreateConstant(inc, 0.0); return; } daceArcSine(ina, inc); daceDoubleSubtract(inc, M_PI_2, inc); } /*! Compute the arctangent of a DA object. \param[in] ina Pointer to the DA object to operate on \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. */ void daceArcTangent(const DACEDA *ina, DACEDA *inc) { DACEDA iarg; #if DACE_MEMORY_MODEL == DACE_MEMORY_STATIC double xf[DACE_STATIC_NOMAX+1] = {0}; #else double* xf = (double*) dacecalloc(DACECom_t.nocut+1, sizeof(double)); #endif const double a0 = daceGetConstant(ina); daceAllocateDA(&iarg, 0); daceMultiplyDouble(ina, a0, &iarg); daceAddDouble(&iarg, 1.0, &iarg); daceSubtractDouble(ina, a0, inc); daceDivide(inc, &iarg, &iarg); double s = 1.0; xf[0] = atan(a0); for(unsigned int i = 1; i < DACECom_t.nocut+1; i+=2) { xf[i] = s/i; s = -s; } daceEvaluateSeries(&iarg, xf, inc); daceFreeDA(&iarg); #if DACE_MEMORY_MODEL != DACE_MEMORY_STATIC dacefree(xf); #endif } /*! Arctangent of ina/inb with proper sign in [-pi, pi]. This function follows the C standard atan2(y,x) function syntax. \param[in] ina Pointer to the first DA object to operate on \param[in] ina Pointer to the second DA object to operate on \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. */ void daceArcTangent2(const DACEDA *ina, const DACEDA *inb, DACEDA *inc) { const double cx = daceGetConstant(inb); const double cy = daceGetConstant(ina); if(cx == 0.0 && cy == 0.0) { daceCreateConstant(inc, 0.0); } else { if(fabs(cy) > fabs(cx)) { daceDivide(inb, ina, inc); daceArcTangent(inc, inc); if(cy < 0.0) { daceDoubleSubtract(inc, -M_PI_2, inc); } else { daceDoubleSubtract(inc, M_PI_2, inc); } } else { daceDivide(ina, inb, inc); daceArcTangent(inc, inc); if(cx < 0.0) { if(cy > 0.0) { daceAddDouble(inc, M_PI, inc); } else { daceAddDouble(inc, -M_PI, inc); } } } } } /*! Compute the hyperbolic sine of a DA object. \param[in] ina Pointer to the DA object to operate on \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. */ void daceHyperbolicSine(const DACEDA *ina, DACEDA *inc) { #if DACE_MEMORY_MODEL == DACE_MEMORY_STATIC double xf[DACE_STATIC_NOMAX+1]; #else double* xf = (double*) dacecalloc(DACECom_t.nocut+1, sizeof(double)); #endif const double a0 = daceGetConstant(ina); xf[0] = sinh(a0); xf[1] = cosh(a0); for(unsigned int i = 2; i < DACECom_t.nocut+1; i++) { xf[i] = xf[i-2]/(i*(i-1)); } daceEvaluateSeries(ina, xf, inc); #if DACE_MEMORY_MODEL != DACE_MEMORY_STATIC dacefree(xf); #endif } /*! Compute the hyperbolic cosine of a DA object. \param[in] ina Pointer to the DA object to operate on \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. */ void daceHyperbolicCosine(const DACEDA *ina, DACEDA *inc) { #if DACE_MEMORY_MODEL == DACE_MEMORY_STATIC double xf[DACE_STATIC_NOMAX+1]; #else double* xf = (double*) dacecalloc(DACECom_t.nocut+1, sizeof(double)); #endif const double a0 = daceGetConstant(ina); xf[0] = cosh(a0); xf[1] = sinh(a0); for(unsigned int i = 2; i < DACECom_t.nocut+1; i++) { xf[i] = xf[i-2]/(i*(i-1)); } daceEvaluateSeries(ina, xf, inc); #if DACE_MEMORY_MODEL != DACE_MEMORY_STATIC dacefree(xf); #endif } /*! Compute the hyperbolic tangent of a DA object. \param[in] ina Pointer to the DA object to operate on \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. */ void daceHyperbolicTangent(const DACEDA *ina, DACEDA *inc) { DACEDA itemp; daceAllocateDA(&itemp, 0); daceHyperbolicSine(ina, &itemp); daceHyperbolicCosine(ina, inc); daceDivide(&itemp, inc, inc); daceFreeDA(&itemp); } /*! Compute the hyperbolic arcsince of a DA object. \param[in] ina Pointer to the DA object to operate on \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. */ void daceHyperbolicArcSine(const DACEDA *ina, DACEDA *inc) { DACEDA itemp; daceAllocateDA(&itemp, 0); daceSquare(ina, inc); daceAddDouble(inc, 1.0, &itemp); daceSquareRoot(&itemp, inc); daceAdd(ina, inc, &itemp); daceLogarithm(&itemp, inc); daceFreeDA(&itemp); } /*! Compute the hyperbolic arccosine of a DA object. \param[in] ina Pointer to the DA object to operate on \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. */ void daceHyperbolicArcCosine(const DACEDA *ina, DACEDA *inc) { DACEDA itemp; if(daceGetConstant(ina) < 1.0) { daceSetError(__func__, DACE_ERROR, 50); daceCreateConstant(inc, 0.0); return; } daceAllocateDA(&itemp, 0); daceSquare(ina, inc); daceSubtractDouble(inc, 1.0, &itemp); daceSquareRoot(&itemp, inc); daceAdd(ina, inc, &itemp); daceLogarithm(&itemp, inc); daceFreeDA(&itemp); } /*! Compute the hyperbolic arctangent of a DA object. \param[in] ina Pointer to the DA object to operate on \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. */ void daceHyperbolicArcTangent(const DACEDA *ina, DACEDA *inc) { DACEDA itemp; if(fabs(daceGetConstant(ina)) >= 1.0) { daceSetError(__func__, DACE_ERROR, 50); daceCreateConstant(inc, 0.0); return; } daceAllocateDA(&itemp, 0); daceAddDouble(ina, 1.0, &itemp); daceDoubleSubtract(ina, 1.0, inc); daceDivide(&itemp, inc, inc); daceLogarithm(inc, &itemp); daceMultiplyDouble(&itemp, 0.5, inc); daceFreeDA(&itemp); } /*! Compute the error function of a DA object. \param[in] ina Pointer to the DA object to operate on \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. */ void daceErrorFunction(const DACEDA *ina, DACEDA *inc) { #if DACE_MEMORY_MODEL == DACE_MEMORY_STATIC double xf[DACE_STATIC_NOMAX+1]; #else double* xf = (double*) dacecalloc(DACECom_t.nocut+1, sizeof(double)); #endif const double a0 = daceGetConstant(ina); double factor = 2.0*exp(-a0*a0)/sqrt(M_PI); xf[0] = erf(a0); xf[1] = factor; double Hi2 = 1.0; // Hermite polynomial H_{i-2} = H_0 double Hi1 = 2.0*a0; // Hermite polynomial H_{i-1} = H_1 for(unsigned int i = 2; i < DACECom_t.nocut+1; i++) { factor /= -((double)i); xf[i] = factor*Hi1; const double temp = 2.0*a0*Hi1 - 2.0*(i-1)*Hi2; // recursion relation: H_i = 2*x*H_{i-1} - 2*(i-1)*H_{i-2} Hi2 = Hi1; Hi1 = temp; } daceEvaluateSeries(ina, xf, inc); #if DACE_MEMORY_MODEL != DACE_MEMORY_STATIC dacefree(xf); #endif } /*! Compute the complementary error function of a DA object. \param[in] ina Pointer to the DA object to operate on \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. */ void daceComplementaryErrorFunction(const DACEDA *ina, DACEDA *inc) { #if DACE_MEMORY_MODEL == DACE_MEMORY_STATIC double xf[DACE_STATIC_NOMAX+1]; #else double* xf = (double*) dacecalloc(DACECom_t.nocut+1, sizeof(double)); #endif const double a0 = daceGetConstant(ina); double factor = -2.0*exp(-a0*a0)/sqrt(M_PI); xf[0] = erfc(a0); xf[1] = factor; double Hi2 = 1.0; // Hermite polynomial H_{i-2} = H_0 double Hi1 = 2.0*a0; // Hermite polynomial H_{i-1} = H_1 for(unsigned int i = 2; i < DACECom_t.nocut+1; i++) { factor /= -((double)i); xf[i] = factor*Hi1; const double temp = 2.0*a0*Hi1 - 2.0*(i-1)*Hi2; // recursion relation: H_i = 2*x*H_{i-1} - 2*(i-1)*H_{i-2} Hi2 = Hi1; Hi1 = temp; } daceEvaluateSeries(ina, xf, inc); #if DACE_MEMORY_MODEL != DACE_MEMORY_STATIC dacefree(xf); #endif } /// @cond // Wrappers for contributed netlib Bessel functions (not for public use) /*! Compute value of Bessel functions J_n, Y_n for n in [n0, n1]. \param[in] x function argument (non-negative) \param[in] n0 Lowest order of the Bessel functions to calculate (n0 <= n1) \param[in] n1 Highest order of the Bessel functions to calculate (n0 <= n1) \param[in] type Type of function to evaluate: -1: Bessel J function 1: Bessel Y function \param[out] bz Array of size n1-n0+1 containing the values of B_{n0}, B_{n0+1}, ..., B_{n1} \return Returns 0 if all values are calculated accurately, -1 if x is too large to calculate the result or another error occured, or +1 if some of the results are of reduced accuracy. */ int BesselWrapper(const double x, const int n0, const int n1, const int type, double *bz) { long int nb = (abs(n0) > abs(n1) ? abs(n0) : abs(n1))+1, ncalc; double xx = x, alpha = 0.0; #if DACE_MEMORY_MODEL == DACE_MEMORY_STATIC #define DACE_STATIC_MAX_BESSEL_ORDER 100 if( DACE_STATIC_MAX_BESSEL_ORDER < nb ) return -1; double b[DACE_STATIC_MAX_BESSEL_ORDER]; #else double* b = (double*) dacecalloc(nb, sizeof(double)); #endif if(type < 0) rjbesl_(&xx, &alpha, &nb, b, &ncalc); else rybesl_(&xx, &alpha, &nb, b, &ncalc); // discombobulate results if(ncalc >= 0) { ncalc = (ncalc == nb ? 0 : 1); double s = (n0%2 == 0 ? 1.0 : -1.0); for(int i = n0; i <= n1; i++) { if(i >= 0) *(bz++) = b[i]; else { *(bz++) = s*b[-i]; // for integer orders considered here, (-1)^n J_n = J_{-n}, and (-1)^n Y_n = Y_{-n} s *= -1.0; } } } #if DACE_MEMORY_MODEL != DACE_MEMORY_STATIC dacefree(b); #endif return ncalc < 0 ? -1 : ncalc; } /*! Compute value of modified Bessel functions I_n, K_n for n in [n0, n1]. \param[in] x function argument (non-negative) \param[in] n0 Lowest order of the Bessel functions to calculate (n0 <= n1) \param[in] n1 Highest order of the Bessel functions to calculate (n0 <= n1) \param[in] type Type of function to evaluate: -2: Bessel I function, scaled (i.e. exp(-x)*I_n(x)) -1: Bessel I function 1: Bessel K function 2: Bessel K function, scaled (i.e. exp(x)*K_n(x)) \param[out] bz Array of size n1-n0+1 containing the values of B_{n0}, B_{n0+1}, ..., B_{n1} \return Returns 0 if all values are calculated accurately, -1 if x is too large to calculate the result or another error occured, or +1 if some of the results are of reduced accuracy. */ int ModifiedBesselWrapper(const double x, const int n0, const int n1, const int type, double *bz) { long int nb = (abs(n0) > abs(n1) ? abs(n0) : abs(n1))+1, ize = abs(type), ncalc; double xx = x, alpha = 0.0; #if DACE_MEMORY_MODEL == DACE_MEMORY_STATIC #define DACE_STATIC_MAX_BESSEL_ORDER 100 if( DACE_STATIC_MAX_BESSEL_ORDER < nb ) return -1; double b[DACE_STATIC_MAX_BESSEL_ORDER]; #else double* b = (double*) dacecalloc(nb, sizeof(double)); #endif if(type < 0) ribesl_(&xx, &alpha, &nb, &ize, b, &ncalc); else rkbesl_(&xx, &alpha, &nb, &ize, b, &ncalc); // discombobulate results if(ncalc >= 0) { ncalc = (ncalc == nb ? 0 : 1); for(int i = n0; i <= n1; i++) *(bz++) = b[abs(i)]; // for integer orders considered here, I_n = I_{-n}, and for all orders K_n = K_{-n} } #if DACE_MEMORY_MODEL != DACE_MEMORY_STATIC dacefree(b); #endif return ncalc < 0 ? -1 : ncalc; } /// @endcond /*! Compute the modified Bessel function I_n of a DA object. \param[in] ina Pointer to the DA object to operate on (constant part >= 0) \param[in] n Order of the Bessel function \param[in] scaled If true, the scaled Bessel function is computed (i.e. exp(-x)*I_n(x)) \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. */ void daceBesselIFunction(const DACEDA *ina, const int n, const bool scaled, DACEDA *inc) { const double a0 = daceGetConstant(ina); if(a0 <= 0.0) { daceSetError(__func__, DACE_ERROR, 50); daceCreateConstant(inc, 0.0); return; } #if DACE_MEMORY_MODEL == DACE_MEMORY_STATIC double bz[2*DACE_STATIC_NOMAX+1]; #else double* bz = (double*) dacecalloc(2*DACECom_t.nocut+1, sizeof(double)); #endif const int res = ModifiedBesselWrapper(a0, n-DACECom_t.nocut, n+DACECom_t.nocut, scaled ? -2 : -1, bz); if(res >= 0) { if(scaled) daceEvaluateScaledModifiedBesselFunction(ina, bz, 1.0, inc); else daceEvaluateBesselFunction(ina, bz, 1.0, 1.0, inc); } else { daceSetError(__func__, DACE_ERROR, 50); daceCreateConstant(inc, 0.0); } #if DACE_MEMORY_MODEL != DACE_MEMORY_STATIC dacefree(bz); #endif } /*! Compute the modified Bessel function K_n of a DA object. \param[in] ina Pointer to the DA object to operate on (constant part >= 0) \param[in] n Order of the Bessel function \param[in] scaled If true, the scaled Bessel function is computed (i.e. exp(x)*K_n(x)) \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. */ void daceBesselKFunction(const DACEDA *ina, const int n, const bool scaled, DACEDA *inc) { const double a0 = daceGetConstant(ina); if(a0 <= 0.0) { daceSetError(__func__, DACE_ERROR, 50); daceCreateConstant(inc, 0.0); return; } #if DACE_MEMORY_MODEL == DACE_MEMORY_STATIC double bz[2*DACE_STATIC_NOMAX+1]; #else double* bz = (double*) dacecalloc(2*DACECom_t.nocut+1, sizeof(double)); #endif const int res = ModifiedBesselWrapper(a0, n-DACECom_t.nocut, n+DACECom_t.nocut, scaled ? 2 : 1, bz); if(res >= 0) { if(scaled) daceEvaluateScaledModifiedBesselFunction(ina, bz, -1.0, inc); else daceEvaluateBesselFunction(ina, bz, 1.0, -1.0, inc); } else { daceSetError(__func__, DACE_ERROR, 50); daceCreateConstant(inc, 0.0); } #if DACE_MEMORY_MODEL != DACE_MEMORY_STATIC dacefree(bz); #endif } /*! Compute the Bessel function J_n of a DA object. \param[in] ina Pointer to the DA object to operate on (constant part >= 0) \param[in] n Order of the Bessel function \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. */ void daceBesselJFunction(const DACEDA *ina, const int n, DACEDA *inc) { const double a0 = daceGetConstant(ina); if(a0 <= 0.0) { daceSetError(__func__, DACE_ERROR, 50); daceCreateConstant(inc, 0.0); return; } #if DACE_MEMORY_MODEL == DACE_MEMORY_STATIC double bz[2*DACE_STATIC_NOMAX+1]; #else double* bz = (double*) dacecalloc(2*DACECom_t.nocut+1, sizeof(double)); #endif const int res = BesselWrapper(a0, n-DACECom_t.nocut, n+DACECom_t.nocut, -1, bz); if(res >= 0) daceEvaluateBesselFunction(ina, bz, -1.0, 1.0, inc); else { daceSetError(__func__, DACE_ERROR, 50); daceCreateConstant(inc, 0.0); } #if DACE_MEMORY_MODEL != DACE_MEMORY_STATIC dacefree(bz); #endif } /*! Compute the Bessel function Y_n of a DA object. \param[in] ina Pointer to the DA object to operate on (constant part >= 0) \param[in] n Order of the Bessel function \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. */ void daceBesselYFunction(const DACEDA *ina, const int n, DACEDA *inc) { const double a0 = daceGetConstant(ina); if(a0 <= 0.0) { daceSetError(__func__, DACE_ERROR, 50); daceCreateConstant(inc, 0.0); return; } #if DACE_MEMORY_MODEL == DACE_MEMORY_STATIC double bz[2*DACE_STATIC_NOMAX+1]; #else double* bz = (double*) dacecalloc(2*DACECom_t.nocut+1, sizeof(double)); #endif const int res = BesselWrapper(a0, n-DACECom_t.nocut, n+DACECom_t.nocut, 1, bz); if(res >= 0) daceEvaluateBesselFunction(ina, bz, -1.0, 1.0, inc); else { daceSetError(__func__, DACE_ERROR, 50); daceCreateConstant(inc, 0.0); } #if DACE_MEMORY_MODEL != DACE_MEMORY_STATIC dacefree(bz); #endif } /*! Evaluate a Bessel function with coefficients bz with the non-constant part of ina. \param[in] ina Pointer to the DA object to operate on \param[in] bz C array of 2*nocut+1 elements containing Bessel functions of orders n-nocut, ..., n+nocut \param[in] type Either -1.0 for normal Bessel functions, or +1.0 for modified Bessel functions. \param[in] ktype Either -1.0 for modified Bessel K function, or +1.0 for all other Bessel functions. \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. */ void daceEvaluateBesselFunction(const DACEDA *ina, const double bz[], const double type, const double ktype, DACEDA *inc) { #if DACE_MEMORY_MODEL == DACE_MEMORY_STATIC double xf[DACE_STATIC_NOMAX+1]; double binomial[DACE_STATIC_NOMAX+1]; #else double* xf = (double*) dacecalloc(DACECom_t.nocut+1, sizeof(double)); double* binomial = (double*) dacecalloc(DACECom_t.nocut+1, sizeof(double)); #endif xf[0] = bz[DACECom_t.nocut]; binomial[0] = 1.0; double factor = 1.0; for(unsigned int i = 1; i < DACECom_t.nocut+1; i++) { factor *= ktype*0.5/i; // calculate binomial coefficients i choose j based on previously calculated i-1 choose j. binomial[i] = 1.0; for(unsigned int j = i-1; j > 0; j--) binomial[j] += binomial[j-1]; // Calculate n-th derivative of Bessel function C, see http://dlmf.nist.gov/10.6 // bz contains values of C_{n-o} to C_{n+o} of constant part of ina double sign = 1.0, c = 0.0; xf[i] = 0.0; for(unsigned int j = 0; j <= i; j++) { // use Kahan summation, since signs oscillate and magnitudes can also vary greatly const double y = binomial[j]*sign*bz[DACECom_t.nocut-i+2*j] - c; const double t = xf[i] + y; c = (t - xf[i]) - y; xf[i] = t; // in infinite precision the above is equivalent to: // xf[i] += binomial[j]*sign*bz[DACECom_t.nocut-i+2*j]; sign *= type; } xf[i] *= factor; } daceEvaluateSeries(ina, xf, inc); #if DACE_MEMORY_MODEL != DACE_MEMORY_STATIC dacefree(binomial); dacefree(xf); #endif } /*! Evaluate a scaled modified Bessel function with coefficients bz with the non-constant part of ina. \param[in] ina Pointer to the DA object to operate on \param[in] bz C array of 2*nocut+1 elements containing modified Bessel functions of orders n-nocut, ..., n+nocut \param[in] ktype Either -1.0 for scaled Bessel K function, or +1.0 for scaled Bessel I function \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. */ void daceEvaluateScaledModifiedBesselFunction(const DACEDA *ina, const double bz[], const double ktype, DACEDA *inc) { #if DACE_MEMORY_MODEL == DACE_MEMORY_STATIC double xf[DACE_STATIC_NOMAX+1]; double binomial[2*DACE_STATIC_NOMAX+1]; #else double* xf = (double*) dacecalloc(DACECom_t.nocut+1, sizeof(double)); double* binomial = (double*) dacecalloc(2*DACECom_t.nocut+1, sizeof(double)); #endif xf[0] = bz[DACECom_t.nocut]; binomial[0] = 1.0; double factor = 1.0; for(unsigned int i = 1; i < DACECom_t.nocut+1; i++) { factor *= ktype*0.5/i; // calculate binomial coefficients 2*i-1 choose j based on previously calculated 2*i-2 choose j. binomial[2*i-1] = 1.0; for(unsigned int j = 2*i-2; j > 0; j--) binomial[j] += binomial[j-1]; // calculate binomial coefficients 2*i choose j based on previously calculated 2*i-1 choose j. binomial[2*i] = 1.0; for(unsigned int j = 2*i-1; j > 0; j--) binomial[j] += binomial[j-1]; // Calculate n-th derivative of Bessel function C // bz contains values of C_{n-o} to C_{n+o} of constant part of ina double sign = 1.0, c = 0.0; xf[i] = 0.0; for(unsigned int j = 0; j <= 2*i; j++) { // use Kahan summation, since signs oscillate and magnitudes can also vary greatly const double y = binomial[j]*sign*bz[DACECom_t.nocut-i+j] - c; const double t = xf[i] + y; c = (t - xf[i]) - y; xf[i] = t; // in infinite precision the above is equivalent to: // xf[i] += binomial[j]*sign*bz[DACECom_t.nocut-i+j]; sign *= -1.0; } xf[i] *= factor; } daceEvaluateSeries(ina, xf, inc); #if DACE_MEMORY_MODEL != DACE_MEMORY_STATIC dacefree(binomial); dacefree(xf); #endif } /*! Compute the partial Logarithmic Gamma function of a DA object (without constant part). \param[in] ina Pointer to the DA object to operate on (constant part != 0, -1, -2, ...) \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. \note No argument checking is performed to ensure values are within allowable range. */ void daceLogGammaFunction0(const DACEDA *ina, const double a0, DACEDA *inc) { #if DACE_MEMORY_MODEL == DACE_MEMORY_STATIC double xf[DACE_STATIC_NOMAX+1]; #else double* xf = (double*) dacecalloc(DACECom_t.nocut+1, sizeof(double)); #endif xf[0] = 0.0; xf[1] = psi_(&a0); double s = 1.0; for(unsigned int i = 2; i < DACECom_t.nocut+1; i++) { xf[i] = (s/i)*zeta_(i, a0, NULL); s *= -1.0; } daceEvaluateSeries(ina, xf, inc); #if DACE_MEMORY_MODEL != DACE_MEMORY_STATIC dacefree(xf); #endif } /*! Compute the Logarithmic Gamma function of a DA object. \param[in] ina Pointer to the DA object to operate on (constant part != 0, -1, -2, ...) \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. */ void daceLogGammaFunction(const DACEDA *ina, DACEDA *inc) { const double a0 = daceGetConstant(ina); if(a0 <= 0.0 && trunc(a0) == a0) { daceSetError(__func__, DACE_ERROR, 50); daceCreateConstant(inc, 0.0); return; } daceLogGammaFunction0(ina, a0, inc); daceSetCoefficient0(inc, 0, log(dgamma_(&a0))); } /*! Compute the Gamma function of a DA object. \param[in] ina Pointer to the DA object to operate on (constant part != 0, -1, -2, ...) \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. */ void daceGammaFunction(const DACEDA *ina, DACEDA *inc) { const double a0 = daceGetConstant(ina); if(a0 <= 0.0 && trunc(a0) == a0) { daceSetError(__func__, DACE_ERROR, 50); daceCreateConstant(inc, 0.0); return; } daceLogGammaFunction0(ina, a0, inc); daceExponential(inc, inc); daceMultiplyDouble(inc, dgamma_(&a0), inc); } /*! Compute the n-th Psi function (i.e. the n+1 derivative of the logarithmic gamma function) of a DA object. \param[in] ina Pointer to the DA object to operate on (constant part != 0, -1, -2, ...) \param[in] n Order of the Psi function (n >= 0) \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. */ void dacePsiFunction(const DACEDA *ina, const unsigned int n, DACEDA *inc) { const double a0 = daceGetConstant(ina); if(a0 <= 0.0 && trunc(a0) == a0) { daceSetError(__func__, DACE_ERROR, 50); daceCreateConstant(inc, 0.0); return; } #if DACE_MEMORY_MODEL == DACE_MEMORY_STATIC double xf[DACE_STATIC_NOMAX+1]; #else double* xf = (double*) dacecalloc(DACECom_t.nocut+1, sizeof(double)); #endif if(n == 0) { xf[0] = psi_(&a0); double s = 1.0; for(unsigned int i = 1; i < DACECom_t.nocut+1; i++) { xf[i] = s*zeta_(i+1, a0, NULL); s *= -1.0; } } else { double fac = (n%2 ? 1.0 : -1.0); for(unsigned int i = 2; i <= n; i++) fac *= i; for(unsigned int i = 0; i < DACECom_t.nocut+1; i++) { xf[i] = fac*zeta_(n+i+1, a0, NULL); fac = -(fac/(i+1))*(n+i+1); } } daceEvaluateSeries(ina, xf, inc); #if DACE_MEMORY_MODEL != DACE_MEMORY_STATIC dacefree(xf); #endif } /*! Evaluate a polynomial with coefficients xf with the non-constant part of ina. \param[in] ina Pointer to the DA object to operate on \param[in] xf C array of nocut+1 elements containing the coefficients of the polynomial \param[out] inc Pointer to the DA object to store the result in \note This routine is aliasing safe, i.e. inc can be the same as ina. */ void daceEvaluateSeries(const DACEDA *ina, const double xf[], DACEDA *inc) { DACEDA inon; const unsigned int nocut = DACECom_t.nocut; daceAllocateDA(&inon, 0); daceCopy(ina, &inon); daceSetCoefficient0(&inon, 0, 0.0); DACECom_t.nocut = 1; daceMultiplyDouble(&inon, xf[nocut], inc); daceAddDouble(inc, xf[nocut-1], inc); // evaluate series for(int i = nocut-2; i >= 0; i--) { DACECom_t.nocut = nocut-i; daceMultiply(&inon, inc, inc); daceAddDouble(inc, xf[i], inc); } DACECom_t.nocut = nocut; daceFreeDA(&inon); } /*! Compute the weighted sum of two DA objects. \param[in] ina Pointer to the first DA object to operate on \param[in] afac Weighting factor to multiply ina by \param[in] inb Pointer to the second DA object to operate on \param[in] bfac Weighting factor to multiply inb by \param[out] inc Pointer to the DA object to store the result in \note This routine is NOT aliasing safe! So inc MUST BE DIFFERENT from ina and inb. */ void daceWeightedSum(const DACEDA *ina, const double afac, const DACEDA *inb, const double bfac, DACEDA *inc) { monomial *ipoa; unsigned int ilma, illa; monomial *ipob; unsigned int ilmb, illb; monomial *ipoc; unsigned int ilmc, illc; daceVariableInformation(ina, &ipoa, &ilma, &illa); daceVariableInformation(inb, &ipob, &ilmb, &illb); daceVariableInformation(inc, &ipoc, &ilmc, &illc); monomial *ia = ipoa, *ib = ipob, *ic = ipoc; monomial *const iamax = ipoa+illa, *const ibmax = ipob+illb, *const icmax = ipoc+ilmc; if(illa > 0 && illb > 0) { // both polynomials have coefficients, merge until one runs out unsigned int ja = ia->ii; unsigned int jb = ib->ii; while(true) { if(ja == jb) { // add the two terms if(DACECom.ieo[ja] <= DACECom_t.nocut) { const double ccc = ia->cc*afac + ib->cc*bfac; if(fabs(ccc) >= DACECom_t.eps) { if(ic >= icmax) { daceSetError(__func__, DACE_ERROR, 21); daceSetLength(inc, ilmc); return; } ic->cc = ccc; ic->ii = ia->ii; ic++; } } ia++; ib++; if(ia >= iamax || ib >= ibmax) break; ja = ia->ii; jb = ib->ii; } else if(ja < jb) { // store term a if(DACECom.ieo[ja] <= DACECom_t.nocut) { const double ccc = ia->cc*afac; if(fabs(ccc) >= DACECom_t.eps) { if(ic >= icmax) { daceSetError(__func__, DACE_ERROR, 21); daceSetLength(inc, ilmc); return; } ic->cc = ccc; ic->ii = ia->ii; ic++; } } ia++; if(ia >= iamax) break; ja = ia->ii; } else { // store term b if(DACECom.ieo[jb] <= DACECom_t.nocut) { const double ccc = ib->cc*bfac; if(fabs(ccc) >= DACECom_t.eps) { if(ic >= icmax) { daceSetError(__func__, DACE_ERROR, 21); daceSetLength(inc, ilmc); return; } ic->cc = ccc; ic->ii = ib->ii; ic++; } } ib++; if(ib >= ibmax) break; jb = ib->ii; } } } // copy any remaining terms from either ina or inb monomial *ismin, *ismax; double fac; if(ia < iamax) { ismin = ia; ismax = iamax; fac = afac; } else { ismin = ib; ismax = ibmax; fac = bfac; } for(monomial *is = ismin; is < ismax; is++) { if(DACECom.ieo[is->ii] <= DACECom_t.nocut) { const double ccc = is->cc*fac; if(fabs(ccc) >= DACECom_t.eps) { if(ic >= icmax) { daceSetError(__func__, DACE_ERROR, 21); daceSetLength(inc, ilmc); return; } ic->cc = ccc; ic->ii = is->ii; ic++; } } } daceSetLength(inc, ic-ipoc); } /** @}*/

yolov2.h

#ifndef YOLOV2_H #define YOLOV2_H #include <stdio.h> #include <stdlib.h> #include <iostream> #include <math.h> #include <fcntl.h> #include <string.h> #include <assert.h> #define STB_IMAGE_IMPLEMENTATION #include "stb_image.h" #define STB_IMAGE_WRITE_IMPLEMENTATION #include "stb_image_write.h" //#include "yolo_hls.h" typedef enum{ LOGISTIC, RELU, RELIE, LINEAR, RAMP, TANH, PLSE, LEAKY, ELU, LOGGY, STAIR, HARDTAN, LHTAN } ACTIVATION; typedef enum { CONVOLUTIONAL, DECONVOLUTIONAL, CONNECTED, MAXPOOL, SOFTMAX, DETECTION, DROPOUT, CROP, ROUTE, COST, NORMALIZATION, AVGPOOL, LOCAL, SHORTCUT, ACTIVE, RNN, GRU, LSTM, CRNN, BATCHNORM, NETWORK, XNOR, REGION, YOLO, REORG, UPSAMPLE, LOGXENT, L2NORM, BLANK } LAYER_TYPE; struct network; typedef struct network network; struct layer; typedef struct layer layer; struct layer{ LAYER_TYPE type; ACTIVATION activation; void (*forward) (struct layer, struct network); int batch_normalize; int shortcut; int batch; int forced; int flipped; int inputs; int outputs; int nweights; int nbiases; int extra; int truths; int h,w,c; int out_h, out_w, out_c; int n; int max_boxes; int groups; int size; int side; int stride; int reverse; int flatten; int spatial; int pad; int sqrt; int flip; int index; int binary; int xnor; int steps; int hidden; int truth; float smooth; float dot; float angle; float jitter; float saturation; float exposure; float shift; float ratio; float learning_rate_scale; float clip; int softmax; int classes; int coords; int background; int rescore; int objectness; int joint; int noadjust; int reorg; int log; int tanh; int *mask; int total; float alpha; float beta; float kappa; float coord_scale; float object_scale; float noobject_scale; float mask_scale; float class_scale; int bias_match; int random; float ignore_thresh; float truth_thresh; float thresh; float focus; int classfix; int absolute; int onlyforward; int stopbackward; // int dontload; int dontsave; // int dontloadscales; float temperature; float probability; float scale; char * cweights; int * indexes; int * input_layers; int * input_sizes; int * map; float * rand; float * cost; float * state; float * prev_state; float * forgot_state; float * forgot_delta; float * state_delta; float * combine_cpu; float * combine_delta_cpu; float * concat; float * concat_delta; float * binary_weights; float * biases; float * bias_updates; float * scales; float * scale_updates; float * weights; float * weight_updates; float * delta; float * output; float * loss; float * squared; float * norms; float * spatial_mean; float * mean; float * variance; float * mean_delta; float * variance_delta; float * rolling_mean; float * rolling_variance; float * x; float * x_norm; float * m; float * v; float * bias_m; float * bias_v; float * scale_m; float * scale_v; float *z_cpu; float *r_cpu; float *h_cpu; float * prev_state_cpu; float *temp_cpu; float *temp2_cpu; float *temp3_cpu; float *dh_cpu; float *hh_cpu; float *prev_cell_cpu; float *cell_cpu; float *f_cpu; float *i_cpu; float *g_cpu; float *o_cpu; float *c_cpu; float *dc_cpu; float * binary_input; struct layer *input_layer; struct layer *self_layer; struct layer *output_layer; struct layer *reset_layer; struct layer *update_layer; struct layer *state_layer; struct layer *input_gate_layer; struct layer *state_gate_layer; struct layer *input_save_layer; struct layer *state_save_layer; struct layer *input_state_layer; struct layer *state_state_layer; struct layer *input_z_layer; struct layer *state_z_layer; struct layer *input_r_layer; struct layer *state_r_layer; struct layer *input_h_layer; struct layer *state_h_layer; struct layer *wz; struct layer *uz; struct layer *wr; struct layer *ur; struct layer *wh; struct layer *uh; struct layer *uo; struct layer *wo; struct layer *uf; struct layer *wf; struct layer *ui; struct layer *wi; struct layer *ug; struct layer *wg; //tree *softmax_tree; size_t workspace_size; }; void free_layer(layer l) { if(l.cweights) free(l.cweights); if(l.indexes) free(l.indexes); if(l.input_layers) free(l.input_layers); if(l.input_sizes) free(l.input_sizes); if(l.map) free(l.map); if(l.rand) free(l.rand); if(l.cost) free(l.cost); if(l.state) free(l.state); if(l.prev_state) free(l.prev_state); if(l.forgot_state) free(l.forgot_state); if(l.forgot_delta) free(l.forgot_delta); if(l.state_delta) free(l.state_delta); if(l.concat) free(l.concat); if(l.concat_delta) free(l.concat_delta); if(l.binary_weights) free(l.binary_weights); if(l.biases) free(l.biases); if(l.bias_updates) free(l.bias_updates); if(l.scales) free(l.scales); if(l.scale_updates) free(l.scale_updates); if(l.weights) free(l.weights); if(l.weight_updates) free(l.weight_updates); if(l.delta) free(l.delta); if(l.output) free(l.output); if(l.squared) free(l.squared); if(l.norms) free(l.norms); if(l.spatial_mean) free(l.spatial_mean); if(l.mean) free(l.mean); if(l.variance) free(l.variance); if(l.mean_delta) free(l.mean_delta); if(l.variance_delta) free(l.variance_delta); if(l.rolling_mean) free(l.rolling_mean); if(l.rolling_variance) free(l.rolling_variance); if(l.x) free(l.x); if(l.x_norm) free(l.x_norm); if(l.m) free(l.m); if(l.v) free(l.v); if(l.z_cpu) free(l.z_cpu); if(l.r_cpu) free(l.r_cpu); if(l.h_cpu) free(l.h_cpu); if(l.binary_input) free(l.binary_input); } //void free_layer(layer); typedef enum { CONSTANT, STEP, EXP, POLY, STEPS, SIG, RANDOM } learning_rate_policy; typedef struct network{ int n; int batch; size_t *seen; int *t; float epoch; int subdivisions; layer *layers; float *output; learning_rate_policy policy; float learning_rate; float momentum; float decay; float gamma; float scale; float power; int time_steps; int step; int max_batches; float *scales; int *steps; int num_steps; int burn_in; int adam; float B1; float B2; float eps; int inputs; int outputs; int truths; int notruth; int h, w, c; int max_crop; int min_crop; float max_ratio; float min_ratio; int center; float angle; float aspect; float exposure; float saturation; float hue; int random; int gpu_index; // tree *hierarchy; float *input; float *truth; float *delta; float *workspace; int train; int index; float *cost; float clip; } network; network *make_network(int n); layer get_network_output_layer(network *net); typedef struct { int w; int h; float scale; float rad; float dx; float dy; float aspect; } augment_args; typedef struct { int w; int h; int c; float *data; } image; typedef struct{ float x, y, w, h; } box; typedef struct detection{ box bbox; int classes; float *prob; float *mask; float objectness; int sort_class; } detection; typedef struct matrix{ int rows, cols; float **vals; } matrix; typedef struct{ int w, h; matrix X; matrix y; int shallow; int *num_boxes; box **boxes; } data; typedef enum { CLASSIFICATION_DATA, DETECTION_DATA, CAPTCHA_DATA, REGION_DATA, IMAGE_DATA, COMPARE_DATA, WRITING_DATA, SWAG_DATA, TAG_DATA, OLD_CLASSIFICATION_DATA, STUDY_DATA, DET_DATA, SUPER_DATA, LETTERBOX_DATA, REGRESSION_DATA, SEGMENTATION_DATA, INSTANCE_DATA } data_type; typedef struct load_args{ int threads; char **paths; char *path; int n; int m; char **labels; int h; int w; int out_w; int out_h; int nh; int nw; int num_boxes; int min, max, size; int classes; int background; int scale; int center; int coords; float jitter; float angle; float aspect; float saturation; float exposure; float hue; data *d; image *im; image *resized; data_type type; // tree *hierarchy; } load_args; typedef struct{ int id; float x,y,w,h; float left, right, top, bottom; } box_label; //network *load_network(char *cfg, char *weights, int clear); //load_args get_base_args(network *net); //void free_data(data d); typedef struct{ char *key; char *val; int used; } kvp; typedef struct node{ void *val; struct node *next; struct node *prev; } node; typedef struct list{ int size; node *front; node *back; } list; void error(const char *s) { perror(s); assert(0); exit(-1); } void malloc_error() { fprintf(stderr, "Malloc error\n"); exit(-1); } void file_error(char *s) { fprintf(stderr, "Couldn't open file: %s\n", s); exit(0); } /////////////////list begin list *make_list() { list *l = (list *)malloc(sizeof(list)); l->size = 0; l->front = 0; l->back = 0; return l; } void *list_pop(list *l){ if(!l->back) return 0; node *b = l->back; void *val = b->val; l->back = b->prev; if(l->back) l->back->next = 0; free(b); --l->size; return val; } void list_insert(list *l, void *val) { node *new_node = (node *)malloc(sizeof(node)); new_node->val = val; new_node->next = 0; if(!l->back){ l->front = new_node; new_node->prev = 0; }else{ l->back->next = new_node; new_node->prev = l->back; } l->back = new_node; ++l->size; } void free_node(node *n) { node *next; while(n) { next = n->next; free(n); n = next; } } void free_list(list *l) { free_node(l->front); free(l); } void free_list_contents(list *l) { node *n = l->front; while(n){ free(n->val); n = n->next; } } void **list_to_array(list *l) { void **a = (void **)calloc(l->size, sizeof(void*)); int count = 0; node *n = l->front; while(n){ a[count++] = n->val; n = n->next; } return a; } /////////////////list end /////////////////////utils begin void del_arg(int argc, char **argv, int index) { int i; for(i = index; i < argc-1; ++i) argv[i] = argv[i+1]; argv[i] = 0; } int find_arg(int argc, char* argv[], char *arg) { int i; for(i = 0; i < argc; ++i) { if(!argv[i]) continue; if(0==strcmp(argv[i], arg)) { del_arg(argc, argv, i); return 1; } } return 0; } int find_int_arg(int argc, char **argv, char *arg, int def) { int i; for(i = 0; i < argc-1; ++i){ if(!argv[i]) continue; if(0==strcmp(argv[i], arg)){ def = atoi(argv[i+1]); del_arg(argc, argv, i); del_arg(argc, argv, i); break; } } return def; } float find_float_arg(int argc, char **argv, char *arg, float def) { int i; for(i = 0; i < argc-1; ++i){ if(!argv[i]) continue; if(0==strcmp(argv[i], arg)){ def = atof(argv[i+1]); del_arg(argc, argv, i); del_arg(argc, argv, i); break; } } return def; } char *find_char_arg(int argc, char **argv, char *arg, char *def) { int i; for(i = 0; i < argc-1; ++i){ if(!argv[i]) continue; if(0==strcmp(argv[i], arg)){ def = argv[i+1]; del_arg(argc, argv, i); del_arg(argc, argv, i); break; } } return def; } unsigned char *read_file(char *filename) { FILE *fp = fopen(filename, "rb"); size_t size; fseek(fp, 0, SEEK_END); size = ftell(fp); fseek(fp, 0, SEEK_SET); unsigned char *text = (unsigned char *)calloc(size+1, sizeof(unsigned char)); fread(text, 1, size, fp); fclose(fp); return text; } list *split_str(char *s, char delim) { size_t i; size_t len = strlen(s); list *l = make_list(); list_insert(l, s); for(i = 0; i < len; ++i){ if(s[i] == delim){ s[i] = '\0'; list_insert(l, &(s[i+1])); } } return l; } void strip(char *s) { size_t i; size_t len = strlen(s); size_t offset = 0; for(i = 0; i < len; ++i){ char c = s[i]; if(c==' '||c=='\t'||c=='\n') ++offset; else s[i-offset] = c; } s[len-offset] = '\0'; } void strip_char(char *s, char bad) { size_t i; size_t len = strlen(s); size_t offset = 0; for(i = 0; i < len; ++i){ char c = s[i]; if(c==bad) ++offset; else s[i-offset] = c; } s[len-offset] = '\0'; } void free_ptrs(void **ptrs, int n) { int i; for(i = 0; i < n; ++i) free(ptrs[i]); free(ptrs); } char *fgetl(FILE *fp) { if(feof(fp)) return 0; size_t size = 512; char *line = (char *)malloc(size*sizeof(char)); if(!fgets(line, size, fp)){ free(line); return 0; } size_t curr = strlen(line); while((line[curr-1] != '\n') && !feof(fp)){ if(curr == size-1){ size *= 2; line = (char *)realloc(line, size*sizeof(char)); if(!line) { printf("%ld\n", size); malloc_error(); } } size_t readsize = size-curr; if(readsize > INT_MAX) readsize = INT_MAX-1; fgets(&line[curr], readsize, fp); curr = strlen(line); } if(line[curr-1] == '\n') line[curr-1] = '\0'; return line; } /////////////////////utils end ////////////////////option_list begin void option_insert(list *l, char *key, char *val) { kvp *p = (kvp *)malloc(sizeof(kvp)); p->key = key; p->val = val; p->used = 0; list_insert(l, p); } int read_option(char *s, list *options) { size_t i; size_t len = strlen(s); char *val = 0; for(i = 0; i < len; ++i){ if(s[i] == '='){ s[i] = '\0'; val = s+i+1; break; } } if(i == len-1) return 0; char *key = s; option_insert(options, key, val); return 1; } void option_unused(list *l) { node *n = l->front; while(n){ kvp *p = (kvp *)n->val; if(!p->used){ fprintf(stderr, "Unused field: '%s = %s'\n", p->key, p->val); } n = n->next; } } char *option_find(list *l, char *key) { node *n = l->front; while(n){ kvp *p = (kvp *)n->val; if(strcmp(p->key, key) == 0){ p->used = 1; return p->val; } n = n->next; } return 0; } char *option_find_str(list *l, char *key, char *def) { char *v = option_find(l, key); if(v) return v; if(def) fprintf(stderr, "%s: Using default '%s'\n", key, def); return def; } int option_find_int(list *l, char *key, int def) { char *v = option_find(l, key); if(v) return atoi(v); fprintf(stderr, "%s: Using default '%d'\n", key, def); return def; } int option_find_int_quiet(list *l, char *key, int def) { char *v = option_find(l, key); if(v) return atoi(v); return def; } float option_find_float_quiet(list *l, char *key, float def) { char *v = option_find(l, key); if(v) return atof(v); return def; } float option_find_float(list *l, char *key, float def) { char *v = option_find(l, key); if(v) return atof(v); fprintf(stderr, "%s: Using default '%lf'\n", key, def); return def; } list *read_data_cfg(char *filename) { FILE *file = fopen(filename, "r"); if(file == 0) file_error(filename); char *line; int nu = 0; list *options = make_list(); while((line=fgetl(file)) != 0){ ++ nu; strip(line); switch(line[0]){ case '\0': case '#': case ';': free(line); break; default: if(!read_option(line, options)){ fprintf(stderr, "Config file error line %d, could parse: %s\n", nu, line); free(line); } break; } } fclose(file); return options; } ///////////////////option_list end image make_empty_image(int w, int h, int c) { image out; out.data = 0; out.h = h; out.w = w; out.c = c; return out; } list *get_paths(char *filename) { char *path; FILE *file = fopen(filename, "r"); if(!file) file_error(filename); list *lines = make_list(); while((path=fgetl(file))){ list_insert(lines, path); } fclose(file); return lines; } char **get_labels(char *filename) { list *plist = get_paths(filename); char **labels = (char **)list_to_array(plist); free_list(plist); return labels; } image make_image(int w, int h, int c) { image out = make_empty_image(w,h,c); out.data = (float *)calloc(h*w*c, sizeof(float)); return out; } static float get_pixel(image m, int x, int y, int c) { assert(x < m.w && y < m.h && c < m.c); return m.data[c*m.h*m.w + y*m.w + x]; } static void set_pixel(image m, int x, int y, int c, float val) { if (x < 0 || y < 0 || c < 0 || x >= m.w || y >= m.h || c >= m.c) return; assert(x < m.w && y < m.h && c < m.c); m.data[c*m.h*m.w + y*m.w + x] = val; } static void add_pixel(image m, int x, int y, int c, float val) { assert(x < m.w && y < m.h && c < m.c); m.data[c*m.h*m.w + y*m.w + x] += val; } void free_image(image m) { if(m.data){ free(m.data); } } image resize_image(image im, int w, int h) { image resized = make_image(w, h, im.c); image part = make_image(w, im.h, im.c); int r, c, k; float w_scale = (float)(im.w - 1) / (w - 1); float h_scale = (float)(im.h - 1) / (h - 1); for(k = 0; k < im.c; ++k){ for(r = 0; r < im.h; ++r){ for(c = 0; c < w; ++c){ float val = 0; if(c == w-1 || im.w == 1){ val = get_pixel(im, im.w-1, r, k); } else { float sx = c*w_scale; int ix = (int) sx; float dx = sx - ix; val = (1 - dx) * get_pixel(im, ix, r, k) + dx * get_pixel(im, ix+1, r, k); } set_pixel(part, c, r, k, val); } } } for(k = 0; k < im.c; ++k){ for(r = 0; r < h; ++r){ float sy = r*h_scale; int iy = (int) sy; float dy = sy - iy; for(c = 0; c < w; ++c){ float val = (1-dy) * get_pixel(part, c, iy, k); set_pixel(resized, c, r, k, val); } if(r == h-1 || im.h == 1) continue; for(c = 0; c < w; ++c){ float val = dy * get_pixel(part, c, iy+1, k); add_pixel(resized, c, r, k, val); } } } free_image(part); return resized; } void fill_image(image m, float s) { int i; for(i = 0; i < m.h*m.w*m.c; ++i) m.data[i] = s; } void embed_image(image source, image dest, int dx, int dy) { int x,y,k; for(k = 0; k < source.c; ++k){ for(y = 0; y < source.h; ++y){ for(x = 0; x < source.w; ++x){ float val = get_pixel(source, x,y,k); set_pixel(dest, dx+x, dy+y, k, val); } } } } image letterbox_image(image im, int w, int h) { int new_w = im.w; int new_h = im.h; if (((float)w/im.w) < ((float)h/im.h)) { new_w = w; new_h = (im.h * w)/im.w; } else { new_h = h; new_w = (im.w * h)/im.h; } image resized = resize_image(im, new_w, new_h); image boxed = make_image(w, h, im.c); fill_image(boxed, .5); //int i; //for(i = 0; i < boxed.w*boxed.h*boxed.c; ++i) boxed.data[i] = 0; embed_image(resized, boxed, (w-new_w)/2, (h-new_h)/2); free_image(resized); return boxed; } image load_image_stb(char *filename, int channels) { int w, h, c; unsigned char *data = stbi_load(filename, &w, &h, &c, channels); if (!data) { fprintf(stderr, "Cannot load image \"%s\"\nSTB Reason: %s\n", filename, stbi_failure_reason()); exit(0); } if(channels) c = channels; int i,j,k; image im = make_image(w, h, c); for(k = 0; k < c; ++k){ for(j = 0; j < h; ++j){ for(i = 0; i < w; ++i){ int dst_index = i + w*j + w*h*k; int src_index = k + c*i + c*w*j; im.data[dst_index] = (float)data[src_index]/255.; } } } free(data); return im; } void save_image_png(image im, const char *name) { char buff[256]; //sprintf(buff, "%s (%d)", name, windows); sprintf(buff, "%s.png", name); unsigned char *data = (unsigned char *)calloc(im.w*im.h*im.c, sizeof(char)); int i,k; for(k = 0; k < im.c; ++k){ for(i = 0; i < im.w*im.h; ++i){ data[i*im.c+k] = (unsigned char) (255*im.data[i + k*im.w*im.h]); } } int success = stbi_write_png(buff, im.w, im.h, im.c, data, im.w*im.c); free(data); if(!success) fprintf(stderr, "Failed to write image %s\n", buff); } image **load_alphabet() { int i, j; const int nsize = 8; image **alphabets = (image **)calloc(nsize, sizeof(image)); for(j = 0; j < nsize; ++j){ alphabets[j] = (image *)calloc(128, sizeof(image)); for(i = 32; i < 127; ++i){ char buff[256]; sprintf(buff, "labels/%d_%d.png", i, j); //alphabets[j][i] = load_image_color(buff, 0, 0); alphabets[j][i] = load_image_stb(buff, 3); } } return alphabets; } ///////////////////activation begin static inline float stair_activate(float x) { int n = floor(x); if (n%2 == 0) return floor(x/2.); else return (x - n) + floor(x/2.); } static inline float hardtan_activate(float x) { if (x < -1) return -1; if (x > 1) return 1; return x; } static inline float linear_activate(float x){return x;} static inline float logistic_activate(float x){return 1./(1. + exp(-x));} static inline float loggy_activate(float x){return 2./(1. + exp(-x)) - 1;} static inline float relu_activate(float x){return x*(x>0);} static inline float elu_activate(float x){return (x >= 0)*x + (x < 0)*(exp(x)-1);} static inline float relie_activate(float x){return (x>0) ? x : .01*x;} static inline float ramp_activate(float x){return x*(x>0)+.1*x;} static inline float leaky_activate(float x){return (x>0) ? x : .1*x;} static inline float tanh_activate(float x){return (exp(2*x)-1)/(exp(2*x)+1);} static inline float plse_activate(float x) { if(x < -4) return .01 * (x + 4); if(x > 4) return .01 * (x - 4) + 1; return .125*x + .5; } static inline float lhtan_activate(float x) { if(x < 0) return .001*x; if(x > 1) return .001*(x-1) + 1; return x; } static inline float lhtan_gradient(float x) { if(x > 0 && x < 1) return 1; return .001; } static inline float hardtan_gradient(float x) { if (x > -1 && x < 1) return 1; return 0; } static inline float linear_gradient(float x){return 1;} static inline float logistic_gradient(float x){return (1-x)*x;} static inline float loggy_gradient(float x) { float y = (x+1.)/2.; return 2*(1-y)*y; } static inline float stair_gradient(float x) { if (floor(x) == x) return 0; return 1; } static inline float relu_gradient(float x){return (x>0);} static inline float elu_gradient(float x){return (x >= 0) + (x < 0)*(x + 1);} static inline float relie_gradient(float x){return (x>0) ? 1 : .01;} static inline float ramp_gradient(float x){return (x>0)+.1;} static inline float leaky_gradient(float x){return (x>0) ? 1 : .1;} static inline float tanh_gradient(float x){return 1-x*x;} static inline float plse_gradient(float x){return (x < 0 || x > 1) ? .01 : .125;} char *get_activation_string(ACTIVATION a) { switch(a){ case LOGISTIC: return "logistic"; case LOGGY: return "loggy"; case RELU: return "relu"; case ELU: return "elu"; case RELIE: return "relie"; case RAMP: return "ramp"; case LINEAR: return "linear"; case TANH: return "tanh"; case PLSE: return "plse"; case LEAKY: return "leaky"; case STAIR: return "stair"; case HARDTAN: return "hardtan"; case LHTAN: return "lhtan"; default: break; } return "relu"; } ACTIVATION get_activation(char *s) { if (strcmp(s, "logistic")==0) return LOGISTIC; if (strcmp(s, "loggy")==0) return LOGGY; if (strcmp(s, "relu")==0) return RELU; if (strcmp(s, "elu")==0) return ELU; if (strcmp(s, "relie")==0) return RELIE; if (strcmp(s, "plse")==0) return PLSE; if (strcmp(s, "hardtan")==0) return HARDTAN; if (strcmp(s, "lhtan")==0) return LHTAN; if (strcmp(s, "linear")==0) return LINEAR; if (strcmp(s, "ramp")==0) return RAMP; if (strcmp(s, "leaky")==0) return LEAKY; if (strcmp(s, "tanh")==0) return TANH; if (strcmp(s, "stair")==0) return STAIR; fprintf(stderr, "Couldn't find activation function %s, going with ReLU\n", s); return RELU; } float activate(float x, ACTIVATION a) { switch(a){ case LINEAR: return linear_activate(x); case LOGISTIC: return logistic_activate(x); case LOGGY: return loggy_activate(x); case RELU: return relu_activate(x); case ELU: return elu_activate(x); case RELIE: return relie_activate(x); case RAMP: return ramp_activate(x); case LEAKY: return leaky_activate(x); case TANH: return tanh_activate(x); case PLSE: return plse_activate(x); case STAIR: return stair_activate(x); case HARDTAN: return hardtan_activate(x); case LHTAN: return lhtan_activate(x); } return 0; } void activate_array(float *x, const int n, const ACTIVATION a) { int i; for(i = 0; i < n; ++i){ x[i] = activate(x[i], a); } } float gradient(float x, ACTIVATION a) { switch(a){ case LINEAR: return linear_gradient(x); case LOGISTIC: return logistic_gradient(x); case LOGGY: return loggy_gradient(x); case RELU: return relu_gradient(x); case ELU: return elu_gradient(x); case RELIE: return relie_gradient(x); case RAMP: return ramp_gradient(x); case LEAKY: return leaky_gradient(x); case TANH: return tanh_gradient(x); case PLSE: return plse_gradient(x); case STAIR: return stair_gradient(x); case HARDTAN: return hardtan_gradient(x); case LHTAN: return lhtan_gradient(x); } return 0; } ///////////////////activation end void copy_cpu(int N, float *X, int INCX, float *Y, int INCY) { int i; for(i = 0; i < N; ++i) Y[i*INCY] = X[i*INCX]; } void fill_cpu(int N, float ALPHA, float *X, int INCX) { int i; for(i = 0; i < N; ++i) X[i*INCX] = ALPHA; } void shortcut_cpu(int batch, int w1, int h1, int c1, float *add, int w2, int h2, int c2, float s1, float s2, float *out) { int stride = w1/w2; int sample = w2/w1; assert(stride == h1/h2); assert(sample == h2/h1); //printf("shorcut_layer batch=%d,stride=%d,sample=%d\n",batch,stride,sample); if(stride < 1) stride = 1; if(sample < 1) sample = 1; int minw = (w1 < w2) ? w1 : w2; int minh = (h1 < h2) ? h1 : h2; int minc = (c1 < c2) ? c1 : c2; int i,j,k,b; for(b = 0; b < batch; ++b){ for(k = 0; k < minc; ++k){ for(j = 0; j < minh; ++j){ for(i = 0; i < minw; ++i){ int out_index = i*sample + w2*(j*sample + h2*(k + c2*b)); int add_index = i*stride + w1*(j*stride + h1*(k + c1*b)); out[out_index] = s1*out[out_index] + s2*add[add_index]; } } } } } void forward_shortcut_layer(const layer l, network net) { //copy_cpu(l.outputs*l.batch, net.input, 1, l.output, 1); //shortcut_cpu(l.batch, l.w, l.h, l.c, net.layers[l.index].output, l.out_w, l.out_h, l.out_c, l.alpha, l.beta, l.output); //activate_array(l.output, l.outputs*l.batch, l.activation); int w = l.w; int h = l.h; int c = l.c; float *add = net.layers[l.index].output; float *out = l.output; float *in = net.input; int i,j,k; for(k = 0; k < c; ++k){ for(j = 0; j < h; ++j){ for(i = 0; i < w; ++i){ int index = i + w*(j + h*k ); out[index] = in[index] + add[index]; } } } } layer make_shortcut_layer(int batch, int index, int w, int h, int c, int w2, int h2, int c2) { fprintf(stderr, "res %3d %4d x%4d x%4d -> %4d x%4d x%4d\n",index, w2,h2,c2, w,h,c); layer l; memset(&l,0,sizeof(layer)); l.type = SHORTCUT; l.batch = batch; l.w = w2; l.h = h2; l.c = c2; l.out_w = w; l.out_h = h; l.out_c = c; l.outputs = w*h*c; l.inputs = l.outputs; l.index = index; l.output = (float *)calloc(l.outputs*batch, sizeof(float));; l.forward = forward_shortcut_layer; return l; } int convolutional_out_height(layer l) { return (l.h + 2*l.pad - l.size) / l.stride + 1; } int convolutional_out_width(layer l) { return (l.w + 2*l.pad - l.size) / l.stride + 1; } static size_t get_workspace_size(layer l){ return (size_t)l.out_h*l.out_w*l.size*l.size*l.c/l.groups*sizeof(float); } void add_bias(float *output, float *biases, int batch, int n, int size) { int i,j,b; for(b = 0; b < batch; ++b){ for(i = 0; i < n; ++i){ for(j = 0; j < size; ++j){ output[(b*n + i)*size + j] += biases[i]; } } } } void scale_bias(float *output, float *scales, int batch, int n, int size) { int i,j,b; for(b = 0; b < batch; ++b){ for(i = 0; i < n; ++i){ for(j = 0; j < size; ++j){ output[(b*n + i)*size + j] *= scales[i]; } } } } float im2col_get_pixel(float *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)]; } //From Berkeley Vision's Caffe! //https://github.com/BVLC/caffe/blob/master/LICENSE void im2col_cpu(float* data_im, int channels, int height, int width, int ksize, int stride, int pad, float* 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(data_im, height, width, channels, im_row, im_col, c_im, pad); } } } } void gemm_nn(int M, int N, int K, float ALPHA, float *A, int lda, float *B, int ldb, float *C, int ldc) { int i,j,k; #pragma omp parallel for for(i = 0; i < M; ++i){ for(k = 0; k < K; ++k){ register float A_PART = ALPHA*A[i*lda+k]; for(j = 0; j < N; ++j){ C[i*ldc+j] += A_PART*B[k*ldb+j]; } } } } void gemm_cpu(int TA, int TB, int M, int N, int K, float ALPHA, float *A, int lda, float *B, int ldb, float BETA, float *C, int ldc) { //printf("cpu: %d %d %d %d %d %f %d %d %f %d\n",TA, TB, M, N, K, ALPHA, lda, ldb, BETA, ldc); int i, j; for(i = 0; i < M; ++i){ for(j = 0; j < N; ++j){ C[i*ldc + j] *= BETA; } } if(!TA && !TB) gemm_nn(M, N, K, ALPHA,A,lda, B, ldb,C,ldc); //else if(TA && !TB) // gemm_tn(M, N, K, ALPHA,A,lda, B, ldb,C,ldc); //else if(!TA && TB) // gemm_nt(M, N, K, ALPHA,A,lda, B, ldb,C,ldc); //else // gemm_tt(M, N, K, ALPHA,A,lda, B, ldb,C,ldc); } void gemm(int TA, int TB, int M, int N, int K, float ALPHA, float *A, int lda, float *B, int ldb, float BETA, float *C, int ldc) { gemm_cpu( TA, TB, M, N, K, ALPHA,A,lda, B, ldb,BETA,C,ldc); } void normalize_cpu(float *x, float *mean, float *variance, int batch, int filters, int spatial) { int b, f, i; for(b = 0; b < batch; ++b){ for(f = 0; f < filters; ++f){ for(i = 0; i < spatial; ++i){ int index = b*filters*spatial + f*spatial + i; x[index] = (x[index] - mean[f])/(sqrt(variance[f]) + .000001f); } } } } void forward_batchnorm_layer(layer l, network net)//for conv { normalize_cpu(l.output, l.rolling_mean, l.rolling_variance, l.batch, l.out_c, l.out_h*l.out_w); scale_bias(l.output, l.scales, l.batch, l.out_c, l.out_h*l.out_w); add_bias(l.output, l.biases, l.batch, l.out_c, l.out_h*l.out_w); } void CONV_Padding_Relu(float *Input,float *Output,float *Weight,const int InFM_num,const int OutFM_num,const int Kernel_size,const int Kernel_stride,const int Input_w,const int Input_h,const int Padding) { // (output_w - 1)*Kernel_stride + Kernel_size = Input_w const int output_w = (Input_w - Kernel_size + 2*Padding)/Kernel_stride + 1 ; const int output_h = (Input_h - Kernel_size + 2*Padding)/Kernel_stride + 1 ; int x, y, of, inf; int m,n; for( of = 0; of < OutFM_num; of++){ for( y = 0; y < output_h; y++) { for( x = 0; x < output_w; x++){ float tmp = 0.0; for(inf = 0;inf < InFM_num; inf++) { int intput_offset = inf*Input_w*Input_h + (y*Kernel_stride - Padding)*Input_w + x*Kernel_stride - Padding; for(m = 0;m < Kernel_size; m++) { for(n = 0;n < Kernel_size; n++) { int kernel_offset = of*InFM_num*Kernel_size*Kernel_size + inf*Kernel_size*Kernel_size; bool inFM_width = ((x*Kernel_stride + n - Padding) >= 0)&&((x*Kernel_stride + n - Padding) < Input_w); bool inFM_height = ((y*Kernel_stride + m - Padding) >= 0)&&((y*Kernel_stride + m - Padding) < Input_h); if(inFM_width&&inFM_height) tmp += Weight[kernel_offset + m*Kernel_size + n]*Input[intput_offset + m*Input_w + n]; } } } Output[of*output_w*output_h + y*output_w + x] = tmp; } } } } void forward_convolutional_layer(layer l, network net) { int i, j; fill_cpu(l.outputs*l.batch, 0, l.output, 1); //printf("c=%d,n=%d,size=%d,stride=%d,w=%d,h=%d,pad=%d\n",l.c,l.n,l.size,l.stride,l.w,l.h,l.pad); //int m = l.n/l.groups; //int k = l.size*l.size*l.c/l.groups; //int n = l.out_w*l.out_h; //for(i = 0; i < l.batch; ++i){ // for(j = 0; j < l.groups; ++j){ // float *a = l.weights + j*l.nweights/l.groups; // float *b = net.workspace; // float *c = l.output + (i*l.groups + j)*n*m; // im2col_cpu(net.input + (i*l.groups + j)*l.c/l.groups*l.h*l.w, // l.c/l.groups, l.h, l.w, l.size, l.stride, l.pad, b); // gemm(0,0,m,n,k,1,a,k,b,n,1,c,n); // } //} int m = l.n; int k = l.size*l.size*l.c; int n = l.out_w*l.out_h; float *a = l.weights; float *b = net.workspace; float *c = l.output; im2col_cpu(net.input,l.c, l.h, l.w, l.size, l.stride, l.pad, b); gemm(0,0,m,n,k,1,a,k,b,n,1,c,n); //CONV_Padding_Relu(net.input,l.output,l.weights,l.c,l.n,l.size,l.stride,l.w,l.h,l.pad); if(l.batch_normalize){ forward_batchnorm_layer(l, net); } else { add_bias(l.output, l.biases, l.batch, l.n, l.out_h*l.out_w); } activate_array(l.output, l.outputs*l.batch, l.activation); } layer make_convolutional_layer(int batch, int h, int w, int c, int n, int groups, int size, int stride, int padding, ACTIVATION activation, int batch_normalize, int binary, int xnor, int adam) { int i; layer l; memset(&l,0,sizeof(layer)); l.type = CONVOLUTIONAL; l.groups = groups; l.h = h; l.w = w; l.c = c; l.n = n; l.binary = binary; l.xnor = xnor; l.batch = batch; l.stride = stride; l.size = size; l.pad = padding; l.batch_normalize = batch_normalize; // l.weights = (float *)calloc(c/groups*n*size*size, sizeof(float)); // l.biases = (float *)calloc(n, sizeof(float)); l.nweights = c/groups*n*size*size; l.nbiases = n; int out_w = convolutional_out_width(l); int out_h = convolutional_out_height(l); l.out_h = out_h; l.out_w = out_w; l.out_c = n; l.outputs = l.out_h * l.out_w * l.out_c; l.inputs = l.w * l.h * l.c; // l.output = (float *)calloc(l.batch*l.outputs, sizeof(float)); l.forward = forward_convolutional_layer; if(batch_normalize){ // l.scales = (float *)calloc(n, sizeof(float)); // l.rolling_mean = (float *)calloc(n, sizeof(float)); //l.rolling_variance = (float *)calloc(n, sizeof(float)); } l.workspace_size = get_workspace_size(l); l.activation = activation; fprintf(stderr, "conv %5d %2d x%2d /%2d %4d x%4d x%4d -> %4d x%4d x%4d %5.3f BFLOPs\n", n, size, size, stride, w, h, c, l.out_w, l.out_h, l.out_c, (2.0 * l.n * l.size*l.size*l.c/l.groups * l.out_h*l.out_w)/1000000000.); return l; } void upsample_cpu(float *in, int w, int h, int c, int batch, int stride, int forward, float scale, float *out) { int i, j, k, b; for(b = 0; b < batch; ++b){ for(k = 0; k < c; ++k){ for(j = 0; j < h*stride; ++j){ for(i = 0; i < w*stride; ++i){ int in_index = b*w*h*c + k*w*h + (j/stride)*w + i/stride; int out_index = b*w*h*c*stride*stride + k*w*h*stride*stride + j*w*stride + i; if(forward) out[out_index] = scale*in[in_index]; else in[in_index] += scale*out[out_index]; } } } } } void forward_upsample_layer(const layer l, network net) { //fill_cpu(l.outputs*l.batch, 0, l.output, 1); //upsample_cpu(net.input, l.w, l.h, l.c, l.batch, l.stride, 1, l.scale, l.output); int c = l.c; int h = l.h; int w = l.w; int stride = l.stride; float *in = net.input; float *out = l.output; int i, j, k; for(k = 0; k < c; ++k){ for(j = 0; j < h*stride; ++j){ for(i = 0; i < w*stride; ++i){ int in_index = k*w*h + (j/stride)*w + i/stride; int out_index = k*w*h*stride*stride + j*w*stride + i; out[out_index] = in[in_index]; } } } } layer make_upsample_layer(int batch, int w, int h, int c, int stride) { layer l; memset(&l,0,sizeof(layer)); l.type = UPSAMPLE; l.batch = batch; l.w = w; l.h = h; l.c = c; l.out_w = w*stride; l.out_h = h*stride; l.out_c = c; if(stride < 0){ stride = -stride; l.reverse=1; l.out_w = w/stride; l.out_h = h/stride; } l.stride = stride; l.outputs = l.out_w*l.out_h*l.out_c; l.inputs = l.w*l.h*l.c; l.output = (float *)calloc(l.outputs*batch, sizeof(float));; l.forward = forward_upsample_layer; if(l.reverse) fprintf(stderr, "downsample %2dx %4d x%4d x%4d -> %4d x%4d x%4d\n", stride, w, h, c, l.out_w, l.out_h, l.out_c); else fprintf(stderr, "upsample %2dx %4d x%4d x%4d -> %4d x%4d x%4d\n", stride, w, h, c, l.out_w, l.out_h, l.out_c); return l; } void forward_route_layer(const layer l, network net) { int i, j; int offset = 0; for(i = 0; i < l.n; ++i){ int index = l.input_layers[i]; float *input = net.layers[index].output; int input_size = l.input_sizes[i]; copy_cpu(input_size, input, 1, l.output + offset, 1); offset += input_size; } } layer make_route_layer(int batch, int n, int *input_layers, int *input_sizes) { fprintf(stderr,"route "); layer l; memset(&l,0,sizeof(layer)); l.type = ROUTE; l.batch = batch; l.n = n; l.input_layers = input_layers; l.input_sizes = input_sizes; int i; int outputs = 0; for(i = 0; i < n; ++i){ fprintf(stderr," %d", input_layers[i]); outputs += input_sizes[i]; } fprintf(stderr, "\n"); l.outputs = outputs; l.inputs = outputs; // l.output = (float *)calloc(outputs*batch, sizeof(float));; l.forward = forward_route_layer; return l; } static int entry_index(layer l, int batch, int location, int entry) { int n = location / (l.w*l.h); int loc = location % (l.w*l.h); return batch*l.outputs + n*l.w*l.h*(4+l.classes+1) + entry*l.w*l.h + loc; } void forward_yolo_layer(const layer l, network net) { int i,j,b,t,n; //char line[256]; //FILE *fp3; //char filename[256]; //sprintf(filename, "yolo_layer_%d.txt", l.outputs); //printf("YOLO_layer:outputs=%d,%s\n",l.outputs,filename); // if( (fp3 = fopen(filename, "w")) == NULL)fprintf(stderr,"CANNOT OPEN\n"); //int x; // for( x = 0; x < l.outputs; x++) //{ // sprintf(line, "%f\n", net.input[x]); // if(fputs(line,fp3)<0)fprintf(stderr,"write FILE failed\n"); // } // fclose(fp3); memcpy(l.output, net.input, l.outputs*l.batch*sizeof(float)); for (b = 0; b < l.batch; ++b){ for(n = 0; n < l.n; ++n){ int index = entry_index(l, b, n*l.w*l.h, 0); activate_array(l.output + index, 2*l.w*l.h, LOGISTIC); index = entry_index(l, b, n*l.w*l.h, 4); activate_array(l.output + index, (1+l.classes)*l.w*l.h, LOGISTIC); } } return ; } layer make_yolo_layer(int batch, int w, int h, int n, int total, int *mask, int classes) { int i; layer l; memset(&l,0,sizeof(layer)); l.type = YOLO; l.n = n; l.total = total; l.batch = batch; l.h = h; l.w = w; l.c = n*(classes + 4 + 1); l.out_w = l.w; l.out_h = l.h; l.out_c = l.c; l.classes = classes; //l.cost = (float *)calloc(1, sizeof(float)); l.biases = (float *)calloc(total*2, sizeof(float)); if(mask) l.mask = mask; else{ l.mask = (int *)calloc(n, sizeof(int)); for(i = 0; i < n; ++i){ l.mask[i] = i; } } //l.bias_updates = (float *)calloc(n*2, sizeof(float)); l.outputs = h*w*n*(classes + 4 + 1); l.inputs = l.outputs; //l.truths = 90*(4 + 1); //l.delta = (float *)calloc(batch*l.outputs, sizeof(float)); l.output = (float *)calloc(batch*l.outputs, sizeof(float)); for(i = 0; i < total*2; ++i){ l.biases[i] = .5; } l.forward = forward_yolo_layer; fprintf(stderr, "detection\n"); srand(0); return l; } /////////////////praser begin typedef struct{ char *type; list *options; }section; list *read_cfg(char *filename); LAYER_TYPE string_to_layer_type(char * type) { if (strcmp(type, "[shortcut]")==0) return SHORTCUT; if (strcmp(type, "[crop]")==0) return CROP; if (strcmp(type, "[cost]")==0) return COST; if (strcmp(type, "[detection]")==0) return DETECTION; if (strcmp(type, "[region]")==0) return REGION; if (strcmp(type, "[yolo]")==0) return YOLO; if (strcmp(type, "[local]")==0) return LOCAL; if (strcmp(type, "[conv]")==0 || strcmp(type, "[convolutional]")==0) return CONVOLUTIONAL; if (strcmp(type, "[deconv]")==0 || strcmp(type, "[deconvolutional]")==0) return DECONVOLUTIONAL; if (strcmp(type, "[activation]")==0) return ACTIVE; if (strcmp(type, "[logistic]")==0) return LOGXENT; if (strcmp(type, "[l2norm]")==0) return L2NORM; if (strcmp(type, "[net]")==0 || strcmp(type, "[network]")==0) return NETWORK; if (strcmp(type, "[crnn]")==0) return CRNN; if (strcmp(type, "[gru]")==0) return GRU; if (strcmp(type, "[lstm]") == 0) return LSTM; if (strcmp(type, "[rnn]")==0) return RNN; if (strcmp(type, "[conn]")==0 || strcmp(type, "[connected]")==0) return CONNECTED; if (strcmp(type, "[max]")==0 || strcmp(type, "[maxpool]")==0) return MAXPOOL; if (strcmp(type, "[reorg]")==0) return REORG; if (strcmp(type, "[avg]")==0 || strcmp(type, "[avgpool]")==0) return AVGPOOL; if (strcmp(type, "[dropout]")==0) return DROPOUT; if (strcmp(type, "[lrn]")==0 || strcmp(type, "[normalization]")==0) return NORMALIZATION; if (strcmp(type, "[batchnorm]")==0) return BATCHNORM; if (strcmp(type, "[soft]")==0 || strcmp(type, "[softmax]")==0) return SOFTMAX; if (strcmp(type, "[route]")==0) return ROUTE; if (strcmp(type, "[upsample]")==0) return UPSAMPLE; return BLANK; } void free_section(section *s) { free(s->type); node *n = s->options->front; while(n){ kvp *pair = (kvp *)n->val; free(pair->key); free(pair); node *next = n->next; free(n); n = next; } free(s->options); free(s); } void parse_data(char *data, float *a, int n) { int i; if(!data) return; char *curr = data; char *next = data; int done = 0; for(i = 0; i < n && !done; ++i){ while(*++next !='\0' && *next != ','); if(*next == '\0') done = 1; *next = '\0'; sscanf(curr, "%g", &a[i]); curr = next+1; } } typedef struct size_params{ int batch; int inputs; int h; int w; int c; int index; int time_steps; network *net; } size_params; layer parse_convolutional(list *options, size_params params) { int n = option_find_int(options, "filters",1); int size = option_find_int(options, "size",1); int stride = option_find_int(options, "stride",1); int pad = option_find_int_quiet(options, "pad",0); int padding = option_find_int_quiet(options, "padding",0); int groups = option_find_int_quiet(options, "groups", 1); if(pad) padding = size/2; char *activation_s = option_find_str(options, "activation", "logistic"); ACTIVATION activation = get_activation(activation_s); int batch,h,w,c; h = params.h; w = params.w; c = params.c; batch=params.batch; if(!(h && w && c)) error("Layer before convolutional layer must output image."); int batch_normalize = option_find_int_quiet(options, "batch_normalize", 0); int binary = option_find_int_quiet(options, "binary", 0); int xnor = option_find_int_quiet(options, "xnor", 0); layer l = make_convolutional_layer(batch,h,w,c,n,groups,size,stride,padding,activation, batch_normalize, binary, xnor, params.net->adam); l.flipped = option_find_int_quiet(options, "flipped", 0); l.dot = option_find_float_quiet(options, "dot", 0); return l; } int *parse_yolo_mask(char *a, int *num) { int *mask = 0; if(a){ int len = strlen(a); int n = 1; int i; for(i = 0; i < len; ++i){ if (a[i] == ',') ++n; } mask = (int *)calloc(n, sizeof(int)); for(i = 0; i < n; ++i){ int val = atoi(a); mask[i] = val; a = strchr(a, ',')+1; } *num = n; } return mask; } layer parse_yolo(list *options, size_params params) { int classes = option_find_int(options, "classes", 20); int total = option_find_int(options, "num", 1); int num = total; char *a = option_find_str(options, "mask", 0); int *mask = parse_yolo_mask(a, &num); layer l = make_yolo_layer(params.batch, params.w, params.h, num, total, mask, classes); assert(l.outputs == params.inputs); l.max_boxes = option_find_int_quiet(options, "max",90); l.jitter = option_find_float(options, "jitter", .2); l.ignore_thresh = option_find_float(options, "ignore_thresh", .5); l.truth_thresh = option_find_float(options, "truth_thresh", 1); l.random = option_find_int_quiet(options, "random", 0); a = option_find_str(options, "anchors", 0); if(a){ int len = strlen(a); int n = 1; int i; for(i = 0; i < len; ++i){ if (a[i] == ',') ++n; } for(i = 0; i < n; ++i){ float bias = atof(a); l.biases[i] = bias; a = strchr(a, ',')+1; } } return l; } layer parse_shortcut(list *options, size_params params, network *net) { char *l = option_find(options, "from"); int index = atoi(l); if(index < 0) index = params.index + index; int batch = params.batch; layer from = net->layers[index]; layer s = make_shortcut_layer(batch, index, params.w, params.h, params.c, from.out_w, from.out_h, from.out_c); char *activation_s = option_find_str(options, "activation", "linear"); ACTIVATION activation = get_activation(activation_s); s.activation = activation; s.alpha = option_find_float_quiet(options, "alpha", 1); s.beta = option_find_float_quiet(options, "beta", 1); return s; } layer parse_upsample(list *options, size_params params, network *net) { int stride = option_find_int(options, "stride",2); layer l = make_upsample_layer(params.batch, params.w, params.h, params.c, stride); l.scale = option_find_float_quiet(options, "scale", 1); return l; } layer parse_route(list *options, size_params params, network *net) { char *l = option_find(options, "layers"); int len = strlen(l); if(!l) error("Route Layer must specify input layers"); int n = 1; int i; for(i = 0; i < len; ++i){ if (l[i] == ',') ++n; } int *layers = (int *)calloc(n, sizeof(int)); int *sizes = (int *)calloc(n, sizeof(int)); for(i = 0; i < n; ++i){ int index = atoi(l); l = strchr(l, ',')+1; if(index < 0) index = params.index + index; layers[i] = index; sizes[i] = net->layers[index].outputs; } int batch = params.batch; layer route_layer = make_route_layer(batch, n, layers, sizes); layer first = net->layers[layers[0]]; route_layer.out_w = first.out_w; route_layer.out_h = first.out_h; route_layer.out_c = first.out_c; for(i = 1; i < n; ++i){ int index = layers[i]; layer next = net->layers[index]; if(next.out_w == first.out_w && next.out_h == first.out_h){ route_layer.out_c += next.out_c; }else{ route_layer.out_h = route_layer.out_w = route_layer.out_c = 0; } } return route_layer; } void softmax(float *input, int n, float temp, int stride, float *output) { int i; float sum = 0; float largest = -FLT_MAX; for(i = 0; i < n; ++i){ if(input[i*stride] > largest) largest = input[i*stride]; } for(i = 0; i < n; ++i){ float e = exp(input[i*stride]/temp - largest/temp); sum += e; output[i*stride] = e; } for(i = 0; i < n; ++i){ output[i*stride] /= sum; } } void softmax_cpu(float *input, int n, int batch, int batch_offset, int groups, int group_offset, int stride, float temp, float *output) { int g, b; for(b = 0; b < batch; ++b){ for(g = 0; g < groups; ++g){ softmax(input + b*batch_offset + g*group_offset, n, temp, stride, output + b*batch_offset + g*group_offset); } } } void forward_region_layer(const layer l, network net) { int i,j,b,t,n; memcpy(l.output, net.input, l.outputs*l.batch*sizeof(float)); #ifndef GPU for (b = 0; b < l.batch; ++b){ for(n = 0; n < l.n; ++n){ int index = entry_index(l, b, n*l.w*l.h, 0); activate_array(l.output + index, 2*l.w*l.h, LOGISTIC); index = entry_index(l, b, n*l.w*l.h, l.coords); if(!l.background) activate_array(l.output + index, l.w*l.h, LOGISTIC); index = entry_index(l, b, n*l.w*l.h, l.coords + 1); //if(!l.softmax) activate_array(l.output + index, l.classes*l.w*l.h, LOGISTIC); } } if (l.softmax){ int index = entry_index(l, 0, 0, l.coords + !l.background); softmax_cpu(net.input + index, l.classes + l.background, l.batch*l.n, l.inputs/l.n, l.w*l.h, 1, l.w*l.h, 1, l.output + index); } char line[256]; FILE *fp3; char filename[256]; sprintf(filename, "yolo_layer_%d.txt", 123123); printf("YOLO_layer:outputs=%d,%s\n",l.outputs,filename); if( (fp3 = fopen(filename, "w")) == NULL)fprintf(stderr,"CANNOT OPEN\n"); int x; for( x = 0; x < l.outputs; x++) { sprintf(line, "%f\n", net.input[x]); if(fputs(line,fp3)<0)fprintf(stderr,"write FILE failed\n"); } fclose(fp3); #endif if(!net.train) return; } layer make_region_layer(int batch, int w, int h, int n, int classes, int coords) { layer l; memset(&l,0,sizeof(layer)); l.type = REGION; l.n = n; l.batch = batch; l.h = h; l.w = w; l.c = n*(classes + coords + 1); l.out_w = l.w; l.out_h = l.h; l.out_c = l.c; l.classes = classes; l.coords = coords; l.biases = (float *)calloc(n*2, sizeof(float)); l.outputs = h*w*n*(classes + coords + 1); l.inputs = l.outputs; l.truths = 30*(l.coords + 1); l.output = (float *)calloc(batch*l.outputs, sizeof(float)); int i; for(i = 0; i < n*2; ++i){ l.biases[i] = .5; } l.forward = forward_region_layer; fprintf(stderr, "detection\n"); srand(0); return l; } layer parse_region(list *options, size_params params) { int coords = option_find_int(options, "coords", 4); int classes = option_find_int(options, "classes", 20); int num = option_find_int(options, "num", 1); layer l = make_region_layer(params.batch, params.w, params.h, num, classes, coords); assert(l.outputs == params.inputs); l.log = option_find_int_quiet(options, "log", 0); l.sqrt = option_find_int_quiet(options, "sqrt", 0); l.softmax = option_find_int(options, "softmax", 0); l.background = option_find_int_quiet(options, "background", 0); l.max_boxes = option_find_int_quiet(options, "max",30); l.jitter = option_find_float(options, "jitter", .2); l.rescore = option_find_int_quiet(options, "rescore",0); l.thresh = option_find_float(options, "thresh", .5); l.classfix = option_find_int_quiet(options, "classfix", 0); l.absolute = option_find_int_quiet(options, "absolute", 0); l.random = option_find_int_quiet(options, "random", 0); l.coord_scale = option_find_float(options, "coord_scale", 1); l.object_scale = option_find_float(options, "object_scale", 1); l.noobject_scale = option_find_float(options, "noobject_scale", 1); l.mask_scale = option_find_float(options, "mask_scale", 1); l.class_scale = option_find_float(options, "class_scale", 1); l.bias_match = option_find_int_quiet(options, "bias_match",0); char *tree_file = option_find_str(options, "tree", 0); // if (tree_file) l.softmax_tree = read_tree(tree_file); char *map_file = option_find_str(options, "map", 0); // if (map_file) l.map = read_map(map_file); char *a = option_find_str(options, "anchors", 0); if(a){ int len = strlen(a); int n = 1; int i; for(i = 0; i < len; ++i){ if (a[i] == ',') ++n; } for(i = 0; i < n; ++i){ float bias = atof(a); l.biases[i] = bias; a = strchr(a, ',')+1; } } return l; } void reorg_cpu(float *x, int w, int h, int c, int batch, int stride, int forward, float *out) { int b,i,j,k; int out_c = c/(stride*stride); for(b = 0; b < batch; ++b){ for(k = 0; k < c; ++k){ for(j = 0; j < h; ++j){ for(i = 0; i < w; ++i){ int in_index = i + w*(j + h*(k + c*b)); int c2 = k % out_c; int offset = k / out_c; int w2 = i*stride + offset % stride; int h2 = j*stride + offset / stride; int out_index = w2 + w*stride*(h2 + h*stride*(c2 + out_c*b)); if(forward) out[out_index] = x[in_index]; else out[in_index] = x[out_index]; } } } } } void forward_reorg_layer(const layer l, network net) { int i; //if(l.flatten){ // memcpy(l.output, net.input, l.outputs*l.batch*sizeof(float)); // if(l.reverse){ // flatten(l.output, l.w*l.h, l.c, l.batch, 0); // }else{ // flatten(l.output, l.w*l.h, l.c, l.batch, 1); // } //} else if (l.extra) { // for(i = 0; i < l.batch; ++i){ // copy_cpu(l.inputs, net.input + i*l.inputs, 1, l.output + i*l.outputs, 1); // } //} else if (l.reverse){ // reorg_cpu(net.input, l.w, l.h, l.c, l.batch, l.stride, 1, l.output); //} else { reorg_cpu(net.input, l.w, l.h, l.c, l.batch, l.stride, 0, l.output); //} } layer make_reorg_layer(int batch, int w, int h, int c, int stride, int reverse, int flatten, int extra) { layer l; memset(&l,0,sizeof(layer)); l.type = REORG; l.batch = batch; l.stride = stride; l.extra = extra; l.h = h; l.w = w; l.c = c; l.flatten = flatten; if(reverse){ l.out_w = w*stride; l.out_h = h*stride; l.out_c = c/(stride*stride); }else{ l.out_w = w/stride; l.out_h = h/stride; l.out_c = c*(stride*stride); } l.reverse = reverse; l.outputs = l.out_h * l.out_w * l.out_c; l.inputs = h*w*c; if(l.extra){ l.out_w = l.out_h = l.out_c = 0; l.outputs = l.inputs + l.extra; } if(extra){ fprintf(stderr, "reorg %4d -> %4d\n", l.inputs, l.outputs); } else { fprintf(stderr, "reorg /%2d %4d x%4d x%4d -> %4d x%4d x%4d\n", stride, w, h, c, l.out_w, l.out_h, l.out_c); } int output_size = l.outputs * batch; //l.output = (float *)calloc(output_size, sizeof(float)); l.forward = forward_reorg_layer; return l; } layer parse_reorg(list *options, size_params params) { int stride = option_find_int(options, "stride",1); int reverse = option_find_int_quiet(options, "reverse",0); int flatten = option_find_int_quiet(options, "flatten",0); int extra = option_find_int_quiet(options, "extra",0); int batch,h,w,c; h = params.h; w = params.w; c = params.c; batch=params.batch; if(!(h && w && c)) error("Layer before reorg layer must output image."); layer layer = make_reorg_layer(batch,w,h,c,stride,reverse, flatten, extra); return layer; } void forward_maxpool_layer(layer l, network net) { 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; for(b = 0; b < l.batch; ++b){ for(k = 0; k < c; ++k){ for(i = 0; i < h; ++i){ for(j = 0; j < w; ++j){ int out_index = j + w*(i + h*(k + c*b)); float max = -FLT_MAX; int max_i = -1; for(n = 0; n < l.size; ++n){ 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); float val = (valid != 0) ? net.input[index] : -FLT_MAX; max_i = (val > max) ? index : max_i; max = (val > max) ? val : max; } } l.output[out_index] = max; l.indexes[out_index] = max_i; } } } } } //layer make_maxpool_layer(int batch, int h, int w, int c, int size, int stride, int padding) //{ // layer l; // memset(&l,0,sizeof(layer)); // l.type = MAXPOOL; // l.batch = batch; // l.h = h; // l.w = w; // l.c = c; // l.pad = padding; // l.out_w = (w + 2*padding)/stride; // l.out_h = (h + 2*padding)/stride; // l.out_c = c; // l.outputs = l.out_h * l.out_w * l.out_c; // l.inputs = h*w*c; // l.size = size; // l.stride = stride; // int output_size = l.out_h * l.out_w * l.out_c * batch; // //l.indexes = (int *)calloc(output_size, sizeof(int)); // //l.output = (float *)calloc(output_size, sizeof(float)); // l.forward = forward_maxpool_layer; // // fprintf(stderr, "max %d x %d / %d %4d x%4d x%4d -> %4d x%4d x%4d\n", size, size, stride, w, h, c, l.out_w, l.out_h, l.out_c); // return l; //} layer make_maxpool_layer(int batch, int h, int w, int c, int size, int stride, int padding) { layer l; memset(&l,0,sizeof(layer)); l.type = MAXPOOL; l.batch = batch; l.h = h; l.w = w; l.c = c; l.pad = padding; l.out_w = (w + padding - size)/stride + 1; l.out_h = (h + padding - size)/stride + 1; l.out_c = c; l.outputs = l.out_h * l.out_w * l.out_c; l.inputs = h*w*c; l.size = size; l.stride = stride; int output_size = l.out_h * l.out_w * l.out_c * batch; //l.indexes = calloc(output_size, sizeof(int)); //l.output = calloc(output_size, sizeof(float)); //l.delta = calloc(output_size, sizeof(float)); l.forward = forward_maxpool_layer; //l.backward = backward_maxpool_layer; fprintf(stderr, "max %d x %d / %d %4d x%4d x%4d -> %4d x%4d x%4d\n", size, size, stride, w, h, c, l.out_w, l.out_h, l.out_c); return l; } layer parse_maxpool(list *options, size_params params) { int stride = option_find_int(options, "stride",1); int size = option_find_int(options, "size",stride); int padding = option_find_int_quiet(options, "padding", size-1); int batch,h,w,c; h = params.h; w = params.w; c = params.c; batch=params.batch; if(!(h && w && c)) error("Layer before maxpool layer must output image."); layer maxpool_layer = make_maxpool_layer(batch,h,w,c,size,stride,padding); return maxpool_layer; } learning_rate_policy get_policy(char *s) { if (strcmp(s, "random")==0) return RANDOM; if (strcmp(s, "poly")==0) return POLY; if (strcmp(s, "constant")==0) return CONSTANT; if (strcmp(s, "step")==0) return STEP; if (strcmp(s, "exp")==0) return EXP; if (strcmp(s, "sigmoid")==0) return SIG; if (strcmp(s, "steps")==0) return STEPS; fprintf(stderr, "Couldn't find policy %s, going with constant\n", s); return CONSTANT; } void parse_net_options(list *options, network *net) { net->batch = option_find_int(options, "batch",1); net->learning_rate = option_find_float(options, "learning_rate", .001); net->momentum = option_find_float(options, "momentum", .9); net->decay = option_find_float(options, "decay", .0001); int subdivs = option_find_int(options, "subdivisions",1); net->time_steps = option_find_int_quiet(options, "time_steps",1); net->notruth = option_find_int_quiet(options, "notruth",0); net->batch /= subdivs; net->batch *= net->time_steps; net->subdivisions = subdivs; net->random = option_find_int_quiet(options, "random", 0); net->adam = option_find_int_quiet(options, "adam", 0); if(net->adam){ net->B1 = option_find_float(options, "B1", .9); net->B2 = option_find_float(options, "B2", .999); net->eps = option_find_float(options, "eps", .0000001); } net->h = option_find_int_quiet(options, "height",0); net->w = option_find_int_quiet(options, "width",0); net->c = option_find_int_quiet(options, "channels",0); net->inputs = option_find_int_quiet(options, "inputs", net->h * net->w * net->c); net->max_crop = option_find_int_quiet(options, "max_crop",net->w*2); net->min_crop = option_find_int_quiet(options, "min_crop",net->w); net->max_ratio = option_find_float_quiet(options, "max_ratio", (float) net->max_crop / net->w); net->min_ratio = option_find_float_quiet(options, "min_ratio", (float) net->min_crop / net->w); net->center = option_find_int_quiet(options, "center",0); net->clip = option_find_float_quiet(options, "clip", 0); net->angle = option_find_float_quiet(options, "angle", 0); net->aspect = option_find_float_quiet(options, "aspect", 1); net->saturation = option_find_float_quiet(options, "saturation", 1); net->exposure = option_find_float_quiet(options, "exposure", 1); net->hue = option_find_float_quiet(options, "hue", 0); if(!net->inputs && !(net->h && net->w && net->c)) error("No input parameters supplied"); char *policy_s = option_find_str(options, "policy", "constant"); net->policy = get_policy(policy_s); net->burn_in = option_find_int_quiet(options, "burn_in", 0); net->power = option_find_float_quiet(options, "power", 4); if(net->policy == STEP){ net->step = option_find_int(options, "step", 1); net->scale = option_find_float(options, "scale", 1); } else if (net->policy == STEPS){ char *l = option_find(options, "steps"); char *p = option_find(options, "scales"); if(!l || !p) error("STEPS policy must have steps and scales in cfg file"); int len = strlen(l); int n = 1; int i; for(i = 0; i < len; ++i){ if (l[i] == ',') ++n; } int *steps = (int *)calloc(n, sizeof(int)); float *scales = (float *)calloc(n, sizeof(float)); for(i = 0; i < n; ++i){ int step = atoi(l); float scale = atof(p); l = strchr(l, ',')+1; p = strchr(p, ',')+1; steps[i] = step; scales[i] = scale; } net->scales = scales; net->steps = steps; net->num_steps = n; } else if (net->policy == EXP){ net->gamma = option_find_float(options, "gamma", 1); } else if (net->policy == SIG){ net->gamma = option_find_float(options, "gamma", 1); net->step = option_find_int(options, "step", 1); } else if (net->policy == POLY || net->policy == RANDOM){ } net->max_batches = option_find_int(options, "max_batches", 0); } int is_network(section *s) { return (strcmp(s->type, "[net]")==0 || strcmp(s->type, "[network]")==0); } network *parse_network_cfg(char *filename) { list *sections = read_cfg(filename); node *n = sections->front; if(!n) error("Config file has no sections"); network *net = make_network(sections->size - 1); net->gpu_index = -1; size_params params; section *s = (section *)n->val; list *options = s->options; if(!is_network(s)) error("First section must be [net] or [network]"); parse_net_options(options, net); params.h = net->h; params.w = net->w; params.c = net->c; params.inputs = net->inputs; params.batch = net->batch; params.time_steps = net->time_steps; params.net = net; size_t workspace_size = 0; n = n->next; int count = 0; free_section(s); fprintf(stderr, "layer filters size input output\n"); while(n){ params.index = count; fprintf(stderr, "%5d ", count); s = (section *)n->val; options = s->options; //layer l = {0}; layer l; memset(&l,0,sizeof(layer)); LAYER_TYPE lt = string_to_layer_type(s->type); if(lt == CONVOLUTIONAL){ l = parse_convolutional(options, params); }else if(lt == YOLO){ l = parse_yolo(options, params); }else if(lt == ROUTE){ l = parse_route(options, params, net); }else if(lt == UPSAMPLE){ l = parse_upsample(options, params, net); }else if(lt == SHORTCUT){ l = parse_shortcut(options, params, net); }else if(lt == REGION){ l = parse_region(options, params); }else if(lt == YOLO){ l = parse_yolo(options, params); }else if(lt == MAXPOOL){ l = parse_maxpool(options, params); }else if(lt == REORG){ l = parse_reorg(options, params); }else{ fprintf(stderr, "Type not recognized: %s\n", s->type); } l.clip = net->clip; l.truth = option_find_int_quiet(options, "truth", 0); l.onlyforward = option_find_int_quiet(options, "onlyforward", 0); l.stopbackward = option_find_int_quiet(options, "stopbackward", 0); l.dontsave = option_find_int_quiet(options, "dontsave", 0); // l.dontload = option_find_int_quiet(options, "dontload", 0); // l.dontloadscales = option_find_int_quiet(options, "dontloadscales", 0); //l.learning_rate_scale = option_find_float_quiet(options, "learning_rate", 1); l.smooth = option_find_float_quiet(options, "smooth", 0); option_unused(options); net->layers[count] = l; if (l.workspace_size > workspace_size) workspace_size = l.workspace_size; free_section(s); n = n->next; ++count; if(n){ params.h = l.out_h; params.w = l.out_w; params.c = l.out_c; params.inputs = l.outputs; } } free_list(sections); layer out = get_network_output_layer(net); net->outputs = out.outputs; net->output = out.output; //net->input = (float *)calloc(net->inputs*net->batch, sizeof(float)); workspace_size = 0;//donot calloc workspace //if(workspace_size){ // //printf("%ld\n", workspace_size); // net->workspace = (float *)calloc(1, workspace_size); //} return net; } list *read_cfg(char *filename) { FILE *file = fopen(filename, "r"); if(file == 0) file_error(filename); char *line; int nu = 0; list *options = make_list(); section *current = 0; while((line=fgetl(file)) != 0){ ++ nu; strip(line); switch(line[0]){ case '[': current = (section *)malloc(sizeof(section)); list_insert(options, current); current->options = make_list(); current->type = line; break; case '\0': case '#': case ';': free(line); break; default: if(!read_option(line, current->options)){ fprintf(stderr, "Config file error line %d, could parse: %s\n", nu, line); free(line); } break; } } fclose(file); return options; } void load_convolutional_weights(layer l, FILE *fp) { int num = l.nweights; fread(l.biases, sizeof(float), l.n, fp); if (l.batch_normalize){ fread(l.scales, sizeof(float), l.n, fp); fread(l.rolling_mean, sizeof(float), l.n, fp); fread(l.rolling_variance, sizeof(float), l.n, fp); } fread(l.weights, sizeof(float), num, fp); } void load_weights_upto(network *net, char *filename, int start, int cutoff) { fprintf(stderr, "Loading weights from %s...", filename); fflush(stdout); FILE *fp = fopen(filename, "rb"); if(!fp) file_error(filename); int major; int minor; int revision; fread(&major, sizeof(int), 1, fp); fread(&minor, sizeof(int), 1, fp); fread(&revision, sizeof(int), 1, fp); printf("major=%d;minor=%d;revision=%d\n",major,minor,revision);// 0 2 0 printf("if true ro false:%d\n",(major*10 + minor) >= 2 && major < 1000 && minor < 1000); if ((major*10 + minor) >= 2 && major < 1000 && minor < 1000){ //fread(net->seen, sizeof(size_t), 1, fp); fread(net->seen, sizeof(size_t), 1, fp); fread(net->seen, sizeof(size_t), 1, fp); }else { int iseen = 0; fread(&iseen, sizeof(int), 1, fp); *net->seen = iseen; } //printf("sizeof(size_t)=%u\n",sizeof(size_t));// in my PC is 4 int i; for(i = start; i < net->n && i < cutoff; ++i){ layer l = net->layers[i]; if(l.type == CONVOLUTIONAL){ load_convolutional_weights(l, fp); } } fprintf(stderr, "Done!\n"); fclose(fp); } void load_weights(network *net, char *filename) { load_weights_upto(net, filename, 0, net->n); } /////////////////praser end /////////////////network begin load_args get_base_args(network *net) { load_args args = {0}; args.w = net->w; args.h = net->h; args.size = net->w; args.min = net->min_crop; args.max = net->max_crop; args.angle = net->angle; args.aspect = net->aspect; args.exposure = net->exposure; args.center = net->center; args.saturation = net->saturation; args.hue = net->hue; return args; } network *load_network(char *cfg, char *weights, int clear) { network *net = parse_network_cfg(cfg); //if(weights && weights[0] != 0){ // load_weights(net, weights); //} if(clear) (*net->seen) = 0; return net; } char *get_layer_string(LAYER_TYPE a) { switch(a){ case CONVOLUTIONAL: return "convolutional"; case ACTIVE: return "activation"; case LOCAL: return "local"; case DECONVOLUTIONAL: return "deconvolutional"; case CONNECTED: return "connected"; case RNN: return "rnn"; case GRU: return "gru"; case LSTM: return "lstm"; case CRNN: return "crnn"; case MAXPOOL: return "maxpool"; case REORG: return "reorg"; case AVGPOOL: return "avgpool"; case SOFTMAX: return "softmax"; case DETECTION: return "detection"; case REGION: return "region"; case YOLO: return "yolo"; case DROPOUT: return "dropout"; case CROP: return "crop"; case COST: return "cost"; case ROUTE: return "route"; case SHORTCUT: return "shortcut"; case NORMALIZATION: return "normalization"; case BATCHNORM: return "batchnorm"; default: break; } return "none"; } network *make_network(int n) { network *net = (network *)calloc(1, sizeof(network)); net->n = n; net->layers = (layer *)calloc(net->n, sizeof(layer)); net->seen = (size_t *)calloc(1, sizeof(size_t)); net->t = (int *)calloc(1, sizeof(int)); net->cost = (float *)calloc(1, sizeof(float)); return net; } void forward_network(network *netp) { network net = *netp; int i; for(i = 0; i < net.n; ++i){ net.index = i; layer l = net.layers[i]; l.forward(l, net); net.input = l.output; // printf("layer [%d]\n",i); } } void set_temp_network(network *net, float t) { int i; for(i = 0; i < net->n; ++i){ net->layers[i].temperature = t; } } void set_batch_network(network *net, int b) { net->batch = b; int i; for(i = 0; i < net->n; ++i){ net->layers[i].batch = b; } } float *network_predict(network *net, float *input) { network orig = *net; net->input = input; net->truth = 0; net->train = 0; net->delta = 0; forward_network(net); float *out = net->output; *net = orig; return out; } int yolo_num_detections(layer l, float thresh) { int i, n; int count = 0; for (i = 0; i < l.w*l.h; ++i){ for(n = 0; n < l.n; ++n){ int obj_index = entry_index(l, 0, n*l.w*l.h + i, 4); if(l.output[obj_index] > thresh){ ++count; } } } return count; } int num_detections(network *net, float thresh) { int i; int s = 0; for(i = 0; i < net->n; ++i){ layer l = net->layers[i]; if(l.type == YOLO){ s += yolo_num_detections(l, thresh); } if(l.type == DETECTION || l.type == REGION){ s += l.w*l.h*l.n; } } return s; } detection *make_network_boxes(network *net, float thresh, int *num) { layer l = net->layers[net->n - 1]; int i; int nboxes = num_detections(net, thresh); //printf("num_detections nboxes = %d\n",nboxes); if(num) *num = nboxes; detection *dets = (detection *)calloc(nboxes, sizeof(detection)); for(i = 0; i < nboxes; ++i){ dets[i].prob = (float *)calloc(l.classes, sizeof(float)); } return dets; } box get_yolo_box(float *x, float *biases, int n, int index, int i, int j, int lw, int lh, int w, int h, int stride) { box b; b.x = (i + x[index + 0*stride]) / lw; b.y = (j + x[index + 1*stride]) / lh; b.w = exp(x[index + 2*stride]) * biases[2*n] / w; b.h = exp(x[index + 3*stride]) * biases[2*n+1] / h; return b; } void correct_yolo_boxes(detection *dets, int n, int w, int h, int netw, int neth, int relative) { int i; int new_w=0; int new_h=0; if (((float)netw/w) < ((float)neth/h)) { new_w = netw; new_h = (h * netw)/w; } else { new_h = neth; new_w = (w * neth)/h; } for (i = 0; i < n; ++i){ box b = dets[i].bbox; b.x = (b.x - (netw - new_w)/2./netw) / ((float)new_w/netw); b.y = (b.y - (neth - new_h)/2./neth) / ((float)new_h/neth); b.w *= (float)netw/new_w; b.h *= (float)neth/new_h; if(!relative){ b.x *= w; b.w *= w; b.y *= h; b.h *= h; } dets[i].bbox = b; } } int get_yolo_detections(layer l, int w, int h, int netw, int neth, float thresh, int *map, int relative, detection *dets) { int i,j,n; float *predictions = l.output; // if (l.batch == 2) avg_flipped_yolo(l); int count = 0; for (i = 0; i < l.w*l.h; ++i){ int row = i / l.w; int col = i % l.w; for(n = 0; n < l.n; ++n){ int obj_index = entry_index(l, 0, n*l.w*l.h + i, 4); float objectness = predictions[obj_index]; if(objectness <= thresh) continue; int box_index = entry_index(l, 0, n*l.w*l.h + i, 0); dets[count].bbox = get_yolo_box(predictions, l.biases, l.mask[n], box_index, col, row, l.w, l.h, netw, neth, l.w*l.h); dets[count].objectness = objectness; dets[count].classes = l.classes; for(j = 0; j < l.classes; ++j){ int class_index = entry_index(l, 0, n*l.w*l.h + i, 4 + 1 + j); float prob = objectness*predictions[class_index]; dets[count].prob[j] = (prob > thresh) ? prob : 0; } ++count; } } correct_yolo_boxes(dets, count, w, h, netw, neth, relative); return count; } box get_region_box(float *x, float *biases, int n, int index, int i, int j, int w, int h, int stride) { box b; b.x = (i + x[index + 0*stride]) / w; b.y = (j + x[index + 1*stride]) / h; b.w = exp(x[index + 2*stride]) * biases[2*n] / w; b.h = exp(x[index + 3*stride]) * biases[2*n+1] / h; return b; } void correct_region_boxes(detection *dets, int n, int w, int h, int netw, int neth, int relative) { int i; int new_w=0; int new_h=0; if (((float)netw/w) < ((float)neth/h)) { new_w = netw; new_h = (h * netw)/w; } else { new_h = neth; new_w = (w * neth)/h; } for (i = 0; i < n; ++i){ box b = dets[i].bbox; b.x = (b.x - (netw - new_w)/2./netw) / ((float)new_w/netw); b.y = (b.y - (neth - new_h)/2./neth) / ((float)new_h/neth); b.w *= (float)netw/new_w; b.h *= (float)neth/new_h; if(!relative){ b.x *= w; b.w *= w; b.y *= h; b.h *= h; } dets[i].bbox = b; } } void get_region_detections(layer l, int w, int h, int netw, int neth, float thresh, int *map, float tree_thresh, int relative, detection *dets) { int i,j,n,z; float *predictions = l.output; if (l.batch == 2) { float *flip = l.output + l.outputs; for (j = 0; j < l.h; ++j) { for (i = 0; i < l.w/2; ++i) { for (n = 0; n < l.n; ++n) { for(z = 0; z < l.classes + l.coords + 1; ++z){ int i1 = z*l.w*l.h*l.n + n*l.w*l.h + j*l.w + i; int i2 = z*l.w*l.h*l.n + n*l.w*l.h + j*l.w + (l.w - i - 1); float swap = flip[i1]; flip[i1] = flip[i2]; flip[i2] = swap; if(z == 0){ flip[i1] = -flip[i1]; flip[i2] = -flip[i2]; } } } } } for(i = 0; i < l.outputs; ++i){ l.output[i] = (l.output[i] + flip[i])/2.; } } for (i = 0; i < l.w*l.h; ++i){ int row = i / l.w; int col = i % l.w; for(n = 0; n < l.n; ++n){ int index = n*l.w*l.h + i; for(j = 0; j < l.classes; ++j){ dets[index].prob[j] = 0; } int obj_index = entry_index(l, 0, n*l.w*l.h + i, l.coords); int box_index = entry_index(l, 0, n*l.w*l.h + i, 0); int mask_index = entry_index(l, 0, n*l.w*l.h + i, 4); float scale = l.background ? 1 : predictions[obj_index]; dets[index].bbox = get_region_box(predictions, l.biases, n, box_index, col, row, l.w, l.h, l.w*l.h); dets[index].objectness = scale > thresh ? scale : 0; if(dets[index].mask){ for(j = 0; j < l.coords - 4; ++j){ dets[index].mask[j] = l.output[mask_index + j*l.w*l.h]; } } int class_index = entry_index(l, 0, n*l.w*l.h + i, l.coords + !l.background); if(dets[index].objectness){ for(j = 0; j < l.classes; ++j){ int class_index = entry_index(l, 0, n*l.w*l.h + i, l.coords + 1 + j); float prob = scale*predictions[class_index]; dets[index].prob[j] = (prob > thresh) ? prob : 0; } } } } correct_region_boxes(dets, l.w*l.h*l.n, w, h, netw, neth, relative); } void fill_network_boxes(network *net, int w, int h, float thresh, float hier, int *map, int relative, detection *dets) { int j; for(j = 0; j < net->n; ++j){ layer l = net->layers[j]; if(l.type == YOLO){ int count = get_yolo_detections(l, w, h, net->w, net->h, thresh, map, relative, dets); dets += count; } if(l.type == REGION){ get_region_detections(l, w, h, net->w, net->h, thresh, map, hier, relative, dets); dets += l.w*l.h*l.n; } } } detection *get_network_boxes(network *net, int w, int h, float thresh, float hier, int *map, int relative, int *num) { detection *dets = make_network_boxes(net, thresh, num); fill_network_boxes(net, w, h, thresh, hier, map, relative, dets); return dets; } void free_detections(detection *dets, int n) { int i; for(i = 0; i < n; ++i){ free(dets[i].prob); if(dets[i].mask) free(dets[i].mask); } free(dets); } int network_width(network *net){return net->w;} int network_height(network *net){return net->h;} layer get_network_output_layer(network *net) { int i; for(i = net->n - 1; i >= 0; --i){ if(net->layers[i].type != COST) break; } return net->layers[i]; } void free_network(network *net) { int i; for(i = 0; i < net->n; ++i){ free_layer(net->layers[i]); } free(net->layers); if(net->input) free(net->input); if(net->truth) free(net->truth); free(net); } layer network_output_layer(network *net) { int i; for(i = net->n - 1; i >= 0; --i){ if(net->layers[i].type != COST) break; } return net->layers[i]; } int network_inputs(network *net) { return net->layers[0].inputs; } int network_outputs(network *net) { return network_output_layer(net).outputs; } float *network_output(network *net) { return network_output_layer(net).output; } //////////////////network end //////////////////////box begin int nms_comparator(const void *pa, const void *pb) { detection a = *(detection *)pa; detection b = *(detection *)pb; float diff = 0; if(b.sort_class >= 0){ diff = a.prob[b.sort_class] - b.prob[b.sort_class]; } else { diff = a.objectness - b.objectness; } if(diff < 0) return 1; else if(diff > 0) return -1; return 0; } float overlap(float x1, float w1, float x2, float w2) { float l1 = x1 - w1/2; float l2 = x2 - w2/2; float left = l1 > l2 ? l1 : l2; float r1 = x1 + w1/2; float r2 = x2 + w2/2; float right = r1 < r2 ? r1 : r2; return right - left; } float box_intersection(box a, box b) { float w = overlap(a.x, a.w, b.x, b.w); float h = overlap(a.y, a.h, b.y, b.h); if(w < 0 || h < 0) return 0; float area = w*h; return area; } float box_union(box a, box b) { float i = box_intersection(a, b); float u = a.w*a.h + b.w*b.h - i; return u; } float box_iou(box a, box b) { return box_intersection(a, b)/box_union(a, b); } void do_nms_sort(detection *dets, int total, int classes, float thresh) { int i, j, k; k = total-1; for(i = 0; i <= k; ++i){ if(dets[i].objectness == 0){ detection swap = dets[i]; dets[i] = dets[k]; dets[k] = swap; --k; --i; } } total = k+1; for(k = 0; k < classes; ++k){ for(i = 0; i < total; ++i){ dets[i].sort_class = k; } qsort(dets, total, sizeof(detection), nms_comparator); for(i = 0; i < total; ++i){ if(dets[i].prob[k] == 0) continue; box a = dets[i].bbox; for(j = i+1; j < total; ++j){ box b = dets[j].bbox; if (box_iou(a, b) > thresh){ dets[j].prob[k] = 0; } } } } } //////////////////////box end //////////////////////image begin float colors[6][3] = { {1,0,1}, {0,0,1},{0,1,1},{0,1,0},{1,1,0},{1,0,0} }; float get_color(int c, int x, int max) { float ratio = ((float)x/max)*5; int i = floor(ratio); int j = ceil(ratio); ratio -= i; float r = (1-ratio) * colors[i][c] + ratio*colors[j][c]; //printf("%f\n", r); return r; } static float get_pixel_extend(image m, int x, int y, int c) { if(x < 0 || x >= m.w || y < 0 || y >= m.h) return 0; /* if(x < 0) x = 0; if(x >= m.w) x = m.w-1; if(y < 0) y = 0; if(y >= m.h) y = m.h-1; */ if(c < 0 || c >= m.c) return 0; return get_pixel(m, x, y, c); } void composite_image(image source, image dest, int dx, int dy) { int x,y,k; for(k = 0; k < source.c; ++k){ for(y = 0; y < source.h; ++y){ for(x = 0; x < source.w; ++x){ float val = get_pixel(source, x, y, k); float val2 = get_pixel_extend(dest, dx+x, dy+y, k); set_pixel(dest, dx+x, dy+y, k, val * val2); } } } } image border_image(image a, int border) { image b = make_image(a.w + 2*border, a.h + 2*border, a.c); int x,y,k; for(k = 0; k < b.c; ++k){ for(y = 0; y < b.h; ++y){ for(x = 0; x < b.w; ++x){ float val = get_pixel_extend(a, x - border, y - border, k); if(x - border < 0 || x - border >= a.w || y - border < 0 || y - border >= a.h) val = 1; set_pixel(b, x, y, k, val); } } } return b; } image copy_image(image p) { image copy = p; copy.data = (float *)calloc(p.h*p.w*p.c, sizeof(float)); memcpy(copy.data, p.data, p.h*p.w*p.c*sizeof(float)); return copy; } image tile_images(image a, image b, int dx) { if(a.w == 0) return copy_image(b); image c = make_image(a.w + b.w + dx, (a.h > b.h) ? a.h : b.h, (a.c > b.c) ? a.c : b.c); fill_cpu(c.w*c.h*c.c, 1, c.data, 1); embed_image(a, c, 0, 0); composite_image(b, c, a.w + dx, 0); return c; } image get_label(image **characters, char *string, int size) { size = size/10; if(size > 7) size = 7; image label = make_empty_image(0,0,0); while(*string){ image l = characters[size][(int)*string]; image n = tile_images(label, l, -size - 1 + (size+1)/2); free_image(label); label = n; ++string; } image b = border_image(label, label.h*.25); free_image(label); return b; } void draw_label(image a, int r, int c, image label, const float *rgb) { int w = label.w; int h = label.h; if (r - h >= 0) r = r - h; int i, j, k; for(j = 0; j < h && j + r < a.h; ++j){ for(i = 0; i < w && i + c < a.w; ++i){ for(k = 0; k < label.c; ++k){ float val = get_pixel(label, i, j, k); set_pixel(a, i+c, j+r, k, rgb[k] * val); } } } } void draw_box(image a, int x1, int y1, int x2, int y2, float r, float g, float b) { //normalize_image(a); int i; if(x1 < 0) x1 = 0; if(x1 >= a.w) x1 = a.w-1; if(x2 < 0) x2 = 0; if(x2 >= a.w) x2 = a.w-1; if(y1 < 0) y1 = 0; if(y1 >= a.h) y1 = a.h-1; if(y2 < 0) y2 = 0; if(y2 >= a.h) y2 = a.h-1; for(i = x1; i <= x2; ++i){ a.data[i + y1*a.w + 0*a.w*a.h] = r; a.data[i + y2*a.w + 0*a.w*a.h] = r; a.data[i + y1*a.w + 1*a.w*a.h] = g; a.data[i + y2*a.w + 1*a.w*a.h] = g; a.data[i + y1*a.w + 2*a.w*a.h] = b; a.data[i + y2*a.w + 2*a.w*a.h] = b; } for(i = y1; i <= y2; ++i){ a.data[x1 + i*a.w + 0*a.w*a.h] = r; a.data[x2 + i*a.w + 0*a.w*a.h] = r; a.data[x1 + i*a.w + 1*a.w*a.h] = g; a.data[x2 + i*a.w + 1*a.w*a.h] = g; a.data[x1 + i*a.w + 2*a.w*a.h] = b; a.data[x2 + i*a.w + 2*a.w*a.h] = b; } } void draw_box_width(image a, int x1, int y1, int x2, int y2, int w, float r, float g, float b) { int i; for(i = 0; i < w; ++i){ draw_box(a, x1+i, y1+i, x2-i, y2-i, r, g, b); } } image float_to_image(int w, int h, int c, float *data) { image out = make_empty_image(w,h,c); out.data = data; return out; } image threshold_image(image im, float thresh) { int i; image t = make_image(im.w, im.h, im.c); for(i = 0; i < im.w*im.h*im.c; ++i){ t.data[i] = im.data[i]>thresh ? 1 : 0; } return t; } void draw_detections(image im, detection *dets, int num, float thresh, char **names, image **alphabet, int classes) { int i,j; for(i = 0; i < num; ++i){ char labelstr[4096] = {0}; int class_t = -1; for(j = 0; j < classes; ++j){ if (dets[i].prob[j] > thresh){ if (class_t < 0) { strcat(labelstr, names[j]); class_t = j; } else { strcat(labelstr, ", "); strcat(labelstr, names[j]); } printf("%s: %.0f%%\n", names[j], dets[i].prob[j]*100); } } if(class_t >= 0){ int width = im.h * .006; //printf("%d %s: %.0f%%\n", i, names[class], prob*100); int offset = class_t*123457 % classes; float red = get_color(2,offset,classes); float green = get_color(1,offset,classes); float blue = get_color(0,offset,classes); float rgb[3]; //width = prob*20+2; rgb[0] = red; rgb[1] = green; rgb[2] = blue; box b = dets[i].bbox; //printf("%f %f %f %f\n", b.x, b.y, b.w, b.h); int left = (b.x-b.w/2.)*im.w; int right = (b.x+b.w/2.)*im.w; int top = (b.y-b.h/2.)*im.h; int bot = (b.y+b.h/2.)*im.h; if(left < 0) left = 0; if(right > im.w-1) right = im.w-1; if(top < 0) top = 0; if(bot > im.h-1) bot = im.h-1; draw_box_width(im, left, top, right, bot, width, red, green, blue); if (alphabet) { image label = get_label(alphabet, labelstr, (im.h*.03)); draw_label(im, top + width, left, label, rgb); free_image(label); } if (dets[i].mask){ image mask = float_to_image(14, 14, 1, dets[i].mask); image resized_mask = resize_image(mask, b.w*im.w, b.h*im.h); image tmask = threshold_image(resized_mask, .5); embed_image(tmask, im, left, top); free_image(mask); free_image(resized_mask); free_image(tmask); } } } } //////////////////////image end ///////////////////////////////////////////////////////////////////////20181108 reorg WeightQ BetaQ ok InputQ ok start #define MAX(x,y) ((x)>(y)?(x):(y)) #define MIN(x,y) ((x)<(y)?(x):(y)) #define S 2 #define K 3 #define Tn 4 #define Tm 32 #define Tr 26 #define Tc 26 #define OnChipIB_Width ((Tc-1)*S+K) #define OnChipIB_Height ((Tr-1)*S+K) #define MAX_BETA_LENGTH (1024) //////////////////////////////////////////////////T3 start void input_load(float *input,float input_buffer[Tn][OnChipIB_Height][OnChipIB_Width],int r,int c,int n,int Kernel_stride,int Padding,int TRow,int TCol,int Input_w,int Input_h,int TN_MIN,int IHxIW,int LayerType) { int t1,t2,t3,t4; int xoffset; int yoffset; static float input_memcpy_buffer[Tn*OnChipIB_Height*OnChipIB_Width]; const int Coffset = c*Kernel_stride - Padding; const int Roffset = r*Kernel_stride - Padding; const int CurrentOffset = n*IHxIW + Roffset*Input_w + Coffset; float pad_value = 0; if(LayerType==1) pad_value = -1024*1024; int input_mmcpy_offset = 0; for(t1 = 0;t1 < TN_MIN; t1++) for(t2 = 0;t2 < TRow; t2++) { memcpy((float *)(input_memcpy_buffer + input_mmcpy_offset),(float *)(input + CurrentOffset + t1*IHxIW + t2*Input_w),TCol*sizeof(float)); input_mmcpy_offset += TCol; } input_mmcpy_offset = 0; for(t1 = 0;t1 < Tn; t1++) for(t2 = 0;t2 < TRow; t2++) for(t3 = 0;t3 < TCol; t3++) { xoffset = Coffset + t3; yoffset = Roffset + t2; bool XEnable = (xoffset >= 0)&&(xoffset < Input_w); bool YEnable = (yoffset >= 0)&&(yoffset < Input_h); bool PaddingEnable = XEnable&&YEnable; if(PaddingEnable&&(t1 < TN_MIN)) input_buffer[t1][t2][t3] = input_memcpy_buffer[input_mmcpy_offset]; else input_buffer[t1][t2][t3] = pad_value; input_mmcpy_offset++; } } void weight_load_reorg(int *Weight,float weight_buffer[Tm][Tn][K][K],bool weight_load_enable,int m,int n,int IFM_numxKxK,int KxK,int Kernel_size,int TM_MIN,int TN_MIN,const int WeightQ) { int t1,t2,t3,t4; static int weight_memcpy_buffer[Tm*Tn*K*K/2]; static int Woffset; if(!weight_load_enable) return; if(m==0&&n==0) Woffset = 0; if((TM_MIN*TN_MIN*KxK)%2) printf("weight % error\n"); memcpy(weight_memcpy_buffer,(int *)(Weight + Woffset),TM_MIN*TN_MIN*KxK/2*sizeof(int)); Woffset += TM_MIN*TN_MIN*KxK/2; int weight_memcpy_offset = 0; int cnt = 0; short input_array[2]; float input_value; for(t3 = 0;t3 <Kernel_size; t3++) for(t4 = 0;t4 <Kernel_size; t4++) for(t1 = 0;t1 < Tm; t1++) for(t2 = 0;t2 < Tn; t2++) { bool Enable = (t1 < TM_MIN)&&(t2 < TN_MIN); if(Enable) { if(cnt==0) { input_array[0] = weight_memcpy_buffer[weight_memcpy_offset]; input_array[1] = weight_memcpy_buffer[weight_memcpy_offset] >> 16; weight_memcpy_offset++; } input_value = input_array[cnt]*pow(2.0,-WeightQ); weight_buffer[t1][t2][t3][t4] = input_value; cnt++; if(cnt==2) cnt = 0; } else weight_buffer[t1][t2][t3][t4] = 0; } } void copy_input_weight(float *input,int *Weight,int InFM_num,int Input_w,int Input_h,int OutFM_num,int Kernel_size,int Kernel_stride,int r,int c,int m,int n, int TM_MIN,int TN,int TRow,int TCol,int Padding,float input_buffer[Tn][OnChipIB_Height][OnChipIB_Width],float weight_buffer[Tm][Tn][K][K],int TMP_N_next[1], bool enable,bool weight_load_enable,bool initialize,const int IHxIW,const int KxK,const int IFM_numxKxK,const int LayerType,const int WeightQ) { if(!enable) return ; const int TN_MIN = MIN(TN,InFM_num - n); TMP_N_next[0] = n; input_load(input, input_buffer, r, c, n, Kernel_stride, Padding, TRow, TCol, Input_w, Input_h, TN_MIN, IHxIW, LayerType); weight_load_reorg(Weight,weight_buffer,weight_load_enable,m,n,IFM_numxKxK,KxK,Kernel_size,TM_MIN,TN_MIN,WeightQ); } void copy_local_beta(float beta_buffer[MAX_BETA_LENGTH],float local_beta_buffer[MAX_BETA_LENGTH],const int TM_MIN,int m) { int offset; int tm; for(tm = 0,offset = m;tm < TM_MIN;tm++) { local_beta_buffer[tm] = beta_buffer[offset]; offset++; } } void nonlinear_leaky(float Input[Tm][Tr][Tc],const int TM_MIN,const int TR_MIN,const int TC_MIN,const bool IsNL) { int tr,tc,tm; if(!IsNL) return ; for(tm = 0;tm < TM_MIN;tm++) #pragma HLS LOOP_TRIPCOUNT min=1 max=1 for(tr = 0;tr < TR_MIN;tr++) #pragma HLS LOOP_TRIPCOUNT min=1 max=14 for(tc = 0;tc < TC_MIN;tc++) { #pragma HLS LOOP_TRIPCOUNT min=14 max=14 #pragma HLS PIPELINE float tmp = Input[tm][tr][tc]; if(tmp < 0) Input[tm][tr][tc] = tmp*0.1; } } void compute(float input_buffer[Tn][OnChipIB_Height][OnChipIB_Width],float output_buffer[Tm][Tr][Tc], float weight_buffer[Tm][Tn][K][K],float beta_buffer[MAX_BETA_LENGTH],int TMP_N_next[1], const int Kernel_size,const int Kernel_stride,int TMP_M, const int TM_MIN,const int TR_MIN,const int TC_MIN,bool enable,const bool IsNL,const bool reluenable) { static float local_beta_buffer[Tm]; #pragma HLS ARRAY_PARTITION variable=local_beta_buffer complete dim=1 if(!enable) { copy_local_beta(beta_buffer,local_beta_buffer,TM_MIN,TMP_M); return; } int i,j,tr,tc,tm,tn; int n = TMP_N_next[0]; float partial_mul[Tm][Tn]; float partial_add[Tm]; for(i =0;i < Kernel_size; i++) #pragma HLS LOOP_TRIPCOUNT min=1 max=5 for(j = 0;j < Kernel_size; j++) #pragma HLS LOOP_TRIPCOUNT min=1 max=5 for(tr = 0;tr < TR_MIN;tr++) #pragma HLS LOOP_TRIPCOUNT min=14 max=14 for(tc = 0;tc < TC_MIN;tc++) { #pragma HLS LOOP_TRIPCOUNT min=14 max=14 #pragma HLS PIPELINE for(tm = 0;tm < Tm;tm++) { if(i==0&&j==0&&n==0) partial_add[tm] = local_beta_buffer[tm]; else partial_add[tm] = output_buffer[tm][tr][tc]; } for(tm = 0;tm < Tm;tm++) for(tn = 0;tn <Tn;tn++) { partial_mul[tm][tn] = weight_buffer[tm][tn][i][j]*input_buffer[tn][Kernel_stride*tr+i][Kernel_stride*tc+j]; } for(tm = 0;tm < Tm;tm++) { float partial_sum = 0; for(tn = 0;tn <Tn;tn++) { partial_sum += partial_mul[tm][tn]; } output_buffer[tm][tr][tc] = partial_add[tm] + partial_sum; } } if(reluenable) nonlinear_leaky(output_buffer,TM_MIN,TR_MIN,TC_MIN,IsNL); } void write_back_output_reorg(float output_buffer[Tm][Tr][Tc],float *Output,int r,int c,int m,const int Output_w,const int Output_h, const int TM_MIN,const int TR_MIN,const int TC_MIN,const int OHxOW,bool write_flag) { if(!write_flag) return; const int offset = m*OHxOW + r*Output_w + c; int tr,tm; //for(tm = 0;tm < TM_MIN;tm++) // for(tr = 0;tr < TR_MIN;tr++) // for(tc = 0;tc < TC_MIN;tc++) // { // Output[tm*OHxOW + tr*Output_w + tc + offset] = output_buffer[tm][tr][tc]; // } for(tm = 0;tm < TM_MIN;tm++) for(tr = 0;tr < TR_MIN;tr++) { memcpy((float *)(Output + tm*OHxOW + tr*Output_w + offset),output_buffer[tm][tr],TC_MIN*sizeof(float)); } } void pool_yolo2(float Input[Tn][OnChipIB_Height][OnChipIB_Width],float Output[Tm][Tr][Tc], const int Kernel_size,const int Kernel_stride, const int TM_MIN,const int TR_MIN,const int TC_MIN,bool enable) { if(!enable) return; int i,j,tr,tc,of; float tmp[Tn]; for(tr = 0;tr < TR_MIN;tr++) for(tc = 0;tc < TC_MIN;tc++) for(i =0;i < Kernel_size; i++) for(j = 0;j < Kernel_size; j++) { #pragma HLS PIPELINE for( of = 0; of < Tn; of++) { if(i==0&&j==0) tmp[of] = -1024*1024; if(Input[of][tr*Kernel_stride+i][tc*Kernel_stride+j] > tmp[of]) tmp[of] = Input[of][tr*Kernel_stride+i][tc*Kernel_stride+j]; if(i==1&&j==1) Output[of][tr][tc] = tmp[of]; } } } void reorg_yolo2(float Input[Tn][OnChipIB_Height][OnChipIB_Width],float Output[Tm][Tr][Tc], const int Kernel_size,const int Kernel_stride, const int TM_MIN,const int TR_MIN,const int TC_MIN,bool enable) { int x, y,kx,ky; unsigned char Yoffset; unsigned char Xoffset; if(!enable) return; for( y = 0; y < TR_MIN; y++) for( x = 0; x < TC_MIN; x++) for(ky= 0;ky < 2; ky++) for(kx = 0;kx < 2; kx++) { #pragma HLS PIPELINE Yoffset = (y << 1) + ky; Xoffset = (x << 1) + kx; int in_index = (ky << 1) + kx; Output[in_index][y][x] = Input[0][Yoffset][Xoffset]; } } void intra_pingpong_wrapper(float *Input,int *Weight, float output_buffer[Tm][Tr][Tc],float beta_buffer[MAX_BETA_LENGTH], float input_buffer0[Tn][OnChipIB_Height][OnChipIB_Width],float input_buffer1[Tn][OnChipIB_Height][OnChipIB_Width], int InFM_num,int Input_w,int Input_h,int OutFM_num,int Kernel_size,int Kernel_stride, int TMP_R,int TMP_C,int TMP_M,int m,int TM_MIN,int TR_MIN,int TC_MIN,int TN,int TRow,int TCol,int Padding, int IHxIW,int KxK,int IFM_numxKxK,int nLoops,bool IsNL,int LayerType,int TM,int TMP_X_next[1],int TX_MIN_next[1],bool pingpongx,bool input_flag,bool process_flag, int WeightQ) { static float weight_buffer0[Tm][Tn][K][K]; #pragma HLS ARRAY_PARTITION variable=weight_buffer0 complete dim=1 #pragma HLS ARRAY_PARTITION variable=weight_buffer0 complete dim=2 static float weight_buffer1[Tm][Tn][K][K]; #pragma HLS ARRAY_PARTITION variable=weight_buffer1 complete dim=1 #pragma HLS ARRAY_PARTITION variable=weight_buffer1 complete dim=2 static int NOP[1]; static int tmp_x; static int tmp_tx_min; if(LayerType==0) { if(!input_flag) return; TMP_X_next[0] = TMP_M;//consider by the inner-out loop TX_MIN_next[0] = TM_MIN;// like above bool pingpong = 0; int TMP_N_next0[1]; int TMP_N_next1[1]; int n; int TMP_N; for(TMP_N = 0,n = 0;n < nLoops+1; n++,TMP_N += TN) { if(pingpong == 1) { copy_input_weight(Input,Weight,InFM_num,Input_w,Input_h,OutFM_num,Kernel_size,Kernel_stride,TMP_R,TMP_C,TMP_M,TMP_N, TM_MIN,TN,TRow,TCol,Padding,input_buffer1,weight_buffer1,TMP_N_next1,n!=nLoops,1,(m==0)&&(n==0),IHxIW,KxK,IFM_numxKxK,LayerType,WeightQ); compute(input_buffer0,output_buffer,weight_buffer0,beta_buffer,TMP_N_next0,Kernel_size,Kernel_stride,TMP_M,TM_MIN,TR_MIN,TC_MIN,n!=0,IsNL,n==nLoops); pingpong = 0; }else { copy_input_weight(Input,Weight,InFM_num,Input_w,Input_h,OutFM_num,Kernel_size,Kernel_stride,TMP_R,TMP_C,TMP_M,TMP_N, TM_MIN,TN,TRow,TCol,Padding,input_buffer0,weight_buffer0,TMP_N_next0,n!=nLoops,1,(m==0)&&(n==0),IHxIW,KxK,IFM_numxKxK,LayerType,WeightQ); compute(input_buffer1,output_buffer,weight_buffer1,beta_buffer,TMP_N_next1,Kernel_size,Kernel_stride,TMP_M,TM_MIN,TR_MIN,TC_MIN,n!=0,IsNL,n==nLoops); pingpong = 1; } } } else if(LayerType==1) { if(pingpongx==0) { TMP_X_next[0] = tmp_x; TX_MIN_next[0] = tmp_tx_min; tmp_x = TMP_M; tmp_tx_min = TM_MIN; copy_input_weight(Input,Weight,InFM_num,Input_w,Input_h,OutFM_num,Kernel_size,Kernel_stride,TMP_R,TMP_C,TMP_M,TMP_M, TM_MIN,TM,TRow,TCol,0,input_buffer0,NULL,NOP,input_flag,0,0,IHxIW,KxK,IFM_numxKxK,LayerType,WeightQ); pool_yolo2(input_buffer1,output_buffer,Kernel_size,Kernel_stride,TX_MIN_next[0],TR_MIN,TC_MIN,process_flag); }else { TMP_X_next[0] = tmp_x; TX_MIN_next[0] = tmp_tx_min; tmp_x = TMP_M; tmp_tx_min = TM_MIN; copy_input_weight(Input,Weight,InFM_num,Input_w,Input_h,OutFM_num,Kernel_size,Kernel_stride,TMP_R,TMP_C,TMP_M,TMP_M, TM_MIN,TM,TRow,TCol,0,input_buffer1,NULL,NOP,input_flag,0,0,IHxIW,KxK,IFM_numxKxK,LayerType,WeightQ); pool_yolo2(input_buffer0,output_buffer,Kernel_size,Kernel_stride,TX_MIN_next[0],TR_MIN,TC_MIN,process_flag); } } else if(LayerType==2) { if(pingpongx==0) { TMP_X_next[0] = tmp_x; TX_MIN_next[0] = tmp_tx_min; tmp_x = TMP_M; tmp_tx_min = TM_MIN; copy_input_weight(Input,Weight,InFM_num,Input_w,Input_h,OutFM_num,Kernel_size,Kernel_stride,TMP_R,TMP_C,TMP_M,TMP_M, TM_MIN,TM,TRow,TCol,0,input_buffer0,NULL,NOP,input_flag,0,0,IHxIW,KxK,IFM_numxKxK,LayerType,WeightQ); reorg_yolo2(input_buffer1,output_buffer,Kernel_size,Kernel_stride,TX_MIN_next[0],TR_MIN,TC_MIN,process_flag); }else { TMP_X_next[0] = tmp_x; TX_MIN_next[0] = tmp_tx_min; tmp_x = TMP_M; tmp_tx_min = TM_MIN; copy_input_weight(Input,Weight,InFM_num,Input_w,Input_h,OutFM_num,Kernel_size,Kernel_stride,TMP_R,TMP_C,TMP_M,TMP_M, TM_MIN,TM,TRow,TCol,0,input_buffer1,NULL,NOP,input_flag,0,0,IHxIW,KxK,IFM_numxKxK,LayerType,WeightQ); reorg_yolo2(input_buffer0,output_buffer,Kernel_size,Kernel_stride,TX_MIN_next[0],TR_MIN,TC_MIN,process_flag); } } } void copy_beta(float beta_buffer[MAX_BETA_LENGTH],int *Beta,const int OFM_NUM,const int BetaQ) { static int beta_tmp[MAX_BETA_LENGTH/2]; int NUM = (OFM_NUM+1)/2; memcpy(beta_tmp,(int *)Beta,NUM*sizeof(int)); int x; for(x = 0;x < NUM;x++) { beta_buffer[2*x] = ((short)(beta_tmp[x]))*pow(2.0,-BetaQ); beta_buffer[2*x+1] = ((short)(beta_tmp[x]>>16))*pow(2.0,-BetaQ); } } void YOLO2_FPGA(float *Input,float *Output,int *Weight,int *Beta,const int InFM_num,const int OutFM_num, const int Kernel_size,const int Kernel_stride, const int Input_w,const int Input_h,const int Padding,const bool IsNL,const bool IsBN, const int TM,const int TN,const int TR,const int TC, const int mLoops,const int nLoops,const int rLoops,const int cLoops,const int LayerType, const int WeightQ,const int BetaQ) { //const int output_w = (Input_w - Kernel_size + 2*Padding)/Kernel_stride + 1 ; //const int output_h = (Input_h - Kernel_size + 2*Padding)/Kernel_stride + 1 ; int output_w = (Input_w - Kernel_size + (Padding << 1))/Kernel_stride + 1 ; int output_h = (Input_h - Kernel_size + (Padding << 1))/Kernel_stride + 1 ; if(LayerType==1) { output_w = (Input_w - 1)/Kernel_stride + 1 ; output_h = (Input_h - 1)/Kernel_stride + 1 ; } const int OHxOW = output_h*output_w; const int TRow = (TR-1)*Kernel_stride+Kernel_size; const int TCol = (TC-1)*Kernel_stride+Kernel_size; const int IHxIW = Input_h*Input_w; const int KxK = Kernel_size*Kernel_size; const int IFM_numxKxK = InFM_num*KxK; const int mLoops_bound = LayerType ? (mLoops + 2): (mLoops + 1); static float input_buffer0[Tn][OnChipIB_Height][OnChipIB_Width]; #pragma HLS ARRAY_PARTITION variable=input_buffer0 complete dim=1 static float input_buffer1[Tn][OnChipIB_Height][OnChipIB_Width]; #pragma HLS ARRAY_PARTITION variable=input_buffer1 complete dim=1 static float output_buffer[Tm][Tr][Tc]; #pragma HLS ARRAY_PARTITION variable=output_buffer complete dim=1 static float output_buffer1[Tm][Tr][Tc]; #pragma HLS ARRAY_PARTITION variable=output_buffer1 complete dim=1 static float beta_buffer[MAX_BETA_LENGTH]; int r,c,m; /////////////////////////////////param int TMP_R,TMP_C,TMP_M; int TM_MIN,TR_MIN,TC_MIN; /////////////////////////////////////// int TMP_M_next0[1]; int TMP_M_next1[1]; int TM_MIN_next0[1]; int TM_MIN_next1[1]; bool pingpongm; if(LayerType==0) copy_beta(beta_buffer,Beta,OutFM_num,BetaQ); for(TMP_R = 0,r = 0; r < rLoops; r++, TMP_R += TR) { TR_MIN = MIN(TR,output_h -TMP_R); for(TMP_C = 0,c = 0; c < cLoops; c++,TMP_C += TC) { TC_MIN = MIN(TC,output_w -TMP_C); pingpongm = 0; for(TMP_M = 0, m = 0; m < mLoops_bound; m++,TMP_M += TM) { TM_MIN = MIN(TM,OutFM_num-TMP_M); bool MneZero = (m!=0); bool MneOne = (m!=1); bool MnemLoops = (m!=mLoops); bool MneMLoopsaddOne = (m!=(mLoops+1)); bool input_flag = LayerType ? MnemLoops&&MneMLoopsaddOne: MnemLoops; bool process_flag = LayerType ? MneZero&&MneMLoopsaddOne : MnemLoops; bool write_flag = LayerType ? MneZero&&MneOne : MneZero; if(pingpongm==0) { intra_pingpong_wrapper(Input,Weight,output_buffer1,beta_buffer,input_buffer0,input_buffer1, InFM_num, Input_w, Input_h, OutFM_num, Kernel_size, Kernel_stride, TMP_R, TMP_C, TMP_M, m, TM_MIN, TR_MIN, TC_MIN, TN, TRow, TCol, Padding,IHxIW,KxK,IFM_numxKxK,nLoops,IsNL,LayerType,TM, TMP_M_next1,TM_MIN_next1, pingpongm, input_flag, process_flag, WeightQ); write_back_output_reorg(output_buffer,Output,TMP_R,TMP_C,TMP_M_next0[0],output_w,output_h,TM_MIN_next0[0],TR_MIN,TC_MIN,OHxOW,write_flag); pingpongm = 1; }else { intra_pingpong_wrapper(Input,Weight,output_buffer,beta_buffer,input_buffer0,input_buffer1, InFM_num, Input_w, Input_h, OutFM_num, Kernel_size, Kernel_stride, TMP_R, TMP_C, TMP_M, m, TM_MIN, TR_MIN, TC_MIN, TN, TRow, TCol, Padding,IHxIW,KxK,IFM_numxKxK,nLoops,IsNL,LayerType,TM, TMP_M_next0,TM_MIN_next0, pingpongm, input_flag, process_flag, WeightQ); write_back_output_reorg(output_buffer1,Output,TMP_R,TMP_C,TMP_M_next1[0],output_w,output_h,TM_MIN_next1[0],TR_MIN,TC_MIN,OHxOW,write_flag); pingpongm = 0; } } } } } #define MIN_VALUE (-1024*1024*1024) #define MAX_VALUE (1024*1024*1024) int quantize(float *in,float *out,int *offset,int layer_num,float *ap16_range,int *maxQ_array) { int i; int offset_index = 0; int woffset = 0; for(i=0;i<layer_num;i++) { if(offset[offset_index]==0) return i; printf("Layer %2d;weight num=%12d ",i,offset[offset_index]); int j; float min,max; min = MAX_VALUE; max = MIN_VALUE; for(j=0;j<offset[offset_index];j++) { float tmp_in_float = in[woffset+j]; if(tmp_in_float<min) min = tmp_in_float; if(tmp_in_float>max) max = tmp_in_float; } printf("float min=%.7lf,max=%.7lf ",min,max);//find float min max int k; int maxQ = -1; for(k=0;k<16;k++)//find maxQ { if(min>ap16_range[2*k]&&max<ap16_range[2*k+1]) { maxQ = k; } else if(k==0) { printf("beyond Q0 min=%.7lf,max=%.7lf ",min,max); break; } } printf("maxQ=%d ",maxQ); maxQ_array[i] = maxQ; double max_error,min_error,sum_error; sum_error = 0; max_error = MIN_VALUE; min_error = MAX_VALUE; for(j=0;j<offset[offset_index];j++) { float tmp_in_float = in[woffset+j]; short tmp_fixed = (short)(tmp_in_float*pow(2.0,maxQ)); float tmp_out_float = (float)tmp_fixed*pow(2.0,-maxQ); double error = (tmp_out_float - tmp_in_float)*(tmp_out_float - tmp_in_float); error = sqrt(error); sum_error += error; if(error<min_error) min_error = error; if(error>max_error) max_error = error; out[woffset+j] = tmp_out_float; } printf("sum2_error = %.7lf,min_error=%.7lf,max_error=%.7lf",sum_error,min_error,max_error); printf("\n"); woffset += offset[offset_index]; offset_index++; } return 0; } void yolov2_hls_ps(network *net, float *input) { int x; network orig = *net; net->input = input; int weight_offset[32] = {864, 18432, 73728, 8192, 73728, 294912, 32768, 294912, 1179648, 131072, 1179648, 131072, 1179648, 4718592, 524288, 4718592, 524288, 4718592, 9437184, 9437184, 32768, 11796480, 435200, 0, 0, 0, 0, 0, 0, 0, 0, 0}; int beta_offset[32] = {32, 64, 128, 64, 128, 256, 128, 256, 512, 256, 512, 256, 512, 1024, 512, 1024, 512, 1024, 1024, 1024, 64, 1024, 425, 0, 0, 0, 0, 0, 0, 0, 0, 0}; int offset_index = 0; int *Weight_buf = (int *)calloc(203767168/4/2,sizeof(int)); int *Beta_buf = (int *)calloc((43044+4)/4/2,sizeof(int)); FILE *fp_w = fopen("weightsv2_comb_reorg_ap16.bin", "rb"); if(!fp_w) file_error("weightsv2_comb_reorg_ap16.bin"); FILE *fp_b = fopen("biasv2_comb_ap16.bin", "rb"); if(!fp_b) file_error("biasv2_comb_ap16.bin"); fread(Weight_buf, sizeof(int), 203767168/4/2, fp_w); fread(Beta_buf, sizeof(int), (43044+4)/4/2, fp_b); fclose(fp_w); fclose(fp_b); #define QNUM 23 short ap16_min = 0x8000; short ap16_max = 0x7fff; printf("ap16_min = %d \nap16_max = %d\n",ap16_min,ap16_max); float ap16_range[16*2]; for(x=0;x<16;x++) { printf("Q%2d:",x); ap16_range[2*x] = (float)ap16_min*pow((float)2,-x);//min ap16_range[2*x+1] = (float)ap16_max*pow((float)2,-x);//max printf("min=%.7lf,max=%.7lf\n",ap16_range[2*x],ap16_range[2*x+1]); } int maxQarray[QNUM+1]; int weightQ[QNUM]; int betaQ[QNUM]; FILE *Qin; Qin = fopen("weightsv2_comb_reorg_ap16_maxQ_23.bin","rb"); if(!Qin) file_error("Qin error 2\n"); fread(weightQ,sizeof(int),QNUM,Qin); fclose(Qin); for(x=0;x<QNUM;x++) printf("[%2d weightQ]=%2d\n",x,weightQ[x]); Qin = fopen("biasv2_comb_ap16_maxQ_23.bin","rb"); if(!Qin) file_error("Qin error 4\n"); fread(betaQ,sizeof(int),QNUM,Qin); fclose(Qin); for(x=0;x<QNUM;x++) printf("[%2d betaQ]=%2d\n",x,betaQ[x]); #define MEM_LEN (416*416*32+208*208*32) float *Memory_buf = (float*)calloc(MEM_LEN+1024+1024,sizeof(float)); float *Memory_top = Memory_buf+1024; float *Memory_bottom = Memory_top + MEM_LEN; //memcpy(Memory_top,input,416*416*3*sizeof(float));//416x416x3 input_pic for(x=0;x<416*416*3;x++)//1st Layer input Q14 { Memory_top[x] = ((short)(input[x]*pow(2.0,14)))*pow(2.0,-14); } float *inout_fixed_buf = (float *)calloc(sizeof(float),416*416*32); maxQarray[0] = 14;//1st layer input Q14 float* in_ptr[32]; float* out_ptr[32]; #define ROUTE16_LEN (26*26*512) #define CONV27_LEN (13*13*256) #define CONV24_LEN (13*13*1024) for(x=0;x<18;x++) { if(x%2==0) { in_ptr[x] = Memory_top; out_ptr[x] = Memory_bottom - net->layers[x].outputs ; } else { in_ptr[x] = out_ptr[x-1]; out_ptr[x] = Memory_top; } } for(x=18;x<25;x++) { if(x%2==0) { in_ptr[x] = Memory_top; out_ptr[x] = Memory_bottom - ROUTE16_LEN - net->layers[x].outputs; }else { in_ptr[x] = out_ptr[x-1]; out_ptr[x] = Memory_top; } } in_ptr[26] = Memory_bottom - ROUTE16_LEN; out_ptr[26] = Memory_top; in_ptr[27] = Memory_top; out_ptr[27] = Memory_bottom - ROUTE16_LEN - CONV24_LEN - CONV27_LEN; in_ptr[29] = out_ptr[27]; out_ptr[29] = Memory_top; in_ptr[30] = Memory_top; out_ptr[30] = Memory_bottom - net->layers[30].outputs; in_ptr[31] = out_ptr[30]; network netp = *net; int i; int woffset = 0; int aoffset = 0; int boffset = 0; int TR,TC,TM,TN; int output_w,output_h; int rLoops,cLoops,mLoops,nLoops; double sum_gop = 0.0; for(i = 0; i < netp.n; ++i) { netp.index = i; layer l = netp.layers[i]; printf("Layer[%2d]: ",i); switch(l.type) { case CONVOLUTIONAL: printf("outputMemory:%8d;BN=%d;Activation=%d;conv %5d %2d x%2d /%2d %4d x%4d x%4d -> %4d x%4d x%4d %5.3f BFLOPs\n",l.outputs,l.batch_normalize,l.activation, l.n, l.size, l.size, l.stride, l.w, l.h, l.c, l.out_w, l.out_h, l.out_c, (2.0 * l.n * l.size*l.size*l.c/l.groups * l.out_h*l.out_w)/1000000000.); sum_gop += (2.0 * l.n * l.size*l.size*l.c/l.groups * l.out_h*l.out_w)/1000000000.; output_w = (l.w - l.size + 2*l.pad)/l.stride + 1 ; output_h = (l.h - l.size + 2*l.pad)/l.stride + 1 ; TR = MIN(((OnChipIB_Height-l.size)/l.stride+1),Tr);//keep Kernel_stride>=1 TR = MIN(output_h,TR); TC = MIN(((OnChipIB_Width-l.size)/l.stride+1),Tc); TC = MIN(output_w,TC); TM = MIN(l.n,Tm); TN = MIN(l.c,Tn); rLoops = (int)ceil(((float)output_h)/TR); cLoops = (int)ceil(((float)output_w)/TC); mLoops = (int)ceil(((float)l.n)/TM); nLoops = (int)ceil(((float)l.c)/TN); YOLO2_FPGA(in_ptr[i],out_ptr[i],Weight_buf+woffset/2,Beta_buf+boffset/2, l.c,l.n,l.size, l.stride,l.w,l.h,l.pad,l.activation==LEAKY?1:0,l.batch_normalize?1:0, TM,TN,TR,TC, mLoops,nLoops,rLoops,cLoops,0, weightQ[offset_index],betaQ[offset_index]); quantize(out_ptr[i],inout_fixed_buf,&l.outputs, 1,ap16_range,&maxQarray[offset_index+1]); memcpy(out_ptr[i],inout_fixed_buf,l.outputs*sizeof(float)); printf("TR=%d,TC=%d,TM=%d,TN=%d,rLoops=%d,cLoops=%d,mLoops=%d,nLoops=%d\n",TR,TC,TM,TN,rLoops,cLoops,mLoops,nLoops); woffset += weight_offset[offset_index]; boffset += beta_offset[offset_index]; offset_index++; break; case MAXPOOL: printf("outputMemory:%8d;max %d x %d / %d %4d x%4d x%4d -> %4d x%4d x%4d\n",l.outputs, l.size, l.size, l.stride, l.w, l.h, l.c, l.out_w, l.out_h, l.out_c); //output_w = (l.w - l.size)/l.stride + 1 ; //output_h = (l.h - l.size)/l.stride + 1 ; output_w = l.out_h; output_h = l.out_w; TR = MIN(((OnChipIB_Height-l.size)/l.stride+1),Tr);//keep Kernel_stride>=1 TC = MIN(((OnChipIB_Width-l.size)/l.stride+1),Tc); TR = MIN(output_h,TR); TC = MIN(output_w,TC); TM = MIN(Tm,Tn); TM = MIN(l.c,TM); rLoops = (int)ceil(((float)output_h)/TR); cLoops = (int)ceil(((float)output_w)/TC); mLoops = (int)ceil(((float)l.c)/TM); YOLO2_FPGA(in_ptr[i],out_ptr[i],NULL,NULL,l.c,l.c, l.size,l.stride,l.w,l.h,l.pad,0,0,TM,0,TR,TC,mLoops,0,rLoops,cLoops,1, 0,0); break; case REORG: printf("outputMemory:%8d;reorg /%2d %4d x%4d x%4d -> %4d x%4d x%4d\n",l.outputs, l.stride, l.w, l.h, l.c, l.out_w, l.out_h, l.out_c); output_w = 26; output_h = 32*13; TR = MIN(((OnChipIB_Height-l.stride)/l.stride+1),Tr);//keep Kernel_stride>=1 TR = MIN(output_h,TR); TC = MIN(((OnChipIB_Width-l.stride)/l.stride+1),Tc); TC = MIN(output_w,TC); TM = 4; rLoops = (int)ceil(((float)output_h)/TR); cLoops = (int)ceil(((float)output_w)/TC); mLoops = 1; YOLO2_FPGA(in_ptr[i],out_ptr[i],NULL,NULL,1,4, l.stride,l.stride,52,32*26,0,0,0,TM,0,TR,TC,mLoops,0,rLoops,cLoops,2, 0,0); break; case ROUTE: printf("outputMemory:%8d;route ",l.outputs); int j; for(j = 0; j < l.n; ++j){ printf(" %d", l.input_layers[j]); } printf("\n"); break; case REGION: printf("outputMemory:%8d;Detection\n",l.outputs); netp.input = in_ptr[i]; forward_region_layer(l,netp); break; } netp.input = l.output; } printf("SUM_GOP=%g\n",sum_gop); *net = orig; for(i=0;i<QNUM+1;i++) { printf("[%2d layer input maxQ]=%2d\n",i,maxQarray[i]); } FILE* fout; char layer_num_string[256]; char s[256]; sprintf(s,"yolov2_ap16_inout_maxQ_%s.bin",itoa(QNUM+1,layer_num_string,10)); printf("%s\n",s); fout = fopen(s,"wb"); if(!fout) printf("fopen %s error\n",s); fwrite(maxQarray,sizeof(int), QNUM+1,fout); fclose(fout); free(Memory_buf); free(Weight_buf); free(Beta_buf); } ///////////////////////////////////////////////////////////////////////20181108 reorg WeightQ BetaQ ok InputQ ok end #endif

GB_binop__bshift_int8.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__bshift_int8) // A.*B function (eWiseMult): GB (_AemultB_01__bshift_int8) // A.*B function (eWiseMult): GB (_AemultB_02__bshift_int8) // A.*B function (eWiseMult): GB (_AemultB_03__bshift_int8) // A.*B function (eWiseMult): GB (_AemultB_bitmap__bshift_int8) // A*D function (colscale): GB ((none)) // D*A function (rowscale): GB ((none)) // C+=B function (dense accum): GB (_Cdense_accumB__bshift_int8) // C+=b function (dense accum): GB (_Cdense_accumb__bshift_int8) // C+=A+B function (dense ewise3): GB ((none)) // C=A+B function (dense ewise3): GB (_Cdense_ewise3_noaccum__bshift_int8) // C=scalar+B GB (_bind1st__bshift_int8) // C=scalar+B' GB (_bind1st_tran__bshift_int8) // C=A+scalar GB (_bind2nd__bshift_int8) // C=A'+scalar GB (_bind2nd_tran__bshift_int8) // C type: int8_t // A type: int8_t // B,b type: int8_t // BinaryOp: cij = GB_bitshift_int8 (aij, bij) #define GB_ATYPE \ int8_t #define GB_BTYPE \ int8_t #define GB_CTYPE \ int8_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) \ int8_t aij = GBX (Ax, pA, A_iso) // bij = Bx [pB] #define GB_GETB(bij,Bx,pB,B_iso) \ int8_t bij = GBX (Bx, pB, B_iso) // declare scalar of the same type as C #define GB_CTYPE_SCALAR(t) \ int8_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_bitshift_int8 (x, y) ; // true if the binop must be flipped #define GB_BINOP_FLIP \ 1 // 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_BSHIFT || GxB_NO_INT8 || GxB_NO_BSHIFT_INT8) //------------------------------------------------------------------------------ // 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 //------------------------------------------------------------------------------ GrB_Info GB (_Cdense_ewise3_noaccum__bshift_int8) ( 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__bshift_int8) ( 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__bshift_int8) ( 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 int8_t int8_t bwork = (*((int8_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 //------------------------------------------------------------------------------ #if 0 GrB_Info GB ((none)) ( 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 int8_t *restrict Cx = (int8_t *) C->x ; #include "GB_AxB_colscale_template.c" return (GrB_SUCCESS) ; #endif } #endif //------------------------------------------------------------------------------ // C = D*B, row scale with diagonal D matrix //------------------------------------------------------------------------------ #if 0 GrB_Info GB ((none)) ( 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 int8_t *restrict Cx = (int8_t *) C->x ; #include "GB_AxB_rowscale_template.c" return (GrB_SUCCESS) ; #endif } #endif //------------------------------------------------------------------------------ // eWiseAdd: C = A+B or C<M> = A+B //------------------------------------------------------------------------------ GrB_Info GB (_AaddB__bshift_int8) ( 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__bshift_int8) ( 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__bshift_int8) ( 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__bshift_int8) ( 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__bshift_int8) ( 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__bshift_int8) ( 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 int8_t *Cx = (int8_t *) Cx_output ; int8_t x = (*((int8_t *) x_input)) ; int8_t *Bx = (int8_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 ; int8_t bij = GBX (Bx, p, false) ; Cx [p] = GB_bitshift_int8 (x, bij) ; } return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // Cx = op (Ax,y): apply a binary operator to a matrix with scalar bind2nd //------------------------------------------------------------------------------ GrB_Info GB (_bind2nd__bshift_int8) ( 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 ; int8_t *Cx = (int8_t *) Cx_output ; int8_t *Ax = (int8_t *) Ax_input ; int8_t y = (*((int8_t *) y_input)) ; #pragma omp parallel for num_threads(nthreads) schedule(static) for (p = 0 ; p < anz ; p++) { if (!GBB (Ab, p)) continue ; int8_t aij = GBX (Ax, p, false) ; Cx [p] = GB_bitshift_int8 (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) \ { \ int8_t aij = GBX (Ax, pA, false) ; \ Cx [pC] = GB_bitshift_int8 (x, aij) ; \ } GrB_Info GB (_bind1st_tran__bshift_int8) ( 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 \ int8_t #if GB_DISABLE return (GrB_NO_VALUE) ; #else int8_t x = (*((const int8_t *) x_input)) ; #include "GB_unop_transpose.c" return (GrB_SUCCESS) ; #endif #undef GB_ATYPE #define GB_ATYPE \ int8_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) \ { \ int8_t aij = GBX (Ax, pA, false) ; \ Cx [pC] = GB_bitshift_int8 (aij, y) ; \ } GrB_Info GB (_bind2nd_tran__bshift_int8) ( 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 int8_t y = (*((const int8_t *) y_input)) ; #include "GB_unop_transpose.c" return (GrB_SUCCESS) ; #endif } #endif

reconstruction.h

/* Multi-view Image Restoration "Multi-view Image Restoration From Plenoptic Raw Images" Shan Xu, Zhi-Liang Zhou and Nicholas Devaney In Asian Conference on Computer Vision 2014 Emerging Topics In Image Restoration and Enhancement workshop Author: Shan Xu <xushan2011@gmail.com> Copyright (C) 2014-2018 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. 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. */ #ifndef _RECONSTRUCTION #define _RECONSTRUCTION #include <opencv2/opencv.hpp> #include "config.h" #include "misc.h" using namespace std; using namespace cv; unsigned short bilinear(unsigned short* data, float index_y, float index_x, int W){ float value; float cof[4]; float a,b,c,d; int y = int(index_y); int x = int(index_x); int base = y*W+x; a = data[base]; b = data[base+1]; c = data[base+W]; d = data[base+W+1]; cof[0]=(1-(index_y-y))*(1-(index_x-x)); cof[1]=(1-(index_y-y))*(index_x-x); cof[2]= (index_y-y)*(1-(index_x-x)); cof[3]= (index_y-y)*(index_x-x); value= (cof[0]*a+cof[1]*b+cof[2]*c+cof[3]*d); return (unsigned short) value; } bool grad_difference (unsigned short* img, size_t j, size_t i, int WHST, size_t IMG_W, size_t T,size_t S, int m, int n){ int ii = ((j%2)==0) ? (i-1)/2 : i/2; int c = ((j%2)==0) ? 2 : 0; //ugly implementation float grad_x_max=0; float grad_y_max=0; for (int k=0; k<3; k++){ float grad_x = abs( img[k*WHST+(j*T+m)*IMG_W*S+ii*S+n]- img[k*WHST+(j*T+m)*IMG_W*S+(ii-1+c)*S+n]); if (grad_x>grad_x_max) grad_x_max = grad_x; float grad_y = abs( img[k*WHST+((j-1)*T+m)*IMG_W*S+(ii)*S+n]- img[k*WHST+((j+1)*T+m)*IMG_W*S+(ii)*S+n]); if (grad_y>grad_y_max) grad_y_max = grad_y; } bool value = ((4*grad_y_max < grad_x_max)?true:false); return value; } void devig_simple(Mat raw, Mat raw_ref, Mat& rawc){ unsigned short *rawc_ptr = (unsigned short*) rawc.data; Mat img, img2; raw_ref.convertTo(img, CV_32F); raw.convertTo(img2, CV_32F); Scalar mean,stddev; //float min= int(percentage2value ((float*) img.data, img.total(), 0.001));//<<endl; //float max= int(percentage2value ((float*) img.data, img.total(), 0.999));//<<endl; clamp_normalize_mat( (float*) img.data, img.total(), 4095.0); meanStdDev(img,mean,stddev,cv::Mat()); //float mean50= percentage2value ((float*) img.data, img.total(), 0.50);//<<endl; gen_vig_mat((float*) img.data, img.total(), mean.val[0]); devig((float*) img2.data, (float*) img.data, img.total()); double min, max; minMaxLoc(img2, &min, &max); gamma(rawc_ptr, (float*) img2.data, 4095, 0.50, img2.total()); } void decode(Mat img_colour, Mat& multiview, GRID grid, PARA para){ size_t IMG_W = para.ML_W*2; //final image is 2 times larger due to hexgonal interpolation size_t IMG_H = para.ML_H; size_t ML_W = para.ML_W; size_t ML_H = para.ML_H; size_t S = para.S; size_t T = para.T; int WHST = IMG_W*IMG_H*S*T; unsigned short* lf_buf = new unsigned short[3*WHST]; unsigned short *multiview_buf = new unsigned short[3*WHST]; multiview = Mat::zeros(IMG_H*T, IMG_W*S, CV_16UC3); Mat bgr[3]; //destination array split(img_colour,bgr);//split source //4D array registration #pragma omp parallel for for (size_t j=0; j<ML_H; j++){ for (size_t i=0; i<ML_W; i++){ float index_y,index_x; if (grid.pt_dst2.size()>0){ index_y= grid.pt_dst2[j*ML_W+i].y; //_dst2 index_x= grid.pt_dst2[j*ML_W+i].x; } else{ index_y= grid.pt_dst1[j*ML_W+i].y; //pt2 index_x= grid.pt_dst1[j*ML_W+i].x; } int ix = int (index_x); int iy = int (index_y); Mat subimg; for (int k=0; k<3; k++){ resize(bgr[k](Rect(ix-5,iy-5,11,11)),subimg,Size(),4,4, INTER_CUBIC); //cout<<subimg<<endl; int idx_new = 22+int(4*(index_x-ix)); int idy_new = 22+int(4*(index_y-iy)); for (int m=-4; m<5; m++) for (int n=-4; n<5; n++){ int temp_index = (j*T+(m+4))*ML_W*S + i*S + (n+4); lf_buf[temp_index+ k*WHST/2] = subimg.at<unsigned short>(idy_new+4*m, idx_new+4*n); } } } } bool grad_h_v; //cout<<"=============================================="<<endl; for (size_t j=1; j<(IMG_H-1); j++){ for (size_t i=1; i<(IMG_W-1); i++){ if ((j%2)==0){ // o x o x o x if ((i%2)==1){ // interpolate for (size_t m=0; m<T; m++){ for (size_t n=0; n<S; n++){ grad_h_v= grad_difference (lf_buf, j, i, WHST/2, ML_W, T, S, m, n); for (size_t k=0; k<3; k++){ multiview_buf[k*WHST+(j*T+m)*IMG_W*S+i*S+n] = grad_h_v? (lf_buf[k*WHST/2+((j-1)*T+m)*ML_W*S+(i-1)/2*S+n] +lf_buf[k*WHST/2+((j+1)*T+m)*ML_W*S+(i-1)/2*S+n])/2: ( lf_buf[k*WHST/2+(j*T+m)*ML_W*S+(i-1)/2*S+n] +lf_buf[k*WHST/2+(j*T+m)*ML_W*S+(i+1)/2*S+n])/2; } } } } else{ for (size_t m=0; m<T; m++){ for (size_t n=0; n<S; n++){ for (size_t k=0; k<3; k++){ multiview_buf[k*WHST+(j*T+m)*IMG_W*S+i*S+n] = lf_buf[k*WHST/2+(j*T+m)*ML_W*S+(i/2)*S+n]; } } } } } else{ // x o x o x o if((i%2)==0){ //interpolate for (size_t m=0; m<T; m++){ for (size_t n=0; n<S; n++){ grad_h_v= grad_difference (lf_buf,j,i,WHST/2,ML_W,T,S,m,n); for(size_t k=0; k<3; k++){ multiview_buf[k*WHST+(j*T+m)*IMG_W*S+i*S+n] = grad_h_v? (lf_buf[k*WHST/2+((j-1)*T+m)*ML_W*S+i/2*S+n] +lf_buf[k*WHST/2+((j+1)*T+m)*ML_W*S+i/2*S+n])/2: (lf_buf[k*WHST/2+(j*T+m)*ML_W*S+(i/2-1)*S+n] +lf_buf[k*WHST/2+(j*T+m)*ML_W*S+i/2*S+n])/2; } } } } else{ //copy for (size_t m=0; m<T; m++){ for (size_t n=0; n<S; n++){ for(size_t k=0; k<3; k++){ multiview_buf[k*WHST+(j*T+m)*IMG_W*S+i*S+n] = lf_buf[k*WHST/2+(j*T+m)*ML_W*S+(i-1)/2*S+n]; } } } } } } } //ml array->multiview for (size_t j=0; j<IMG_H; j++){ for (size_t i=0; i<IMG_W; i++){ for (size_t m=0; m<T; m++){ for (size_t n=0; n<S; n++){ int index_2=(j*T+m)*IMG_W*S + i*S+n; multiview.at<Vec3w>(m*IMG_H+j, n*IMG_W +i) = Vec3w(multiview_buf[index_2],multiview_buf[WHST+index_2],multiview_buf[2*WHST+index_2]); //if ((multiview_buf[2*WHST+index_2]==212)&&(multiview_buf[WHST+index_2]==67)) // cout<<j<<" "<<i<<" "<<m<<" "<<n<<endl; } } } } } #endif

timer.h

#ifndef SPLATT_TIMER_H #define SPLATT_TIMER_H /****************************************************************************** * INCLUDES *****************************************************************************/ #include <time.h> #include <stddef.h> #include <stdbool.h> #ifdef __MACH__ #include <mach/mach.h> #include <mach/mach_time.h> #endif /****************************************************************************** * STRUCTURES *****************************************************************************/ /** * @brief Represents a wall-clock timer. */ typedef struct { bool running; double seconds; double start; double stop; } sp_timer_t; /** * @brief timer_id provides easy indexing into timers[]. */ typedef enum { TIMER_LVL0, /* LEVEL 0 */ TIMER_ALL, TIMER_CPD, TIMER_REORDER, TIMER_CONVERT, TIMER_LVL1, /* LEVEL 1 */ TIMER_MTTKRP, TIMER_ADMM, TIMER_CHOLESKY, TIMER_BACKSOLVE, TIMER_INV, TIMER_FIT, TIMER_MATMUL, TIMER_ATA, TIMER_MATNORM, TIMER_IO, TIMER_PART, TIMER_LVL2, /* LEVEL 2 */ #ifdef SPLATT_USE_MPI TIMER_MPI, TIMER_MPI_IDLE, TIMER_MPI_COMM, TIMER_MPI_ATA, TIMER_MPI_REDUCE, TIMER_MPI_PARTIALS, TIMER_MPI_NORM, TIMER_MPI_UPDATE, TIMER_MPI_FIT, /* timer max */ TIMER_MTTKRP_MAX, TIMER_MPI_MAX, TIMER_MPI_IDLE_MAX, TIMER_MPI_COMM_MAX, #endif TIMER_SPLATT, TIMER_GIGA, TIMER_DFACTO, TIMER_TTBOX, TIMER_SORT, TIMER_TILE, TIMER_MISC, TIMER_NTIMERS /* LEVEL N */ } timer_id; /* globals */ extern int timer_lvl; extern sp_timer_t timers[TIMER_NTIMERS]; /****************************************************************************** * PUBLIC FUNCTIONS *****************************************************************************/ #define init_timers splatt_init_timers /** * @brief Call timer_reset() on all of timers[]. */ void init_timers(void); #define report_times splatt_report_times /** * @brief Output a summary of all used timers. */ void report_times(void); #define timer_inc_verbose splatt_timer_inc_verbose /** * @brief Increment timer verbosity to the next level; */ void timer_inc_verbose(void); /** * @brief Return the number of seconds since an unspecified time (e.g., Unix * epoch). This is accomplished with a high-resolution monotonic timer, * suitable for performance timing. * * @return The number of seconds. */ static inline double monotonic_seconds() { #ifdef __MACH__ /* OSX */ static mach_timebase_info_data_t info; static double seconds_per_unit; if(seconds_per_unit == 0) { #pragma omp critical { mach_timebase_info(&info); seconds_per_unit = (info.numer / info.denom) / 1e9; } } return seconds_per_unit * mach_absolute_time(); #else /* Linux systems */ struct timespec ts; clock_gettime(CLOCK_MONOTONIC, &ts); return ts.tv_sec + ts.tv_nsec * 1e-9; #endif } /** * @brief Reset all fields of a sp_timer_t. * * @param timer The timer to reset. */ static inline void timer_reset(sp_timer_t * const timer) { timer->running = false; timer->seconds = 0; timer->start = 0; timer->stop = 0; } /** * @brief Start a sp_timer_t. NOTE: this does not reset the timer. * * @param timer The timer to start. */ static inline void timer_start(sp_timer_t * const timer) { if(!timer->running) { timer->running = true; timer->start = monotonic_seconds(); } } /** * @brief Stop a sp_timer_t and update its time. * * @param timer The timer to stop. */ static inline void timer_stop(sp_timer_t * const timer) { timer->running = false; timer->stop = monotonic_seconds(); timer->seconds += timer->stop - timer->start; } /** * @brief Give a sp_timer_t a fresh start by resetting and starting it. * * @param timer The timer to refresh. */ static inline void timer_fstart(sp_timer_t * const timer) { timer_reset(timer); timer_start(timer); } #endif

md5_bmark-par.c

/* * MD5 Benchmark * ------------- * File: md5_bmark.c * * This is the main file for the md5 benchmark kernel. This benchmark was * written as part of the StarBENCH benchmark suite at TU Berlin. It performs * MD5 computation on a number of self-generated input buffers in parallel, * automatically measuring execution time. * * Copyright (C) 2011 Michael Andersch * * 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 3 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, see <http://www.gnu.org/licenses/>. * */ #include <stdio.h> #include <stdlib.h> #include <stdint.h> #include <unistd.h> #include <string.h> #include <sys/time.h> #include <omp.h> #include "md5.h" #include "md5_bmark.h" typedef struct timeval timer; #define TIME(x) gettimeofday(&x, NULL) /* Function declarations */ int initialize(md5bench_t* args); int finalize(md5bench_t* args); void run(md5bench_t* args); void process(uint8_t* in, uint8_t* out, int bufsize); void listInputs(); long timediff(timer* starttime, timer* finishtime); // Input configurations static data_t datasets[] = { {64, 512, 0}, {64, 1024, 0}, {64, 2048, 0}, {64, 4096, 0}, {128, 1024*512, 1}, {128, 1024*1024, 1}, {128, 1024*2048, 1}, {128, 1024*4096, 1}, }; int nt_global; /* * Function: initialize * -------------------- * To initialize the benchmark parameters. Generates the input buffers from random data. */ int initialize(md5bench_t* args) { int index = args->input_set; if(index < 0 || index >= sizeof(datasets)/sizeof(datasets[0])) { fprintf(stderr, "Invalid input set specified! Clamping to set 0\n"); index = 0; } args->numinputs = datasets[index].numbufs; args->size = datasets[index].bufsize; args->inputs = (uint8_t**)calloc(args->numinputs, sizeof(uint8_t*)); args->out = (uint8_t*)calloc(args->numinputs, DIGEST_SIZE); if(args->inputs == NULL || args->out == NULL) { fprintf(stderr, "Memory Allocation Error\n"); return -1; } //fprintf(stderr, "Reading input set: %d buffers, %d bytes per buffer\n", datasets[index].numbufs, datasets[index].bufsize); // Now the input buffers need to be generated, for replicability, use same seed srand(datasets[index].rseed); for(int i = 0; i < args->numinputs; i++) { args->inputs[i] = (uint8_t*)malloc(sizeof(uint8_t)*datasets[index].bufsize); uint8_t* p = args->inputs[i]; if(p == NULL) { fprintf(stderr, "Memory Allocation Error\n"); return -1; } for(int j = 0; j < datasets[index].bufsize; j++) *p++ = rand() % 255; } return 0; } /* * Function: process * ----------------- * Processes one input buffer, delivering the digest into out. */ void process(uint8_t* in, uint8_t* out, int bufsize) { MD5_CTX context; uint8_t digest[16]; MD5_Init(&context); MD5_Update(&context, in, bufsize); MD5_Final(digest, &context); memcpy(out, digest, DIGEST_SIZE); } /* * Function: run * -------------------- * Main benchmarking function. If called, processes buffers with MD5 * until no more buffers available. The resulting message digests * are written into consecutive locations in the preallocated output * buffer. */ void run(md5bench_t* args) { #pragma omp parallel num_threads(nt_global) for(int i = 0; i < args->iterations; i++) { int buffers_to_process = args->numinputs; int next = 0; uint8_t** in = args->inputs; uint8_t* out = args->out; #pragma omp single nowait while(buffers_to_process > 0) { uint8_t* aux = out+next*DIGEST_SIZE; #pragma omp task depend(in: in[next:1]) depend(out: aux) process(in[next], aux, args->size); next++; buffers_to_process--; } #pragma omp taskwait } } /* * Function: finalize * ------------------ * Cleans up memory used by the benchmark for input and output buffers. */ int finalize(md5bench_t* args) { char buffer[64]; int offset = 0; for(int i = 0; i < args->numinputs; i++) { #ifdef DEBUG sprintf(buffer, "Buffer %d has checksum ", i); fwrite(buffer, sizeof(char), strlen(buffer)+1, stdout); #endif for(int j = 0; j < DIGEST_SIZE*2; j+=2) { sprintf(buffer+j, "%x", args->out[DIGEST_SIZE*i+j/2] & 0xf); sprintf(buffer+j+1, "%x", args->out[DIGEST_SIZE*i+j/2] & 0xf0); } buffer[32] = '\0'; #ifdef DEBUG fwrite(buffer, sizeof(char), 32, stdout); fputc('\n', stdout); #else printf("%s ", buffer); #endif } #ifndef DEBUG printf("\n"); #endif if(args->inputs) { for(int i = 0; i < args->numinputs; i++) { if(args->inputs[i]) free(args->inputs[i]); } free(args->inputs); } if(args->out) free(args->out); return 0; } /* * Function: timediff * ------------------ * Compute the difference between timers starttime and finishtime in msecs. */ long timediff(timer* starttime, timer* finishtime) { long msec; msec=(finishtime->tv_sec-starttime->tv_sec)*1000; msec+=(finishtime->tv_usec-starttime->tv_usec)/1000; return msec; } /** MAIN **/ int main(int argc, char** argv) { timer b_start, b_end; md5bench_t args; //nt = number of threads int nt; //Receber parâmetros scanf("%d", &nt); scanf("%d", &args.input_set); scanf("%d", &args.iterations); args.outflag = 1; nt_global = nt; // Parameter initialization if(initialize(&args)) { fprintf(stderr, "Initialization Error\n"); exit(EXIT_FAILURE); } TIME(b_start); run(&args); TIME(b_end); // Free memory if(finalize(&args)) { fprintf(stderr, "Finalization Error\n"); exit(EXIT_FAILURE); } double b_time = (double)timediff(&b_start, &b_end)/1000; printf("%.3f\n", b_time); return 0; }

zip_fmt_plug.c

/* * ZIP cracker patch for JtR. Hacked together during June of 2011 * by Dhiru Kholia <dhiru.kholia at gmail.com> for GSoC. * * This software is Copyright (c) 2011, 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. * * http://www.winzip.com/aes_info.htm (There is a 1 in 65,536 chance that an * incorrect password will yield a matching verification value; therefore, a * matching verification value cannot be absolutely relied on to indicate a * correct password.). The alternative is to implement/use a full unzip engine. * * This format significantly improved, Summer of 2014, JimF. Changed the signature * to the $zip2$, and added logic to properly make this format work. Now there is no * false positives any more. Now it properly cracks the passwords. There is * an hmac-sha1 'key' that is also processed (and the decryption key), in the pbkdf2 * call. Now we use this hmac-sha1 key, process the compressed and encrypted buffer, * compare to a 10 byte checksum (which is now the binary blob), and we KNOW that we * have cracked or not cracked the key. The $zip$ was broken before, so that signature * has simply been retired as DOA. This format is now much like the pkzip format. * it may have all data contained within the hash string, OR it may have some, and * have a file pointer on where to get the rest of the data. * * optimizations still that can be done. * 1. decrypt and inflate some data for really large buffers, BEFORE doing the * hmac-sha1 call. The inflate algorithm is pretty self checking for 'valid' * data, so a few hundred bytes of checking and we are 99.999% sure we have the * right password, before starting an expensive hmac (for instance if the zip blob * was 50mb). * 2. Put in the 'file magic' logic we have for pkzip. There is a place holder for it, * but the logic has not been added. */ #if FMT_EXTERNS_H extern struct fmt_main fmt_zip; #elif FMT_REGISTERS_H john_register_one(&fmt_zip); #else #include <string.h> #include <assert.h> #include <errno.h> #include <ctype.h> #include "arch.h" #include "crc32.h" #include "misc.h" #include "params.h" #include "common.h" #include "formats.h" #include "johnswap.h" #include "memory.h" #include "pkzip.h" #include "pbkdf2_hmac_sha1.h" #include "dyna_salt.h" #ifdef _OPENMP #include <omp.h> #ifndef OMP_SCALE #define OMP_SCALE 1 // Tuned on core i7 #endif static int omp_t = 1; #endif #include "hmac_sha.h" #include "memdbg.h" #define KEY_LENGTH(mode) (8 * ((mode) & 3) + 8) #define SALT_LENGTH(mode) (4 * ((mode) & 3) + 4) typedef struct my_salt_t { dyna_salt dsalt; uint32_t comp_len; struct { uint16_t type : 4; uint16_t mode : 4; } v; unsigned char passverify[2]; unsigned char salt[SALT_LENGTH(3)]; //uint64_t data_key; // MSB of md5(data blob). We lookup using this. unsigned char datablob[1]; } my_salt; #define FORMAT_LABEL "ZIP" #define FORMAT_NAME "WinZip" #ifdef SIMD_COEF_32 #define ALGORITHM_NAME "PBKDF2-SHA1 " SHA1_ALGORITHM_NAME #else #define ALGORITHM_NAME "PBKDF2-SHA1 32/" ARCH_BITS_STR #endif #define PLAINTEXT_LENGTH 125 #define BINARY_ALIGN sizeof(ARCH_WORD_32) #define SALT_SIZE sizeof(my_salt*) #define SALT_ALIGN sizeof(my_salt*) #ifdef SIMD_COEF_32 #define MIN_KEYS_PER_CRYPT SSE_GROUP_SZ_SHA1 #define MAX_KEYS_PER_CRYPT SSE_GROUP_SZ_SHA1 #else #define MIN_KEYS_PER_CRYPT 1 #define MAX_KEYS_PER_CRYPT 1 #endif static char (*saved_key)[PLAINTEXT_LENGTH + 1]; static unsigned char (*crypt_key)[((WINZIP_BINARY_SIZE+3)/4)*4]; static my_salt *saved_salt; // filename:$zip2$*Ty*Mo*Ma*Sa*Va*Le*DF*Au*$/zip2$ // Ty = type (0) and ignored. // Mo = mode (1 2 3 for 128/192/256 bit // Ma = magic (file magic). This is reserved for now. See pkzip_fmt_plug.c or zip2john.c for information. // For now, this must be a '0' // Sa = salt(hex). 8, 12 or 16 bytes of salt (depends on mode) // Va = Verification bytes(hex) (2 byte quick checker) // Le = real compr len (hex) length of compressed/encrypted data (field DF) // DF = compressed data DF can be L*2 hex bytes, and if so, then it is the ENTIRE file blob written 'inline'. // However, if the data blob is too long, then a .zip ZIPDATA_FILE_PTR_RECORD structure will be the 'contents' of DF // Au = Authentication code (hex) a 10 byte hex value that is the hmac-sha1 of data over D. This is the binary() value // ZIPDATA_FILE_PTR_RECORD (this can be the 'DF' of this above hash line. // *ZFILE*Fn*Oh*Ob* (Note, the leading and trailing * are the * that 'wrap' the DF object. // ZFILE This is the literal string ZFILE // Fn This is the name of the .zip file. NOTE the user will need to keep the .zip file in proper locations (same as // was seen when running zip2john. If the file is removed, this hash line will no longer be valid. // Oh Offset to the zip central header record for this blob. // Ob Offset to the start of the blob data static void init(struct fmt_main *self) { #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(self->params.max_keys_per_crypt, sizeof(*saved_key)); crypt_key = mem_calloc(self->params.max_keys_per_crypt, sizeof(*crypt_key)); } static void done(void) { MEM_FREE(crypt_key); MEM_FREE(saved_key); } static void *get_salt(char *ciphertext) { int i; my_salt salt, *psalt; static unsigned char *ptr; /* extract data from "ciphertext" */ c8 *copy_mem = strdup(ciphertext); c8 *cp, *p; if (!ptr) ptr = mem_alloc_tiny(sizeof(my_salt*),sizeof(my_salt*)); p = copy_mem + WINZIP_TAG_LENGTH+1; /* skip over "$zip2$*" */ memset(&salt, 0, sizeof(salt)); cp = strtokm(p, "*"); // type salt.v.type = atoi((const char*)cp); cp = strtokm(NULL, "*"); // mode salt.v.mode = atoi((const char*)cp); cp = strtokm(NULL, "*"); // file_magic enum (ignored) cp = strtokm(NULL, "*"); // salt for (i = 0; i < SALT_LENGTH(salt.v.mode); i++) salt.salt[i] = (atoi16[ARCH_INDEX(cp[i<<1])]<<4) | atoi16[ARCH_INDEX(cp[(i<<1)+1])]; cp = strtokm(NULL, "*"); // validator salt.passverify[0] = (atoi16[ARCH_INDEX(cp[0])]<<4) | atoi16[ARCH_INDEX(cp[1])]; salt.passverify[1] = (atoi16[ARCH_INDEX(cp[2])]<<4) | atoi16[ARCH_INDEX(cp[3])]; cp = strtokm(NULL, "*"); // data len sscanf((const char *)cp, "%x", &salt.comp_len); // later we will store the data blob in our own static data structure, and place the 64 bit LSB of the // MD5 of the data blob into a field in the salt. For the first POC I store the entire blob and just // make sure all my test data is small enough to fit. cp = strtokm(NULL, "*"); // data blob // Ok, now create the allocated salt record we are going to return back to John, using the dynamic // sized data buffer. psalt = (my_salt*)mem_calloc(1, sizeof(my_salt) + salt.comp_len); psalt->v.type = salt.v.type; psalt->v.mode = salt.v.mode; psalt->comp_len = salt.comp_len; psalt->dsalt.salt_alloc_needs_free = 1; // we used mem_calloc, so JtR CAN free our pointer when done with them. memcpy(psalt->salt, salt.salt, sizeof(salt.salt)); psalt->passverify[0] = salt.passverify[0]; psalt->passverify[1] = salt.passverify[1]; // set the JtR core linkage stuff for this dyna_salt psalt->dsalt.salt_cmp_offset = SALT_CMP_OFF(my_salt, comp_len); psalt->dsalt.salt_cmp_size = SALT_CMP_SIZE(my_salt, comp_len, datablob, psalt->comp_len); if (strcmp((const char*)cp, "ZFILE")) { for (i = 0; i < psalt->comp_len; i++) psalt->datablob[i] = (atoi16[ARCH_INDEX(cp[i<<1])]<<4) | atoi16[ARCH_INDEX(cp[(i<<1)+1])]; } else { c8 *Fn, *Oh, *Ob; long len; uint32_t id; FILE *fp; Fn = strtokm(NULL, "*"); Oh = strtokm(NULL, "*"); Ob = strtokm(NULL, "*"); fp = fopen((const char*)Fn, "rb"); if (!fp) { psalt->v.type = 1; // this will tell the format to 'skip' this salt, it is garbage goto Bail; } sscanf((const char*)Oh, "%lx", &len); if (fseek(fp, len, SEEK_SET)) { fclose(fp); psalt->v.type = 1; goto Bail; } id = fget32LE(fp); if (id != 0x04034b50U) { fclose(fp); psalt->v.type = 1; goto Bail; } sscanf((const char*)Ob, "%lx", &len); if (fseek(fp, len, SEEK_SET)) { fclose(fp); psalt->v.type = 1; goto Bail; } if (fread(psalt->datablob, 1, psalt->comp_len, fp) != psalt->comp_len) { fclose(fp); psalt->v.type = 1; goto Bail; } fclose(fp); } Bail:; MEM_FREE(copy_mem); memcpy(ptr, &psalt, sizeof(my_salt*)); return (void*)ptr; } static void set_salt(void *salt) { saved_salt = *((my_salt**)salt); } static void set_key(char *key, int index) { int saved_len = strlen(key); if (saved_len > PLAINTEXT_LENGTH) saved_len = PLAINTEXT_LENGTH; memcpy(saved_key[index], key, saved_len); saved_key[index][saved_len] = 0; } static char *get_key(int index) { return saved_key[index]; } static int get_hash_0(int index) { return ((ARCH_WORD_32*)&(crypt_key[index]))[0] & PH_MASK_0; } static int get_hash_1(int index) { return ((ARCH_WORD_32*)&(crypt_key[index]))[0] & PH_MASK_1; } static int get_hash_2(int index) { return ((ARCH_WORD_32*)&(crypt_key[index]))[0] & PH_MASK_2; } static int get_hash_3(int index) { return ((ARCH_WORD_32*)&(crypt_key[index]))[0] & PH_MASK_3; } static int get_hash_4(int index) { return ((ARCH_WORD_32*)&(crypt_key[index]))[0] & PH_MASK_4; } static int get_hash_5(int index) { return ((ARCH_WORD_32*)&(crypt_key[index]))[0] & PH_MASK_5; } static int get_hash_6(int index) { return ((ARCH_WORD_32*)&(crypt_key[index]))[0] & PH_MASK_6; } static int crypt_all(int *pcount, struct db_salt *salt) { int count = *pcount; int index; if (saved_salt->v.type) { // This salt passed valid() but failed get_salt(). // Should never happen. memset(crypt_key, 0, count * WINZIP_BINARY_SIZE); return count; } #ifdef _OPENMP #pragma omp parallel for default(none) private(index) shared(count, saved_key, saved_salt, crypt_key) #endif for (index = 0; index < count; index += MAX_KEYS_PER_CRYPT) { #ifdef SIMD_COEF_32 unsigned char pwd_ver[(2+64)*MAX_KEYS_PER_CRYPT]; int lens[MAX_KEYS_PER_CRYPT], i; unsigned char *pin[MAX_KEYS_PER_CRYPT], *pout[MAX_KEYS_PER_CRYPT]; for (i = 0; i < MAX_KEYS_PER_CRYPT; ++i) { lens[i] = strlen(saved_key[i+index]); pin[i] = (unsigned char*)saved_key[i+index]; pout[i] = &pwd_ver[i*(2+2*KEY_LENGTH(saved_salt->v.mode))]; } pbkdf2_sha1_sse((const unsigned char **)pin, lens, saved_salt->salt, SALT_LENGTH(saved_salt->v.mode), KEYING_ITERATIONS, pout, 2+2*KEY_LENGTH(saved_salt->v.mode), 0); for (i = 0; i < MAX_KEYS_PER_CRYPT; ++i) { if (!memcmp(&(pout[i][KEY_LENGTH(saved_salt->v.mode)<<1]), saved_salt->passverify, 2)) { hmac_sha1(&(pout[i][KEY_LENGTH(saved_salt->v.mode)]), KEY_LENGTH(saved_salt->v.mode), (const unsigned char*)saved_salt->datablob, saved_salt->comp_len, crypt_key[index+i], WINZIP_BINARY_SIZE); } else memset(crypt_key[index+i], 0, WINZIP_BINARY_SIZE); } #else int LEN = 2+2*KEY_LENGTH(saved_salt->v.mode); union { unsigned char pwd_ver[4+64]; ARCH_WORD_32 w; } x; unsigned char *pwd_ver = x.pwd_ver; pbkdf2_sha1((unsigned char *)saved_key[index], strlen(saved_key[index]), saved_salt->salt, SALT_LENGTH(saved_salt->v.mode), KEYING_ITERATIONS, pwd_ver, LEN, 0); if (!memcmp(&(pwd_ver[KEY_LENGTH(saved_salt->v.mode)<<1]), saved_salt->passverify, 2)) { hmac_sha1(&(pwd_ver[KEY_LENGTH(saved_salt->v.mode)]), KEY_LENGTH(saved_salt->v.mode), (const unsigned char*)saved_salt->datablob, saved_salt->comp_len, crypt_key[index], WINZIP_BINARY_SIZE); } else memset(crypt_key[index], 0, WINZIP_BINARY_SIZE); #endif } return count; } static int cmp_all(void *binary, int count) { int i; for (i = 0; i < count; i++) if (((ARCH_WORD_32*)&(crypt_key[i]))[0] == ((ARCH_WORD_32*)binary)[0]) return 1; return 0; } static int cmp_one(void *binary, int index) { return (((ARCH_WORD_32*)&(crypt_key[index]))[0] == ((ARCH_WORD_32*)binary)[0]); } static int cmp_exact(char *source, int index) { void *b = winzip_common_binary(source); return !memcmp(b, crypt_key[index], sizeof(crypt_key[index])); } struct fmt_main fmt_zip = { { FORMAT_LABEL, FORMAT_NAME, ALGORITHM_NAME, WINZIP_BENCHMARK_COMMENT, WINZIP_BENCHMARK_LENGTH, 0, PLAINTEXT_LENGTH, 4, // WINZIP_BINARY_SIZE, BINARY_ALIGN, SALT_SIZE, SALT_ALIGN, MIN_KEYS_PER_CRYPT, MAX_KEYS_PER_CRYPT, FMT_CASE | FMT_8_BIT | FMT_OMP | FMT_DYNA_SALT, { NULL }, winzip_common_tests }, { init, done, fmt_default_reset, fmt_default_prepare, winzip_common_valid, fmt_default_split, winzip_common_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 }, fmt_default_dyna_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 */

omp2.c

// RUN: mlir-clang %s --function=* -fopenmp -S | FileCheck %s void square2(double** x, int sstart, int send, int sinc, int tstart, int tend, int tinc) { #pragma omp parallel for collapse(2) for(int i=sstart; i < send; i+= sinc) { for(int j=tstart; j < tend; j+= tinc) { x[i][j] = i + j; } } } // CHECK: func @square2(%arg0: memref<?xmemref<?xf64>>, %arg1: i32, %arg2: i32, %arg3: i32, %arg4: i32, %arg5: i32, %arg6: i32) attributes {llvm.linkage = #llvm.linkage<external>} { // CHECK-NEXT: %c-1_i32 = arith.constant -1 : i32 // CHECK-NEXT: %0 = arith.index_cast %arg1 : i32 to index // CHECK-NEXT: %1 = arith.index_cast %arg4 : i32 to index // CHECK-NEXT: %2 = arith.subi %arg2, %arg1 : i32 // CHECK-NEXT: %3 = arith.addi %2, %c-1_i32 : i32 // CHECK-NEXT: %4 = arith.addi %3, %arg3 : i32 // CHECK-NEXT: %5 = arith.divui %4, %arg3 : i32 // CHECK-NEXT: %6 = arith.muli %5, %arg3 : i32 // CHECK-NEXT: %7 = arith.addi %arg1, %6 : i32 // CHECK-NEXT: %8 = arith.index_cast %7 : i32 to index // CHECK-NEXT: %9 = arith.subi %arg5, %arg4 : i32 // CHECK-NEXT: %10 = arith.addi %9, %c-1_i32 : i32 // CHECK-NEXT: %11 = arith.addi %10, %arg6 : i32 // CHECK-NEXT: %12 = arith.divui %11, %arg6 : i32 // CHECK-NEXT: %13 = arith.muli %12, %arg6 : i32 // CHECK-NEXT: %14 = arith.addi %arg4, %13 : i32 // CHECK-NEXT: %15 = arith.index_cast %14 : i32 to index // CHECK-NEXT: %16 = arith.index_cast %arg3 : i32 to index // CHECK-NEXT: %17 = arith.index_cast %arg6 : i32 to index // CHECK-NEXT: scf.parallel (%arg7, %arg8) = (%0, %1) to (%8, %15) step (%16, %17) { // CHECK-NEXT: %18 = arith.index_cast %arg7 : index to i64 // CHECK-NEXT: %19 = arith.index_cast %arg8 : index to i64 // CHECK-NEXT: %20 = memref.load %arg0[%arg7] : memref<?xmemref<?xf64>> // CHECK-NEXT: %21 = arith.addi %18, %19 : i64 // CHECK-NEXT: %22 = arith.sitofp %21 : i64 to f64 // CHECK-NEXT: memref.store %22, %20[%arg8] : memref<?xf64> // CHECK-NEXT: scf.yield // CHECK-NEXT: } // CHECK-NEXT: return // CHECK-NEXT: }

matvec.c

/* * matvec.c: Example of matrix-vector product in OpenMP. * * (C) 2015 Mikhail Kurnosov <mkurnosov@gmail.com> */ #include <stdio.h> #include <stdlib.h> #include <inttypes.h> #include <omp.h> #include <sys/time.h> /* * Memory consumption: O(m * n + n + m) */ enum { m = 20000, n = 20000 }; void *xmalloc(size_t size) { void *p = malloc(size); if (!p) { fprintf(stderr, "malloc failed\n"); exit(EXIT_FAILURE); } return p; } double wtime() { struct timeval t; gettimeofday(&t, NULL); return (double)t.tv_sec + (double)t.tv_usec * 1E-6; } /* matrix_vector_product: Compute matrix-vector product c[m] = a[m][n] * b[n] */ void matrix_vector_product(double *a, double *b, double *c, int m, int n) { for (int i = 0; i < m; i++) { c[i] = 0.0; for (int j = 0; j < n; j++) c[i] += a[i * n + j] * b[j]; } } /* matrix_vector_product_omp: Compute matrix-vector product c[m] = a[m][n] * b[n] in OpenMP */ void matrix_vector_product_omp(double *a, double *b, double *c, int m, int n) { #pragma omp parallel { int nthreads = omp_get_num_threads(); int threadid = omp_get_thread_num(); int items_per_thread = m / nthreads; int lb = threadid * items_per_thread; int ub = (threadid == nthreads - 1) ? (m - 1) : (lb + items_per_thread - 1); for (int i = lb; i <= ub; i++) { c[i] = 0.0; for (int j = 0; j < n; j++) c[i] += a[i * n + j] * b[j]; } } } double run_serial() { double *a, *b, *c; // Allocate memory for 2-d array a[m, n] a = xmalloc(sizeof(*a) * m * n); b = xmalloc(sizeof(*b) * n); c = xmalloc(sizeof(*c) * m); for (int i = 0; i < m; i++) { for (int j = 0; j < n; j++) a[i * n + j] = i + j; } for (int j = 0; j < n; j++) b[j] = j; double t = wtime(); matrix_vector_product(a, b, c, m, n); t = wtime() - t; printf("Elapsed time (serial): %.6f sec.\n", t); free(a); free(b); free(c); return t; } double run_parallel() { double *a, *b, *c; // Allocate memory for 2-d array a[m, n] a = xmalloc(sizeof(*a) * m * n); b = xmalloc(sizeof(*b) * n); c = xmalloc(sizeof(*c) * m); // Initialize and allocate pages from NUMA-nodes of threads (first-touch policy). #pragma omp parallel { int nthreads = omp_get_num_threads(); int threadid = omp_get_thread_num(); int items_per_thread = m / nthreads; int lb = threadid * items_per_thread; int ub = (threadid == nthreads - 1) ? (m - 1) : (lb + items_per_thread - 1); for (int i = lb; i <= ub; i++) { for (int j = 0; j < n; j++) a[i * n + j] = i + j; c[i] = 0.0; } } for (int j = 0; j < n; j++) b[j] = j; double t = wtime(); matrix_vector_product_omp(a, b, c, m, n); t = wtime() - t; printf("Elapsed time (parallel): %.6f sec.\n", t); free(a); free(b); free(c); return t; } int main(int argc, char **argv) { printf("Matrix-vector product (c[m] = a[m, n] * b[n]; m = %d, n = %d)\n", m, n); printf("Memory used: %" PRIu64 " MiB\n", (uint64_t)(((double)m * n + m + n) * sizeof(double)) >> 20); double tser = run_serial(); double tpar = run_parallel(); printf("Speedup: %.2f\n", tser / tpar); return 0; }

fig4.77-reduction.c

/* DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS HEADER. Copyright 2009 Sun Microsystems, Inc. All rights reserved. The contents of this file are subject to the terms of the BSD License("BSD")(the "License"). You can obtain a copy of the License at: http://www.opensparc.net/pubs/t1/licenses/BSD+_License.txt The BSD License Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistribution of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistribution 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 Sun Microsystems, Inc. or the names of contributors may be used to endorse or promote products derived from this software without specific prior written permission. This software is provided "AS IS," without a warranty of any kind. ALL EXPRESS OR IMPLIED CONDITIONS, REPRESENTATIONS AND WARRANTIES, INCLUDING ANY IMPLIED WARRANTY OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE OR NON-INFRINGEMENT, ARE HEREBY EXCLUDED. SUN MICROSYSTEMS, INC. ("SUN") AND ITS LICENSORS SHALL NOT BE LIABLE FOR ANY DAMAGES SUFFERED BY LICENSEE AS A RESULT OF USING, MODIFYING OR DISTRIBUTING THIS SOFTWARE OR ITS DERIVATIVES. IN NO EVENT WILL SUN OR ITS LICENSORS BE LIABLE FOR ANY LOST REVENUE, PROFIT OR DATA, OR FOR DIRECT, INDIRECT, SPECIAL, CONSEQUENTIAL, INCIDENTAL OR PUNITIVE DAMAGES, HOWEVER CAUSED AND REGARDLESS OF THE THEORY OF LIABILITY, ARISING OUT OF THE USE OF OR INABILITY TO USE THIS SOFTWARE, EVEN IF SUN HAS BEEN ADVISED OF THE POSSIBILITY OF SUCH DAMAGES. You acknowledge that this software is not designed, licensed or intended for use in the design, construction, operation or maintenance of any nuclear facility. */ #include <stdio.h> #include <stdlib.h> #ifdef _OPENMP #include <omp.h> #define TRUE 1 #define FALSE 0 #else #define omp_get_thread_num() 0 #define omp_get_num_threads() 1 #endif #define SUM_INIT 0 int main() { int i, n = 25; int sum, a[n]; int ref = SUM_INIT + (n-1)*n/2; #ifdef _OPENMP (void) omp_set_dynamic(FALSE); if (omp_get_dynamic()) {printf("Warning: dynamic adjustment of threads has been set\n");} (void) omp_set_num_threads(3); #endif for (i=0; i<n; i++) a[i] = i; #pragma omp parallel { #pragma omp single printf("Number of threads is %d\n",omp_get_num_threads()); } sum = SUM_INIT; printf("Value of sum prior to parallel region: %d\n",sum); #pragma omp parallel for default(none) shared(n,a) \ reduction(+:sum) for (i=0; i<n; i++) sum += a[i]; /*-- End of parallel reduction --*/ printf("Value of sum after parallel region: %d\n",sum); printf("Check results: sum = %d (should be %d)\n",sum,ref); return(0); }

tdbjac2.c

#include "dbjac2.h" #include "wnrme.h" #include "rnd.h" #include "timer.h" int main(int argc, char *argv[]) { if (4 != argc) { (void)fprintf(stderr, "%s filename 2^{batch_size} #batches\n", *argv); return EXIT_FAILURE; } const size_t n = ((size_t)1u << atoz(argv[2u])); if (n % VDL) { (void)fprintf(stderr, "batch_size has to be a multiple of %u.\n", VDL); return EXIT_FAILURE; } int th = 0; #ifdef _OPENMP th = omp_get_max_threads(); if (n % th) { (void)fprintf(stderr, "batch_size has to be a multiple of %d.\n", th); return EXIT_FAILURE; } #endif /* _OPENMP */ const size_t b = atoz(argv[3u]); if (!b) return EXIT_SUCCESS; const size_t nl = strlen(argv[1u]), nl1 = (nl + 1u); char *const fn = calloc((nl + 3u), sizeof(char)); assert(fn); strcpy(fn, argv[1u])[nl] = '.'; int fm = O_RDONLY; #ifdef _LARGEFILE64_SOURCE fm |= O_LARGEFILE; #endif /* _LARGEFILE64_SOURCE */ fn[nl1] = 'k'; const int fk = open(fn, fm); if (-1 >= fk) { (void)fprintf(stderr, "Cannot open %s for reading!\n", fn); return EXIT_FAILURE; } fn[nl1] = 'l'; const int fl = open(fn, fm); if (-1 >= fl) { (void)fprintf(stderr, "Cannot open %s for reading!\n", fn); return EXIT_FAILURE; } fn[nl1] = 'f'; const int ff = open(fn, fm); if (-1 >= ff) { (void)fprintf(stderr, "Cannot open %s for reading!\n", fn); return EXIT_FAILURE; } fn[nl1] = 'g'; const int fg = open(fn, fm); if (-1 >= fg) { (void)fprintf(stderr, "Cannot open %s for reading!\n", fn); return EXIT_FAILURE; } fn[nl1] = 'h'; const int fh = open(fn, fm); if (-1 >= fh) { (void)fprintf(stderr, "Cannot open %s for reading!\n", fn); return EXIT_FAILURE; } const size_t nt = n * sizeof(double); double *const a11 = (double*)aligned_alloc(VA, nt), *const a22 = (double*)aligned_alloc(VA, nt), *const a21 = (double*)aligned_alloc(VA, nt), *const c = (double*)aligned_alloc(VA, nt), *const at = (double*)aligned_alloc(VA, nt), *const l1 = (double*)aligned_alloc(VA, nt), *const l2 = (double*)aligned_alloc(VA, nt); assert(a11); assert(a22); assert(a21); assert(c); assert(at); assert(l1); assert(l2); unsigned *const p = (unsigned*)malloc((n >> VDLlg) * sizeof(unsigned)); assert(p); unsigned rd[2u] = { 0u, 0u }; uint64_t hz = tsc_get_freq_hz_(rd), be[2u] = { UINT64_C(0), UINT64_C(0) }; (void)fprintf(stderr, "TSC frequency: %llu+(%u/%u) Hz.\n", (unsigned long long)hz, rd[0u], rd[1u]); (void)fflush(stderr); (void)fprintf(stdout, "\"B\",\"Ts\",\"ORT\",\"REN\",\"RLN\",\"RLX\",\"RLM\"\n"); (void)fflush(stdout); const char *bf = (const char*)NULL; if (b <= 10u) bf = "%1zu"; else if (b <= 100u) bf = "%2zu"; else if (b <= 1000u) bf = "%3zu"; else // b > 1000 bf = "%zu"; const size_t n_t = n / imax(th, 1); const size_t cnt = n_t * sizeof(double); char a[31u] = { '\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' }; for (size_t j = 0u; j < b; ++j) { (void)fprintf(stdout, bf, j); (void)fflush(stdout); const size_t jn = j * n; #ifdef _OPENMP #pragma omp parallel default(none) shared(ff,fg,fh,a11,a22,a21,n,n_t,cnt,jn) #endif /* _OPENMP */ { const int mt = #ifdef _OPENMP omp_get_thread_num() #else /* !_OPENMP */ 0 #endif /* ?_OPENMP */ ; const size_t tnt = mt * n_t; const off_t off = (jn + tnt) * sizeof(double); if ((ssize_t)cnt != pread(ff, (a11 + tnt), cnt, off)) exit(EXIT_FAILURE); if ((ssize_t)cnt != pread(fg, (a22 + tnt), cnt, off)) exit(EXIT_FAILURE); if ((ssize_t)cnt != pread(fh, (a21 + tnt), cnt, off)) exit(EXIT_FAILURE); } (void)fprintf(stdout, ","); (void)fflush(stdout); be[0u] = rdtsc_beg(rd); const fint _n = -(fint)n; (void)dbjac2_(&_n, a11, a22, a21, c, at, l1, l2, p); be[1u] = rdtsc_end(rd); (void)fprintf(stdout, "%15.9Lf,", tsc_lap(hz, be[0u], be[1u])); (void)fflush(stdout); wide o = W_ZERO, r = W_ZERO; #ifdef _OPENMP #pragma omp parallel for default(none) shared(n,a11,a22,a21,c,at,l1,l2) reduction(max:o,r) #endif /* _OPENMP */ for (size_t i = 0u; i < n; ++i) { const wide CS = (wide)(c[i]); const wide SN = (wide)(at[i]); wide AE = W_ZERO, AN = W_ZERO; o = fmaxw(o, worr(CS, SN)); r = fmaxw(r, wrer(a11[i], a22[i], a21[i], CS, SN, l1[i], l2[i], &AE, &AN)); } (void)fprintf(stdout, "%s,", xtoa(a, (long double)o)); (void)fprintf(stdout, "%s", xtoa(a, (long double)r)); (void)fflush(stdout); #ifdef _OPENMP #pragma omp parallel default(none) shared(fk,fl,c,at,n,n_t,cnt,jn) #endif /* _OPENMP */ { const int mt = #ifdef _OPENMP omp_get_thread_num() #else /* !_OPENMP */ 0 #endif /* ?_OPENMP */ ; const size_t tnt = mt * n_t; const off_t off = (jn + tnt) * sizeof(double); if ((ssize_t)cnt != pread(fk, (c + tnt), cnt, off)) exit(EXIT_FAILURE); if ((ssize_t)cnt != pread(fl, (at + tnt), cnt, off)) exit(EXIT_FAILURE); } (void)fprintf(stdout, ","); (void)fflush(stdout); wide x = W_ZERO, m = W_ZERO; r = W_ZERO; #ifdef _OPENMP #pragma omp parallel for default(none) shared(n,l1,l2,c,at) reduction(max:r,x,m) #endif /* _OPENMP */ for (size_t i = 0u; i < n; ++i) { wide AE = W_ZERO, AN = W_ZERO; const wide RE = wlam(l1[i], l2[i], c[i], at[i], &AE, &AN); r = fmaxw(r, RE); x = fmaxw(x, AE); m = fmaxw(m, AN); } (void)fprintf(stdout, "%s,", xtoa(a, (long double)r)); (void)fprintf(stdout, "%s,", xtoa(a, (long double)x)); (void)fprintf(stdout, "%s\n", xtoa(a, (long double)m)); (void)fflush(stdout); } (void)close(fh); (void)close(fg); (void)close(ff); (void)close(fl); (void)close(fk); free(p); free(l2); free(l1); free(at); free(c); free(a21); free(a22); free(a11); free(fn); return EXIT_SUCCESS; }

SE3P_direct_rsrc.c

#include <math.h> #include "mex.h" #define IDX prhs[0] #define X prhs[1] // Source locations #define Q prhs[2] // Source strengths #define OPT prhs[3] // Parameters #define PHI plhs[0] // Output #ifndef VERBOSE #define VERBOSE 0 #endif #define PI 3.141592653589793 typedef struct { double box[3]; double xi; int layers; double rc; } ewald_opts; void unpack_opt(ewald_opts* opt, const mxArray* mx_opt) { // mandatory options -- will trigger core dump if missing opt->xi = mxGetScalar(mxGetField(mx_opt,0,"xi")); double* box = mxGetPr(mxGetField(mx_opt,0,"box")); opt->box[0] = box[0]; opt->box[1] = box[1]; opt->box[2] = box[2]; // layers: mandatory for ewald sums that are truncated const mxArray* mx_layers = mxGetField(mx_opt,0,"layers"); if(mx_layers) opt->layers = (int)mxGetScalar(mx_layers); else opt->layers = -1; // rc: mandatory for short-range real sum const mxArray* mx_rc = mxGetField(mx_opt,0,"real_cutoff"); if(mx_rc) opt->rc = mxGetScalar(mx_rc); else opt->rc = -1; } // MATLAB (one-based, doubles) to C (zero-based, integers) index translation void index_translation(int* idx, const double* idx_d, int N) { for(int i=0; i<N; i++) idx[i] = (int)idx_d[i] - 1; } void SE3P_direct_real_rc(double* restrict phi, const int* restrict idx, int nidx, const double* restrict x, const double* restrict q, int N, const ewald_opts opt) { double rvec[3]; double qn; double p, r; #ifdef _OPENMP #pragma omp parallel for private(rvec, qn, p, r) #endif for(int m=0; m<nidx; m++) { p = 0; for(int n=0; n<N; n++) { rvec[0] = x[idx[m] ]-x[n ]; rvec[1] = x[idx[m]+N ]-x[n+N ]; rvec[2] = x[idx[m]+2*N]-x[n+2*N]; qn = q[n]; for(int p0 = -opt.layers; p0<=opt.layers; p0++) for(int p1 = -opt.layers; p1<=opt.layers; p1++) for(int p2 = -opt.layers; p2<=opt.layers; p2++) { if(idx[m] == n && p2 == 0 && p1 == 0 && p0 == 0) continue; r = sqrt((rvec[0]+p0*opt.box[0])* (rvec[0]+p0*opt.box[0])+ (rvec[1]+p1*opt.box[1])* (rvec[1]+p1*opt.box[1])+ (rvec[2]+p2*opt.box[2])* (rvec[2]+p2*opt.box[2])); if(r > opt.rc) continue; p += qn*erfc(opt.xi*r)/r; } } phi[m] += p; } } /* no input checking is done */ void mexFunction(int nlhs, mxArray *plhs[], int nrhs, const mxArray *prhs[] ) { // input dims const int N = mxGetM(X); const int num_eval = mxGetN(IDX); // FIXME: indices assumed to be row vec const double* idx_d = mxGetPr(IDX); int* idx = mxMalloc(num_eval*sizeof(int)); index_translation(idx, idx_d, num_eval); const double* x = mxGetPr(X); const double* q = mxGetPr(Q); PHI = mxCreateDoubleMatrix(num_eval, 1, mxREAL); double* restrict phi = mxGetPr(PHI); ewald_opts opt; unpack_opt(&opt, OPT); if(VERBOSE) { mexPrintf("[EWALD (%s)] MEX N=(%d,%d) ","RSRC3P",N,num_eval); mexPrintf("xi = %.2f [rc = %.2f, layers=%d]\n", opt.xi,opt.rc,opt.layers); } // call kernel SE3P_direct_real_rc(phi, idx, num_eval, x, q, N, opt); mxFree(idx); }

threading.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_UTILS_THREADING_H_ #define LIGHTGBM_UTILS_THREADING_H_ #include <LightGBM/meta.h> #include <LightGBM/utils/common.h> #include <LightGBM/utils/openmp_wrapper.h> #include <algorithm> #include <functional> #include <vector> namespace LightGBM { class Threading { public: template <typename INDEX_T> static inline void BlockInfo(INDEX_T cnt, INDEX_T min_cnt_per_block, int* out_nblock, INDEX_T* block_size) { int num_threads = OMP_NUM_THREADS(); BlockInfo<INDEX_T>(num_threads, cnt, min_cnt_per_block, out_nblock, block_size); } template <typename INDEX_T> static inline void BlockInfo(int num_threads, INDEX_T cnt, INDEX_T min_cnt_per_block, int* out_nblock, INDEX_T* block_size) { *out_nblock = std::min<int>( num_threads, static_cast<int>((cnt + min_cnt_per_block - 1) / min_cnt_per_block)); if (*out_nblock > 1) { *block_size = SIZE_ALIGNED((cnt + (*out_nblock) - 1) / (*out_nblock)); } else { *block_size = cnt; } } template <typename INDEX_T> static inline void BlockInfo(int num_threads, INDEX_T cnt, INDEX_T min_cnt_per_block, INDEX_T max_cnt_per_block, int* out_nblock, INDEX_T* block_size) { CHECK(max_cnt_per_block >= min_cnt_per_block); *out_nblock = std::min<int>( num_threads, static_cast<int>((cnt + min_cnt_per_block - 1) / min_cnt_per_block)); *out_nblock = std::max<int>( *out_nblock, static_cast<int>((cnt + max_cnt_per_block - 1) / max_cnt_per_block)); if (*out_nblock > 1) { *block_size = SIZE_ALIGNED((cnt + (*out_nblock) - 1) / (*out_nblock)); } else { *block_size = cnt; } } template <typename INDEX_T> static inline void BlockInfoForceSize(int num_threads, INDEX_T cnt, INDEX_T min_cnt_per_block, int* out_nblock, INDEX_T* block_size) { *out_nblock = std::min<int>( num_threads, static_cast<int>((cnt + min_cnt_per_block - 1) / min_cnt_per_block)); if (*out_nblock > 1) { *block_size = (cnt + (*out_nblock) - 1) / (*out_nblock); // force the block size to the times of min_cnt_per_block *block_size = (*block_size + min_cnt_per_block - 1) / min_cnt_per_block * min_cnt_per_block; } else { *block_size = cnt; } } template <typename INDEX_T> static inline void BlockInfoForceSize(INDEX_T cnt, INDEX_T min_cnt_per_block, int* out_nblock, INDEX_T* block_size) { int num_threads = OMP_NUM_THREADS(); BlockInfoForceSize<INDEX_T>(num_threads, cnt, min_cnt_per_block, out_nblock, block_size); } template <typename INDEX_T> static inline int For( INDEX_T start, INDEX_T end, INDEX_T min_block_size, const std::function<void(int, INDEX_T, INDEX_T)>& inner_fun) { int n_block = 1; INDEX_T num_inner = end - start; BlockInfo<INDEX_T>(num_inner, min_block_size, &n_block, &num_inner); OMP_INIT_EX(); #pragma omp parallel for schedule(static, 1) for (int i = 0; i < n_block; ++i) { OMP_LOOP_EX_BEGIN(); INDEX_T inner_start = start + num_inner * i; INDEX_T inner_end = std::min(end, inner_start + num_inner); inner_fun(i, inner_start, inner_end); OMP_LOOP_EX_END(); } OMP_THROW_EX(); return n_block; } }; template <typename INDEX_T, bool TWO_BUFFER> class ParallelPartitionRunner { public: ParallelPartitionRunner(INDEX_T num_data, INDEX_T min_block_size) : min_block_size_(min_block_size) { num_threads_ = OMP_NUM_THREADS(); left_.resize(num_data); if (TWO_BUFFER) { right_.resize(num_data); } offsets_.resize(num_threads_); left_cnts_.resize(num_threads_); right_cnts_.resize(num_threads_); left_write_pos_.resize(num_threads_); right_write_pos_.resize(num_threads_); } ~ParallelPartitionRunner() {} void ReSize(INDEX_T num_data) { left_.resize(num_data); if (TWO_BUFFER) { right_.resize(num_data); } } template<bool FORCE_SIZE> INDEX_T Run( INDEX_T cnt, const std::function<INDEX_T(int, INDEX_T, INDEX_T, INDEX_T*, INDEX_T*)>& func, INDEX_T* out) { int nblock = 1; INDEX_T inner_size = cnt; if (FORCE_SIZE) { Threading::BlockInfoForceSize<INDEX_T>(num_threads_, cnt, min_block_size_, &nblock, &inner_size); } else { Threading::BlockInfo<INDEX_T>(num_threads_, cnt, min_block_size_, &nblock, &inner_size); } OMP_INIT_EX(); #pragma omp parallel for schedule(static, 1) num_threads(num_threads_) for (int i = 0; i < nblock; ++i) { OMP_LOOP_EX_BEGIN(); INDEX_T cur_start = i * inner_size; INDEX_T cur_cnt = std::min(inner_size, cnt - cur_start); offsets_[i] = cur_start; if (cur_cnt <= 0) { left_cnts_[i] = 0; right_cnts_[i] = 0; continue; } auto left_ptr = left_.data() + cur_start; INDEX_T* right_ptr = nullptr; if (TWO_BUFFER) { right_ptr = right_.data() + cur_start; } // split data inner, reduce the times of function called INDEX_T cur_left_count = func(i, cur_start, cur_cnt, left_ptr, right_ptr); if (!TWO_BUFFER) { // reverse for one buffer std::reverse(left_ptr + cur_left_count, left_ptr + cur_cnt); } left_cnts_[i] = cur_left_count; right_cnts_[i] = cur_cnt - cur_left_count; OMP_LOOP_EX_END(); } OMP_THROW_EX(); left_write_pos_[0] = 0; right_write_pos_[0] = 0; for (int i = 1; i < nblock; ++i) { left_write_pos_[i] = left_write_pos_[i - 1] + left_cnts_[i - 1]; right_write_pos_[i] = right_write_pos_[i - 1] + right_cnts_[i - 1]; } data_size_t left_cnt = left_write_pos_[nblock - 1] + left_cnts_[nblock - 1]; auto right_start = out + left_cnt; #pragma omp parallel for schedule(static, 1) num_threads(num_threads_) for (int i = 0; i < nblock; ++i) { std::copy_n(left_.data() + offsets_[i], left_cnts_[i], out + left_write_pos_[i]); if (TWO_BUFFER) { std::copy_n(right_.data() + offsets_[i], right_cnts_[i], right_start + right_write_pos_[i]); } else { std::copy_n(left_.data() + offsets_[i] + left_cnts_[i], right_cnts_[i], right_start + right_write_pos_[i]); } } return left_cnt; } private: int num_threads_; INDEX_T min_block_size_; std::vector<INDEX_T> left_; std::vector<INDEX_T> right_; std::vector<INDEX_T> offsets_; std::vector<INDEX_T> left_cnts_; std::vector<INDEX_T> right_cnts_; std::vector<INDEX_T> left_write_pos_; std::vector<INDEX_T> right_write_pos_; }; } // namespace LightGBM #endif // LightGBM_UTILS_THREADING_H_

recon3d.c

#include <stdlib.h> #include <stdio.h> #include <math.h> #include <time.h> #include <sys/time.h> #include <string.h> #include <omp.h> #include "mbir_ct.h" #include "MBIRModularDefs.h" #include "MBIRModularUtils.h" #include "allocate.h" #include "icd3d.h" #include "heap.h" #include "A_comp.h" #include "initialize.h" #include "recon3d.h" #define c_ratio 0.07 #define convergence_rho 0.7 /* Internal functions */ void super_voxel_recon(int jj,struct SVParams svpar,unsigned long *NumUpdates,float *totalValue,float *totalChange,int iter, char *phaseMap,long *order,int *indexList,float **w,float **e, struct AValues_char **A_Padded_Map,float *Aval_max_ptr,struct heap_node *headNodeArray, struct SinoParams3DParallel sinoparams,struct ReconParams reconparams,struct Image3D *Image, float *voxelsBuffer1,float *voxelsBuffer2,char *group_array,int group_id); void coordinateShuffle(int *order1, int *order2,int len); void three_way_shuffle(long *order1, char *order2, struct heap_node *headNodeArray,int len); float MAPCostFunction3D(float **e,struct Image3D *Image,struct Sino3DParallel *sinogram,struct ReconParams *reconparams); void MBIRReconstruct3D( struct Image3D *Image, struct Sino3DParallel *sinogram, float **e, /* e=y-Ax, error */ struct ReconParams reconparams, struct SVParams svpar, struct AValues_char ** A_Padded_Map, float *Aval_max_ptr, char *ImageReconMask, char verboseLevel) { int i,j,jj,p,t,iter,it_print=1; int NumMaskVoxels=0; //float **x; /* image data */ //float **y; /* sinogram projections data */ float **w; /* projections weights data */ float *voxelsBuffer1; /* the first N entries are the voxel values. */ float *voxelsBuffer2; unsigned long NumUpdates=0; float totalValue=0,totalChange=0,equits=0; float avg_update,avg_update_rel; struct heap priorityheap; initialize_heap(&priorityheap); long *order; char *phaseMap; //struct tm1,tm2; //x = Image->image; /* x is the image vector */ //y = sinogram->sino; /* y is the sinogram vector */ w = sinogram->weight; /* vector of weights for each sinogram measurement */ int Nx = Image->imgparams.Nx; int Ny = Image->imgparams.Ny; int Nxy = Nx*Ny; int Nz = Image->imgparams.Nz; int MaxIterations = reconparams.MaxIterations; float StopThreshold = reconparams.StopThreshold; int SVLength = svpar.SVLength; int overlappingDistance = svpar.overlap; int SV_depth = svpar.SVDepth; int SV_per_Z = svpar.SV_per_Z; int SVsPerRow = svpar.SVsPerRow; int sum = svpar.Nsv; //int pieceLength = svpar.pieceLength; //struct minStruct * bandMinMap = svpar.bandMinMap; //struct maxStruct * bandMaxMap = svpar.bandMaxMap; int rep_num=(int)ceil(1/(4*c_ratio*convergence_rho)); for(j=0;j<Nxy;j++) if(ImageReconMask[j]) NumMaskVoxels++; #if 0 //#ifdef find_RMSE float **golden; golden = (float **)multialloc(sizeof(float), 2, Nz,Nxy); // note this needs to be updated read_golden(cmdline->ReconImageDataFile,golden,Nz,Nxy,Image); float updatedVoxelsList[300]; float sumOfSE=0; for(i=0;i<Nz;i++) for(j=0;j<Nxy;j++) sumOfSE+=(Image->image[i][j]-golden[i][j])*(Image->image[i][j]-golden[i][j]); float MSE=sumOfSE/Nxy/Nz; float RMSE=sqrt(MSE); fprintf(stdout,"Rho: %f initial_RMSE: %f \n",convergence_rho,RMSE); #endif order = (long *) mget_spc(sum*SV_per_Z,sizeof(long)); /* Order of pixel updates need NOT be raster order, just initialize */ t=0; for(p=0;p<Nz;p+=SV_depth) for(i=0;i<Ny;i+=(SVLength*2-overlappingDistance)) for(j=0;j<Nx;j+=(SVLength*2-overlappingDistance)) { order[t]=(long)p*Nxy+i*Nx+j; /* order is the first voxel coordinate, not the center */ t++; } phaseMap = (char *) mget_spc(sum*SV_per_Z,sizeof(char)); #pragma omp parallel for private(jj) schedule(dynamic) for(i=0;i<SV_per_Z;i++) for(jj=0;jj<sum;jj++) { if((jj/SVsPerRow)%2==0) { if((jj%SVsPerRow)%2==0) phaseMap[i*sum+jj]=0; else phaseMap[i*sum+jj]=1; } else { if((jj%SVsPerRow)%2==0) phaseMap[i*sum+jj]=2; else phaseMap[i*sum+jj]=3; } } char group_id_list[SV_per_Z][4]; for(i=0;i<SV_per_Z;i++){ if(i%4==0){ group_id_list[i][0]=0; group_id_list[i][1]=3; group_id_list[i][2]=1; group_id_list[i][3]=2; } else if(i%4==1){ group_id_list[i][0]=3; group_id_list[i][1]=0; group_id_list[i][2]=2; group_id_list[i][3]=1; } else if(i%4==2){ group_id_list[i][0]=1; group_id_list[i][1]=2; group_id_list[i][2]=3; group_id_list[i][3]=0; } else{ group_id_list[i][0]=2; group_id_list[i][1]=1; group_id_list[i][2]=0; group_id_list[i][3]=3; } } srand(time(NULL)); //struct heap_node headNodeArray[sum*SV_per_Z]; //This allocation crashed silently for a large problem struct heap_node *headNodeArray; headNodeArray = (struct heap_node *) mget_spc(sum*SV_per_Z,sizeof(struct heap_node)); for(i=0;i<SV_per_Z;i++) for(jj=0;jj<sum;jj++) { headNodeArray[i*sum+jj].pt=i*sum+jj; headNodeArray[i*sum+jj].x=0.0; } int indexList_size=(int) sum*SV_per_Z*4*c_ratio*(1-convergence_rho); int indexList[indexList_size]; #ifdef ICC voxelsBuffer1 = (float *)_mm_malloc(Nxy*sizeof(float),64); voxelsBuffer2 = (float *)_mm_malloc(Nxy*sizeof(float),64); #else voxelsBuffer1 = (float *) malloc(Nxy*sizeof(float)); voxelsBuffer2 = (float *) malloc(Nxy*sizeof(float)); //voxelsBuffer1 = (float *) aligned_alloc(64,Nxy*sizeof(float)); //voxelsBuffer2 = (float *) aligned_alloc(64,Nxy*sizeof(float)); //voxelsBuffer1 = (float *) _aligned_malloc(Nxy*sizeof(float),64); //voxelsBuffer2 = (float *) _aligned_malloc(Nxy*sizeof(float),64); #endif for(i=0;i<Nxy;i++) voxelsBuffer1[i]=0; for(i=0;i<Nxy;i++) voxelsBuffer2[i]=0; iter=0; //coordinateShuffle(&order[0],&phaseMap[0],sum*SV_per_Z); long tmp_long; char tmp_char; for(i=0; i<sum*SV_per_Z-1; i++) { j = i + (rand() % (sum*SV_per_Z-i)); tmp_long = order[j]; order[j] = order[i]; order[i] = tmp_long; tmp_char = phaseMap[j]; phaseMap[j] = phaseMap[i]; phaseMap[i] = tmp_char; } int startIndex=0; int endIndex=0; //gettimeofday(&tm1,NULL); char stop_FLAG=0; #pragma omp parallel { while(stop_FLAG==0 && equits<MaxIterations && iter<100*MaxIterations) { #pragma omp single { if(iter==0) { startIndex=0; endIndex=sum*SV_per_Z; } else { if((iter-1)%(2*rep_num)==0 && iter!=1) three_way_shuffle(&order[0],&phaseMap[0],&headNodeArray[0],sum*SV_per_Z); if(iter%2==1) { //SJK: This is a memory leak!! //initialize_heap(&priorityheap); priorityheap.size=0; for(jj=0;jj<sum*SV_per_Z;jj++){ heap_insert(&priorityheap, &(headNodeArray[jj])); } startIndex=0; endIndex=indexList_size; for(i=0;i<endIndex;i++){ struct heap_node tempNode; get_heap_max(&priorityheap, &tempNode); indexList[i]=tempNode.pt; } } else{ startIndex=((iter-2)/2)%rep_num*sum*SV_per_Z/rep_num; endIndex=(((iter-2)/2)%rep_num+1)*sum*SV_per_Z/rep_num; } } } int group=0; for (group = 0; group < 4; group++) { #pragma omp for schedule(dynamic) reduction(+:NumUpdates) reduction(+:totalValue) reduction(+:totalChange) for (jj = startIndex; jj < endIndex; jj+=1) super_voxel_recon(jj,svpar,&NumUpdates,&totalValue,&totalChange,iter,&phaseMap[0],order,&indexList[0],w,e,A_Padded_Map,&Aval_max_ptr[0],&headNodeArray[0],sinogram->sinoparams,reconparams,Image,voxelsBuffer1,voxelsBuffer2,&group_id_list[0][0],group); } #pragma omp single { if(NumUpdates>0) { avg_update = totalChange/NumUpdates; float avg_value = totalValue/NumUpdates; avg_update_rel = avg_update/avg_value * 100; //printf("avg_update %f, avg_value %f, avg_update_rel %f\n",avg_update,avg_value,avg_update_rel); } /* float cost = MAPCostFunction3D(e, Image, sinogram, &reconparams); fprintf(stdout, "it %d cost = %-15f, avg_update %f \n", iter, cost, avg_update); */ #if 0 //#ifdef find_RMSE float sumOfSE=0; for(i=0;i<Nz;i++) for(j=0;j<Nxy;j++) sumOfSE+=(Image->image[i][j]-golden[i][j])*(Image->image[i][j]-golden[i][j]); float MSE=sumOfSE/Nxy/Nz; float RMSE=sqrt(MSE); if(iter<300) { updatedVoxelsList[iter]=NumUpdates*1.0/Nxy/Nz; fprintf(stdout,"Rho: %f Equits: %f RMSE: %f \n",convergence_rho,updatedVoxelsList[iter],RMSE); } #endif if (avg_update_rel < StopThreshold && (endIndex!=0)) stop_FLAG = 1; iter++; equits += (float)NumUpdates/((float)NumMaskVoxels*Nz); if(verboseLevel) if(equits > it_print) { fprintf(stdout,"\titeration %d, average change %.4f %%\n",it_print,avg_update_rel); it_print++; } NumUpdates=0; totalValue=0; totalChange=0; } } } //gettimeofday(&tm2,NULL); //unsigned long long tt = 1000 * (tm2.tv_sec - tm1.tv_sec) + (tm2.tv_usec - tm1.tv_usec) / 1000; //printf("\trun time %llu ms (iterations only)\n", tt); if(verboseLevel) { if(StopThreshold <= 0) fprintf(stdout,"\tNo stopping condition--running fixed iterations\n"); else if(stop_FLAG == 1) fprintf(stdout,"\tReached stopping condition\n"); else fprintf(stdout,"\tWarning: Didn't reach stopping condition\n"); } if(verboseLevel>1) { fprintf(stdout,"\tEquivalent iterations = %.1f, (non-homogeneous iterations = %d)\n",equits,iter); fprintf(stdout,"\tAverage update in last iteration (relative) = %f %%\n",avg_update_rel); fprintf(stdout,"\tAverage update in last iteration (magnitude) = %.4g\n",avg_update); } #ifdef ICC _mm_free((void *)voxelsBuffer1); _mm_free((void *)voxelsBuffer2); #else free((void *)voxelsBuffer1); free((void *)voxelsBuffer2); //_aligned_free((void *)voxelsBuffer1); //_aligned_free((void *)voxelsBuffer2); #endif free((void *)headNodeArray); free_heap((void *)&priorityheap); free((void *)phaseMap); free((void *)order); #ifdef find_RMSE multifree(golden,2); #endif } /* END MBIRReconstruct3D() */ void forwardProject2D( float *e, float *x, struct AValues_char ** A_Padded_Map, float *Aval_max_ptr, struct SinoParams3DParallel *sinoparams, struct ImageParams3D *imgparams, struct SVParams svpar) { int jx,jy,i,r,j,p; int SVLength = svpar.SVLength; int overlappingDistance = svpar.overlap; struct minStruct * bandMinMap = svpar.bandMinMap; int pieceLength = svpar.pieceLength; int SVsPerRow = svpar.SVsPerRow; int NViewSets = sinoparams->NViews/pieceLength; int Nx = imgparams->Nx; int Ny = imgparams->Ny; int NChannels = sinoparams->NChannels; int M = sinoparams->NViews*sinoparams->NChannels; for (i = 0; i < M; i++) e[i] = 0.0; for (jy = 0; jy < Ny; jy++) for (jx = 0; jx < Nx; jx++) { int SV_ind_y = jy/(2*SVLength-overlappingDistance); int SV_ind_x = jx/(2*SVLength-overlappingDistance); int SVPosition = SV_ind_y*SVsPerRow + SV_ind_x; int SV_jy = SV_ind_y*(2*SVLength-overlappingDistance); int SV_jx = SV_ind_x*(2*SVLength-overlappingDistance); int VoxelPosition = (jy-SV_jy)*(2*SVLength+1)+(jx-SV_jx); // fprintf(stdout,"jy %d jx %d SVPosition %d SV_jy %d SV_jx %d VoxelPosition %d \n",jy,jx,SVPosition,SV_jy,SV_jx,VoxelPosition); // I think the second condition will always be true if (A_Padded_Map[SVPosition][VoxelPosition].length > 0 && VoxelPosition < ((2*SVLength+1)*(2*SVLength+1))) { unsigned char* A_padd_Tr_ptr = &A_Padded_Map[SVPosition][VoxelPosition].val[0]; float rescale = Aval_max_ptr[jy*Nx+jx]*(1.0/255); float xval = x[jy*Nx+jx]; for(p=0;p<NViewSets;p++) { int myCount = A_Padded_Map[SVPosition][VoxelPosition].pieceWiseWidth[p]; int pieceWiseMin = A_Padded_Map[SVPosition][VoxelPosition].pieceWiseMin[p]; int position = p*pieceLength*NChannels + pieceWiseMin; for(r=0;r<myCount;r++) for(j=0;j<pieceLength;j++) { int bandMin = bandMinMap[SVPosition].bandMin[p*pieceLength+j]; int proj_idx = position + j*NChannels + bandMin + r; if((pieceWiseMin + bandMin + r) >= NChannels || proj_idx >= M ) { fprintf(stderr,"forwardProject() out of bounds: p %d r %d j %d\n",p,r,j); fprintf(stderr,"forwardProject() out of bounds: total_1 %d total_2 %d\n",pieceWiseMin+bandMin+r,proj_idx); exit(-1); } else e[proj_idx] += A_padd_Tr_ptr[r*pieceLength+j]*rescale * xval; } A_padd_Tr_ptr += myCount*pieceLength; } } } } /* END forwardProject2D() */ void super_voxel_recon( int jj, struct SVParams svpar, unsigned long *NumUpdates, float *totalValue, float *totalChange, int iter, char *phaseMap, long *order, int *indexList, float **w, float **e, struct AValues_char ** A_Padded_Map, float *Aval_max_ptr, struct heap_node *headNodeArray, struct SinoParams3DParallel sinoparams, struct ReconParams reconparams, struct Image3D *Image, float *voxelsBuffer1, float *voxelsBuffer2, char *group_array, int group_id) { int jy,jx,p,i,q,t,j,currentSlice,startSlice; int SV_depth_modified; int NumUpdates_loc=0; float totalValue_loc=0,totalChange_loc=0; float ** image = Image->image; float ** proximalmap = reconparams.proximalmap; struct ImageParams3D imgparams = Image->imgparams; int Nx = imgparams.Nx; int Ny = imgparams.Ny; int Nz = imgparams.Nz; char PositivityFlag = reconparams.Positivity; int SVLength = svpar.SVLength; int overlappingDistance = svpar.overlap; int SV_depth = svpar.SVDepth; int SVsPerRow = svpar.SVsPerRow; struct minStruct * bandMinMap = svpar.bandMinMap; struct maxStruct * bandMaxMap = svpar.bandMaxMap; int pieceLength = svpar.pieceLength; int NViewSets = sinoparams.NViews/pieceLength; int jj_new; if(iter%2==0) jj_new=jj; else jj_new=indexList[jj]; startSlice = order[jj_new] / Nx / Ny; jy = (order[jj_new] - startSlice* Nx * Ny) / Nx; jx = (order[jj_new] - startSlice* Nx * Ny) % Nx; if(phaseMap[jj_new]!=group_array[startSlice/SV_depth*4+group_id]) return; if((startSlice+SV_depth)>Nz) SV_depth_modified=Nz-startSlice; else SV_depth_modified=SV_depth; int SVPosition=jy/(2*SVLength-overlappingDistance)*SVsPerRow+jx/(2*SVLength-overlappingDistance); int countNumber=0; /*XW: the number of voxels chosen for a certain radius of circle*/ int radius =SVLength; /*XW: choose the circle radius*/ int coordinateSize=1; /*XW: CoordinateSize is the size of a minimum square enclosing the circle. For the baseline code, coordinateSize=1 because only 1 voxel*/ /*XW: imagine that this is a minimum square enclosing the circle. The square * "touches" the circle on 4 coordinate points. CoordianteSize is the possible * maximum number of voxels for a certain radius of circle */ if(radius!=0) coordinateSize=(2*radius+1)*(2*radius+1); int k_newCoordinate[coordinateSize]; int j_newCoordinate[coordinateSize]; int j_newAA=0; int k_newAA=0; int voxelIncrement=0; /*XW: choosing the voxels locations in a circle*/ for(j_newAA=jy;j_newAA<=(jy+2*radius);j_newAA++) for(k_newAA=jx;k_newAA<=(jx+2*radius);k_newAA++) { if(j_newAA>=0 && k_newAA >=0 && j_newAA <Ny && k_newAA < Nx) { if(A_Padded_Map[SVPosition][voxelIncrement].length >0) { j_newCoordinate[countNumber]=j_newAA; k_newCoordinate[countNumber]=k_newAA; countNumber++; } } voxelIncrement++; } /*XW: if no voxel chosen, we skip this loop iteration*/ if(countNumber==0) return; coordinateShuffle(&j_newCoordinate[0],&k_newCoordinate[0],countNumber); /*XW: for a supervoxel, bandMin records the starting position of the sinogram band at each view*/ /*XW: for a supervoxel, bandMax records the end position of the sinogram band at each view */ channel_t bandMin[sinoparams.NViews]__attribute__((aligned(32))); channel_t bandMax[sinoparams.NViews]__attribute__((aligned(32))); channel_t bandWidthTemp[sinoparams.NViews]__attribute__((aligned(32))); channel_t bandWidth[NViewSets]__attribute__((aligned(32))); #ifdef ICC _intel_fast_memcpy(&bandMin[0],&bandMinMap[SVPosition].bandMin[0],sizeof(channel_t)*(sinoparams.NViews)); _intel_fast_memcpy(&bandMax[0],&bandMaxMap[SVPosition].bandMax[0],sizeof(channel_t)*(sinoparams.NViews)); #else memcpy(&bandMin[0],&bandMinMap[SVPosition].bandMin[0],sizeof(channel_t)*(sinoparams.NViews)); memcpy(&bandMax[0],&bandMaxMap[SVPosition].bandMax[0],sizeof(channel_t)*(sinoparams.NViews)); #endif #pragma vector aligned for(p=0;p< sinoparams.NViews;p++) bandWidthTemp[p]=bandMax[p]-bandMin[p]; for (p = 0; p < NViewSets; p++) { int bandWidthMax=bandWidthTemp[p*pieceLength]; for(t=0;t<pieceLength;t++){ if(bandWidthTemp[p*pieceLength+t]>bandWidthMax) bandWidthMax=bandWidthTemp[p*pieceLength+t]; } bandWidth[p]=bandWidthMax; } float ** newWArray = (float **)malloc(sizeof(float *) * NViewSets); float ** newEArray = (float **)malloc(sizeof(float *) * NViewSets); float ** CopyNewEArray = (float **)malloc(sizeof(float *) * NViewSets); for (p = 0; p < NViewSets; p++) { newWArray[p] = (float *)malloc(sizeof(float)*bandWidth[p]*pieceLength*SV_depth_modified); newEArray[p] = (float *)malloc(sizeof(float)*bandWidth[p]*pieceLength*SV_depth_modified); CopyNewEArray[p] = (float *)malloc(sizeof(float)*bandWidth[p]*pieceLength*SV_depth_modified); } float *newWArrayPointer=&newWArray[0][0]; float *newEArrayPointer=&newEArray[0][0]; /*XW: copy the interlaced we into the memory buffer*/ for (p = 0; p < NViewSets; p++) { newWArrayPointer=&newWArray[p][0]; newEArrayPointer=&newEArray[p][0]; for(i=0;i<SV_depth_modified;i++) for(q=0;q<pieceLength;q++) { #ifdef ICC _intel_fast_memcpy(newWArrayPointer,&w[startSlice+i][p*pieceLength*sinoparams.NChannels+q*sinoparams.NChannels+bandMin[p*pieceLength+q]],sizeof(float)*(bandWidth[p])); _intel_fast_memcpy(newEArrayPointer,&e[startSlice+i][p*pieceLength*sinoparams.NChannels+q*sinoparams.NChannels+bandMin[p*pieceLength+q]],sizeof(float)*(bandWidth[p])); #else memcpy(newWArrayPointer,&w[startSlice+i][p*pieceLength*sinoparams.NChannels+q*sinoparams.NChannels+bandMin[p*pieceLength+q]],sizeof(float)*(bandWidth[p])); memcpy(newEArrayPointer,&e[startSlice+i][p*pieceLength*sinoparams.NChannels+q*sinoparams.NChannels+bandMin[p*pieceLength+q]],sizeof(float)*(bandWidth[p])); #endif newWArrayPointer+=bandWidth[p]; newEArrayPointer+=bandWidth[p]; } } for (p = 0; p < NViewSets; p++) { #ifdef ICC _intel_fast_memcpy(&CopyNewEArray[p][0],&newEArray[p][0],sizeof(float)*bandWidth[p]*pieceLength*SV_depth_modified); #else memcpy(&CopyNewEArray[p][0],&newEArray[p][0],sizeof(float)*bandWidth[p]*pieceLength*SV_depth_modified); #endif } float ** newWArrayTransposed = (float **)malloc(sizeof(float *) * NViewSets); float ** newEArrayTransposed = (float **)malloc(sizeof(float *) * NViewSets); for (p = 0; p < NViewSets; p++) { newWArrayTransposed[p] = (float *)malloc(sizeof(float)*bandWidth[p]*pieceLength*SV_depth_modified); newEArrayTransposed[p] = (float *)malloc(sizeof(float)*bandWidth[p]*pieceLength*SV_depth_modified); } float *WTransposeArrayPointer=&newWArrayTransposed[0][0]; float *ETransposeArrayPointer=&newEArrayTransposed[0][0]; for (p = 0; p < NViewSets; p++) for(currentSlice=0;currentSlice<(SV_depth_modified);currentSlice++) { WTransposeArrayPointer=&newWArrayTransposed[p][currentSlice*bandWidth[p]*pieceLength]; ETransposeArrayPointer=&newEArrayTransposed[p][currentSlice*bandWidth[p]*pieceLength]; newEArrayPointer=&newEArray[p][currentSlice*bandWidth[p]*pieceLength]; newWArrayPointer=&newWArray[p][currentSlice*bandWidth[p]*pieceLength]; for(q=0;q<bandWidth[p];q++) { #pragma vector aligned for(t=0;t<pieceLength;t++) { ETransposeArrayPointer[q*pieceLength+t]=newEArrayPointer[bandWidth[p]*t+q]; WTransposeArrayPointer[q*pieceLength+t]=newWArrayPointer[bandWidth[p]*t+q]; } } } WTransposeArrayPointer=&newWArrayTransposed[0][0]; ETransposeArrayPointer=&newEArrayTransposed[0][0]; newEArrayPointer=&newEArray[0][0]; for (p = 0; p < NViewSets; p++) free((void *)newWArray[p]); free((void **)newWArray); /* Turn off zero-skipping for 1st iteration */ char zero_skip_enable=0; // 1: enable, 0: disable if(iter>0 && PositivityFlag) zero_skip_enable=1; /*XW: the start of the loop to compute theta1, theta2*/ for(i=0;i<countNumber;i++) { const short j_new = j_newCoordinate[i]; /*XW: get the voxel's x,y location*/ const short k_new = k_newCoordinate[i]; float Aval_max = Aval_max_ptr[j_new*Nx+k_new]; float tempV[SV_depth_modified]; float tempProxMap[SV_depth_modified]; float neighbors[SV_depth_modified][10]; char zero_skip_FLAG[SV_depth_modified]; float diff[SV_depth_modified]; float THETA1[SV_depth_modified]; float THETA2[SV_depth_modified]; memset(&THETA1[0],0.0, sizeof(THETA1)); memset(&THETA2[0],0.0, sizeof(THETA2)); int theVoxelPosition=(j_new-jy)*(2*SVLength+1)+(k_new-jx); unsigned char * A_padd_Tranpose_pointer = &A_Padded_Map[SVPosition][theVoxelPosition].val[0]; for(currentSlice=0;currentSlice<SV_depth_modified;currentSlice++) { tempV[currentSlice] = (float)(image[startSlice+currentSlice][j_new*Nx+k_new]); /*XW: current voxel's value*/ zero_skip_FLAG[currentSlice] = 0; if(reconparams.ReconType == MBIR_MODULAR_RECONTYPE_QGGMRF_3D) { ExtractNeighbors3D(&neighbors[currentSlice][0],k_new,j_new,&image[startSlice+currentSlice][0],imgparams); if((startSlice+currentSlice)==0) neighbors[currentSlice][8]=voxelsBuffer1[j_new*Nx+k_new]; else neighbors[currentSlice][8]=image[startSlice+currentSlice-1][j_new*Nx+k_new]; if((startSlice+currentSlice)<(Nz-1)) neighbors[currentSlice][9]=image[startSlice+currentSlice+1][j_new*Nx+k_new]; else neighbors[currentSlice][9]=voxelsBuffer2[j_new*Nx+k_new]; if(zero_skip_enable) if(tempV[currentSlice] == 0.0) { zero_skip_FLAG[currentSlice] = 1; for (j = 0; j < 10; j++) { if (neighbors[currentSlice][j] != 0.0) { zero_skip_FLAG[currentSlice] = 0; break; } } } } if(reconparams.ReconType == MBIR_MODULAR_RECONTYPE_PandP) tempProxMap[currentSlice] = proximalmap[startSlice+currentSlice][j_new*Nx+k_new]; } A_padd_Tranpose_pointer = &A_Padded_Map[SVPosition][theVoxelPosition].val[0]; for(p=0;p<NViewSets;p++) { const int myCount=A_Padded_Map[SVPosition][theVoxelPosition].pieceWiseWidth[p]; const int pieceMin=A_Padded_Map[SVPosition][theVoxelPosition].pieceWiseMin[p]; #pragma vector aligned for(currentSlice=0;currentSlice<SV_depth_modified;currentSlice++) if(zero_skip_FLAG[currentSlice] == 0) { WTransposeArrayPointer=&newWArrayTransposed[p][currentSlice*bandWidth[p]*pieceLength]; ETransposeArrayPointer=&newEArrayTransposed[p][currentSlice*bandWidth[p]*pieceLength]; WTransposeArrayPointer+=pieceMin*pieceLength; ETransposeArrayPointer+=pieceMin*pieceLength; float tempTHETA1=0.0; float tempTHETA2=0.0; //Not finding evidence this makes a difference --SJK //Deprecated by Intel anyway //#pragma vector aligned //#pragma simd reduction(+:tempTHETA2,tempTHETA1) for(t=0;t<myCount*pieceLength;t++) { /* summing over voxels which are not skipped or masked*/ tempTHETA1 += A_padd_Tranpose_pointer[t]*WTransposeArrayPointer[t]*ETransposeArrayPointer[t]; tempTHETA2 += A_padd_Tranpose_pointer[t]*WTransposeArrayPointer[t]*A_padd_Tranpose_pointer[t]; } THETA1[currentSlice]+=tempTHETA1; THETA2[currentSlice]+=tempTHETA2; } A_padd_Tranpose_pointer += myCount*pieceLength; } for(currentSlice=0;currentSlice<SV_depth_modified;currentSlice++) { THETA1[currentSlice]=-THETA1[currentSlice]*Aval_max*(1.0/255); THETA2[currentSlice]=THETA2[currentSlice]*Aval_max*(1.0/255)*Aval_max*(1.0/255); } ETransposeArrayPointer=&newEArrayTransposed[0][0]; A_padd_Tranpose_pointer = &A_Padded_Map[SVPosition][theVoxelPosition].val[0]; for(currentSlice=0;currentSlice<SV_depth_modified;currentSlice++) if(zero_skip_FLAG[currentSlice] == 0) { float pixel,step; if(reconparams.ReconType == MBIR_MODULAR_RECONTYPE_QGGMRF_3D) { step = QGGMRF3D_Update(reconparams,tempV[currentSlice],&neighbors[currentSlice][0],THETA1[currentSlice],THETA2[currentSlice]); } else if(reconparams.ReconType == MBIR_MODULAR_RECONTYPE_PandP) { step = PandP_Update(reconparams,tempV[currentSlice],tempProxMap[currentSlice],THETA1[currentSlice],THETA2[currentSlice]); } else { fprintf(stderr,"Error** Unrecognized ReconType in ICD update\n"); exit(-1); } pixel = tempV[currentSlice] + step; /* can apply over-relaxation to the step size here */ if(PositivityFlag) image[startSlice+currentSlice][j_new*Nx+k_new] = ((pixel < 0.0) ? 0.0 : pixel); else image[startSlice+currentSlice][j_new*Nx+k_new] = pixel; diff[currentSlice] = image[startSlice+currentSlice][j_new*Nx+k_new] - tempV[currentSlice]; totalChange_loc += fabs(diff[currentSlice]); totalValue_loc += fabs(tempV[currentSlice]); NumUpdates_loc++; diff[currentSlice]=diff[currentSlice]*Aval_max*(1.0/255); } for(p=0;p<NViewSets;p++) { const int myCount=A_Padded_Map[SVPosition][theVoxelPosition].pieceWiseWidth[p]; const int pieceMin=A_Padded_Map[SVPosition][theVoxelPosition].pieceWiseMin[p]; #pragma vector aligned for(currentSlice=0;currentSlice<SV_depth_modified;currentSlice++) if(diff[currentSlice]!=0 && zero_skip_FLAG[currentSlice] == 0) { ETransposeArrayPointer=&newEArrayTransposed[p][currentSlice*bandWidth[p]*pieceLength]; ETransposeArrayPointer+=pieceMin*pieceLength; #pragma vector aligned for(t=0;t<(myCount*pieceLength);t++) ETransposeArrayPointer[t]= ETransposeArrayPointer[t]-A_padd_Tranpose_pointer[t]*diff[currentSlice]; } A_padd_Tranpose_pointer+=myCount*pieceLength; } } for (p = 0; p < NViewSets; p++) free((void *)newWArrayTransposed[p]); free((void **)newWArrayTransposed); headNodeArray[jj_new].x=totalChange_loc; for (p = 0; p < NViewSets; p++) for(currentSlice=0;currentSlice<SV_depth_modified;currentSlice++) { ETransposeArrayPointer=&newEArrayTransposed[p][currentSlice*bandWidth[p]*pieceLength]; newEArrayPointer=&newEArray[p][currentSlice*bandWidth[p]*pieceLength]; for(q=0;q<bandWidth[p];q++) { #pragma vector aligned for(t=0;t<pieceLength;t++) newEArrayPointer[bandWidth[p]*t+q]=ETransposeArrayPointer[q*pieceLength+t]; } } for (p = 0; p < NViewSets; p++) free((void *)newEArrayTransposed[p]); free((void **)newEArrayTransposed); newEArrayPointer=&newEArray[0][0]; float* CopyNewEArrayPointer=&CopyNewEArray[0][0]; float* eArrayPointer=&e[0][0]; for (p = 0; p < NViewSets; p++) /*XW: update the error term in the memory buffer*/ { newEArrayPointer=&newEArray[p][0]; CopyNewEArrayPointer=&CopyNewEArray[p][0]; for (currentSlice=0; currentSlice< SV_depth_modified;currentSlice++) { #pragma vector aligned for(q=0;q<pieceLength;q++) { eArrayPointer=&e[startSlice+currentSlice][p*pieceLength*sinoparams.NChannels+q*sinoparams.NChannels+bandMin[p*pieceLength+q]]; for(t=0;t<bandWidth[p];t++) { #pragma omp atomic *eArrayPointer += (*newEArrayPointer)-(*CopyNewEArrayPointer); newEArrayPointer++; CopyNewEArrayPointer++; eArrayPointer++; } } } } for (p = 0; p < NViewSets; p++) { free((void *)newEArray[p]); free((void *)CopyNewEArray[p]); } free((void **)newEArray); free((void **)CopyNewEArray); *NumUpdates += NumUpdates_loc; *totalValue += totalValue_loc; *totalChange += totalChange_loc; } /* END super_voxel_recon() */ void coordinateShuffle(int *order1, int *order2,int len) { int i, j, tmp1,tmp2; for (i = 0; i < len-1; i++) { j = i + (rand() % (len-i)); tmp1 = order1[j]; tmp2 = order2[j]; order1[j] = order1[i]; order2[j] = order2[i]; order1[i] = tmp1; order2[i] = tmp2; } } void three_way_shuffle(long *order1, char *order2, struct heap_node *headNodeArray, int len) { int i,j; long tmp_long; char tmp_char; float temp_x; for (i = 0; i < len-1; i++) { j = i + (rand() % (len-i)); tmp_long = order1[j]; order1[j] = order1[i]; order1[i] = tmp_long; tmp_char = order2[j]; order2[j] = order2[i]; order2[i] = tmp_char; temp_x=headNodeArray[j].x; headNodeArray[j].x=headNodeArray[i].x; headNodeArray[i].x=temp_x; } } float MAPCostFunction3D(float **e,struct Image3D *Image,struct Sino3DParallel *sinogram,struct ReconParams *reconparams) { int i, M, j, jx, jy, jz, Nx, Ny, Nz, plusx, minusx, plusy, plusz ; float **x ; float **w ; float nloglike, nlogprior_nearest, nlogprior_diag, nlogprior_interslice ; x = Image->image; w = sinogram->weight; M = sinogram->sinoparams.NViews * sinogram->sinoparams.NChannels ; Nx = Image->imgparams.Nx; Ny = Image->imgparams.Ny; Nz = Image->imgparams.Nz; nloglike = 0.0; for (i = 0; i <sinogram->sinoparams.NSlices; i++){ for (j = 0; j < M; j++) nloglike += e[i][j]*w[i][j]*e[i][j]; } nloglike /= 2.0; nlogprior_nearest = 0.0; nlogprior_diag = 0.0; nlogprior_interslice = 0.0; for (jz = 0; jz < Nz; jz++) for (jy = 0; jy < Ny; jy++) for (jx = 0; jx < Nx; jx++) { plusx = jx + 1; plusx = ((plusx < Nx) ? plusx : 0); minusx = jx - 1; minusx = ((minusx < 0) ? Nx-1 : minusx); plusy = jy + 1; plusy = ((plusy < Ny) ? plusy : 0); plusz = jz + 1; plusz = ((plusz < Nz) ? plusz : 0); j = jy*Nx + jx; nlogprior_nearest += QGGMRF_Potential((x[jz][j] - x[jz][jy*Nx+plusx]), reconparams); nlogprior_nearest += QGGMRF_Potential((x[jz][j] - x[jz][plusy*Nx+jx]),reconparams); nlogprior_diag += QGGMRF_Potential((x[jz][j] - x[jz][plusy*Nx+minusx]),reconparams); nlogprior_diag += QGGMRF_Potential((x[jz][j] - x[jz][plusy*Nx+plusx]),reconparams); nlogprior_interslice += QGGMRF_Potential((x[jz][j] - x[plusz][jy*Nx+jx]),reconparams); } return (nloglike + reconparams->b_nearest * nlogprior_nearest + reconparams->b_diag * nlogprior_diag + reconparams->b_interslice * nlogprior_interslice) ; } #if 0 // NOTE this needs to be updated void read_golden(char *fname,float **golden,int Nz,int N, struct Image3D *Image) { FILE *fp; int i; char slicefname[1024]; char *sliceindex; sliceindex= (char *)malloc(MBIR_MODULAR_MAX_NUMBER_OF_SLICE_DIGITS); for(i=0;i<Nz;i++){ sprintf(sliceindex,"%.*d",MBIR_MODULAR_MAX_NUMBER_OF_SLICE_DIGITS,Image->imgparams.FirstSliceNumber+i); /* Obtain file name for the given slice */ strcpy(slicefname,fname); strcat(slicefname,"_slice"); strcat(slicefname,sliceindex); /* append slice index */ strcat(slicefname,".2Dimgdata"); if ((fp = fopen(slicefname, "r")) == NULL) { fprintf(stderr, "ERROR in read golden: can't open file %s.\n", slicefname); exit(-1); } fread(&golden[i][0],sizeof(float),N,fp); fclose(fp); } } #endif #if 0 static __inline__ unsigned long long rdtsc() { unsigned hi,lo; __asm __volatile__ ("rdtsc" : "=a"(lo),"=d"(hi)); return ( (unsigned long long)lo)|( ((unsigned long long)hi)<<32 ); } #endif

lastPrivate.c

#include <stdio.h> #include <stdlib.h> #include <omp.h> int main(void){ int i; int x; x=44; #pragma omp parallel #pragma omp for lastprivate(x) for(i=0;i<=10;i++){ x=i; printf("Thread number: %d x: %d\n",omp_get_thread_num(),x); } printf("x is %d\n", x); }

j3d27pt.gold.h

#include <cstring> using std::memcpy; template <class T> void jacobi_gold(T *fout, const T *fin, double h2inv, double a, double b, int L, int M, int N) { double (*out)[M][N] = (double (*)[M][N]) fout; double (*in)[M][N] = (double (*)[M][N]) fin; auto ftemp1 = new T[L * M * N]; auto ftemp2 = new T[L * M * N]; memset(ftemp1, 0, sizeof(T)*L*M*N); memset(ftemp2, 0, sizeof(T)*L*M*N); double (*temp1)[M][N] = (T (*)[M][N]) ftemp1; double (*temp2)[M][N] = (T (*)[M][N]) ftemp2; memcpy(ftemp1, fin, sizeof(T)*L*M*N); double c = b * h2inv; double d = c * 0.5; double e = c * 0.125; double f = c * 0.3; for (int t = 0; t < 8; t++) { #pragma omp parallel for for (int k = 1; k < L - 1; ++k) { for (int j = 1; j < M - 1; ++j) { for (int i = 1; i < N - 1; ++i) { if (!(t%2)) { temp2[k][j][i] = a*temp1[k][j][i] - d*(temp1[k-1][j-1][i-1] + temp1[k-1][j-1][i+1] + temp1[k-1][j+1][i-1] + temp1[k-1][j+1][i+1] + temp1[k+1][j-1][i-1] + temp1[k+1][j-1][i+1] + temp1[k+1][j+1][i-1] + temp1[k+1][j+1][i+1]) + e*(temp1[k-1][j-1][i] + temp1[k-1][j][i-1] + temp1[k-1][j][i+1] + temp1[k-1][j+1][i] + temp1[k][j-1][i-1] + temp1[k][j-1][i+1] + temp1[k][j+1][i-1] + temp1[k][j+1][i+1] + temp1[k+1][j-1][i] + temp1[k+1][j][i-1] + temp1[k+1][j][i+1] + temp1[k][j+1][i]) + f*(temp1[k-1][j][i] + temp1[k][j-1][i] + temp1[k][j][i-1] + temp1[k][j][i+1] + temp1[k][j+1][i] + temp1[k+1][j][i]) + 0.13*temp1[k][j][i]; } else { temp1[k][j][i] = a*temp2[k][j][i] - d*(temp2[k-1][j-1][i-1] + temp2[k-1][j-1][i+1] + temp2[k-1][j+1][i-1] + temp2[k-1][j+1][i+1] + temp2[k+1][j-1][i-1] + temp2[k+1][j-1][i+1] + temp2[k+1][j+1][i-1] + temp2[k+1][j+1][i+1]) + e*(temp2[k-1][j-1][i] + temp2[k-1][j][i-1] + temp2[k-1][j][i+1] + temp2[k-1][j+1][i] + temp2[k][j-1][i-1] + temp2[k][j-1][i+1] + temp2[k][j+1][i-1] + temp2[k][j+1][i+1] + temp2[k+1][j-1][i] + temp2[k+1][j][i-1] + temp2[k+1][j][i+1] + temp2[k][j+1][i]) + f*(temp2[k-1][j][i] + temp2[k][j-1][i] + temp2[k][j][i-1] + temp2[k][j][i+1] + temp2[k][j+1][i] + temp2[k+1][j][i]) + 0.13*temp2[k][j][i]; } } } } } memcpy(fout, ftemp1, sizeof(T)*L*M*N); }

GB_AxB_dot2_template.c

//------------------------------------------------------------------------------ // GB_AxB_dot2_template: C=A'B, C<!M>=A'*B, or C<M>=A'*B via dot products //------------------------------------------------------------------------------ // SuiteSparse:GraphBLAS, Timothy A. Davis, (c) 2017-2021, All Rights Reserved. // SPDX-License-Identifier: Apache-2.0 //------------------------------------------------------------------------------ // A and B are sparse, bitmap, or full; never hypersparse. If the input // matrices A and/or B are hypersparse, they are converted into hyper_shallow // sparse matrices, and C is converted from bitmap to sparse/hypersparse when // done. // If A_NOT_TRANSPOSED is #defined, the C=A*B or C<#M>=A*B is computed. // In this case A is bitmap or full, and B is sparse. // GB_DOT_ALWAYS_SAVE_CIJ: C(i,j) = cij #undef GB_DOT_ALWAYS_SAVE_CIJ #if GB_C_IS_FULL #define GB_DOT_ALWAYS_SAVE_CIJ \ { \ GB_PUTC (cij, pC) ; \ } #else #define GB_DOT_ALWAYS_SAVE_CIJ \ { \ GB_PUTC (cij, pC) ; \ Cb [pC] = 1 ; \ task_cnvals++ ; \ } #endif // GB_DOT_SAVE_CIJ: C(i,j) = cij, unless already done by GB_DOT #undef GB_DOT_SAVE_CIJ #if GB_IS_ANY_MONOID // for the ANY monoid, GB_DOT saves C(i,j) as soon as a value is found #define GB_DOT_SAVE_CIJ #else // all other monoids: C(i,j) = cij if it exists #define GB_DOT_SAVE_CIJ \ { \ if (GB_CIJ_EXISTS) \ { \ GB_DOT_ALWAYS_SAVE_CIJ ; \ } \ } #endif #if ( !GB_A_IS_HYPER && !GB_B_IS_HYPER ) { //-------------------------------------------------------------------------- // C=A'*B, C<M>=A'*B, or C<!M>=A'*B where C is bitmap //-------------------------------------------------------------------------- int tid ; #if GB_C_IS_FULL #pragma omp parallel for num_threads(nthreads) schedule(dynamic,1) #else #pragma omp parallel for num_threads(nthreads) schedule(dynamic,1) \ reduction(+:cnvals) #endif for (tid = 0 ; tid < ntasks ; tid++) { //---------------------------------------------------------------------- // get the task descriptor //---------------------------------------------------------------------- const int a_tid = tid / nbslice ; const int b_tid = tid % nbslice ; const int64_t kA_start = A_slice [a_tid] ; const int64_t kA_end = A_slice [a_tid+1] ; const int64_t kB_start = B_slice [b_tid] ; const int64_t kB_end = B_slice [b_tid+1] ; #if (!GB_C_IS_FULL) int64_t task_cnvals = 0 ; #endif //---------------------------------------------------------------------- // C=A'*B, C<M>=A'*B, or C<!M>=A'*B via dot products //---------------------------------------------------------------------- for (int64_t j = kB_start ; j < kB_end ; j++) { //------------------------------------------------------------------ // get C(:,j) //------------------------------------------------------------------ const int64_t pC_start = j * cvlen ; //------------------------------------------------------------------ // get B(:,j) //------------------------------------------------------------------ #if GB_B_IS_SPARSE // B is sparse (never hypersparse) const int64_t pB_start = Bp [j] ; const int64_t pB_end = Bp [j+1] ; const int64_t bjnz = pB_end - pB_start ; if (bjnz == 0) { // no work to do if B(:,j) is empty, except to clear Cb memset (&Cb [pC_start + kA_start], 0, kA_end - kA_start) ; continue ; } #if GB_A_IS_SPARSE // Both A and B are sparse; get first and last in B(:,j) const int64_t ib_first = Bi [pB_start] ; const int64_t ib_last = Bi [pB_end-1] ; #endif #else // B is bitmap or full const int64_t pB_start = j * vlen ; #endif //------------------------------------------------------------------ // C(:,j)<#M(:,j)> = A'*B(:,j), or C(:,j) = A'*B(:,j) if no mask //------------------------------------------------------------------ for (int64_t i = kA_start ; i < kA_end ; i++) { //-------------------------------------------------------------- // get C(i,j), M(i,j), and clear the C(i,j) bitmap //-------------------------------------------------------------- int64_t pC = pC_start + i ; // C is bitmap #if defined ( GB_ANY_SPECIALIZED ) // M is bitmap and structural; Mask_comp true Cb [pC] = 0 ; if (!Mb [pC]) #elif defined ( GB_MASK_IS_PRESENT ) bool mij ; if (M_is_bitmap) { // M is bitmap mij = Mb [pC] && GB_mcast (Mx, pC, msize) ; } else if (M_is_full) { // M is full mij = GB_mcast (Mx, pC, msize) ; } else // M is sparse or hyper { // M has been scattered into the C bitmap mij = (Cb [pC] > 1) ; } Cb [pC] = 0 ; if (mij ^ Mask_comp) #elif GB_C_IS_FULL // C is full; nothing to do #else // M is not present Cb [pC] = 0 ; #endif { //---------------------------------------------------------- // the mask allows C(i,j) to be computed //---------------------------------------------------------- #if GB_A_IS_SPARSE // A is sparse int64_t pA = Ap [i] ; const int64_t pA_end = Ap [i+1] ; const int64_t ainz = pA_end - pA ; #if (!GB_C_IS_FULL) if (ainz > 0) // skip this test if C is full #endif #else // A is bitmap or full #ifdef GB_A_NOT_TRANSPOSED // A(i,:) starts at position i const int64_t pA = i ; #else // A(:,i) starts at position i * vlen const int64_t pA = i * vlen ; #endif #endif { // C(i,j) = A(:,i)'*B(:,j) or A(i,:)*B(:,j) bool cij_exists = false ; GB_CIJ_DECLARE (cij) ; #include "GB_AxB_dot_cij.c" } } } } #if (!GB_C_IS_FULL) cnvals += task_cnvals ; #endif } } #endif #undef GB_A_IS_SPARSE #undef GB_A_IS_HYPER #undef GB_A_IS_BITMAP #undef GB_A_IS_FULL #undef GB_B_IS_SPARSE #undef GB_B_IS_HYPER #undef GB_B_IS_BITMAP #undef GB_B_IS_FULL #undef GB_DOT_ALWAYS_SAVE_CIJ #undef GB_DOT_SAVE_CIJ

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 <nnvm/node.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))); } } void ExecuteMonInputCallback( const nnvm::IndexedGraph &idx, const std::vector<NDArray *> &state_arrays, size_t nid, const std::function<void(const char *, const char *, void *)> &monitor_callback); void ExecuteMonOutputCallback( const nnvm::IndexedGraph &idx, const std::vector<NDArray *> &state_arrays, size_t nid, const std::function<void(const char *, const char *, void *)> &monitor_callback); /*! * \brief This is function can return the output names of a NodeEntry. */ static inline std::string GetOutputName(const nnvm::NodeEntry& e) { nnvm::Symbol sym; sym.outputs.push_back(e); return sym.ListOutputNames()[0]; } inline mxnet::TShape CanonicalizeAxes(const mxnet::TShape& src) { // convert negative axes to positive values const int ndim = src.ndim(); mxnet::TShape axes = src; for (int i = 0; i < ndim; ++i) { if (axes[i] < 0) { axes[i] += ndim; } CHECK(axes[i] >= 0 && axes[i] < ndim) << "axes[" << i << "]=" << axes[i] << " exceeds the range [" << 0 << ", " << ndim << ")"; } return axes; } inline bool is_float(const int dtype) { return dtype == mshadow::kFloat32 || dtype == mshadow::kFloat64 || dtype == mshadow::kFloat16; } } // namespace common } // namespace mxnet #endif // MXNET_COMMON_UTILS_H_

dqp3.c

/*! @copyright (c) 2017 King Abdullah University of Science and * Technology (KAUST). All rights reserved. * * STARS-H is a software package, provided by King Abdullah * University of Science and Technology (KAUST) * * @file src/backends/openmp/blrm/dqp3.c * @version 1.3.0 * @author Aleksandr Mikhalev * @date 2017-11-07 * */ #include "common.h" #include "starsh.h" int starsh_blrm__dqp3_omp(STARSH_blrm **matrix, STARSH_blrf *format, int maxrank, double tol, int onfly) //! Approximate each tile of BLR matrix with RRQR (GEQP3 function). /*! * @param[out] matrix: Address of pointer to @ref STARSH_blrm object. * @param[in] format: Block low-rank format. * @param[in] maxrank: Maximum possible rank. * @param[in] tol: Relative error tolerance. * @param[in] onfly: Whether not to store dense blocks. * @return Error code @ref STARSH_ERRNO. * @ingroup blrm * */ { STARSH_blrf *F = format; STARSH_problem *P = F->problem; STARSH_kernel *kernel = P->kernel; STARSH_int nblocks_far = F->nblocks_far; STARSH_int nblocks_near = F->nblocks_near; // Shortcuts to information about clusters STARSH_cluster *RC = F->row_cluster; STARSH_cluster *CC = F->col_cluster; void *RD = RC->data, *CD = CC->data; // Following values default to given block low-rank format F, but they are // changed when there are false far-field blocks. STARSH_int new_nblocks_far = nblocks_far; STARSH_int new_nblocks_near = nblocks_near; STARSH_int *block_far = F->block_far; STARSH_int *block_near = F->block_near; // Places to store low-rank factors, dense blocks and ranks Array **far_U = NULL, **far_V = NULL, **near_D = NULL; int *far_rank = NULL; double *alloc_U = NULL, *alloc_V = NULL, *alloc_D = NULL; size_t offset_U = 0, offset_V = 0, offset_D = 0; STARSH_int bi, bj = 0; const int oversample = starsh_params.oversample; // Init buffers to store low-rank factors of far-field blocks if needed if(nblocks_far > 0) { STARSH_MALLOC(far_U, nblocks_far); STARSH_MALLOC(far_V, nblocks_far); STARSH_MALLOC(far_rank, nblocks_far); size_t size_U = 0, size_V = 0; // Simple cycle over all far-field blocks for(bi = 0; bi < nblocks_far; bi++) { // Get indexes of corresponding block row and block column STARSH_int i = block_far[2*bi]; STARSH_int j = block_far[2*bi+1]; // Get corresponding sizes and minimum of them size_U += RC->size[i]; size_V += CC->size[j]; } size_U *= maxrank; size_V *= maxrank; STARSH_MALLOC(alloc_U, size_U); STARSH_MALLOC(alloc_V, size_V); for(bi = 0; bi < nblocks_far; bi++) { // Get indexes of corresponding block row and block column STARSH_int i = block_far[2*bi]; STARSH_int j = block_far[2*bi+1]; // Get corresponding sizes and minimum of them size_t nrows = RC->size[i], ncols = CC->size[j]; int shape_U[] = {nrows, maxrank}; int shape_V[] = {ncols, maxrank}; double *U = alloc_U+offset_U, *V = alloc_V+offset_V; offset_U += nrows*maxrank; offset_V += ncols*maxrank; array_from_buffer(far_U+bi, 2, shape_U, 'd', 'F', U); array_from_buffer(far_V+bi, 2, shape_V, 'd', 'F', V); } offset_U = 0; offset_V = 0; } // Work variables int info; // Simple cycle over all far-field admissible blocks #pragma omp parallel for schedule(dynamic,1) for(bi = 0; bi < nblocks_far; bi++) { // Get indexes of corresponding block row and block column STARSH_int i = block_far[2*bi]; STARSH_int j = block_far[2*bi+1]; // Get corresponding sizes and minimum of them int nrows = RC->size[i]; int ncols = CC->size[j]; int mn = nrows < ncols ? nrows : ncols; int mn2 = maxrank+oversample; if(mn2 > mn) mn2 = mn; // Get size of temporary arrays int lwork = 3*ncols+1, lwork_sdd = (4*(size_t)mn2+7)*mn2; if(lwork_sdd > lwork) lwork = lwork_sdd; lwork += (size_t)mn2*(2*ncols+mn2+1)+mn; int liwork = ncols, liwork_sdd = 8*mn2; if(liwork_sdd > liwork) liwork = liwork_sdd; double *D, *work; int *iwork; int info; // Allocate temporary arrays STARSH_PMALLOC(D, (size_t)nrows*(size_t)ncols, info); STARSH_PMALLOC(iwork, liwork, info); STARSH_PMALLOC(work, lwork, info); // Compute elements of a block kernel(nrows, ncols, RC->pivot+RC->start[i], CC->pivot+CC->start[j], RD, CD, D, nrows); starsh_dense_dlrqp3(nrows, ncols, D, nrows, far_U[bi]->data, nrows, far_V[bi]->data, ncols, far_rank+bi, maxrank, oversample, tol, work, lwork, iwork); // Free temporary arrays free(D); free(work); free(iwork); } // Get number of false far-field blocks STARSH_int nblocks_false_far = 0; STARSH_int *false_far = NULL; for(bi = 0; bi < nblocks_far; bi++) if(far_rank[bi] == -1) nblocks_false_far++; if(nblocks_false_far > 0) { // IMPORTANT: `false_far` must to be in ascending order for later code // to work normally STARSH_MALLOC(false_far, nblocks_false_far); bj = 0; for(bi = 0; bi < nblocks_far; bi++) if(far_rank[bi] == -1) false_far[bj++] = bi; } // Update lists of far-field and near-field blocks using previously // generated list of false far-field blocks if(nblocks_false_far > 0) { // Update list of near-field blocks new_nblocks_near = nblocks_near+nblocks_false_far; STARSH_MALLOC(block_near, 2*new_nblocks_near); // At first get all near-field blocks, assumed to be dense #pragma omp parallel for schedule(static) for(bi = 0; bi < 2*nblocks_near; bi++) block_near[bi] = F->block_near[bi]; // Add false far-field blocks #pragma omp parallel for schedule(static) for(bi = 0; bi < nblocks_false_far; bi++) { STARSH_int bj = false_far[bi]; block_near[2*(bi+nblocks_near)] = F->block_far[2*bj]; block_near[2*(bi+nblocks_near)+1] = F->block_far[2*bj+1]; } // Update list of far-field blocks new_nblocks_far = nblocks_far-nblocks_false_far; if(new_nblocks_far > 0) { STARSH_MALLOC(block_far, 2*new_nblocks_far); bj = 0; for(bi = 0; bi < nblocks_far; bi++) { // `false_far` must be in ascending order for this to work if(far_rank[bi] == -1) { bj++; } else { block_far[2*(bi-bj)] = F->block_far[2*bi]; block_far[2*(bi-bj)+1] = F->block_far[2*bi+1]; } } } // Update format by creating new format STARSH_blrf *F2; info = starsh_blrf_new_from_coo(&F2, P, F->symm, RC, CC, new_nblocks_far, block_far, new_nblocks_near, block_near, F->type); // Swap internal data of formats and free unnecessary data STARSH_blrf tmp_blrf = *F; *F = *F2; *F2 = tmp_blrf; STARSH_WARNING("`F` was modified due to false far-field blocks"); starsh_blrf_free(F2); } // Compute near-field blocks if needed if(onfly == 0 && new_nblocks_near > 0) { STARSH_MALLOC(near_D, new_nblocks_near); size_t size_D = 0; // Simple cycle over all near-field blocks for(bi = 0; bi < new_nblocks_near; bi++) { // Get indexes of corresponding block row and block column STARSH_int i = block_near[2*bi]; STARSH_int j = block_near[2*bi+1]; // Get corresponding sizes and minimum of them size_t nrows = RC->size[i]; size_t ncols = CC->size[j]; // Update size_D size_D += nrows*ncols; } STARSH_MALLOC(alloc_D, size_D); // For each near-field block compute its elements #pragma omp parallel for schedule(dynamic,1) for(bi = 0; bi < new_nblocks_near; bi++) { // Get indexes of corresponding block row and block column STARSH_int i = block_near[2*bi]; STARSH_int j = block_near[2*bi+1]; // Get corresponding sizes and minimum of them int nrows = RC->size[i]; int ncols = CC->size[j]; int shape[2] = {nrows, ncols}; double *D; #pragma omp critical { D = alloc_D+offset_D; array_from_buffer(near_D+bi, 2, shape, 'd', 'F', D); offset_D += near_D[bi]->size; } kernel(nrows, ncols, RC->pivot+RC->start[i], CC->pivot+CC->start[j], RD, CD, D, nrows); } } // Change sizes of far_rank, far_U and far_V if there were false // far-field blocks if(nblocks_false_far > 0 && new_nblocks_far > 0) { bj = 0; for(bi = 0; bi < nblocks_far; bi++) { if(far_rank[bi] == -1) bj++; else { int shape_U[2] = {far_U[bi]->shape[0], far_rank[bi]}; int shape_V[2] = {far_V[bi]->shape[0], far_rank[bi]}; array_from_buffer(far_U+bi-bj, 2, shape_U, 'd', 'F', far_U[bi]->data); array_from_buffer(far_V+bi-bj, 2, shape_V, 'd', 'F', far_V[bi]->data); far_rank[bi-bj] = far_rank[bi]; } } STARSH_REALLOC(far_rank, new_nblocks_far); STARSH_REALLOC(far_U, new_nblocks_far); STARSH_REALLOC(far_V, new_nblocks_far); //STARSH_REALLOC(alloc_U, offset_U); //STARSH_REALLOC(alloc_V, offset_V); } // If all far-field blocks are false, then dealloc buffers if(new_nblocks_far == 0 && nblocks_far > 0) { block_far = NULL; free(far_rank); far_rank = NULL; free(far_U); far_U = NULL; free(far_V); far_V = NULL; free(alloc_U); alloc_U = NULL; free(alloc_V); alloc_V = NULL; } // Dealloc list of false far-field blocks if it is not empty if(nblocks_false_far > 0) free(false_far); // Finish with creating instance of Block Low-Rank Matrix with given // buffers return starsh_blrm_new(matrix, F, far_rank, far_U, far_V, onfly, near_D, alloc_U, alloc_V, alloc_D, '1'); }

GB_AxB_dot3.c

//------------------------------------------------------------------------------ // GB_AxB_dot3: compute C<M> = A'*B in parallel //------------------------------------------------------------------------------ // SuiteSparse:GraphBLAS, Timothy A. Davis, (c) 2017-2020, All Rights Reserved. // http://suitesparse.com See GraphBLAS/Doc/License.txt for license. //------------------------------------------------------------------------------ // This function only computes C<M>=A'*B. The mask must be present, and not // complemented. The mask is always applied. #include "GB_mxm.h" #ifndef GBCOMPACT #include "GB_AxB__include.h" #endif #define GB_FREE_WORK \ { \ GB_FREE_MEMORY (TaskList, max_ntasks+1, sizeof (GB_task_struct)) ; \ } #define GB_FREE_ALL \ { \ GB_FREE_WORK ; \ GB_MATRIX_FREE (Chandle) ; \ } GrB_Info GB_AxB_dot3 // C<M> = A'*B using dot product method ( GrB_Matrix *Chandle, // output matrix const GrB_Matrix M, // mask matrix const bool Mask_struct, // if true, use the only structure of M const GrB_Matrix A, // input matrix const GrB_Matrix B, // input matrix const GrB_Semiring semiring, // semiring that defines C=A*B const bool flipxy, // if true, do z=fmult(b,a) vs fmult(a,b) GB_Context Context ) { //-------------------------------------------------------------------------- // check inputs //-------------------------------------------------------------------------- GrB_Info info ; ASSERT (Chandle != NULL) ; ASSERT (*Chandle == NULL) ; ASSERT_MATRIX_OK (M, "M for dot3 A'*B", GB0) ; ASSERT_MATRIX_OK (A, "A for dot3 A'*B", GB0) ; ASSERT_MATRIX_OK (B, "B for dot3 A'*B", GB0) ; ASSERT (!GB_PENDING (M)) ; ASSERT (!GB_ZOMBIES (M)) ; ASSERT (!GB_PENDING (A)) ; ASSERT (!GB_ZOMBIES (A)) ; ASSERT (!GB_PENDING (B)) ; ASSERT (!GB_ZOMBIES (B)) ; ASSERT_SEMIRING_OK (semiring, "semiring for numeric A'*B", GB0) ; ASSERT (A->vlen == B->vlen) ; int ntasks, max_ntasks = 0, nthreads ; GB_task_struct *TaskList = NULL ; //-------------------------------------------------------------------------- // get the semiring operators //-------------------------------------------------------------------------- GrB_BinaryOp mult = semiring->multiply ; GrB_Monoid add = semiring->add ; ASSERT (mult->ztype == add->op->ztype) ; bool op_is_first = mult->opcode == GB_FIRST_opcode ; bool op_is_second = mult->opcode == GB_SECOND_opcode ; bool op_is_pair = mult->opcode == GB_PAIR_opcode ; bool A_is_pattern = false ; bool B_is_pattern = false ; if (flipxy) { // z = fmult (b,a) will be computed A_is_pattern = op_is_first || op_is_pair ; B_is_pattern = op_is_second || op_is_pair ; ASSERT (GB_IMPLIES (!A_is_pattern, GB_Type_compatible (A->type, mult->ytype))) ; ASSERT (GB_IMPLIES (!B_is_pattern, GB_Type_compatible (B->type, mult->xtype))) ; } else { // z = fmult (a,b) will be computed A_is_pattern = op_is_second || op_is_pair ; B_is_pattern = op_is_first || op_is_pair ; ASSERT (GB_IMPLIES (!A_is_pattern, GB_Type_compatible (A->type, mult->xtype))) ; ASSERT (GB_IMPLIES (!B_is_pattern, GB_Type_compatible (B->type, mult->ytype))) ; } (*Chandle) = NULL ; //-------------------------------------------------------------------------- // get M, A, and B //-------------------------------------------------------------------------- const int64_t *GB_RESTRICT Mp = M->p ; const int64_t *GB_RESTRICT Mh = M->h ; const int64_t *GB_RESTRICT Mi = M->i ; const GB_void *GB_RESTRICT Mx = (Mask_struct ? NULL : (M->x)) ; const size_t msize = M->type->size ; const int64_t mvlen = M->vlen ; const int64_t mvdim = M->vdim ; const int64_t mnz = GB_NNZ (M) ; const int64_t mnvec = M->nvec ; const bool M_is_hyper = M->is_hyper ; const int64_t *GB_RESTRICT Ap = A->p ; const int64_t *GB_RESTRICT Ah = A->h ; // const int64_t *GB_RESTRICT Ai = A->i ; // const int64_t avlen = A->vlen ; // const int64_t avdim = A->vdim ; // const int64_t anz = GB_NNZ (A) ; const int64_t anvec = A->nvec ; const bool A_is_hyper = A->is_hyper ; const int64_t *GB_RESTRICT Bp = B->p ; const int64_t *GB_RESTRICT Bh = B->h ; // const int64_t *GB_RESTRICT Bi = B->i ; // const int64_t bvlen = B->vlen ; // const int64_t bvdim = B->vdim ; // const int64_t bnz = GB_NNZ (B) ; const int64_t bnvec = B->nvec ; const bool B_is_hyper = B->is_hyper ; //-------------------------------------------------------------------------- // allocate C, the same size and # of entries as M //-------------------------------------------------------------------------- GrB_Type ctype = add->op->ztype ; int64_t cvlen = mvlen ; int64_t cvdim = mvdim ; int64_t cnz = mnz ; int64_t cnvec = mnvec ; GB_CREATE (Chandle, ctype, cvlen, cvdim, GB_Ap_malloc, true, GB_SAME_HYPER_AS (M_is_hyper), M->hyper_ratio, cnvec, cnz+1, // add one to cnz for GB_cumsum of Cwork in GB_AxB_dot3_slice true, Context) ; if (info != GrB_SUCCESS) { // out of memory GB_FREE_ALL ; return (info) ; } GrB_Matrix C = (*Chandle) ; int64_t *GB_RESTRICT Cp = C->p ; int64_t *GB_RESTRICT Ch = C->h ; int64_t *GB_RESTRICT Cwork = C->i ; // use C->i as workspace //-------------------------------------------------------------------------- // determine the # of threads to use //-------------------------------------------------------------------------- GB_GET_NTHREADS_MAX (nthreads_max, chunk, Context) ; //-------------------------------------------------------------------------- // copy Mp and Mh into C //-------------------------------------------------------------------------- // FUTURE:: C->p and C->h could be shallow copies of M->p and M->h, which // could same some time and memory if C is then, say, transposed by // GB_accum_mask later on. nthreads = GB_nthreads (cnvec, chunk, nthreads_max) ; GB_memcpy (Cp, Mp, (cnvec+1) * sizeof (int64_t), nthreads) ; if (M_is_hyper) { GB_memcpy (Ch, Mh, cnvec * sizeof (int64_t), nthreads) ; } C->magic = GB_MAGIC ; C->nvec_nonempty = M->nvec_nonempty ; C->nvec = M->nvec ; //-------------------------------------------------------------------------- // construct the tasks for the first phase //-------------------------------------------------------------------------- nthreads = GB_nthreads (cnz, chunk, nthreads_max) ; GB_OK (GB_AxB_dot3_one_slice (&TaskList, &max_ntasks, &ntasks, &nthreads, M, Context)) ; //-------------------------------------------------------------------------- // phase1: estimate the work to compute each entry in C //-------------------------------------------------------------------------- // The work to compute C(i,j) is held in Cwork [p], if C(i,j) appears in // as the pth entry in C. int taskid; #pragma omp parallel for num_threads(nthreads) schedule(dynamic,1) for (taskid = 0 ; taskid < ntasks ; taskid++) { //---------------------------------------------------------------------- // get the task descriptor //---------------------------------------------------------------------- // GB_GET_TASK_DESCRIPTOR ; int64_t kfirst = TaskList [taskid].kfirst ; int64_t klast = TaskList [taskid].klast ; bool fine_task = (klast == -1) ; if (fine_task) { // a fine task operates on a slice of a single vector klast = kfirst ; } int64_t bpleft = 0 ; //---------------------------------------------------------------------- // compute all vectors in this task //---------------------------------------------------------------------- for (int64_t k = kfirst ; k <= klast ; k++) { //------------------------------------------------------------------ // get j, the kth vector of C and M //------------------------------------------------------------------ int64_t j = (Mh == NULL) ? k : Mh [k] ; GB_GET_VECTOR (pM, pM_end, pM, pM_end, Mp, k) ; //------------------------------------------------------------------ // get B(:,j) //------------------------------------------------------------------ int64_t pB, pB_end ; GB_lookup (B_is_hyper, Bh, Bp, &bpleft, bnvec-1, j, &pB, &pB_end) ; int64_t bjnz = pB_end - pB ; //------------------------------------------------------------------ // estimate the work to compute each entry of C(:,j) //------------------------------------------------------------------ // A decent estimate of the work to compute the dot product C(i,j) // = A(:,i)'*B(:,j) is min (|A(:,i)|, |B(:,j)|) + 1. This is a // lower bound. The actual work could require a binary search of // either A(:,i) or B(:,j), or a merge of the two vectors. Or it // could require no work at all if all entries in A(:,i) appear // before all entries in B(:,j), or visa versa. No work is done if // M(i,j)=0. A more accurate estimate is possible to compute, // following the different methods used in // Template/GB_AxB_dot_cij.c. if (bjnz == 0) { // B(:,j) is empty, so C(:,j) is empty as well. No work is to // be done, but it still takes unit work to flag each C(:,j) as // a zombie for ( ; pM < pM_end ; pM++) { Cwork [pM] = 1 ; } } else { int64_t apleft = 0 ; for ( ; pM < pM_end ; pM++) { int64_t work = 1 ; if (GB_mcast (Mx, pM, msize)) { int64_t pA, pA_end, i = Mi [pM] ; GB_lookup (A_is_hyper, Ah, Ap, &apleft, anvec-1, i, &pA, &pA_end) ; int64_t ajnz = pA_end - pA ; work += GB_IMIN (ajnz, bjnz) ; } Cwork [pM] = work ; } } } } //-------------------------------------------------------------------------- // free the current tasks and construct the tasks for the second phase //-------------------------------------------------------------------------- GB_FREE_MEMORY (TaskList, max_ntasks+1, sizeof (GB_task_struct)) ; GB_OK (GB_AxB_dot3_slice (&TaskList, &max_ntasks, &ntasks, &nthreads, C, Context)) ; GBBURBLE ("nthreads %d ntasks %d ", nthreads, ntasks) ; //-------------------------------------------------------------------------- // C<M> = A'*B, via masked dot product method and built-in semiring //-------------------------------------------------------------------------- bool done = false ; #ifndef GBCOMPACT //-------------------------------------------------------------------------- // define the worker for the switch factory //-------------------------------------------------------------------------- #define GB_Adot3B(add,mult,xyname) GB_Adot3B_ ## add ## mult ## xyname #define GB_AxB_WORKER(add,mult,xyname) \ { \ info = GB_Adot3B (add,mult,xyname) (C, M, Mask_struct, \ A, A_is_pattern, B, B_is_pattern, \ TaskList, ntasks, nthreads) ; \ done = (info != GrB_NO_VALUE) ; \ } \ break ; //-------------------------------------------------------------------------- // launch the switch factory //-------------------------------------------------------------------------- GB_Opcode mult_opcode, add_opcode ; GB_Type_code xycode, zcode ; if (GB_AxB_semiring_builtin (A, A_is_pattern, B, B_is_pattern, semiring, flipxy, &mult_opcode, &add_opcode, &xycode, &zcode)) { #include "GB_AxB_factory.c" } #endif //-------------------------------------------------------------------------- // C<M> = A'*B, via masked dot product method and typecasting //-------------------------------------------------------------------------- if (!done) { GB_BURBLE_MATRIX (C, "generic ") ; //---------------------------------------------------------------------- // get operators, functions, workspace, contents of A, B, C, and M //---------------------------------------------------------------------- GxB_binary_function fmult = mult->function ; GxB_binary_function fadd = add->op->function ; size_t csize = C->type->size ; size_t asize = A_is_pattern ? 0 : A->type->size ; size_t bsize = B_is_pattern ? 0 : B->type->size ; size_t xsize = mult->xtype->size ; size_t ysize = mult->ytype->size ; // scalar workspace: because of typecasting, the x/y types need not // be the same as the size of the A and B types. // flipxy false: aki = (xtype) A(k,i) and bkj = (ytype) B(k,j) // flipxy true: aki = (ytype) A(k,i) and bkj = (xtype) B(k,j) size_t aki_size = flipxy ? ysize : xsize ; size_t bkj_size = flipxy ? xsize : ysize ; GB_void *GB_RESTRICT terminal = add->terminal ; GB_cast_function cast_A, cast_B ; if (flipxy) { // A is typecasted to y, and B is typecasted to x cast_A = A_is_pattern ? NULL : GB_cast_factory (mult->ytype->code, A->type->code) ; cast_B = B_is_pattern ? NULL : GB_cast_factory (mult->xtype->code, B->type->code) ; } else { // A is typecasted to x, and B is typecasted to y cast_A = A_is_pattern ? NULL : GB_cast_factory (mult->xtype->code, A->type->code) ; cast_B = B_is_pattern ? NULL : GB_cast_factory (mult->ytype->code, B->type->code) ; } //---------------------------------------------------------------------- // C<M> = A'*B via dot products, function pointers, and typecasting //---------------------------------------------------------------------- // aki = A(k,i), located in Ax [pA] #define GB_GETA(aki,Ax,pA) \ GB_void aki [GB_VLA(aki_size)] ; \ if (!A_is_pattern) cast_A (aki, Ax +((pA)*asize), asize) // bkj = B(k,j), located in Bx [pB] #define GB_GETB(bkj,Bx,pB) \ GB_void bkj [GB_VLA(bkj_size)] ; \ if (!B_is_pattern) cast_B (bkj, Bx +((pB)*bsize), bsize) // break if cij reaches the terminal value #define GB_DOT_TERMINAL(cij) \ if (terminal != NULL && memcmp (cij, terminal, csize) == 0) \ { \ break ; \ } // C(i,j) = A(i,k) * B(k,j) #define GB_MULT(cij, aki, bkj) \ GB_MULTIPLY (cij, aki, bkj) // C(i,j) += A(i,k) * B(k,j) #define GB_MULTADD(cij, aki, bkj) \ GB_void zwork [GB_VLA(csize)] ; \ GB_MULTIPLY (zwork, aki, bkj) ; \ fadd (cij, cij, zwork) // define cij for each task #define GB_CIJ_DECLARE(cij) \ GB_void cij [GB_VLA(csize)] // address of Cx [p] #define GB_CX(p) Cx +((p)*csize) // save the value of C(i,j) #define GB_CIJ_SAVE(cij,p) \ memcpy (GB_CX (p), cij, csize) #define GB_ATYPE GB_void #define GB_BTYPE GB_void #define GB_CTYPE GB_void // no vectorization #define GB_PRAGMA_VECTORIZE #define GB_PRAGMA_VECTORIZE_DOT if (flipxy) { #define GB_MULTIPLY(z,x,y) fmult (z,y,x) #include "GB_AxB_dot3_template.c" #undef GB_MULTIPLY } else { #define GB_MULTIPLY(z,x,y) fmult (z,x,y) #include "GB_AxB_dot3_template.c" #undef GB_MULTIPLY } } //-------------------------------------------------------------------------- // free workspace and return result //-------------------------------------------------------------------------- if (C->nzombies > 0) { // C has been created with zombies, so place it in the queue GB_CRITICAL (GB_queue_insert (C)) ; } GB_FREE_WORK ; ASSERT_MATRIX_OK (C, "dot3: C<M> = A'*B output", GB0) ; ASSERT (*Chandle == C) ; ASSERT (GB_ZOMBIES_OK (C)) ; ASSERT (!GB_PENDING (C)) ; return (GrB_SUCCESS) ; }

3d25pt_var.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 25 point stencil with axis-symmetric ariable 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])+8; Ny = atoi(argv[2])+8; Nz = atoi(argv[3])+8; } 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***)*13); for(m=0; m<13;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] = 4; tile_size[3] = 2048; 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<13; 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 /* 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<=floord(Nt-1,2);t1++) { lbp=max(ceild(t1,2),ceild(4*t1-Nt+2,4)); ubp=min(floord(4*Nt+Nz-9,16),floord(8*t1+Nz+2,16)); #pragma omp parallel for private(lbv,ubv,t3,t4,t5,t6,t7,t8) for (t2=lbp;t2<=ubp;t2++) { for (t3=max(max(max(1,ceild(16*t2-Nz+9,4)),2*t1+1),4*t1-4*t2+2);t3<=min(min(min(floord(4*Nt+Ny-9,4),floord(8*t1+Ny+7,4)),floord(16*t2+Ny+3,4)),floord(16*t1-16*t2+Nz+Ny+5,4));t3++) { for (t4=max(max(max(0,ceild(t1-255,256)),ceild(16*t2-Nz-2035,2048)),ceild(4*t3-Ny-2035,2048));t4<=min(min(min(min(floord(4*Nt+Nx-9,2048),floord(8*t1+Nx+7,2048)),floord(16*t2+Nx+3,2048)),floord(4*t3+Nx-9,2048)),floord(16*t1-16*t2+Nz+Nx+5,2048));t4++) { for (t5=max(max(max(max(max(0,ceild(16*t2-Nz+5,4)),ceild(4*t3-Ny+5,4)),ceild(2048*t4-Nx+5,4)),2*t1),4*t1-4*t2+1);t5<=min(min(min(min(min(floord(16*t1-16*t2+Nz+10,4),Nt-1),2*t1+3),4*t2+2),t3-1),512*t4+510);t5++) { for (t6=max(max(16*t2,4*t5+4),-16*t1+16*t2+8*t5-15);t6<=min(min(16*t2+15,-16*t1+16*t2+8*t5),4*t5+Nz-5);t6++) { for (t7=4*t3;t7<=min(4*t3+3,4*t5+Ny-5);t7++) { lbv=max(2048*t4,4*t5+4); ubv=min(2048*t4+2047,4*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)] = (((((((((((((coef[0][ (-4*t5+t6)][ (-4*t5+t7)][ (-4*t5+t8)] * A[ t5 % 2][ (-4*t5+t6)][ (-4*t5+t7)][ (-4*t5+t8)]) + (coef[1][ (-4*t5+t6)][ (-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) + 1][ (-4*t5+t7)][ (-4*t5+t8)]))) + (coef[2][ (-4*t5+t6)][ (-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)]))) + (coef[3][ (-4*t5+t6)][ (-4*t5+t7)][ (-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]))) + (coef[4][ (-4*t5+t6)][ (-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) + 2][ (-4*t5+t7)][ (-4*t5+t8)]))) + (coef[5][ (-4*t5+t6)][ (-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)]))) + (coef[6][ (-4*t5+t6)][ (-4*t5+t7)][ (-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]))) + (coef[7][ (-4*t5+t6)][ (-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) + 3][ (-4*t5+t7)][ (-4*t5+t8)]))) + (coef[8][ (-4*t5+t6)][ (-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)]))) + (coef[9][ (-4*t5+t6)][ (-4*t5+t7)][ (-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]))) + (coef[10][ (-4*t5+t6)][ (-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][ (-4*t5+t7)][ (-4*t5+t8)]))) + (coef[11][ (-4*t5+t6)][ (-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)]))) + (coef[12][ (-4*t5+t6)][ (-4*t5+t7)][ (-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, "variable axis-symmetric") #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<13;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; }

ClientComm.h

/*! @brief Flag for checking if this header has already been included. */ #ifndef YGGCLIENTCOMM_H_ #define YGGCLIENTCOMM_H_ #include <../tools.h> #include <CommBase.h> #include <DefaultComm.h> #include "../datatypes/datatypes.h" #ifdef __cplusplus /* If this is a C++ compiler, use C linkage */ extern "C" { #endif // Handle is send address // Info is response static unsigned _client_rand_seeded = 0; // @brief Structure for storing requests/responses typedef struct responses_t { comm_t* comm; //!< Response comm. size_t nreq; //!< Number of requests sent. char** request_id; //!< Request ids. char** data; //!< Received responses size_t* len; //!< Lengths of received messages. } responses_t; /*! @brief Create a new registry of requests and responses. @returns responses_t* Structure containing a registry of requests and responses. */ static inline responses_t* client_new_responses() { responses_t* out = (responses_t*)malloc(sizeof(responses_t)); if (out != NULL) { out->comm = NULL; out->nreq = 0; out->request_id = NULL; out->data = NULL; out->len = NULL; } return out; }; /*! @brief Free a registry of requests and responses. @param[in] x responses_t** Pointer to structure containing a registry of requests and responses. */ static inline void client_free_responses(responses_t** x) { if (x[0] != NULL) { if (x[0]->comm != NULL) { free_default_comm(x[0]->comm); free_comm_base(x[0]->comm); } if (x[0]->data != NULL) { for (size_t i = 0; i < x[0]->nreq; i++) if (x[0]->data[i] != NULL) free(x[0]->data[i]); free(x[0]->data); } if (x[0]->len != NULL) free(x[0]->len); free(x[0]); x[0] = NULL; } }; /*! @brief Determine if there is a request in the registry. @param[in] x responses_t* Structure containing a registry of requests and responses. @param[in] request_id const char* ID associated with the request to check for. @returns int -1 if there is an error, otherwise the index of the request in the registry. */ static inline int client_has_request(responses_t *x, const char* request_id) { if (x == NULL) return -1; for (size_t i = 0; i < x->nreq; i++) { if (strcmp(x->request_id[i], request_id) == 0) return (int)i; } return -1; }; /*! @brief Determine if there is a response in the registry. @param[in] x responses_t* Structure containing a registry of requests and responses. @param[in] request_id const char* ID associated with the response to check for. @returns int -1 if there is an error, otherwise the index of the response in the registry. */ static inline int client_has_response(responses_t *x, const char* request_id) { int idx = client_has_request(x, request_id); if (idx < 0) return idx; if (x->data[idx] != NULL) return idx; return -1; }; /*! @brief Add a request to the registry. @param[in] x responses_t* Structure containing a registry of requests and responses. @param[in] request_id const char* ID associated with the request being added. @returns int -1 if there is an error, 0 otherwise. */ static inline int client_add_request(responses_t *x, const char* request_id) { if (x == NULL) return -1; x->request_id = (char**)realloc(x->request_id, (x->nreq + 1) * sizeof(char*)); if (x->request_id == NULL) return -1; size_t request_len = strlen(request_id); x->request_id[x->nreq] = (char*)malloc(request_len + 1); if (x->request_id[x->nreq] == NULL) return -1; memcpy(x->request_id[x->nreq], request_id, request_len); x->request_id[x->nreq][request_len] = '\0'; x->data = (char**)realloc(x->data, (x->nreq + 1) * sizeof(char*)); if (x->data == NULL) return -1; x->data[x->nreq] = NULL; x->len = (size_t*)realloc(x->len, (x->nreq + 1) * sizeof(size_t)); if (x->len == NULL) return -1; x->len[x->nreq] = 0; x->nreq++; return 0; }; /*! @brief Add a response to the registry. @param[in] x responses_t* Structure containing a registry of requests and responses. @param[in] request_id const char* ID associated with the response being added. @param[in] data const char* Response message. @param[in] len size_t Size of the response message. @returns int -1 if there is an error, 0 otherwise. */ static inline int client_add_response(responses_t *x, const char* request_id, const char* data, const size_t len) { int idx = client_has_request(x, request_id); if (idx < 0) { ygglog_error("client_add_response: idx = %d", idx); return idx; } x->data[idx] = (char*)malloc(len + 1); if (x->data[idx] == NULL) { ygglog_error("client_add_response: failed to malloc data"); return -1; } memcpy(x->data[idx], data, len); x->data[idx][len] = '\0'; x->len[idx] = len; return 0; }; /*! @brief Remove a request/response from the registry. @param[in] x responses_t* Structure containing a registry of requests and responses. @param[in] request_id const char* ID associated with the request/response that should be removed. @returns int -1 if there is an error, 0 otherwise. */ static inline int client_remove_request(responses_t *x, const char* request_id) { if (x == NULL) return -1; int idx = client_has_request(x, request_id); if (idx < 0) return 0; int nrem = x->nreq - (idx + 1); free(x->request_id[idx]); if (x->data[idx] != NULL) free(x->data[idx]); if (nrem > 0) { memmove(x->request_id + idx, x->request_id + idx + 1, nrem * sizeof(char*)); memmove(x->data + idx, x->data + idx + 1, nrem * sizeof(char*)); memmove(x->len + idx, x->len + idx + 1, nrem * sizeof(size_t)); } x->nreq--; return 0; }; /*! @brief Remove and return a response from the registry after it has been received. @param[in] x responses_t* Structure containing a registry of requests and responses. @param[in] request_id const char* ID associated with the response that should be removed and returned. @param[in,out] data char** Pointer to memory where the response should be stored. @param[in] len const size_t Size of the existing buffer pointed to by data. @param[in] allow_realloc int If 1 and the response exceeds len, the buffer pointed to by data will be reallocated, if 0 and the response exceeds len, an error will be returned. @returns int -1 if there is an error, otherwise the size of the reponse message will be returned. */ static inline int client_pop_response(responses_t *x, const char* request_id, char **data, const size_t len, const int allow_realloc) { if (x == NULL) return -1; int idx = client_has_response(x, request_id); if (idx < 0) return -1; int ret = x->len[idx]; if ((ret + 1) > len) { if (allow_realloc) { ygglog_debug("client_pop_response: reallocating buffer from %d to %d bytes.", len, ret + 1); (*data) = (char*)realloc(*data, ret + 1); if (*data == NULL) { ygglog_error("client_pop_response: failed to realloc buffer."); return -1; } } else { ygglog_error("client_pop_response: buffer (%d bytes) is not large enough for message (%d bytes)", len, ret + 1); return -((int)(ret)); } } memcpy(*data, x->data[idx], ret); (*data)[ret] = '\0'; if (client_remove_request(x, request_id) < 0) return -1; return ret; }; /*! @brief Create a new channel. @param[in] comm comm_t * Comm structure initialized with new_comm_base. @returns int -1 if the address could not be created. */ static inline int new_client_address(comm_t *comm) { #ifdef _OPENMP #pragma omp critical (client) { #endif if (!(_client_rand_seeded)) { srand(ptr2seed(comm)); _client_rand_seeded = 1; } #ifdef _OPENMP } #endif comm->type = _default_comm; return new_default_address(comm); }; /*! @brief Initialize a client communicator. @param[in] comm comm_t * Comm structure initialized with init_comm_base. @returns int -1 if the comm could not be initialized. */ static inline int init_client_comm(comm_t *comm) { int ret = 0; ygglog_debug("init_client_comm: Creating a client comm"); #ifdef _OPENMP #pragma omp critical (client) { #endif if (!(_client_rand_seeded)) { srand(ptr2seed(comm)); _client_rand_seeded = 1; } #ifdef _OPENMP } #endif // Called to create temp comm for send/recv if ((strlen(comm->name) == 0) && (strlen(comm->address) > 0)) { comm->type = _default_comm; return init_default_comm(comm); } // Called to initialize/create client comm dtype_t *dtype_out = NULL; if (strlen(comm->direction) > 0) { dtype_out = create_dtype_format(comm->direction, 0, false); if (dtype_out == NULL) { ygglog_error("init_client_comm: Failed to create output datatype."); return -1; } } comm_t *handle; if (strlen(comm->name) == 0) { handle = new_comm_base(comm->address, "send", _default_comm, dtype_out); sprintf(handle->name, "client_request.%s", comm->address); } else { handle = init_comm_base(comm->name, "send", _default_comm, dtype_out); } handle->flags = handle->flags | COMM_FLAG_CLIENT; ret = init_default_comm(handle); strcpy(comm->address, handle->address); comm->handle = (void*)handle; // Keep track of response comms responses_t *resp = client_new_responses(); if (resp == NULL) { ygglog_error("init_client_comm: Failed to malloc responses."); return -1; } comm->info = (void*)resp; strcpy(comm->direction, "send"); comm->flags = comm->flags | COMM_ALWAYS_SEND_HEADER; return ret; }; /*! @brief Perform deallocation for client communicator. @param[in] x comm_t* Pointer to communicator to deallocate. @returns int 1 if there is and error, 0 otherwise. */ static inline int free_client_comm(comm_t *x) { if (x->info != NULL) { responses_t *resp = (responses_t*)(x->info); if (resp != NULL) client_free_responses(&resp); x->info = NULL; } if (x->handle != NULL) { comm_t *handle = (comm_t*)(x->handle); free_default_comm(handle); free_comm_base(handle); free(x->handle); x->handle = NULL; } return 0; }; /*! @brief Get number of messages in the comm. @param[in] x comm_t* Communicator to check. @returns int Number of messages. -1 indicates an error. */ static inline int client_comm_nmsg(const comm_t* x) { comm_t *handle = (comm_t*)(x->handle); int ret = default_comm_nmsg(handle); return ret; }; /*! @brief Create response comm and add info to header. @param[in] x comm_t* structure that header will be sent to. @param[in] head comm_head_t Prexisting header structure. @returns comm_head_t Header structure that includes the additional information about the response comm. */ static inline comm_head_t client_response_header(const comm_t* x, comm_head_t head) { // Initialize new comm responses_t *resp = (responses_t*)(x->info); if (resp->comm == NULL) { dtype_t * dtype_copy = copy_dtype(x->datatype); resp->comm = new_comm_base(NULL, "recv", _default_comm, dtype_copy); resp->comm->flags = resp->comm->flags | COMM_FLAG_CLIENT_RESPONSE; int ret = new_default_address(resp->comm); if (ret < 0) { ygglog_error("client_response_header(%s): could not create response comm", x->name); head.flags = head.flags & ~HEAD_FLAG_VALID; return head; } resp->comm->const_flags[0] = resp->comm->const_flags[0] | COMM_EOF_SENT | COMM_EOF_RECV; ygglog_debug("client_response_header(%s): Created response comm", x->name); } // Add address & request ID to header strcpy(head.response_address, resp->comm->address); sprintf(head.request_id, "%d", rand()); if (client_add_request(resp, head.request_id) < 0) { ygglog_error("client_response_header(%s): Failed to add request", x->name); head.flags = head.flags & ~HEAD_FLAG_VALID; return head; } if (client_has_request(resp, head.request_id) < 0) { ygglog_error("client_response_header(%s): Failed to add request", x->name); head.flags = head.flags & ~HEAD_FLAG_VALID; return head; } ygglog_debug("client_response_header(%s): response_address = %s, request_id = %s", x->name, head.response_address, head.request_id); return head; }; /*! @brief Send a message to the comm. @param[in] x comm_t* structure that comm should be sent to. @param[in] data character pointer to message that should be sent. @param[in] len size_t length of message to be sent. @returns int 0 if send succesfull, -1 if send unsuccessful. */ static inline int client_comm_send(const comm_t* x, const char *data, const size_t len) { int ret; ygglog_debug("client_comm_send(%s): %d bytes", x->name, len); if (x->handle == NULL) { ygglog_error("client_comm_send(%s): no request comm registered", x->name); return -1; } comm_t *req_comm = (comm_t*)(x->handle); ret = default_comm_send(req_comm, data, len); if (is_eof(data)) { req_comm->const_flags[0] = req_comm->const_flags[0] | COMM_EOF_SENT; } return ret; }; /*! @brief Receive a message from an input comm. @param[in] x comm_t* structure that message should be sent to. @param[out] data char ** pointer to allocated buffer where the message should be saved. This should be a malloc'd buffer if allow_realloc is 1. @param[in] len const size_t length of the allocated message buffer in bytes. @param[in] allow_realloc const int If 1, the buffer will be realloced if it is not large enought. Otherwise an error will be returned. @returns int -1 if message could not be received. Length of the received message if message was received. */ static inline int client_comm_recv(const comm_t* x, char **data, const size_t len, const int allow_realloc) { ygglog_debug("client_comm_recv(%s)", x->name); if (x->info == NULL) { ygglog_error("client_comm_recv(%s): no response struct set up", x->name); return -1; } responses_t *resp = (responses_t*)(x->info); if ((resp->comm == NULL) || (resp->nreq == 0)) { ygglog_error("client_comm_recv(%s): no response comm registered", x->name); return -1; } char* request_id = resp->request_id[0]; int ret = 0; while (client_has_response(resp, request_id) < 0) { ret = default_comm_recv(resp->comm, data, len, allow_realloc); if (ret < 0) { ygglog_error("client_comm_recv(%s): default_comm_recv returned %d", x->name, ret); return ret; } comm_head_t head = parse_comm_header(*data, len); if (!(head.flags & HEAD_FLAG_VALID)) { ygglog_error("client_comm_recv(%s): Invalid header.", x->name); return -1; } if (strcmp(head.request_id, request_id) == 0) { ygglog_debug("client_comm_recv(%s): default_comm_recv returned %d", x->name, ret); if (client_remove_request(resp, request_id) < 0) { ygglog_error("client_comm_recv(%s): Failed to remove request %s", x->name, request_id); return -1; } return ret; } if (client_add_response(resp, head.request_id, *data, ret) < 0) { ygglog_error("client_comm_recv(%s): Failed to add response %s", x->name, head.request_id); return -1; } } ret = client_pop_response(resp, request_id, data, len, allow_realloc); // Close response comm and decrement count of response comms ygglog_debug("client_comm_recv(%s): client_pop_response returned %d", x->name, ret); return ret; }; #ifdef __cplusplus /* If this is a C++ compiler, end C linkage */ } #endif #endif /*YGGCLIENTCOMM_H_*/

nodal_residualbased_elimination_builder_and_solver_for_FSI.h

// | / | // ' / __| _` | __| _ \ __| // . \ | ( | | ( |\__ ` // _|\_\_| \__,_|\__|\___/ ____/ // Multi-Physics // // License: BSD License // Kratos default license: kratos/license.txt // // Main authors: Riccardo Rossi, Alessandro Franci // // #if !defined(KRATOS_NODAL_RESIDUAL_BASED_ELIMINATION_BUILDER_AND_SOLVER_FOR_FSI) #define KRATOS_NODAL_RESIDUAL_BASED_ELIMINATION_BUILDER_AND_SOLVER_FOR_FSI /* System includes */ #include <set> #ifdef _OPENMP #include <omp.h> #endif /* External includes */ // #define USE_GOOGLE_HASH #ifdef USE_GOOGLE_HASH #include "sparsehash/dense_hash_set" //included in external libraries #else #include <unordered_set> #endif /* Project includes */ #include "utilities/timer.h" #include "includes/define.h" #include "includes/key_hash.h" #include "solving_strategies/builder_and_solvers/builder_and_solver.h" #include "includes/model_part.h" #include "pfem_fluid_dynamics_application_variables.h" namespace Kratos { ///@name Kratos Globals ///@{ ///@} ///@name Type Definitions ///@{ ///@} ///@name Enum's ///@{ ///@} ///@name Functions ///@{ ///@} ///@name Kratos Classes ///@{ /** * @class NodalResidualBasedEliminationBuilderAndSolverForFSI * @ingroup KratosCore * @brief Current class provides an implementation for standard builder and solving operations. * @details The RHS is constituted by the unbalanced loads (residual) * Degrees of freedom are reordered putting the restrained degrees of freedom at * the end of the system ordered in reverse order with respect to the DofSet. * Imposition of the dirichlet conditions is naturally dealt with as the residual already contains * this information. * Calculation of the reactions involves a cost very similiar to the calculation of the total residual * @author Riccardo Rossi */ template <class TSparseSpace, class TDenseSpace, //= DenseSpace<double>, class TLinearSolver //= LinearSolver<TSparseSpace,TDenseSpace> > class NodalResidualBasedEliminationBuilderAndSolverForFSI : public BuilderAndSolver<TSparseSpace, TDenseSpace, TLinearSolver> { public: ///@name Type Definitions ///@{ KRATOS_CLASS_POINTER_DEFINITION(NodalResidualBasedEliminationBuilderAndSolverForFSI); typedef BuilderAndSolver<TSparseSpace, TDenseSpace, TLinearSolver> BaseType; typedef typename BaseType::TSchemeType TSchemeType; typedef typename BaseType::TDataType TDataType; typedef typename BaseType::DofsArrayType DofsArrayType; typedef typename BaseType::TSystemMatrixType TSystemMatrixType; typedef typename BaseType::TSystemVectorType TSystemVectorType; typedef typename BaseType::LocalSystemVectorType LocalSystemVectorType; typedef typename BaseType::LocalSystemMatrixType LocalSystemMatrixType; typedef typename BaseType::TSystemMatrixPointerType TSystemMatrixPointerType; typedef typename BaseType::TSystemVectorPointerType TSystemVectorPointerType; typedef Node<3> NodeType; typedef typename BaseType::NodesArrayType NodesArrayType; typedef typename BaseType::ElementsArrayType ElementsArrayType; typedef typename BaseType::ConditionsArrayType ConditionsArrayType; typedef typename BaseType::ElementsContainerType ElementsContainerType; typedef Vector VectorType; typedef GlobalPointersVector<Node<3>> NodeWeakPtrVectorType; ///@} ///@name Life Cycle ///@{ /** Constructor. */ NodalResidualBasedEliminationBuilderAndSolverForFSI( typename TLinearSolver::Pointer pNewLinearSystemSolver) : BuilderAndSolver<TSparseSpace, TDenseSpace, TLinearSolver>(pNewLinearSystemSolver) { // KRATOS_INFO("NodalResidualBasedEliminationBuilderAndSolverForFSI") << "Using the standard builder and solver " << std::endl; } /** Destructor. */ ~NodalResidualBasedEliminationBuilderAndSolverForFSI() override { } ///@} ///@name Operators ///@{ ///@} ///@name Operations ///@{ void SetMaterialPropertiesToFluid( ModelPart::NodeIterator itNode, double &density, double &deviatoricCoeff, double &volumetricCoeff, double timeInterval, double nodalVolume) { density = itNode->FastGetSolutionStepValue(DENSITY); deviatoricCoeff = itNode->FastGetSolutionStepValue(DYNAMIC_VISCOSITY); double yieldShear = itNode->FastGetSolutionStepValue(YIELD_SHEAR); if (yieldShear > 0) { double adaptiveExponent = itNode->FastGetSolutionStepValue(ADAPTIVE_EXPONENT); double equivalentStrainRate = itNode->FastGetSolutionStepValue(NODAL_EQUIVALENT_STRAIN_RATE); double exponent = -adaptiveExponent * equivalentStrainRate; if (equivalentStrainRate != 0) { deviatoricCoeff += (yieldShear / equivalentStrainRate) * (1 - exp(exponent)); } if (equivalentStrainRate < 0.00001 && yieldShear != 0 && adaptiveExponent != 0) { // for gamma_dot very small the limit of the Papanastasiou viscosity is mu=m*tau_yield deviatoricCoeff = adaptiveExponent * yieldShear; } } volumetricCoeff = timeInterval * itNode->FastGetSolutionStepValue(BULK_MODULUS); if (volumetricCoeff > 0) { volumetricCoeff = timeInterval * itNode->FastGetSolutionStepValue(BULK_MODULUS); double bulkReduction = density * nodalVolume / (timeInterval * volumetricCoeff); volumetricCoeff *= bulkReduction; } } void SetMaterialPropertiesToSolid( ModelPart::NodeIterator itNode, double &density, double &deviatoricCoeff, double &volumetricCoeff, double timeInterval, double nodalVolume) { density = itNode->FastGetSolutionStepValue(SOLID_DENSITY); double youngModulus = itNode->FastGetSolutionStepValue(YOUNG_MODULUS); double poissonRatio = itNode->FastGetSolutionStepValue(POISSON_RATIO); //deviatoricCoeff=deltaT*secondLame deviatoricCoeff = timeInterval * youngModulus / (1.0 + poissonRatio) * 0.5; //volumetricCoeff=bulk*deltaT=deltaT*(firstLame+2*secondLame/3) volumetricCoeff = timeInterval * poissonRatio * youngModulus / ((1.0 + poissonRatio) * (1.0 - 2.0 * poissonRatio)) + 2.0 * deviatoricCoeff / 3.0; } void BuildSolidNodally( typename TSchemeType::Pointer pScheme, ModelPart &rModelPart, TSystemMatrixType &A, TSystemVectorType &b) { KRATOS_TRY KRATOS_ERROR_IF(!pScheme) << "No scheme provided!" << std::endl; //contributions to the system LocalSystemMatrixType solidLHS_Contribution = LocalSystemMatrixType(0, 0); LocalSystemVectorType solidRHS_Contribution = LocalSystemVectorType(0); //vector containing the localization in the system of the different terms Element::EquationIdVectorType solidEquationId; ProcessInfo &CurrentProcessInfo = rModelPart.GetProcessInfo(); const unsigned int dimension = rModelPart.ElementsBegin()->GetGeometry().WorkingSpaceDimension(); const double timeInterval = CurrentProcessInfo[DELTA_TIME]; const double FourThirds = 4.0 / 3.0; const double nTwoThirds = -2.0 / 3.0; double theta = 0.5; //double theta=1.0; array_1d<double, 3> Acc(3, 0.0); double dNdXi = 0; double dNdYi = 0; double dNdZi = 0; double dNdXj = 0; double dNdYj = 0; double dNdZj = 0; unsigned int firstRow = 0; unsigned int firstCol = 0; double density = 0; double deviatoricCoeff = 0; double volumetricCoeff = 0; /* #pragma omp parallel */ // { ModelPart::NodeIterator NodesBegin; ModelPart::NodeIterator NodesEnd; OpenMPUtils::PartitionedIterators(rModelPart.Nodes(), NodesBegin, NodesEnd); for (ModelPart::NodeIterator itNode = NodesBegin; itNode != NodesEnd; ++itNode) { if (itNode->Is(SOLID)) { NodeWeakPtrVectorType &neighb_nodes = itNode->GetValue(NEIGHBOUR_NODES); Vector solidNodalSFDneighboursId = itNode->FastGetSolutionStepValue(SOLID_NODAL_SFD_NEIGHBOURS_ORDER); // const unsigned int neighSize = neighb_nodes.size()+1; const unsigned int neighSize = solidNodalSFDneighboursId.size(); const double nodalVolume = itNode->FastGetSolutionStepValue(SOLID_NODAL_VOLUME); if (neighSize > 1 && nodalVolume > 0) { const unsigned int localSize = itNode->FastGetSolutionStepValue(SOLID_NODAL_SFD_NEIGHBOURS).size(); if (solidLHS_Contribution.size1() != localSize) solidLHS_Contribution.resize(localSize, localSize, false); //false says not to preserve existing storage!! if (solidRHS_Contribution.size() != localSize) solidRHS_Contribution.resize(localSize, false); //false says not to preserve existing storage!! if (solidEquationId.size() != localSize) solidEquationId.resize(localSize, false); solidLHS_Contribution = ZeroMatrix(localSize, localSize); solidRHS_Contribution = ZeroVector(localSize); this->SetMaterialPropertiesToSolid(itNode, density, deviatoricCoeff, volumetricCoeff, timeInterval, nodalVolume); firstRow = 0; firstCol = 0; if (dimension == 2) { //////////////////////////// LHS TERMS ////////////////////////////// solidLHS_Contribution(0, 0) += nodalVolume * density * 2.0 / timeInterval; solidLHS_Contribution(1, 1) += nodalVolume * density * 2.0 / timeInterval; //////////////////////////// RHS TERMS ////////////////////////////// //-------- DYNAMIC FORCES TERM -------// Acc = 2.0 * (itNode->FastGetSolutionStepValue(VELOCITY, 0) - itNode->FastGetSolutionStepValue(VELOCITY, 1)) / timeInterval - itNode->FastGetSolutionStepValue(ACCELERATION, 0); solidRHS_Contribution[0] += -nodalVolume * density * Acc[0]; solidRHS_Contribution[1] += -nodalVolume * density * Acc[1]; //-------- EXTERNAL FORCES TERM -------// array_1d<double, 3> &VolumeAcceleration = itNode->FastGetSolutionStepValue(VOLUME_ACCELERATION); // double posX= itNode->X(); // double posY= itNode->Y(); // double coeffX =(12.0-24.0*posY)*pow(posX,4); // coeffX += (-24.0+48.0*posY)*pow(posX,3); // coeffX += (-48.0*posY+72.0*pow(posY,2)-48.0*pow(posY,3)+12.0)*pow(posX,2); // coeffX += (-2.0+24.0*posY-72.0*pow(posY,2)+48.0*pow(posY,3))*posX; // coeffX += 1.0-4.0*posY+12.0*pow(posY,2)-8.0*pow(posY,3); // double coeffY =(8.0-48.0*posY+48.0*pow(posY,2))*pow(posX,3); // coeffY += (-12.0+72.0*posY-72.0*pow(posY,2))*pow(posX,2); // coeffY += (4.0-24.0*posY+48.0*pow(posY,2)-48.0*pow(posY,3)+24.0*pow(posY,4))*posX; // coeffY += -12.0*pow(posY,2)+24.0*pow(posY,3)-12.0*pow(posY,4); // RHS_Contribution[0]+=nodalVolume*density*VolumeAcceleration[0]*coeffX; // RHS_Contribution[1]+=nodalVolume*density*VolumeAcceleration[1]*coeffY; solidRHS_Contribution[0] += nodalVolume * density * VolumeAcceleration[0]; solidRHS_Contribution[1] += nodalVolume * density * VolumeAcceleration[1]; ///////////////LOAD CONDITIONS FOR BELITSCHKO CASE // if(itNode->X0()>24.999){ // // solidRHS_Contribution[1]+=40.0/2.0; // mesh 4 (1 element per edge) // // solidRHS_Contribution[1]+=40.0/3.0; // mesh 2 (2 element per edge) // // solidRHS_Contribution[1]+=40.0/5.0; // mesh 1 (4 element per edge) // // solidRHS_Contribution[1]+=40.0/9.0; // mesh 0.5 (8 element per edge) // // solidRHS_Contribution[1]+=40.0/17.0; // mesh 0.25 (16 element per edge) // // solidRHS_Contribution[1]+=40.0/33.0; // mesh 0.125 (32 element per edge) // // solidRHS_Contribution[1]+=40.0/65.0; // mesh 0.0625 (64 element per edge) // } //-------- INTERNAL FORCES TERM -------// array_1d<double, 3> Sigma(3, 0.0); Sigma = itNode->FastGetSolutionStepValue(SOLID_NODAL_CAUCHY_STRESS); const unsigned int xDofPos = itNode->GetDofPosition(VELOCITY_X); solidEquationId[0] = itNode->GetDof(VELOCITY_X, xDofPos).EquationId(); solidEquationId[1] = itNode->GetDof(VELOCITY_Y, xDofPos + 1).EquationId(); for (unsigned int i = 0; i < neighSize; i++) { dNdXi = itNode->FastGetSolutionStepValue(SOLID_NODAL_SFD_NEIGHBOURS)[firstCol]; dNdYi = itNode->FastGetSolutionStepValue(SOLID_NODAL_SFD_NEIGHBOURS)[firstCol + 1]; solidRHS_Contribution[firstCol] += -nodalVolume * (dNdXi * Sigma[0] + dNdYi * Sigma[2]); solidRHS_Contribution[firstCol + 1] += -nodalVolume * (dNdYi * Sigma[1] + dNdXi * Sigma[2]); for (unsigned int j = 0; j < neighSize; j++) { dNdXj = itNode->FastGetSolutionStepValue(SOLID_NODAL_SFD_NEIGHBOURS)[firstRow]; dNdYj = itNode->FastGetSolutionStepValue(SOLID_NODAL_SFD_NEIGHBOURS)[firstRow + 1]; solidLHS_Contribution(firstRow, firstCol) += nodalVolume * ((FourThirds * deviatoricCoeff + volumetricCoeff) * dNdXj * dNdXi + dNdYj * dNdYi * deviatoricCoeff) * theta; solidLHS_Contribution(firstRow, firstCol + 1) += nodalVolume * ((nTwoThirds * deviatoricCoeff + volumetricCoeff) * dNdXj * dNdYi + dNdYj * dNdXi * deviatoricCoeff) * theta; solidLHS_Contribution(firstRow + 1, firstCol) += nodalVolume * ((nTwoThirds * deviatoricCoeff + volumetricCoeff) * dNdYj * dNdXi + dNdXj * dNdYi * deviatoricCoeff) * theta; solidLHS_Contribution(firstRow + 1, firstCol + 1) += nodalVolume * ((FourThirds * deviatoricCoeff + volumetricCoeff) * dNdYj * dNdYi + dNdXj * dNdXi * deviatoricCoeff) * theta; firstRow += 2; } firstRow = 0; firstCol += 2; unsigned int indexNode = i + 1; if (itNode->FastGetSolutionStepValue(INTERFACE_NODE) == true && indexNode < neighSize) { unsigned int other_neigh_nodes_id = solidNodalSFDneighboursId[indexNode]; // std::cout<<"other_neigh_nodes_id= "<<other_neigh_nodes_id<<" within "<<nodalSFDneighboursId<<std::endl; for (unsigned int k = 0; k < neighb_nodes.size(); k++) { unsigned int neigh_nodes_id = neighb_nodes[k].Id(); // std::cout<<" neigh_nodes_id= "<< neigh_nodes_id<<std::endl; if (neigh_nodes_id == other_neigh_nodes_id) { solidEquationId[firstCol] = neighb_nodes[k].GetDof(VELOCITY_X, xDofPos).EquationId(); solidEquationId[firstCol + 1] = neighb_nodes[k].GetDof(VELOCITY_Y, xDofPos + 1).EquationId(); break; } } } else if (i < neighb_nodes.size()) { solidEquationId[firstCol] = neighb_nodes[i].GetDof(VELOCITY_X, xDofPos).EquationId(); solidEquationId[firstCol + 1] = neighb_nodes[i].GetDof(VELOCITY_Y, xDofPos + 1).EquationId(); } } /* std::cout << "LHS_Contribution = " << LHS_Contribution << std::endl; */ } else if (dimension == 3) { //////////////////////////// LHS TERMS ////////////////////////////// solidLHS_Contribution(0, 0) += nodalVolume * density * 2.0 / timeInterval; solidLHS_Contribution(1, 1) += nodalVolume * density * 2.0 / timeInterval; solidLHS_Contribution(2, 2) += nodalVolume * density * 2.0 / timeInterval; //////////////////////////// RHS TERMS ////////////////////////////// //-------- DYNAMIC FORCES TERM -------// Acc = 2.0 * (itNode->FastGetSolutionStepValue(VELOCITY, 0) - itNode->FastGetSolutionStepValue(VELOCITY, 1)) / timeInterval - itNode->FastGetSolutionStepValue(ACCELERATION, 0); solidRHS_Contribution[0] += -nodalVolume * density * Acc[0]; solidRHS_Contribution[1] += -nodalVolume * density * Acc[1]; solidRHS_Contribution[2] += -nodalVolume * density * Acc[2]; //-------- EXTERNAL FORCES TERM -------// array_1d<double, 3> &VolumeAcceleration = itNode->FastGetSolutionStepValue(VOLUME_ACCELERATION); solidRHS_Contribution[0] += nodalVolume * density * VolumeAcceleration[0]; solidRHS_Contribution[1] += nodalVolume * density * VolumeAcceleration[1]; solidRHS_Contribution[2] += nodalVolume * density * VolumeAcceleration[2]; ///////////////LOAD CONDITIONS FOR BELITSCHKO CASE // if(itNode->X0()>24.999){ // // solidRHS_Contribution[1]+=40.0/2.0; // mesh 4 (1 element per edge) // // solidRHS_Contribution[1]+=40.0/3.0; // mesh 2 (2 element per edge) // // solidRHS_Contribution[1]+=40.0/5.0; // mesh 1 (4 element per edge) // solidRHS_Contribution[1]+=40.0/27.0; // mesh 0.5 (8 element per edge, 2 per width) // // solidRHS_Contribution[1]+=40.0/17.0; // mesh 0.25 (16 element per edge) // // solidRHS_Contribution[1]+=40.0/33.0; // mesh 0.125 (32 element per edge) // // solidRHS_Contribution[1]+=40.0/65.0; // mesh 0.0625 (64 element per edge) // } //-------- INTERNAL FORCES TERM -------// array_1d<double, 6> Sigma(6, 0.0); Sigma = itNode->FastGetSolutionStepValue(SOLID_NODAL_CAUCHY_STRESS); // if(itNode->FastGetSolutionStepValue(INTERFACE_NODE)==true){ // Sigma=itNode->FastGetSolutionStepValue(SOLID_NODAL_CAUCHY_STRESS); // } const unsigned int xDofPos = itNode->GetDofPosition(VELOCITY_X); solidEquationId[0] = itNode->GetDof(VELOCITY_X, xDofPos).EquationId(); solidEquationId[1] = itNode->GetDof(VELOCITY_Y, xDofPos + 1).EquationId(); solidEquationId[2] = itNode->GetDof(VELOCITY_Z, xDofPos + 2).EquationId(); for (unsigned int i = 0; i < neighSize; i++) { dNdXi = itNode->FastGetSolutionStepValue(SOLID_NODAL_SFD_NEIGHBOURS)[firstCol]; dNdYi = itNode->FastGetSolutionStepValue(SOLID_NODAL_SFD_NEIGHBOURS)[firstCol + 1]; dNdZi = itNode->FastGetSolutionStepValue(SOLID_NODAL_SFD_NEIGHBOURS)[firstCol + 2]; solidRHS_Contribution[firstCol] += -nodalVolume * (dNdXi * Sigma[0] + dNdYi * Sigma[3] + dNdZi * Sigma[4]); solidRHS_Contribution[firstCol + 1] += -nodalVolume * (dNdYi * Sigma[1] + dNdXi * Sigma[3] + dNdZi * Sigma[5]); solidRHS_Contribution[firstCol + 2] += -nodalVolume * (dNdZi * Sigma[2] + dNdXi * Sigma[4] + dNdYi * Sigma[5]); for (unsigned int j = 0; j < neighSize; j++) { dNdXj = itNode->FastGetSolutionStepValue(SOLID_NODAL_SFD_NEIGHBOURS)[firstRow]; dNdYj = itNode->FastGetSolutionStepValue(SOLID_NODAL_SFD_NEIGHBOURS)[firstRow + 1]; dNdZj = itNode->FastGetSolutionStepValue(SOLID_NODAL_SFD_NEIGHBOURS)[firstRow + 2]; solidLHS_Contribution(firstRow, firstCol) += nodalVolume * ((FourThirds * deviatoricCoeff + volumetricCoeff) * dNdXj * dNdXi + (dNdYj * dNdYi + dNdZj * dNdZi) * deviatoricCoeff) * theta; solidLHS_Contribution(firstRow, firstCol + 1) += nodalVolume * ((nTwoThirds * deviatoricCoeff + volumetricCoeff) * dNdXj * dNdYi + dNdYj * dNdXi * deviatoricCoeff) * theta; solidLHS_Contribution(firstRow, firstCol + 2) += nodalVolume * ((nTwoThirds * deviatoricCoeff + volumetricCoeff) * dNdXj * dNdZi + dNdZj * dNdXi * deviatoricCoeff) * theta; solidLHS_Contribution(firstRow + 1, firstCol) += nodalVolume * ((nTwoThirds * deviatoricCoeff + volumetricCoeff) * dNdYj * dNdXi + dNdXj * dNdYi * deviatoricCoeff) * theta; solidLHS_Contribution(firstRow + 1, firstCol + 1) += nodalVolume * ((FourThirds * deviatoricCoeff + volumetricCoeff) * dNdYj * dNdYi + (dNdXj * dNdXi + dNdZj * dNdZi) * deviatoricCoeff) * theta; solidLHS_Contribution(firstRow + 1, firstCol + 2) += nodalVolume * ((nTwoThirds * deviatoricCoeff + volumetricCoeff) * dNdYj * dNdZi + dNdZj * dNdYi * deviatoricCoeff) * theta; solidLHS_Contribution(firstRow + 2, firstCol) += nodalVolume * ((nTwoThirds * deviatoricCoeff + volumetricCoeff) * dNdZj * dNdXi + dNdXj * dNdZi * deviatoricCoeff) * theta; solidLHS_Contribution(firstRow + 2, firstCol + 1) += nodalVolume * ((nTwoThirds * deviatoricCoeff + volumetricCoeff) * dNdZj * dNdYi + dNdYj * dNdZi * deviatoricCoeff) * theta; solidLHS_Contribution(firstRow + 2, firstCol + 2) += nodalVolume * ((FourThirds * deviatoricCoeff + volumetricCoeff) * dNdZj * dNdZi + (dNdXj * dNdXi + dNdYj * dNdYi) * deviatoricCoeff) * theta; firstRow += 3; } firstRow = 0; firstCol += 3; unsigned int indexNode = i + 1; if (itNode->FastGetSolutionStepValue(INTERFACE_NODE) == true && indexNode < neighSize) { unsigned int other_neigh_nodes_id = solidNodalSFDneighboursId[indexNode]; // std::cout<<"other_neigh_nodes_id= "<<other_neigh_nodes_id<<" within "<<nodalSFDneighboursId<<std::endl; for (unsigned int k = 0; k < neighb_nodes.size(); k++) { unsigned int neigh_nodes_id = neighb_nodes[k].Id(); // std::cout<<" neigh_nodes_id= "<< neigh_nodes_id<<std::endl; if (neigh_nodes_id == other_neigh_nodes_id) { solidEquationId[firstCol] = neighb_nodes[k].GetDof(VELOCITY_X, xDofPos).EquationId(); solidEquationId[firstCol + 1] = neighb_nodes[k].GetDof(VELOCITY_Y, xDofPos + 1).EquationId(); solidEquationId[firstCol + 2] = neighb_nodes[k].GetDof(VELOCITY_Z, xDofPos + 2).EquationId(); break; } } } else if (i < neighb_nodes.size()) { solidEquationId[firstCol] = neighb_nodes[i].GetDof(VELOCITY_X, xDofPos).EquationId(); solidEquationId[firstCol + 1] = neighb_nodes[i].GetDof(VELOCITY_Y, xDofPos + 1).EquationId(); solidEquationId[firstCol + 2] = neighb_nodes[i].GetDof(VELOCITY_Z, xDofPos + 2).EquationId(); } } } #ifdef _OPENMP Assemble(A, b, solidLHS_Contribution, solidRHS_Contribution, solidEquationId, mlock_array); #else Assemble(A, b, solidLHS_Contribution, solidRHS_Contribution, solidEquationId); #endif } } } // } KRATOS_CATCH("") } void BuildFluidNodally( typename TSchemeType::Pointer pScheme, ModelPart &rModelPart, TSystemMatrixType &A, TSystemVectorType &b) { KRATOS_TRY KRATOS_ERROR_IF(!pScheme) << "No scheme provided!" << std::endl; /* std::cout<<"Building LHS and RHS of Momentum Equation Nodally"<<std::endl; */ //contributions to the system LocalSystemMatrixType LHS_Contribution = LocalSystemMatrixType(0, 0); LocalSystemVectorType RHS_Contribution = LocalSystemVectorType(0); //vector containing the localization in the system of the different terms Element::EquationIdVectorType EquationId; ProcessInfo &CurrentProcessInfo = rModelPart.GetProcessInfo(); const unsigned int dimension = rModelPart.ElementsBegin()->GetGeometry().WorkingSpaceDimension(); const double timeInterval = CurrentProcessInfo[DELTA_TIME]; const double FourThirds = 4.0 / 3.0; const double nTwoThirds = -2.0 / 3.0; double theta = 0.5; array_1d<double, 3> Acc(3, 0.0); // array_1d<double,6> Sigma(6,0.0); double pressure = 0; double dNdXi = 0; double dNdYi = 0; double dNdZi = 0; double dNdXj = 0; double dNdYj = 0; double dNdZj = 0; unsigned int firstRow = 0; unsigned int firstCol = 0; double density = 0; double deviatoricCoeff = 0; double volumetricCoeff = 0; /* #pragma omp parallel */ // { ModelPart::NodeIterator NodesBegin; ModelPart::NodeIterator NodesEnd; OpenMPUtils::PartitionedIterators(rModelPart.Nodes(), NodesBegin, NodesEnd); for (ModelPart::NodeIterator itNode = NodesBegin; itNode != NodesEnd; ++itNode) { if ((itNode->Is(FLUID) && itNode->IsNot(SOLID)) || itNode->FastGetSolutionStepValue(INTERFACE_NODE) == true) { NodeWeakPtrVectorType &neighb_nodes = itNode->GetValue(NEIGHBOUR_NODES); Vector nodalSFDneighboursId = itNode->FastGetSolutionStepValue(NODAL_SFD_NEIGHBOURS_ORDER); // const unsigned int neighSize = neighb_nodes.size()+1; const unsigned int neighSize = nodalSFDneighboursId.size(); const double nodalVolume = itNode->FastGetSolutionStepValue(NODAL_VOLUME); if (neighSize > 1 && nodalVolume > 0) { const unsigned int localSize = itNode->FastGetSolutionStepValue(NODAL_SFD_NEIGHBOURS).size(); if (LHS_Contribution.size1() != localSize) LHS_Contribution.resize(localSize, localSize, false); //false says not to preserve existing storage!! if (RHS_Contribution.size() != localSize) RHS_Contribution.resize(localSize, false); //false says not to preserve existing storage!! if (EquationId.size() != localSize) EquationId.resize(localSize, false); LHS_Contribution = ZeroMatrix(localSize, localSize); RHS_Contribution = ZeroVector(localSize); this->SetMaterialPropertiesToFluid(itNode, density, deviatoricCoeff, volumetricCoeff, timeInterval, nodalVolume); // if(itNode->FastGetSolutionStepValue(INTERFACE_NODE)==true){ // // std::cout<<"density,deviatoricCoeff,volumetricCoeff "<<density<<" "<<deviatoricCoeff<<" "<<volumetricCoeff<<std::endl; // std::cout<<"INTERFACE nodalVolume "<<nodalVolume<<std::endl; // }else{ // std::cout<<"nodalVolume "<<nodalVolume<<std::endl; // } firstRow = 0; firstCol = 0; if (dimension == 2) { //////////////////////////// LHS TERMS ////////////////////////////// LHS_Contribution(0, 0) += nodalVolume * density * 2.0 / timeInterval; LHS_Contribution(1, 1) += nodalVolume * density * 2.0 / timeInterval; //////////////////////////// RHS TERMS ////////////////////////////// //-------- DYNAMIC FORCES TERM -------// Acc = 2.0 * (itNode->FastGetSolutionStepValue(VELOCITY, 0) - itNode->FastGetSolutionStepValue(VELOCITY, 1)) / timeInterval - itNode->FastGetSolutionStepValue(ACCELERATION, 0); RHS_Contribution[0] += -nodalVolume * density * Acc[0]; RHS_Contribution[1] += -nodalVolume * density * Acc[1]; //-------- EXTERNAL FORCES TERM -------// array_1d<double, 3> &VolumeAcceleration = itNode->FastGetSolutionStepValue(VOLUME_ACCELERATION); // double posX= itNode->X(); // double posY= itNode->Y(); // double coeffX =(12.0-24.0*posY)*pow(posX,4); // coeffX += (-24.0+48.0*posY)*pow(posX,3); // coeffX += (-48.0*posY+72.0*pow(posY,2)-48.0*pow(posY,3)+12.0)*pow(posX,2); // coeffX += (-2.0+24.0*posY-72.0*pow(posY,2)+48.0*pow(posY,3))*posX; // coeffX += 1.0-4.0*posY+12.0*pow(posY,2)-8.0*pow(posY,3); // double coeffY =(8.0-48.0*posY+48.0*pow(posY,2))*pow(posX,3); // coeffY += (-12.0+72.0*posY-72.0*pow(posY,2))*pow(posX,2); // coeffY += (4.0-24.0*posY+48.0*pow(posY,2)-48.0*pow(posY,3)+24.0*pow(posY,4))*posX; // coeffY += -12.0*pow(posY,2)+24.0*pow(posY,3)-12.0*pow(posY,4); // RHS_Contribution[0]+=nodalVolume*density*VolumeAcceleration[0]*coeffX; // RHS_Contribution[1]+=nodalVolume*density*VolumeAcceleration[1]*coeffY; RHS_Contribution[0] += nodalVolume * density * VolumeAcceleration[0]; RHS_Contribution[1] += nodalVolume * density * VolumeAcceleration[1]; //-------- INTERNAL FORCES TERM -------// array_1d<double, 3> Sigma(3, 0.0); Sigma = itNode->FastGetSolutionStepValue(NODAL_CAUCHY_STRESS); // if(itNode->FastGetSolutionStepValue(INTERFACE_NODE)==true){ // Sigma=itNode->FastGetSolutionStepValue(SOLID_NODAL_CAUCHY_STRESS); // } if (itNode->IsNot(SOLID) || itNode->FastGetSolutionStepValue(INTERFACE_NODE) == true) { pressure = itNode->FastGetSolutionStepValue(PRESSURE, 0) * theta + itNode->FastGetSolutionStepValue(PRESSURE, 1) * (1 - theta); Sigma[0] = itNode->FastGetSolutionStepValue(NODAL_DEVIATORIC_CAUCHY_STRESS)[0] + pressure; Sigma[1] = itNode->FastGetSolutionStepValue(NODAL_DEVIATORIC_CAUCHY_STRESS)[1] + pressure; } const unsigned int xDofPos = itNode->GetDofPosition(VELOCITY_X); EquationId[0] = itNode->GetDof(VELOCITY_X, xDofPos).EquationId(); EquationId[1] = itNode->GetDof(VELOCITY_Y, xDofPos + 1).EquationId(); for (unsigned int i = 0; i < neighSize; i++) { dNdXi = itNode->FastGetSolutionStepValue(NODAL_SFD_NEIGHBOURS)[firstCol]; dNdYi = itNode->FastGetSolutionStepValue(NODAL_SFD_NEIGHBOURS)[firstCol + 1]; RHS_Contribution[firstCol] += -nodalVolume * (dNdXi * Sigma[0] + dNdYi * Sigma[2]); RHS_Contribution[firstCol + 1] += -nodalVolume * (dNdYi * Sigma[1] + dNdXi * Sigma[2]); for (unsigned int j = 0; j < neighSize; j++) { dNdXj = itNode->FastGetSolutionStepValue(NODAL_SFD_NEIGHBOURS)[firstRow]; dNdYj = itNode->FastGetSolutionStepValue(NODAL_SFD_NEIGHBOURS)[firstRow + 1]; LHS_Contribution(firstRow, firstCol) += nodalVolume * ((FourThirds * deviatoricCoeff + volumetricCoeff) * dNdXj * dNdXi + dNdYj * dNdYi * deviatoricCoeff) * theta; LHS_Contribution(firstRow, firstCol + 1) += nodalVolume * ((nTwoThirds * deviatoricCoeff + volumetricCoeff) * dNdXj * dNdYi + dNdYj * dNdXi * deviatoricCoeff) * theta; LHS_Contribution(firstRow + 1, firstCol) += nodalVolume * ((nTwoThirds * deviatoricCoeff + volumetricCoeff) * dNdYj * dNdXi + dNdXj * dNdYi * deviatoricCoeff) * theta; LHS_Contribution(firstRow + 1, firstCol + 1) += nodalVolume * ((FourThirds * deviatoricCoeff + volumetricCoeff) * dNdYj * dNdYi + dNdXj * dNdXi * deviatoricCoeff) * theta; firstRow += 2; } firstRow = 0; firstCol += 2; unsigned int indexNode = i + 1; if (itNode->FastGetSolutionStepValue(INTERFACE_NODE) == true && indexNode < neighSize) { unsigned int other_neigh_nodes_id = nodalSFDneighboursId[indexNode]; // std::cout<<"other_neigh_nodes_id= "<<other_neigh_nodes_id<<" within "<<nodalSFDneighboursId<<std::endl; for (unsigned int k = 0; k < neighb_nodes.size(); k++) { unsigned int neigh_nodes_id = neighb_nodes[k].Id(); // std::cout<<" neigh_nodes_id= "<< neigh_nodes_id<<std::endl; if (neigh_nodes_id == other_neigh_nodes_id) { EquationId[firstCol] = neighb_nodes[k].GetDof(VELOCITY_X, xDofPos).EquationId(); EquationId[firstCol + 1] = neighb_nodes[k].GetDof(VELOCITY_Y, xDofPos + 1).EquationId(); break; } } } else if (i < neighb_nodes.size()) { EquationId[firstCol] = neighb_nodes[i].GetDof(VELOCITY_X, xDofPos).EquationId(); EquationId[firstCol + 1] = neighb_nodes[i].GetDof(VELOCITY_Y, xDofPos + 1).EquationId(); } } /* std::cout << "LHS_Contribution = " << LHS_Contribution << std::endl; */ } else if (dimension == 3) { //////////////////////////// LHS TERMS ////////////////////////////// LHS_Contribution(0, 0) += nodalVolume * density * 2.0 / timeInterval; LHS_Contribution(1, 1) += nodalVolume * density * 2.0 / timeInterval; LHS_Contribution(2, 2) += nodalVolume * density * 2.0 / timeInterval; //////////////////////////// RHS TERMS ////////////////////////////// //-------- DYNAMIC FORCES TERM -------// Acc = 2.0 * (itNode->FastGetSolutionStepValue(VELOCITY, 0) - itNode->FastGetSolutionStepValue(VELOCITY, 1)) / timeInterval - itNode->FastGetSolutionStepValue(ACCELERATION, 0); RHS_Contribution[0] += -nodalVolume * density * Acc[0]; RHS_Contribution[1] += -nodalVolume * density * Acc[1]; RHS_Contribution[2] += -nodalVolume * density * Acc[2]; //-------- EXTERNAL FORCES TERM -------// array_1d<double, 3> &VolumeAcceleration = itNode->FastGetSolutionStepValue(VOLUME_ACCELERATION); RHS_Contribution[0] += nodalVolume * density * VolumeAcceleration[0]; RHS_Contribution[1] += nodalVolume * density * VolumeAcceleration[1]; RHS_Contribution[2] += nodalVolume * density * VolumeAcceleration[2]; //-------- INTERNAL FORCES TERM -------// array_1d<double, 6> Sigma(6, 0.0); Sigma = itNode->FastGetSolutionStepValue(NODAL_CAUCHY_STRESS); // if(itNode->FastGetSolutionStepValue(INTERFACE_NODE)==true){ // Sigma=itNode->FastGetSolutionStepValue(SOLID_NODAL_CAUCHY_STRESS); // } if (itNode->IsNot(SOLID) || itNode->FastGetSolutionStepValue(INTERFACE_NODE) == true) { pressure = itNode->FastGetSolutionStepValue(PRESSURE, 0) * theta + itNode->FastGetSolutionStepValue(PRESSURE, 1) * (1 - theta); Sigma[0] = itNode->FastGetSolutionStepValue(NODAL_DEVIATORIC_CAUCHY_STRESS)[0] + pressure; Sigma[1] = itNode->FastGetSolutionStepValue(NODAL_DEVIATORIC_CAUCHY_STRESS)[1] + pressure; Sigma[2] = itNode->FastGetSolutionStepValue(NODAL_DEVIATORIC_CAUCHY_STRESS)[2] + pressure; } const unsigned int xDofPos = itNode->GetDofPosition(VELOCITY_X); EquationId[0] = itNode->GetDof(VELOCITY_X, xDofPos).EquationId(); EquationId[1] = itNode->GetDof(VELOCITY_Y, xDofPos + 1).EquationId(); EquationId[2] = itNode->GetDof(VELOCITY_Z, xDofPos + 2).EquationId(); for (unsigned int i = 0; i < neighSize; i++) { dNdXi = itNode->FastGetSolutionStepValue(NODAL_SFD_NEIGHBOURS)[firstCol]; dNdYi = itNode->FastGetSolutionStepValue(NODAL_SFD_NEIGHBOURS)[firstCol + 1]; dNdZi = itNode->FastGetSolutionStepValue(NODAL_SFD_NEIGHBOURS)[firstCol + 2]; RHS_Contribution[firstCol] += -nodalVolume * (dNdXi * Sigma[0] + dNdYi * Sigma[3] + dNdZi * Sigma[4]); RHS_Contribution[firstCol + 1] += -nodalVolume * (dNdYi * Sigma[1] + dNdXi * Sigma[3] + dNdZi * Sigma[5]); RHS_Contribution[firstCol + 2] += -nodalVolume * (dNdZi * Sigma[2] + dNdXi * Sigma[4] + dNdYi * Sigma[5]); for (unsigned int j = 0; j < neighSize; j++) { dNdXj = itNode->FastGetSolutionStepValue(NODAL_SFD_NEIGHBOURS)[firstRow]; dNdYj = itNode->FastGetSolutionStepValue(NODAL_SFD_NEIGHBOURS)[firstRow + 1]; dNdZj = itNode->FastGetSolutionStepValue(NODAL_SFD_NEIGHBOURS)[firstRow + 2]; LHS_Contribution(firstRow, firstCol) += nodalVolume * ((FourThirds * deviatoricCoeff + volumetricCoeff) * dNdXj * dNdXi + (dNdYj * dNdYi + dNdZj * dNdZi) * deviatoricCoeff) * theta; LHS_Contribution(firstRow, firstCol + 1) += nodalVolume * ((nTwoThirds * deviatoricCoeff + volumetricCoeff) * dNdXj * dNdYi + dNdYj * dNdXi * deviatoricCoeff) * theta; LHS_Contribution(firstRow, firstCol + 2) += nodalVolume * ((nTwoThirds * deviatoricCoeff + volumetricCoeff) * dNdXj * dNdZi + dNdZj * dNdXi * deviatoricCoeff) * theta; LHS_Contribution(firstRow + 1, firstCol) += nodalVolume * ((nTwoThirds * deviatoricCoeff + volumetricCoeff) * dNdYj * dNdXi + dNdXj * dNdYi * deviatoricCoeff) * theta; LHS_Contribution(firstRow + 1, firstCol + 1) += nodalVolume * ((FourThirds * deviatoricCoeff + volumetricCoeff) * dNdYj * dNdYi + (dNdXj * dNdXi + dNdZj * dNdZi) * deviatoricCoeff) * theta; LHS_Contribution(firstRow + 1, firstCol + 2) += nodalVolume * ((nTwoThirds * deviatoricCoeff + volumetricCoeff) * dNdYj * dNdZi + dNdZj * dNdYi * deviatoricCoeff) * theta; LHS_Contribution(firstRow + 2, firstCol) += nodalVolume * ((nTwoThirds * deviatoricCoeff + volumetricCoeff) * dNdZj * dNdXi + dNdXj * dNdZi * deviatoricCoeff) * theta; LHS_Contribution(firstRow + 2, firstCol + 1) += nodalVolume * ((nTwoThirds * deviatoricCoeff + volumetricCoeff) * dNdZj * dNdYi + dNdYj * dNdZi * deviatoricCoeff) * theta; LHS_Contribution(firstRow + 2, firstCol + 2) += nodalVolume * ((FourThirds * deviatoricCoeff + volumetricCoeff) * dNdZj * dNdZi + (dNdXj * dNdXi + dNdYj * dNdYi) * deviatoricCoeff) * theta; firstRow += 3; } firstRow = 0; firstCol += 3; unsigned int indexNode = i + 1; if (itNode->FastGetSolutionStepValue(INTERFACE_NODE) == true && indexNode < neighSize) { unsigned int other_neigh_nodes_id = nodalSFDneighboursId[indexNode]; // std::cout<<"other_neigh_nodes_id= "<<other_neigh_nodes_id<<" within "<<nodalSFDneighboursId<<std::endl; for (unsigned int k = 0; k < neighb_nodes.size(); k++) { unsigned int neigh_nodes_id = neighb_nodes[k].Id(); // std::cout<<" neigh_nodes_id= "<< neigh_nodes_id<<std::endl; if (neigh_nodes_id == other_neigh_nodes_id) { EquationId[firstCol] = neighb_nodes[k].GetDof(VELOCITY_X, xDofPos).EquationId(); EquationId[firstCol + 1] = neighb_nodes[k].GetDof(VELOCITY_Y, xDofPos + 1).EquationId(); EquationId[firstCol + 2] = neighb_nodes[k].GetDof(VELOCITY_Z, xDofPos + 2).EquationId(); break; } } } else if (i < neighb_nodes.size()) { EquationId[firstCol] = neighb_nodes[i].GetDof(VELOCITY_X, xDofPos).EquationId(); EquationId[firstCol + 1] = neighb_nodes[i].GetDof(VELOCITY_Y, xDofPos + 1).EquationId(); EquationId[firstCol + 2] = neighb_nodes[i].GetDof(VELOCITY_Z, xDofPos + 2).EquationId(); } } } #ifdef _OPENMP Assemble(A, b, LHS_Contribution, RHS_Contribution, EquationId, mlock_array); #else Assemble(A, b, LHS_Contribution, RHS_Contribution, EquationId); #endif } } } // } KRATOS_CATCH("") } /** * @brief This is a call to the linear system solver * @param A The LHS matrix * @param Dx The Unknowns vector * @param b The RHS vector */ void SystemSolve( TSystemMatrixType &A, TSystemVectorType &Dx, TSystemVectorType &b) override { KRATOS_TRY double norm_b; if (TSparseSpace::Size(b) != 0) norm_b = TSparseSpace::TwoNorm(b); else norm_b = 0.00; if (norm_b != 0.00) { //do solve BaseType::mpLinearSystemSolver->Solve(A, Dx, b); } else TSparseSpace::SetToZero(Dx); // Prints informations about the current time KRATOS_INFO_IF("NodalResidualBasedEliminationBuilderAndSolverForFSI", this->GetEchoLevel() > 1) << *(BaseType::mpLinearSystemSolver) << std::endl; KRATOS_CATCH("") } /** *@brief This is a call to the linear system solver (taking into account some physical particularities of the problem) * @param A The LHS matrix * @param Dx The Unknowns vector * @param b The RHS vector * @param rModelPart The model part of the problem to solve */ void SystemSolveWithPhysics( TSystemMatrixType &A, TSystemVectorType &Dx, TSystemVectorType &b, ModelPart &rModelPart) { KRATOS_TRY double norm_b; if (TSparseSpace::Size(b) != 0) norm_b = TSparseSpace::TwoNorm(b); else norm_b = 0.00; if (norm_b != 0.00) { //provide physical data as needed if (BaseType::mpLinearSystemSolver->AdditionalPhysicalDataIsNeeded()) BaseType::mpLinearSystemSolver->ProvideAdditionalData(A, Dx, b, BaseType::mDofSet, rModelPart); //do solve BaseType::mpLinearSystemSolver->Solve(A, Dx, b); } else { TSparseSpace::SetToZero(Dx); KRATOS_WARNING_IF("NodalResidualBasedEliminationBuilderAndSolverForFSI", rModelPart.GetCommunicator().MyPID() == 0) << "ATTENTION! setting the RHS to zero!" << std::endl; } // Prints informations about the current time KRATOS_INFO_IF("NodalResidualBasedEliminationBuilderAndSolverForFSI", this->GetEchoLevel() > 1 && rModelPart.GetCommunicator().MyPID() == 0) << *(BaseType::mpLinearSystemSolver) << std::endl; KRATOS_CATCH("") } /** * @brief Function to perform the building and solving phase at the same time. * @details It is ideally the fastest and safer function to use when it is possible to solve * just after building * @param pScheme The integration scheme considered * @param rModelPart The model part of the problem to solve * @param A The LHS matrix * @param Dx The Unknowns vector * @param b The RHS vector */ void BuildAndSolve( typename TSchemeType::Pointer pScheme, ModelPart &rModelPart, TSystemMatrixType &A, TSystemVectorType &Dx, TSystemVectorType &b) override { KRATOS_TRY Timer::Start("Build"); // boost::timer m_build_time; BuildSolidNodally(pScheme, rModelPart, A, b); BuildFluidNodally(pScheme, rModelPart, A, b); // std::cout << "MOMENTUM EQ: build_time : " << m_build_time.elapsed() << std::endl; Timer::Stop("Build"); // ApplyPointLoads(pScheme,rModelPart,b); // Does nothing...dirichlet conditions are naturally dealt with in defining the residual ApplyDirichletConditions(pScheme, rModelPart, A, Dx, b); KRATOS_INFO_IF("ResidualBasedBlockBuilderAndSolver", (this->GetEchoLevel() == 3)) << "Before the solution of the system" << "\nSystem Matrix = " << A << "\nUnknowns vector = " << Dx << "\nRHS vector = " << b << std::endl; const double start_solve = OpenMPUtils::GetCurrentTime(); Timer::Start("Solve"); /* boost::timer m_solve_time; */ SystemSolveWithPhysics(A, Dx, b, rModelPart); /* std::cout << "MOMENTUM EQ: solve_time : " << m_solve_time.elapsed() << std::endl; */ Timer::Stop("Solve"); const double stop_solve = OpenMPUtils::GetCurrentTime(); KRATOS_INFO_IF("ResidualBasedBlockBuilderAndSolver", (this->GetEchoLevel() >= 1 && rModelPart.GetCommunicator().MyPID() == 0)) << "System solve time: " << stop_solve - start_solve << std::endl; KRATOS_INFO_IF("ResidualBasedBlockBuilderAndSolver", (this->GetEchoLevel() == 3)) << "After the solution of the system" << "\nSystem Matrix = " << A << "\nUnknowns vector = " << Dx << "\nRHS vector = " << b << std::endl; KRATOS_CATCH("") } /** * @brief Builds the list of the DofSets involved in the problem by "asking" to each element * and condition its Dofs. * @details The list of dofs is stores insde the BuilderAndSolver as it is closely connected to the * way the matrix and RHS are built * @param pScheme The integration scheme considered * @param rModelPart The model part of the problem to solve */ void SetUpDofSet( typename TSchemeType::Pointer pScheme, ModelPart &rModelPart) override { KRATOS_TRY; KRATOS_INFO_IF("NodalResidualBasedEliminationBuilderAndSolverForFSI", this->GetEchoLevel() > 1 && rModelPart.GetCommunicator().MyPID() == 0) << "Setting up the dofs" << std::endl; //Gets the array of elements from the modeler ElementsArrayType &pElements = rModelPart.Elements(); const int nelements = static_cast<int>(pElements.size()); Element::DofsVectorType ElementalDofList; ProcessInfo &CurrentProcessInfo = rModelPart.GetProcessInfo(); unsigned int nthreads = OpenMPUtils::GetNumThreads(); // typedef boost::fast_pool_allocator< NodeType::DofType::Pointer > allocator_type; // typedef std::unordered_set < NodeType::DofType::Pointer, // DofPointerHasher, // DofPointerComparor, // allocator_type > set_type; #ifdef USE_GOOGLE_HASH typedef google::dense_hash_set<NodeType::DofType::Pointer, DofPointerHasher> set_type; #else typedef std::unordered_set<NodeType::DofType::Pointer, DofPointerHasher> set_type; #endif // std::vector<set_type> dofs_aux_list(nthreads); // std::vector<allocator_type> allocators(nthreads); for (int i = 0; i < static_cast<int>(nthreads); i++) { #ifdef USE_GOOGLE_HASH dofs_aux_list[i].set_empty_key(NodeType::DofType::Pointer()); #else // dofs_aux_list[i] = set_type( allocators[i]); dofs_aux_list[i].reserve(nelements); #endif } // #pragma omp parallel for firstprivate(nelements, ElementalDofList) for (int i = 0; i < static_cast<int>(nelements); i++) { typename ElementsArrayType::iterator it = pElements.begin() + i; const unsigned int this_thread_id = OpenMPUtils::ThisThread(); // gets list of Dof involved on every element pScheme->GetElementalDofList(*(it.base()), ElementalDofList, CurrentProcessInfo); dofs_aux_list[this_thread_id].insert(ElementalDofList.begin(), ElementalDofList.end()); } ConditionsArrayType &pConditions = rModelPart.Conditions(); const int nconditions = static_cast<int>(pConditions.size()); #pragma omp parallel for firstprivate(nconditions, ElementalDofList) for (int i = 0; i < nconditions; i++) { typename ConditionsArrayType::iterator it = pConditions.begin() + i; const unsigned int this_thread_id = OpenMPUtils::ThisThread(); // gets list of Dof involved on every element pScheme->GetConditionDofList(*(it.base()), ElementalDofList, CurrentProcessInfo); dofs_aux_list[this_thread_id].insert(ElementalDofList.begin(), ElementalDofList.end()); } //here we do a reduction in a tree so to have everything on thread 0 unsigned int old_max = nthreads; unsigned int new_max = ceil(0.5 * static_cast<double>(old_max)); while (new_max >= 1 && new_max != old_max) { // //just for debugging // std::cout << "old_max" << old_max << " new_max:" << new_max << std::endl; // for (int i = 0; i < new_max; i++) // { // if (i + new_max < old_max) // { // std::cout << i << " - " << i + new_max << std::endl; // } // } // std::cout << "********************" << std::endl; #pragma omp parallel for for (int i = 0; i < static_cast<int>(new_max); i++) { if (i + new_max < old_max) { dofs_aux_list[i].insert(dofs_aux_list[i + new_max].begin(), dofs_aux_list[i + new_max].end()); dofs_aux_list[i + new_max].clear(); } } old_max = new_max; new_max = ceil(0.5 * static_cast<double>(old_max)); } DofsArrayType Doftemp; BaseType::mDofSet = DofsArrayType(); Doftemp.reserve(dofs_aux_list[0].size()); for (auto it = dofs_aux_list[0].begin(); it != dofs_aux_list[0].end(); it++) { Doftemp.push_back(*it); } Doftemp.Sort(); BaseType::mDofSet = Doftemp; // Throws an execption if there are no Degrees of freedom involved in the analysis KRATOS_ERROR_IF(BaseType::mDofSet.size() == 0) << "No degrees of freedom!" << std::endl; BaseType::mDofSetIsInitialized = true; KRATOS_INFO_IF("NodalResidualBasedEliminationBuilderAndSolverForFSI", this->GetEchoLevel() > 2 && rModelPart.GetCommunicator().MyPID() == 0) << "Finished setting up the dofs" << std::endl; #ifdef _OPENMP if (mlock_array.size() != 0) { for (int i = 0; i < static_cast<int>(mlock_array.size()); i++) omp_destroy_lock(&mlock_array[i]); } mlock_array.resize(BaseType::mDofSet.size()); for (int i = 0; i < static_cast<int>(mlock_array.size()); i++) omp_init_lock(&mlock_array[i]); #endif // If reactions are to be calculated, we check if all the dofs have reactions defined // This is tobe done only in debug mode #ifdef KRATOS_DEBUG if (BaseType::GetCalculateReactionsFlag()) { for (auto dof_iterator = BaseType::mDofSet.begin(); dof_iterator != BaseType::mDofSet.end(); ++dof_iterator) { KRATOS_ERROR_IF_NOT(dof_iterator->HasReaction()) << "Reaction variable not set for the following : " << std::endl << "Node : " << dof_iterator->Id() << std::endl << "Dof : " << (*dof_iterator) << std::endl << "Not possible to calculate reactions." << std::endl; } } #endif KRATOS_CATCH(""); } /** * @brief Organises the dofset in order to speed up the building phase * @param rModelPart The model part of the problem to solve */ void SetUpSystem( ModelPart &rModelPart) override { // Set equation id for degrees of freedom // the free degrees of freedom are positioned at the beginning of the system, // while the fixed one are at the end (in opposite order). // // that means that if the EquationId is greater than "mEquationSystemSize" // the pointed degree of freedom is restrained // int free_id = 0; int fix_id = BaseType::mDofSet.size(); for (typename DofsArrayType::iterator dof_iterator = BaseType::mDofSet.begin(); dof_iterator != BaseType::mDofSet.end(); ++dof_iterator) if (dof_iterator->IsFixed()) dof_iterator->SetEquationId(--fix_id); else dof_iterator->SetEquationId(free_id++); BaseType::mEquationSystemSize = fix_id; } //************************************************************************** //************************************************************************** void ResizeAndInitializeVectors( typename TSchemeType::Pointer pScheme, TSystemMatrixPointerType &pA, TSystemVectorPointerType &pDx, TSystemVectorPointerType &pb, ModelPart &rModelPart) override { KRATOS_TRY // boost::timer m_contruct_matrix; if (pA == NULL) //if the pointer is not initialized initialize it to an empty matrix { TSystemMatrixPointerType pNewA = TSystemMatrixPointerType(new TSystemMatrixType(0, 0)); pA.swap(pNewA); } if (pDx == NULL) //if the pointer is not initialized initialize it to an empty matrix { TSystemVectorPointerType pNewDx = TSystemVectorPointerType(new TSystemVectorType(0)); pDx.swap(pNewDx); } if (pb == NULL) //if the pointer is not initialized initialize it to an empty matrix { TSystemVectorPointerType pNewb = TSystemVectorPointerType(new TSystemVectorType(0)); pb.swap(pNewb); } if (BaseType::mpReactionsVector == NULL) //if the pointer is not initialized initialize it to an empty matrix { TSystemVectorPointerType pNewReactionsVector = TSystemVectorPointerType(new TSystemVectorType(0)); BaseType::mpReactionsVector.swap(pNewReactionsVector); } TSystemMatrixType &A = *pA; TSystemVectorType &Dx = *pDx; TSystemVectorType &b = *pb; //resizing the system vectors and matrix if (A.size1() == 0 || BaseType::GetReshapeMatrixFlag() == true) //if the matrix is not initialized { A.resize(BaseType::mEquationSystemSize, BaseType::mEquationSystemSize, false); ConstructMatrixStructureForFSI(pScheme, A, rModelPart); } else { if (A.size1() != BaseType::mEquationSystemSize || A.size2() != BaseType::mEquationSystemSize) { KRATOS_WATCH("it should not come here!!!!!!!! ... this is SLOW"); KRATOS_ERROR << "The equation system size has changed during the simulation. This is not permited." << std::endl; A.resize(BaseType::mEquationSystemSize, BaseType::mEquationSystemSize, true); ConstructMatrixStructureForFSI(pScheme, A, rModelPart); } } if (Dx.size() != BaseType::mEquationSystemSize) Dx.resize(BaseType::mEquationSystemSize, false); if (b.size() != BaseType::mEquationSystemSize) b.resize(BaseType::mEquationSystemSize, false); //if needed resize the vector for the calculation of reactions if (BaseType::mCalculateReactionsFlag == true) { unsigned int ReactionsVectorSize = BaseType::mDofSet.size(); if (BaseType::mpReactionsVector->size() != ReactionsVectorSize) BaseType::mpReactionsVector->resize(ReactionsVectorSize, false); } // std::cout << "MOMENTUM EQ: contruct_matrix : " << m_contruct_matrix.elapsed() << std::endl; KRATOS_CATCH("") } //************************************************************************** //************************************************************************** /** * @brief Applies the dirichlet conditions. This operation may be very heavy or completely * unexpensive depending on the implementation choosen and on how the System Matrix is built. * @details For explanation of how it works for a particular implementation the user * should refer to the particular Builder And Solver choosen * @param pScheme The integration scheme considered * @param rModelPart The model part of the problem to solve * @param A The LHS matrix * @param Dx The Unknowns vector * @param b The RHS vector */ void ApplyDirichletConditions( typename TSchemeType::Pointer pScheme, ModelPart &rModelPart, TSystemMatrixType &A, TSystemVectorType &Dx, TSystemVectorType &b) override { } /** * @brief This function is intended to be called at the end of the solution step to clean up memory storage not needed */ void Clear() override { this->mDofSet = DofsArrayType(); if (this->mpReactionsVector != NULL) TSparseSpace::Clear((this->mpReactionsVector)); // this->mReactionsVector = TSystemVectorType(); this->mpLinearSystemSolver->Clear(); KRATOS_INFO_IF("NodalResidualBasedEliminationBuilderAndSolverForFSI", this->GetEchoLevel() > 1) << "Clear Function called" << std::endl; } /** * @brief This function is designed to be called once to perform all the checks needed * on the input provided. Checks can be "expensive" as the function is designed * to catch user's errors. * @param rModelPart The model part of the problem to solve * @return 0 all ok */ int Check(ModelPart &rModelPart) override { KRATOS_TRY return 0; KRATOS_CATCH(""); } ///@} ///@name Access ///@{ ///@} ///@name Inquiry ///@{ ///@} ///@name Friends ///@{ ///@} protected: ///@name Protected static Member Variables ///@{ ///@} ///@name Protected member Variables ///@{ ///@} ///@name Protected Operators ///@{ ///@} ///@name Protected Operations ///@{ void Assemble( TSystemMatrixType &A, TSystemVectorType &b, const LocalSystemMatrixType &LHS_Contribution, const LocalSystemVectorType &RHS_Contribution, const Element::EquationIdVectorType &EquationId #ifdef _OPENMP , std::vector<omp_lock_t> &lock_array #endif ) { unsigned int local_size = LHS_Contribution.size1(); for (unsigned int i_local = 0; i_local < local_size; i_local++) { unsigned int i_global = EquationId[i_local]; if (i_global < BaseType::mEquationSystemSize) { #ifdef _OPENMP omp_set_lock(&lock_array[i_global]); #endif b[i_global] += RHS_Contribution(i_local); for (unsigned int j_local = 0; j_local < local_size; j_local++) { unsigned int j_global = EquationId[j_local]; if (j_global < BaseType::mEquationSystemSize) { A(i_global, j_global) += LHS_Contribution(i_local, j_local); } } #ifdef _OPENMP omp_unset_lock(&lock_array[i_global]); #endif } //note that assembly on fixed rows is not performed here } } //************************************************************************** virtual void ConstructMatrixStructureForFSI( typename TSchemeType::Pointer pScheme, TSystemMatrixType &A, ModelPart &rModelPart) { //filling with zero the matrix (creating the structure) Timer::Start("MatrixStructure"); ProcessInfo &CurrentProcessInfo = rModelPart.GetProcessInfo(); // Getting the array of the conditions const int nconditions = static_cast<int>(rModelPart.Conditions().size()); ModelPart::ConditionsContainerType::iterator cond_begin = rModelPart.ConditionsBegin(); const std::size_t equation_size = BaseType::mEquationSystemSize; #ifdef USE_GOOGLE_HASH std::vector<google::dense_hash_set<std::size_t>> indices(equation_size); const std::size_t empty_key = 2 * equation_size + 10; #else std::vector<std::unordered_set<std::size_t>> indices(equation_size); #endif #pragma omp parallel for firstprivate(equation_size) for (int iii = 0; iii < static_cast<int>(equation_size); iii++) { #ifdef USE_GOOGLE_HASH indices[iii].set_empty_key(empty_key); #else indices[iii].reserve(40); #endif } Element::EquationIdVectorType EquationId; ModelPart::NodeIterator NodesBegin; ModelPart::NodeIterator NodesEnd; OpenMPUtils::PartitionedIterators(rModelPart.Nodes(), NodesBegin, NodesEnd); for (ModelPart::NodeIterator itNode = NodesBegin; itNode != NodesEnd; ++itNode) { if (itNode->Is(SOLID)) { const unsigned int localSize = itNode->FastGetSolutionStepValue(SOLID_NODAL_SFD_NEIGHBOURS).size(); const unsigned int dimension = rModelPart.ElementsBegin()->GetGeometry().WorkingSpaceDimension(); Vector nodalSFDneighboursId = itNode->FastGetSolutionStepValue(SOLID_NODAL_SFD_NEIGHBOURS_ORDER); const unsigned int neighSize = nodalSFDneighboursId.size(); if (EquationId.size() != localSize) EquationId.resize(localSize, false); unsigned int firstCol = 0; const unsigned int xDofPos = itNode->GetDofPosition(VELOCITY_X); EquationId[0] = itNode->GetDof(VELOCITY_X, xDofPos).EquationId(); EquationId[1] = itNode->GetDof(VELOCITY_Y, xDofPos + 1).EquationId(); if (dimension == 3) EquationId[2] = itNode->GetDof(VELOCITY_Z, xDofPos + 2).EquationId(); if (itNode->FastGetSolutionStepValue(INTERFACE_NODE) == true) { NodeWeakPtrVectorType &neighb_nodes = itNode->GetValue(NEIGHBOUR_NODES); for (unsigned int i = 0; i < neighb_nodes.size(); i++) { unsigned int indexNode = i + 1; if (indexNode < neighSize) { unsigned int other_neigh_nodes_id = nodalSFDneighboursId[indexNode]; firstCol += dimension; for (unsigned int k = 0; k < neighb_nodes.size(); k++) { unsigned int neigh_nodes_id = neighb_nodes[k].Id(); if (neigh_nodes_id == other_neigh_nodes_id) { EquationId[firstCol] = neighb_nodes[k].GetDof(VELOCITY_X, xDofPos).EquationId(); EquationId[firstCol + 1] = neighb_nodes[k].GetDof(VELOCITY_Y, xDofPos + 1).EquationId(); if (dimension == 3) { EquationId[firstCol + 2] = neighb_nodes[k].GetDof(VELOCITY_Z, xDofPos + 2).EquationId(); } break; } } } } } else { NodeWeakPtrVectorType &neighb_nodes = itNode->GetValue(NEIGHBOUR_NODES); for (unsigned int i = 0; i < neighb_nodes.size(); i++) { firstCol += dimension; EquationId[firstCol] = neighb_nodes[i].GetDof(VELOCITY_X, xDofPos).EquationId(); EquationId[firstCol + 1] = neighb_nodes[i].GetDof(VELOCITY_Y, xDofPos + 1).EquationId(); if (dimension == 3) { EquationId[firstCol + 2] = neighb_nodes[i].GetDof(VELOCITY_Z, xDofPos + 2).EquationId(); } } } } if ((itNode->Is(FLUID) && itNode->IsNot(SOLID)) || itNode->FastGetSolutionStepValue(INTERFACE_NODE) == true) { const unsigned int localSize = itNode->FastGetSolutionStepValue(NODAL_SFD_NEIGHBOURS).size(); const unsigned int dimension = rModelPart.ElementsBegin()->GetGeometry().WorkingSpaceDimension(); Vector nodalSFDneighboursId = itNode->FastGetSolutionStepValue(NODAL_SFD_NEIGHBOURS_ORDER); const unsigned int neighSize = nodalSFDneighboursId.size(); if (EquationId.size() != localSize) EquationId.resize(localSize, false); unsigned int firstCol = 0; const unsigned int xDofPos = itNode->GetDofPosition(VELOCITY_X); EquationId[0] = itNode->GetDof(VELOCITY_X, xDofPos).EquationId(); EquationId[1] = itNode->GetDof(VELOCITY_Y, xDofPos + 1).EquationId(); if (dimension == 3) EquationId[2] = itNode->GetDof(VELOCITY_Z, xDofPos + 2).EquationId(); if (itNode->FastGetSolutionStepValue(INTERFACE_NODE) == true) { NodeWeakPtrVectorType &neighb_nodes = itNode->GetValue(NEIGHBOUR_NODES); for (unsigned int i = 0; i < neighb_nodes.size(); i++) { unsigned int indexNode = i + 1; if (indexNode < neighSize) { unsigned int other_neigh_nodes_id = nodalSFDneighboursId[indexNode]; firstCol += dimension; for (unsigned int k = 0; k < neighb_nodes.size(); k++) { unsigned int neigh_nodes_id = neighb_nodes[k].Id(); if (neigh_nodes_id == other_neigh_nodes_id) { EquationId[firstCol] = neighb_nodes[k].GetDof(VELOCITY_X, xDofPos).EquationId(); EquationId[firstCol + 1] = neighb_nodes[k].GetDof(VELOCITY_Y, xDofPos + 1).EquationId(); if (dimension == 3) { EquationId[firstCol + 2] = neighb_nodes[k].GetDof(VELOCITY_Z, xDofPos + 2).EquationId(); } break; } } } } } else { NodeWeakPtrVectorType &neighb_nodes = itNode->GetValue(NEIGHBOUR_NODES); for (unsigned int i = 0; i < neighb_nodes.size(); i++) { firstCol += dimension; EquationId[firstCol] = neighb_nodes[i].GetDof(VELOCITY_X, xDofPos).EquationId(); EquationId[firstCol + 1] = neighb_nodes[i].GetDof(VELOCITY_Y, xDofPos + 1).EquationId(); if (dimension == 3) { EquationId[firstCol + 2] = neighb_nodes[i].GetDof(VELOCITY_Z, xDofPos + 2).EquationId(); } } } } for (std::size_t i = 0; i < EquationId.size(); i++) { if (EquationId[i] < BaseType::mEquationSystemSize) { #ifdef _OPENMP omp_set_lock(&mlock_array[EquationId[i]]); #endif auto &row_indices = indices[EquationId[i]]; for (auto it = EquationId.begin(); it != EquationId.end(); it++) { if (*it < BaseType::mEquationSystemSize) row_indices.insert(*it); } #ifdef _OPENMP omp_unset_lock(&mlock_array[EquationId[i]]); #endif } } } Element::EquationIdVectorType ids(3, 0); #pragma omp parallel for firstprivate(nconditions, ids) for (int iii = 0; iii < nconditions; iii++) { typename ConditionsArrayType::iterator i_condition = cond_begin + iii; pScheme->Condition_EquationId(*(i_condition.base()), ids, CurrentProcessInfo); for (std::size_t i = 0; i < ids.size(); i++) { if (ids[i] < BaseType::mEquationSystemSize) { #ifdef _OPENMP omp_set_lock(&mlock_array[ids[i]]); #endif auto &row_indices = indices[ids[i]]; for (auto it = ids.begin(); it != ids.end(); it++) { if (*it < BaseType::mEquationSystemSize) row_indices.insert(*it); } #ifdef _OPENMP omp_unset_lock(&mlock_array[ids[i]]); #endif } } } //count the row sizes unsigned int nnz = 0; for (unsigned int i = 0; i < indices.size(); i++) nnz += indices[i].size(); A = boost::numeric::ublas::compressed_matrix<double>(indices.size(), indices.size(), nnz); double *Avalues = A.value_data().begin(); std::size_t *Arow_indices = A.index1_data().begin(); std::size_t *Acol_indices = A.index2_data().begin(); //filling the index1 vector - DO NOT MAKE PARALLEL THE FOLLOWING LOOP! Arow_indices[0] = 0; for (int i = 0; i < static_cast<int>(A.size1()); i++) Arow_indices[i + 1] = Arow_indices[i] + indices[i].size(); #pragma omp parallel for for (int i = 0; i < static_cast<int>(A.size1()); i++) { const unsigned int row_begin = Arow_indices[i]; const unsigned int row_end = Arow_indices[i + 1]; unsigned int k = row_begin; for (auto it = indices[i].begin(); it != indices[i].end(); it++) { Acol_indices[k] = *it; Avalues[k] = 0.0; k++; } std::sort(&Acol_indices[row_begin], &Acol_indices[row_end]); } A.set_filled(indices.size() + 1, nnz); Timer::Stop("MatrixStructure"); } void AssembleLHS( TSystemMatrixType &A, LocalSystemMatrixType &LHS_Contribution, Element::EquationIdVectorType &EquationId) { unsigned int local_size = LHS_Contribution.size1(); for (unsigned int i_local = 0; i_local < local_size; i_local++) { unsigned int i_global = EquationId[i_local]; if (i_global < BaseType::mEquationSystemSize) { for (unsigned int j_local = 0; j_local < local_size; j_local++) { unsigned int j_global = EquationId[j_local]; if (j_global < BaseType::mEquationSystemSize) A(i_global, j_global) += LHS_Contribution(i_local, j_local); } } } } ///@} ///@name Protected Access ///@{ ///@} ///@name Protected Inquiry ///@{ ///@} ///@name Protected LifeCycle ///@{ ///@} private: ///@name Static Member Variables ///@{ ///@} ///@name Member Variables ///@{ #ifdef _OPENMP std::vector<omp_lock_t> mlock_array; #endif ///@} ///@name Private Operators ///@{ ///@} ///@name Private Operations ///@{ inline void AddUnique(std::vector<std::size_t> &v, const std::size_t &candidate) { std::vector<std::size_t>::iterator i = v.begin(); std::vector<std::size_t>::iterator endit = v.end(); while (i != endit && (*i) != candidate) { i++; } if (i == endit) { v.push_back(candidate); } } void AssembleRHS( TSystemVectorType &b, const LocalSystemVectorType &RHS_Contribution, const Element::EquationIdVectorType &EquationId) { unsigned int local_size = RHS_Contribution.size(); if (BaseType::mCalculateReactionsFlag == false) { for (unsigned int i_local = 0; i_local < local_size; i_local++) { const unsigned int i_global = EquationId[i_local]; if (i_global < BaseType::mEquationSystemSize) //free dof { // ASSEMBLING THE SYSTEM VECTOR double &b_value = b[i_global]; const double &rhs_value = RHS_Contribution[i_local]; #pragma omp atomic b_value += rhs_value; } } } else { TSystemVectorType &ReactionsVector = *BaseType::mpReactionsVector; for (unsigned int i_local = 0; i_local < local_size; i_local++) { const unsigned int i_global = EquationId[i_local]; if (i_global < BaseType::mEquationSystemSize) //free dof { // ASSEMBLING THE SYSTEM VECTOR double &b_value = b[i_global]; const double &rhs_value = RHS_Contribution[i_local]; #pragma omp atomic b_value += rhs_value; } else //fixed dof { double &b_value = ReactionsVector[i_global - BaseType::mEquationSystemSize]; const double &rhs_value = RHS_Contribution[i_local]; #pragma omp atomic b_value += rhs_value; } } } } //************************************************************************** void AssembleLHS_CompleteOnFreeRows( TSystemMatrixType &A, LocalSystemMatrixType &LHS_Contribution, Element::EquationIdVectorType &EquationId) { unsigned int local_size = LHS_Contribution.size1(); for (unsigned int i_local = 0; i_local < local_size; i_local++) { unsigned int i_global = EquationId[i_local]; if (i_global < BaseType::mEquationSystemSize) { for (unsigned int j_local = 0; j_local < local_size; j_local++) { int j_global = EquationId[j_local]; A(i_global, j_global) += LHS_Contribution(i_local, j_local); } } } } ///@} ///@name Private Operations ///@{ ///@} ///@name Private Access ///@{ ///@} ///@name Private Inquiry ///@{ ///@} ///@name Un accessible methods ///@{ ///@} }; /* Class NodalResidualBasedEliminationBuilderAndSolverForFSI */ ///@} ///@name Type Definitions ///@{ ///@} } /* namespace Kratos.*/ #endif /* KRATOS_NODAL_RESIDUAL_BASED_ELIMINATION_BUILDER_AND_SOLVER_FOR_FSI defined */

GB_unop__identity_fp32_uint8.c

//------------------------------------------------------------------------------ // GB_unop: 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_unop__include.h" // C=unop(A) is defined by the following types and operators: // op(A) function: GB_unop_apply__identity_fp32_uint8 // op(A') function: GB_unop_tran__identity_fp32_uint8 // C type: float // A type: uint8_t // cast: float cij = (float) aij // unaryop: cij = aij #define GB_ATYPE \ uint8_t #define GB_CTYPE \ float // aij = Ax [pA] #define GB_GETA(aij,Ax,pA) \ uint8_t aij = Ax [pA] #define GB_CX(p) Cx [p] // unary operator #define GB_OP(z, x) \ z = x ; // casting #define GB_CAST(z, aij) \ float z = (float) aij ; // cij = op (aij) #define GB_CAST_OP(pC,pA) \ { \ /* aij = Ax [pA] */ \ uint8_t aij = Ax [pA] ; \ /* Cx [pC] = op (cast (aij)) */ \ float z = (float) aij ; \ Cx [pC] = z ; \ } // disable this operator and use the generic case if these conditions hold #define GB_DISABLE \ (GxB_NO_IDENTITY || GxB_NO_FP32 || GxB_NO_UINT8) //------------------------------------------------------------------------------ // Cx = op (cast (Ax)): apply a unary operator //------------------------------------------------------------------------------ GrB_Info GB_unop_apply__identity_fp32_uint8 ( float *Cx, // Cx and Ax may be aliased const uint8_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++) { uint8_t aij = Ax [p] ; float z = (float) aij ; Cx [p] = z ; } return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // C = op (cast (A')): transpose, typecast, and apply a unary operator //------------------------------------------------------------------------------ GrB_Info GB_unop_tran__identity_fp32_uint8 ( 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_unop_transpose.c" return (GrB_SUCCESS) ; #endif } #endif

GrB_IndexUnaryOp_wait.c

//------------------------------------------------------------------------------ // GrB_IndexUnaryOp_wait: wait for a user-defined GrB_IndexUnaryOp to complete //------------------------------------------------------------------------------ // SuiteSparse:GraphBLAS, Timothy A. Davis, (c) 2017-2022, All Rights Reserved. // SPDX-License-Identifier: Apache-2.0 //------------------------------------------------------------------------------ // In SuiteSparse:GraphBLAS, a user-defined GrB_IndexUnaryOp has no pending // operations to wait for. All this method does is verify that the op is // properly initialized, and then it does an OpenMP flush. #include "GB.h" GrB_Info GrB_IndexUnaryOp_wait // no work, just check if valid ( GrB_IndexUnaryOp op, GrB_WaitMode waitmode ) { //-------------------------------------------------------------------------- // check inputs //-------------------------------------------------------------------------- GB_WHERE1 ("GrB_IndexUnaryOp_wait (op, waitmode)") ; GB_RETURN_IF_NULL_OR_FAULTY (op) ; //-------------------------------------------------------------------------- // return result //-------------------------------------------------------------------------- #pragma omp flush return (GrB_SUCCESS) ; }

GB_unaryop__abs_int32_int32.c

//------------------------------------------------------------------------------ // GB_unaryop: hard-coded functions for each built-in unary operator //------------------------------------------------------------------------------ // SuiteSparse:GraphBLAS, Timothy A. Davis, (c) 2017-2019, 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__abs_int32_int32 // op(A') function: GB_tran__abs_int32_int32 // C type: int32_t // A type: int32_t // cast: int32_t cij = (int32_t) aij // unaryop: cij = GB_IABS (aij) #define GB_ATYPE \ int32_t #define GB_CTYPE \ int32_t // aij = Ax [pA] #define GB_GETA(aij,Ax,pA) \ int32_t aij = Ax [pA] #define GB_CX(p) Cx [p] // unary operator #define GB_OP(z, x) \ z = GB_IABS (x) ; // casting #define GB_CASTING(z, x) \ int32_t z = (int32_t) x ; // 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 (x, aij) ; \ GB_OP (GB_CX (pC), x) ; \ } // disable this operator and use the generic case if these conditions hold #define GB_DISABLE \ (GxB_NO_ABS || GxB_NO_INT32) //------------------------------------------------------------------------------ // Cx = op (cast (Ax)): apply a unary operator //------------------------------------------------------------------------------ GrB_Info GB_unop__abs_int32_int32 ( int32_t *restrict Cx, const int32_t *restrict Ax, int64_t anz, int nthreads ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else #pragma omp parallel for num_threads(nthreads) schedule(static) for (int64_t 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__abs_int32_int32 ( GrB_Matrix C, const GrB_Matrix A, int64_t **Rowcounts, GBI_single_iterator Iter, const int64_t *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

DRB008-indirectaccess4-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. */ /* Two pointers have a distance of 12 (xa2 - xa1 = 12). They are used as base addresses for indirect array accesses using an index set (another array). The index set has two indices with distance of 12 : indexSet[1]- indexSet[0] = 533 - 521 = 12 So xa1[idx] and xa2[idx] may cause loop carried dependence for N=0 and N=3. We use the default loop scheduling (static even) in OpenMP. It is possible that two dependent iterations will be scheduled within a same chunk to a same thread. So there is no runtime data races. N is 180, two iteraions with N=0 and N= 1 have loop carried dependences. For static even scheduling, we must have at least 180 threads (180180=1 iterations) so iteration 0 and 1 will be scheduled to two different threads. Data race pair: xa1[idx]@128:5 vs. xa2[idx]@129:5 */ #include <assert.h> #include <stdio.h> #include <stdlib.h> /* 521+12=533 */ int indexSet[180] = {521, 533, 525, 527, 529, 531, 547, 549, 551, 553, 555, 557, 573, 575, 577, 579, 581, 583, 599, 601, 603, 605, 607, 609, 625, 627, 629, 631, 633, 635, 651, 653, 655, 657, 659, 661, 859, 861, 863, 865, 867, 869, 885, 887, 889, 891, 893, 895, 911, 913, 915, 917, 919, 921, 937, 939, 941, 943, 945, 947, 963, 965, 967, 969, 971, 973, 989, 991, 993, 995, 997, 999, 1197, 1199, 1201, 1203, 1205, 1207, 1223, 1225, 1227, 1229, 1231, 1233, 1249, 1251, 1253, 1255, 1257, 1259, 1275, 1277, 1279, 1281, 1283, 1285, 1301, 1303, 1305, 1307, 1309, 1311, 1327, 1329, 1331, 1333, 1335, 1337, 1535, 1537, 1539, 1541, 1543, 1545, 1561, 1563, 1565, 1567, 1569, 1571, 1587, 1589, 1591, 1593, 1595, 1597, 1613, 1615, 1617, 1619, 1621, 1623, 1639, 1641, 1643, 1645, 1647, 1649, 1665, 1667, 1669, 1671, 1673, 1675, 1873, 1875, 1877, 1879, 1881, 1883, 1899, 1901, 1903, 1905, 1907, 1909, 1925, 1927, 1929, 1931, 1933, 1935, 1951, 1953, 1955, 1957, 1959, 1961, 1977, 1979, 1981, 1983, 1985, 1987, 2003, 2005, 2007, 2009, 2011, 2013}; int main(int argc, char * argv[]) { double * base = (double * )malloc(sizeof (double)*((2013+12)+1)); double * xa1 = base; double * xa2 = xa1+12; int i; int _ret_val_0; if (base==0) { printf("Error in malloc(). Aborting ...\n"); _ret_val_0=1; return _ret_val_0; } /* initialize segments touched by indexSet */ #pragma loop name main#0 #pragma cetus parallel #pragma omp parallel for for (i=521; i<=2025; ++ i) { base[i]=(0.5*i); } #pragma loop name main#1 for (i=0; i<180; ++ i) { int idx = indexSet[i]; xa1[idx]+=1.0; xa2[idx]+=3.0; } printf("x1[999]=%f xa2[1285]=%f\n", xa1[999], xa2[1285]); free(base); _ret_val_0=0; return _ret_val_0; }

ocp_nlp_sqp.c

/* * Copyright 2019 Gianluca Frison, Dimitris Kouzoupis, Robin Verschueren, * Andrea Zanelli, Niels van Duijkeren, Jonathan Frey, Tommaso Sartor, * Branimir Novoselnik, Rien Quirynen, Rezart Qelibari, Dang Doan, * Jonas Koenemann, Yutao Chen, Tobias Schöls, Jonas Schlagenhauf, Moritz Diehl * * This file is part of acados. * * The 2-Clause BSD License * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are met: * * 1. Redistributions of source code must retain the above copyright notice, * this list of conditions and the following disclaimer. * * 2. 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. * * 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.; */ #include "acados/ocp_nlp/ocp_nlp_sqp.h" // external #include <assert.h> #include <math.h> #include <stdio.h> #include <string.h> #include <stdlib.h> #if defined(ACADOS_WITH_OPENMP) #include <omp.h> #endif // blasfeo #include "blasfeo/include/blasfeo_d_aux.h" #include "blasfeo/include/blasfeo_d_aux_ext_dep.h" #include "blasfeo/include/blasfeo_d_blas.h" // acados #include "acados/ocp_nlp/ocp_nlp_common.h" #include "acados/ocp_nlp/ocp_nlp_dynamics_cont.h" #include "acados/ocp_nlp/ocp_nlp_reg_common.h" #include "acados/ocp_qp/ocp_qp_common.h" #include "acados/utils/mem.h" #include "acados/utils/print.h" #include "acados/utils/timing.h" #include "acados/utils/types.h" #include "acados_c/ocp_qp_interface.h" /************************************************ * options ************************************************/ int ocp_nlp_sqp_opts_calculate_size(void *config_, void *dims_) { ocp_nlp_dims *dims = dims_; ocp_nlp_config *config = config_; int size = 0; size += sizeof(ocp_nlp_sqp_opts); size += ocp_nlp_opts_calculate_size(config, dims); return size; } void *ocp_nlp_sqp_opts_assign(void *config_, void *dims_, void *raw_memory) { ocp_nlp_dims *dims = dims_; ocp_nlp_config *config = config_; char *c_ptr = (char *) raw_memory; ocp_nlp_sqp_opts *opts = (ocp_nlp_sqp_opts *) c_ptr; c_ptr += sizeof(ocp_nlp_sqp_opts); opts->nlp_opts = ocp_nlp_opts_assign(config, dims, c_ptr); c_ptr += ocp_nlp_opts_calculate_size(config, dims); assert((char *) raw_memory + ocp_nlp_sqp_opts_calculate_size(config, dims) >= c_ptr); return opts; } void ocp_nlp_sqp_opts_initialize_default(void *config_, void *dims_, void *opts_) { ocp_nlp_dims *dims = dims_; ocp_nlp_config *config = config_; ocp_nlp_sqp_opts *opts = opts_; ocp_nlp_opts *nlp_opts = opts->nlp_opts; ocp_qp_xcond_solver_config *qp_solver = config->qp_solver; // int ii; // this first !!! ocp_nlp_opts_initialize_default(config, dims, nlp_opts); // SQP opts opts->max_iter = 20; opts->tol_stat = 1e-8; opts->tol_eq = 1e-8; opts->tol_ineq = 1e-8; opts->tol_comp = 1e-8; opts->ext_qp_res = 0; opts->qp_warm_start = 0; opts->warm_start_first_qp = false; opts->rti_phase = 0; opts->print_level = 0; opts->initialize_t_slacks = 0; // overwrite default submodules opts // qp tolerance qp_solver->opts_set(qp_solver, opts->nlp_opts->qp_solver_opts, "tol_stat", &opts->tol_stat); qp_solver->opts_set(qp_solver, opts->nlp_opts->qp_solver_opts, "tol_eq", &opts->tol_eq); qp_solver->opts_set(qp_solver, opts->nlp_opts->qp_solver_opts, "tol_ineq", &opts->tol_ineq); qp_solver->opts_set(qp_solver, opts->nlp_opts->qp_solver_opts, "tol_comp", &opts->tol_comp); return; } void ocp_nlp_sqp_opts_update(void *config_, void *dims_, void *opts_) { ocp_nlp_dims *dims = dims_; ocp_nlp_config *config = config_; ocp_nlp_sqp_opts *opts = opts_; ocp_nlp_opts *nlp_opts = opts->nlp_opts; ocp_nlp_opts_update(config, dims, nlp_opts); return; } void ocp_nlp_sqp_opts_set(void *config_, void *opts_, const char *field, void* value) { ocp_nlp_config *config = config_; ocp_nlp_sqp_opts *opts = (ocp_nlp_sqp_opts *) opts_; ocp_nlp_opts *nlp_opts = opts->nlp_opts; int ii; char module[MAX_STR_LEN]; char *ptr_module = NULL; int module_length = 0; // extract module name char *char_ = strchr(field, '_'); if (char_!=NULL) { module_length = char_-field; for (ii=0; ii<module_length; ii++) module[ii] = field[ii]; module[module_length] = '\0'; // add end of string ptr_module = module; } // pass options to QP module if ( ptr_module!=NULL && (!strcmp(ptr_module, "qp")) ) { ocp_nlp_opts_set(config, nlp_opts, field, value); if (!strcmp(field, "qp_warm_start")) { int* i_ptr = (int *) value; opts->qp_warm_start = *i_ptr; } } else // nlp opts { if (!strcmp(field, "max_iter")) { int* max_iter = (int *) value; opts->max_iter = *max_iter; } else if (!strcmp(field, "tol_stat")) { double* tol_stat = (double *) value; opts->tol_stat = *tol_stat; // TODO: set accuracy of the qp_solver to the minimum of current QP accuracy and the one specified. config->qp_solver->opts_set(config->qp_solver, opts->nlp_opts->qp_solver_opts, "tol_stat", value); } else if (!strcmp(field, "tol_eq")) { double* tol_eq = (double *) value; opts->tol_eq = *tol_eq; // TODO: set accuracy of the qp_solver to the minimum of current QP accuracy and the one specified. config->qp_solver->opts_set(config->qp_solver, opts->nlp_opts->qp_solver_opts, "tol_eq", value); } else if (!strcmp(field, "tol_ineq")) { double* tol_ineq = (double *) value; opts->tol_ineq = *tol_ineq; // TODO: set accuracy of the qp_solver to the minimum of current QP accuracy and the one specified. config->qp_solver->opts_set(config->qp_solver, opts->nlp_opts->qp_solver_opts, "tol_ineq", value); } else if (!strcmp(field, "tol_comp")) { double* tol_comp = (double *) value; opts->tol_comp = *tol_comp; // TODO: set accuracy of the qp_solver to the minimum of current QP accuracy and the one specified. config->qp_solver->opts_set(config->qp_solver, opts->nlp_opts->qp_solver_opts, "tol_comp", value); } else if (!strcmp(field, "ext_qp_res")) { int* ext_qp_res = (int *) value; opts->ext_qp_res = *ext_qp_res; } else if (!strcmp(field, "warm_start_first_qp")) { bool* warm_start_first_qp = (bool *) value; opts->warm_start_first_qp = *warm_start_first_qp; } else if (!strcmp(field, "rti_phase")) { int* rti_phase = (int *) value; if (*rti_phase < 0 || *rti_phase > 0) { printf("\nerror: ocp_nlp_sqp_opts_set: invalid value for rti_phase field."); printf("possible values are: 0\n"); exit(1); } else opts->rti_phase = *rti_phase; } else if (!strcmp(field, "print_level")) { int* print_level = (int *) value; if (*print_level < 0) { printf("\nerror: ocp_nlp_sqp_opts_set: invalid value for print_level field, need int >=0, got %d.", *print_level); exit(1); } opts->print_level = *print_level; } else if (!strcmp(field, "initialize_t_slacks")) { int* initialize_t_slacks = (int *) value; if (*initialize_t_slacks != 0 && *initialize_t_slacks != 1) { printf("\nerror: ocp_nlp_sqp_opts_set: invalid value for initialize_t_slacks field, need int 0 or 1, got %d.", *initialize_t_slacks); exit(1); } opts->initialize_t_slacks = *initialize_t_slacks; } else { ocp_nlp_opts_set(config, nlp_opts, field, value); } } return; } void ocp_nlp_sqp_opts_set_at_stage(void *config_, void *opts_, int stage, const char *field, void* value) { ocp_nlp_config *config = config_; ocp_nlp_sqp_opts *opts = (ocp_nlp_sqp_opts *) opts_; ocp_nlp_opts *nlp_opts = opts->nlp_opts; ocp_nlp_opts_set_at_stage(config, nlp_opts, stage, field, value); return; } /************************************************ * memory ************************************************/ int ocp_nlp_sqp_memory_calculate_size(void *config_, void *dims_, void *opts_) { ocp_nlp_dims *dims = dims_; ocp_nlp_config *config = config_; ocp_nlp_sqp_opts *opts = opts_; ocp_nlp_opts *nlp_opts = opts->nlp_opts; // int N = dims->N; // int *nx = dims->nx; // int *nu = dims->nu; // int *nz = dims->nz; int size = 0; size += sizeof(ocp_nlp_sqp_memory); // nlp mem size += ocp_nlp_memory_calculate_size(config, dims, nlp_opts); // stat int stat_m = opts->max_iter+1; int stat_n = 6; if (opts->ext_qp_res) stat_n += 4; size += stat_n*stat_m*sizeof(double); size += 3*8; // align make_int_multiple_of(8, &size); return size; } void *ocp_nlp_sqp_memory_assign(void *config_, void *dims_, void *opts_, void *raw_memory) { ocp_nlp_dims *dims = dims_; ocp_nlp_config *config = config_; ocp_nlp_sqp_opts *opts = opts_; ocp_nlp_opts *nlp_opts = opts->nlp_opts; // ocp_qp_xcond_solver_config *qp_solver = config->qp_solver; // ocp_nlp_dynamics_config **dynamics = config->dynamics; // ocp_nlp_cost_config **cost = config->cost; // ocp_nlp_constraints_config **constraints = config->constraints; char *c_ptr = (char *) raw_memory; // int N = dims->N; // int *nx = dims->nx; // int *nu = dims->nu; // int *nz = dims->nz; // initial align align_char_to(8, &c_ptr); ocp_nlp_sqp_memory *mem = (ocp_nlp_sqp_memory *) c_ptr; c_ptr += sizeof(ocp_nlp_sqp_memory); align_char_to(8, &c_ptr); // nlp mem mem->nlp_mem = ocp_nlp_memory_assign(config, dims, nlp_opts, c_ptr); c_ptr += ocp_nlp_memory_calculate_size(config, dims, nlp_opts); // stat mem->stat = (double *) c_ptr; mem->stat_m = opts->max_iter+1; mem->stat_n = 6; if (opts->ext_qp_res) mem->stat_n += 4; c_ptr += mem->stat_m*mem->stat_n*sizeof(double); mem->status = ACADOS_READY; align_char_to(8, &c_ptr); assert((char *) raw_memory + ocp_nlp_sqp_memory_calculate_size(config, dims, opts) >= c_ptr); return mem; } /************************************************ * workspace ************************************************/ int ocp_nlp_sqp_workspace_calculate_size(void *config_, void *dims_, void *opts_) { ocp_nlp_dims *dims = dims_; ocp_nlp_config *config = config_; ocp_nlp_sqp_opts *opts = opts_; ocp_nlp_opts *nlp_opts = opts->nlp_opts; int size = 0; // sqp size += sizeof(ocp_nlp_sqp_workspace); // nlp size += ocp_nlp_workspace_calculate_size(config, dims, nlp_opts); // tmp qp in size += ocp_qp_in_calculate_size(dims->qp_solver->orig_dims); // tmp qp out size += ocp_qp_out_calculate_size(dims->qp_solver->orig_dims); if (opts->ext_qp_res) { // qp res size += ocp_qp_res_calculate_size(dims->qp_solver->orig_dims); // qp res ws size += ocp_qp_res_workspace_calculate_size(dims->qp_solver->orig_dims); } return size; } static void ocp_nlp_sqp_cast_workspace(ocp_nlp_config *config, ocp_nlp_dims *dims, ocp_nlp_sqp_opts *opts, ocp_nlp_sqp_memory *mem, ocp_nlp_sqp_workspace *work) { ocp_nlp_opts *nlp_opts = opts->nlp_opts; ocp_nlp_memory *nlp_mem = mem->nlp_mem; // sqp char *c_ptr = (char *) work; c_ptr += sizeof(ocp_nlp_sqp_workspace); // nlp work->nlp_work = ocp_nlp_workspace_assign(config, dims, nlp_opts, nlp_mem, c_ptr); c_ptr += ocp_nlp_workspace_calculate_size(config, dims, nlp_opts); // tmp qp in work->tmp_qp_in = ocp_qp_in_assign(dims->qp_solver->orig_dims, c_ptr); c_ptr += ocp_qp_in_calculate_size(dims->qp_solver->orig_dims); // tmp qp out work->tmp_qp_out = ocp_qp_out_assign(dims->qp_solver->orig_dims, c_ptr); c_ptr += ocp_qp_out_calculate_size(dims->qp_solver->orig_dims); if (opts->ext_qp_res) { // qp res work->qp_res = ocp_qp_res_assign(dims->qp_solver->orig_dims, c_ptr); c_ptr += ocp_qp_res_calculate_size(dims->qp_solver->orig_dims); // qp res ws work->qp_res_ws = ocp_qp_res_workspace_assign(dims->qp_solver->orig_dims, c_ptr); c_ptr += ocp_qp_res_workspace_calculate_size(dims->qp_solver->orig_dims); } assert((char *) work + ocp_nlp_sqp_workspace_calculate_size(config, dims, opts) >= c_ptr); return; } /************************************************ * functions ************************************************/ int ocp_nlp_sqp(void *config_, void *dims_, void *nlp_in_, void *nlp_out_, void *opts_, void *mem_, void *work_) { acados_timer timer0, timer1; acados_tic(&timer0); ocp_nlp_dims *dims = dims_; ocp_nlp_config *config = config_; ocp_nlp_sqp_opts *opts = opts_; ocp_nlp_opts *nlp_opts = opts->nlp_opts; ocp_nlp_sqp_memory *mem = mem_; ocp_nlp_in *nlp_in = nlp_in_; ocp_nlp_out *nlp_out = nlp_out_; ocp_nlp_memory *nlp_mem = mem->nlp_mem; ocp_qp_xcond_solver_config *qp_solver = config->qp_solver; ocp_nlp_sqp_workspace *work = work_; ocp_nlp_sqp_cast_workspace(config, dims, opts, mem, work); ocp_nlp_workspace *nlp_work = work->nlp_work; // zero timers double total_time = 0.0; double tmp_time; mem->time_qp_sol = 0.0; mem->time_qp_solver_call = 0.0; mem->time_qp_xcond = 0.0; mem->time_lin = 0.0; mem->time_reg = 0.0; mem->time_tot = 0.0; int N = dims->N; int ii; int qp_iter = 0; int qp_status = 0; #if defined(ACADOS_WITH_OPENMP) // backup number of threads int num_threads_bkp = omp_get_num_threads(); // set number of threads omp_set_num_threads(opts->nlp_opts->num_threads); #pragma omp parallel { // beginning of parallel region #endif // alias to dynamics_memory #if defined(ACADOS_WITH_OPENMP) #pragma omp for #endif for (ii = 0; ii < N; ii++) { config->dynamics[ii]->memory_set_ux_ptr(nlp_out->ux+ii, nlp_mem->dynamics[ii]); config->dynamics[ii]->memory_set_tmp_ux_ptr(nlp_work->tmp_nlp_out->ux+ii, nlp_mem->dynamics[ii]); config->dynamics[ii]->memory_set_ux1_ptr(nlp_out->ux+ii+1, nlp_mem->dynamics[ii]); config->dynamics[ii]->memory_set_tmp_ux1_ptr(nlp_work->tmp_nlp_out->ux+ii+1, nlp_mem->dynamics[ii]); config->dynamics[ii]->memory_set_pi_ptr(nlp_out->pi+ii, nlp_mem->dynamics[ii]); config->dynamics[ii]->memory_set_tmp_pi_ptr(nlp_work->tmp_nlp_out->pi+ii, nlp_mem->dynamics[ii]); config->dynamics[ii]->memory_set_BAbt_ptr(nlp_mem->qp_in->BAbt+ii, nlp_mem->dynamics[ii]); config->dynamics[ii]->memory_set_RSQrq_ptr(nlp_mem->qp_in->RSQrq+ii, nlp_mem->dynamics[ii]); config->dynamics[ii]->memory_set_dzduxt_ptr(nlp_mem->dzduxt+ii, nlp_mem->dynamics[ii]); config->dynamics[ii]->memory_set_sim_guess_ptr(nlp_mem->sim_guess+ii, nlp_mem->set_sim_guess+ii, nlp_mem->dynamics[ii]); config->dynamics[ii]->memory_set_z_alg_ptr(nlp_mem->z_alg+ii, nlp_mem->dynamics[ii]); } // alias to cost_memory #if defined(ACADOS_WITH_OPENMP) #pragma omp for #endif for (ii = 0; ii <= N; ii++) { config->cost[ii]->memory_set_ux_ptr(nlp_out->ux+ii, nlp_mem->cost[ii]); config->cost[ii]->memory_set_tmp_ux_ptr(nlp_work->tmp_nlp_out->ux+ii, nlp_mem->cost[ii]); config->cost[ii]->memory_set_z_alg_ptr(nlp_mem->z_alg+ii, nlp_mem->cost[ii]); config->cost[ii]->memory_set_dzdux_tran_ptr(nlp_mem->dzduxt+ii, nlp_mem->cost[ii]); config->cost[ii]->memory_set_RSQrq_ptr(nlp_mem->qp_in->RSQrq+ii, nlp_mem->cost[ii]); config->cost[ii]->memory_set_Z_ptr(nlp_mem->qp_in->Z+ii, nlp_mem->cost[ii]); } // alias to constraints_memory #if defined(ACADOS_WITH_OPENMP) #pragma omp for #endif for (ii = 0; ii <= N; ii++) { config->constraints[ii]->memory_set_ux_ptr(nlp_out->ux+ii, nlp_mem->constraints[ii]); config->constraints[ii]->memory_set_tmp_ux_ptr(nlp_work->tmp_nlp_out->ux+ii, nlp_mem->constraints[ii]); config->constraints[ii]->memory_set_lam_ptr(nlp_out->lam+ii, nlp_mem->constraints[ii]); config->constraints[ii]->memory_set_tmp_lam_ptr(nlp_work->tmp_nlp_out->lam+ii, nlp_mem->constraints[ii]); config->constraints[ii]->memory_set_z_alg_ptr(nlp_mem->z_alg+ii, nlp_mem->constraints[ii]); config->constraints[ii]->memory_set_dzdux_tran_ptr(nlp_mem->dzduxt+ii, nlp_mem->constraints[ii]); config->constraints[ii]->memory_set_DCt_ptr(nlp_mem->qp_in->DCt+ii, nlp_mem->constraints[ii]); config->constraints[ii]->memory_set_RSQrq_ptr(nlp_mem->qp_in->RSQrq+ii, nlp_mem->constraints[ii]); config->constraints[ii]->memory_set_idxb_ptr(nlp_mem->qp_in->idxb[ii], nlp_mem->constraints[ii]); config->constraints[ii]->memory_set_idxs_rev_ptr(nlp_mem->qp_in->idxs_rev[ii], nlp_mem->constraints[ii]); config->constraints[ii]->memory_set_idxe_ptr(nlp_mem->qp_in->idxe[ii], nlp_mem->constraints[ii]); } // alias to regularize memory config->regularize->memory_set_RSQrq_ptr(dims->regularize, nlp_mem->qp_in->RSQrq, nlp_mem->regularize_mem); config->regularize->memory_set_rq_ptr(dims->regularize, nlp_mem->qp_in->rqz, nlp_mem->regularize_mem); config->regularize->memory_set_BAbt_ptr(dims->regularize, nlp_mem->qp_in->BAbt, nlp_mem->regularize_mem); config->regularize->memory_set_b_ptr(dims->regularize, nlp_mem->qp_in->b, nlp_mem->regularize_mem); config->regularize->memory_set_idxb_ptr(dims->regularize, nlp_mem->qp_in->idxb, nlp_mem->regularize_mem); config->regularize->memory_set_DCt_ptr(dims->regularize, nlp_mem->qp_in->DCt, nlp_mem->regularize_mem); config->regularize->memory_set_ux_ptr(dims->regularize, nlp_mem->qp_out->ux, nlp_mem->regularize_mem); config->regularize->memory_set_pi_ptr(dims->regularize, nlp_mem->qp_out->pi, nlp_mem->regularize_mem); config->regularize->memory_set_lam_ptr(dims->regularize, nlp_mem->qp_out->lam, nlp_mem->regularize_mem); // copy sampling times into dynamics model #if defined(ACADOS_WITH_OPENMP) #pragma omp for #endif // NOTE(oj): this will lead in an error for irk_gnsf, T must be set in precompute; // -> remove here and make sure precompute is called everywhere. for (ii = 0; ii < N; ii++) { config->dynamics[ii]->model_set(config->dynamics[ii], dims->dynamics[ii], nlp_in->dynamics[ii], "T", nlp_in->Ts+ii); } #if defined(ACADOS_WITH_OPENMP) } // end of parallel region #endif // if (opts->initialize_t_slacks > 0) ocp_nlp_initialize_t_slacks(config, dims, nlp_in, nlp_out, nlp_opts, nlp_mem, nlp_work); // initialize QP ocp_nlp_initialize_qp(config, dims, nlp_in, nlp_out, nlp_opts, nlp_mem, nlp_work); // main sqp loop int sqp_iter = 0; nlp_mem->sqp_iter = &sqp_iter; for (; sqp_iter < opts->max_iter; sqp_iter++) { // linearizate NLP and update QP matrices acados_tic(&timer1); ocp_nlp_approximate_qp_matrices(config, dims, nlp_in, nlp_out, nlp_opts, nlp_mem, nlp_work); mem->time_lin += acados_toc(&timer1); // update QP rhs for SQP (step prim var, abs dual var) ocp_nlp_approximate_qp_vectors_sqp(config, dims, nlp_in, nlp_out, nlp_opts, nlp_mem, nlp_work); // compute nlp residuals ocp_nlp_res_compute(dims, nlp_in, nlp_out, nlp_mem->nlp_res, nlp_mem); nlp_out->inf_norm_res = nlp_mem->nlp_res->inf_norm_res_stat; nlp_out->inf_norm_res = (nlp_mem->nlp_res->inf_norm_res_eq > nlp_out->inf_norm_res) ? nlp_mem->nlp_res->inf_norm_res_eq : nlp_out->inf_norm_res; nlp_out->inf_norm_res = (nlp_mem->nlp_res->inf_norm_res_ineq > nlp_out->inf_norm_res) ? nlp_mem->nlp_res->inf_norm_res_ineq : nlp_out->inf_norm_res; nlp_out->inf_norm_res = (nlp_mem->nlp_res->inf_norm_res_comp > nlp_out->inf_norm_res) ? nlp_mem->nlp_res->inf_norm_res_comp : nlp_out->inf_norm_res; if (opts->print_level > sqp_iter + 1) print_ocp_qp_in(nlp_mem->qp_in); // save statistics if (sqp_iter < mem->stat_m) { mem->stat[mem->stat_n*sqp_iter+0] = nlp_mem->nlp_res->inf_norm_res_stat; mem->stat[mem->stat_n*sqp_iter+1] = nlp_mem->nlp_res->inf_norm_res_eq; mem->stat[mem->stat_n*sqp_iter+2] = nlp_mem->nlp_res->inf_norm_res_ineq; mem->stat[mem->stat_n*sqp_iter+3] = nlp_mem->nlp_res->inf_norm_res_comp; } // exit conditions on residuals if ((nlp_mem->nlp_res->inf_norm_res_stat < opts->tol_stat) & (nlp_mem->nlp_res->inf_norm_res_eq < opts->tol_eq) & (nlp_mem->nlp_res->inf_norm_res_ineq < opts->tol_ineq) & (nlp_mem->nlp_res->inf_norm_res_comp < opts->tol_comp)) { // save sqp iterations number mem->sqp_iter = sqp_iter; nlp_out->sqp_iter = sqp_iter; // stop timer total_time += acados_toc(&timer0); // save time nlp_out->total_time = total_time; mem->time_tot = total_time; #if defined(ACADOS_WITH_OPENMP) // restore number of threads omp_set_num_threads(num_threads_bkp); #endif mem->status = ACADOS_SUCCESS; if (opts->print_level > 0) { printf("%i\t%e\t%e\t%e\t%e.\n", sqp_iter, nlp_mem->nlp_res->inf_norm_res_stat, nlp_mem->nlp_res->inf_norm_res_eq, nlp_mem->nlp_res->inf_norm_res_ineq, nlp_mem->nlp_res->inf_norm_res_comp ); printf("\n\n"); } return mem->status; } // regularize Hessian acados_tic(&timer1); config->regularize->regularize_hessian(config->regularize, dims->regularize, opts->nlp_opts->regularize, nlp_mem->regularize_mem); mem->time_reg += acados_toc(&timer1); // (typically) no warm start at first iteration if (sqp_iter == 0 && !opts->warm_start_first_qp) { int tmp_int = 0; config->qp_solver->opts_set(config->qp_solver, opts->nlp_opts->qp_solver_opts, "warm_start", &tmp_int); } // solve qp acados_tic(&timer1); qp_status = qp_solver->evaluate(qp_solver, dims->qp_solver, nlp_mem->qp_in, nlp_mem->qp_out, opts->nlp_opts->qp_solver_opts, nlp_mem->qp_solver_mem, nlp_work->qp_work); mem->time_qp_sol += acados_toc(&timer1); qp_solver->memory_get(qp_solver, nlp_mem->qp_solver_mem, "time_qp_solver_call", &tmp_time); mem->time_qp_solver_call += tmp_time; qp_solver->memory_get(qp_solver, nlp_mem->qp_solver_mem, "time_qp_xcond", &tmp_time); mem->time_qp_xcond += tmp_time; // compute correct dual solution in case of Hessian regularization acados_tic(&timer1); config->regularize->correct_dual_sol(config->regularize, dims->regularize, opts->nlp_opts->regularize, nlp_mem->regularize_mem); mem->time_reg += acados_toc(&timer1); // restore default warm start if (sqp_iter==0) { config->qp_solver->opts_set(config->qp_solver, opts->nlp_opts->qp_solver_opts, "warm_start", &opts->qp_warm_start); } // TODO move into QP solver memory ??? qp_info *qp_info_; ocp_qp_out_get(nlp_mem->qp_out, "qp_info", &qp_info_); nlp_out->qp_iter = qp_info_->num_iter; // printf("\nqp_iter = %d, sqp_iter = %d, max_sqp_iter = %d\n", nlp_out->qp_iter, sqp_iter, opts->max_iter); qp_iter = qp_info_->num_iter; // save statistics of last qp solver call if (sqp_iter+1 < mem->stat_m) { mem->stat[mem->stat_n*(sqp_iter+1)+4] = qp_status; mem->stat[mem->stat_n*(sqp_iter+1)+5] = qp_iter; } // compute external QP residuals (for debugging) if (opts->ext_qp_res) { ocp_qp_res_compute(nlp_mem->qp_in, nlp_mem->qp_out, work->qp_res, work->qp_res_ws); if (sqp_iter+1 < mem->stat_m) ocp_qp_res_compute_nrm_inf(work->qp_res, mem->stat+(mem->stat_n*(sqp_iter+1)+6)); } if ((qp_status!=ACADOS_SUCCESS) & (qp_status!=ACADOS_MAXITER)) { // print_ocp_qp_in(nlp_mem->qp_in); if (opts->print_level > 0) { printf("%i\t%e\t%e\t%e\t%e.\n", sqp_iter, nlp_mem->nlp_res->inf_norm_res_stat, nlp_mem->nlp_res->inf_norm_res_eq, nlp_mem->nlp_res->inf_norm_res_ineq, nlp_mem->nlp_res->inf_norm_res_comp ); printf("\n\n"); } // save sqp iterations number mem->sqp_iter = sqp_iter; nlp_out->sqp_iter = sqp_iter; // stop timer total_time += acados_toc(&timer0); // save time mem->time_tot = total_time; nlp_out->total_time = total_time; #ifndef ACADOS_SILENT printf("QP solver returned error status %d in iteration %d\n", qp_status, sqp_iter); #endif #if defined(ACADOS_WITH_OPENMP) // restore number of threads omp_set_num_threads(num_threads_bkp); #endif if (opts->print_level > 1) { printf("\n Failed to solve the following QP:\n"); if (opts->print_level > sqp_iter + 1) print_ocp_qp_in(nlp_mem->qp_in); } mem->status = ACADOS_QP_FAILURE; return mem->status; } ocp_nlp_update_variables_sqp(config, dims, nlp_in, nlp_out, nlp_opts, nlp_mem, nlp_work); // ocp_nlp_dims_print(nlp_out->dims); // ocp_nlp_out_print(nlp_out); // exit(1); // ??? @rien // for (int_t i = 0; i < N; i++) // { // ocp_nlp_dynamics_opts *dynamics_opts = opts->dynamics[i]; // sim_opts *opts = dynamics_opts->sim_solver; // if (opts->scheme == NULL) // continue; // opts->sens_adj = (opts->scheme->type != exact); // if (nlp_in->freezeSens) { // // freeze inexact sensitivities after first SQP iteration !! // opts->scheme->freeze = true; // } // } if (opts->print_level > 0) { if (sqp_iter%10 == 0) { printf("# it\tstat\t\teq\t\tineq\t\tcomp\n"); } printf("%i\t%e\t%e\t%e\t%e.\n", sqp_iter, nlp_mem->nlp_res->inf_norm_res_stat, nlp_mem->nlp_res->inf_norm_res_eq, nlp_mem->nlp_res->inf_norm_res_ineq, nlp_mem->nlp_res->inf_norm_res_comp ); } } // stop timer total_time += acados_toc(&timer0); if (opts->print_level > 0) printf("\n\n"); // ocp_nlp_out_print(nlp_out); // save sqp iterations number mem->sqp_iter = sqp_iter; nlp_out->sqp_iter = sqp_iter; // save time mem->time_tot = total_time; nlp_out->total_time = total_time; // maximum number of iterations reached #if defined(ACADOS_WITH_OPENMP) // restore number of threads omp_set_num_threads(num_threads_bkp); #endif mem->status = ACADOS_MAXITER; #ifndef ACADOS_SILENT printf("\n ocp_nlp_sqp: maximum iterations reached\n"); #endif return mem->status; } int ocp_nlp_sqp_precompute(void *config_, void *dims_, void *nlp_in_, void *nlp_out_, void *opts_, void *mem_, void *work_) { ocp_nlp_dims *dims = dims_; ocp_nlp_config *config = config_; ocp_nlp_sqp_opts *opts = opts_; ocp_nlp_sqp_memory *mem = mem_; ocp_nlp_in *nlp_in = nlp_in_; // ocp_nlp_out *nlp_out = nlp_out_; ocp_nlp_memory *nlp_mem = mem->nlp_mem; ocp_nlp_sqp_workspace *work = work_; ocp_nlp_sqp_cast_workspace(config, dims, opts, mem, work); ocp_nlp_workspace *nlp_work = work->nlp_work; int N = dims->N; int status = ACADOS_SUCCESS; int ii; // TODO(all) add flag to enable/disable checks for (ii = 0; ii <= N; ii++) { int module_val; config->constraints[ii]->dims_get(config->constraints[ii], dims->constraints[ii], "ns", &module_val); if (dims->ns[ii] != module_val) { printf("ocp_nlp_sqp_precompute: inconsistent dimension ns for stage %d with constraint module, got %d, module: %d.", ii, dims->ns[ii], module_val); exit(1); } } // precompute for (ii = 0; ii < N; ii++) { // set T config->dynamics[ii]->model_set(config->dynamics[ii], dims->dynamics[ii], nlp_in->dynamics[ii], "T", nlp_in->Ts+ii); // dynamics precompute status = config->dynamics[ii]->precompute(config->dynamics[ii], dims->dynamics[ii], nlp_in->dynamics[ii], opts->nlp_opts->dynamics[ii], nlp_mem->dynamics[ii], nlp_work->dynamics[ii]); if (status != ACADOS_SUCCESS) return status; } return status; } void ocp_nlp_sqp_eval_param_sens(void *config_, void *dims_, void *opts_, void *mem_, void *work_, char *field, int stage, int index, void *sens_nlp_out_) { ocp_nlp_dims *dims = dims_; ocp_nlp_config *config = config_; ocp_nlp_sqp_opts *opts = opts_; ocp_nlp_sqp_memory *mem = mem_; ocp_nlp_memory *nlp_mem = mem->nlp_mem; ocp_nlp_out *sens_nlp_out = sens_nlp_out_; ocp_nlp_sqp_workspace *work = work_; ocp_nlp_sqp_cast_workspace(config, dims, opts, mem, work); ocp_nlp_workspace *nlp_work = work->nlp_work; d_ocp_qp_copy_all(nlp_mem->qp_in, work->tmp_qp_in); d_ocp_qp_set_rhs_zero(work->tmp_qp_in); double one = 1.0; if ((!strcmp("ex", field)) & (stage==0)) { d_ocp_qp_set_el("lbx", stage, index, &one, work->tmp_qp_in); d_ocp_qp_set_el("ubx", stage, index, &one, work->tmp_qp_in); // d_ocp_qp_print(work->tmp_qp_in->dim, work->tmp_qp_in); config->qp_solver->eval_sens(config->qp_solver, dims->qp_solver, work->tmp_qp_in, work->tmp_qp_out, opts->nlp_opts->qp_solver_opts, nlp_mem->qp_solver_mem, nlp_work->qp_work); // d_ocp_qp_sol_print(work->tmp_qp_out->dim, work->tmp_qp_out); // exit(1); /* copy tmp_qp_out into sens_nlp_out */ int i; int N = dims->N; int *nv = dims->nv; int *nx = dims->nx; // int *nu = dims->nu; int *ni = dims->ni; // int *nz = dims->nz; for (i = 0; i <= N; i++) { blasfeo_dveccp(nv[i], work->tmp_qp_out->ux + i, 0, sens_nlp_out->ux + i, 0); if (i < N) blasfeo_dveccp(nx[i + 1], work->tmp_qp_out->pi + i, 0, sens_nlp_out->pi + i, 0); blasfeo_dveccp(2 * ni[i], work->tmp_qp_out->lam + i, 0, sens_nlp_out->lam + i, 0); blasfeo_dveccp(2 * ni[i], work->tmp_qp_out->t + i, 0, sens_nlp_out->t + i, 0); } } else { printf("\nerror: field %s at stage %d not available in ocp_nlp_sqp_eval_param_sens\n", field, stage); exit(1); } return; } // TODO rename memory_get ??? void ocp_nlp_sqp_get(void *config_, void *dims_, void *mem_, const char *field, void *return_value_) { ocp_nlp_config *config = config_; ocp_nlp_dims *dims = dims_; ocp_nlp_sqp_memory *mem = mem_; if (!strcmp("sqp_iter", field)) { int *value = return_value_; *value = mem->sqp_iter; } else if (!strcmp("status", field)) { int *value = return_value_; *value = mem->status; } else if (!strcmp("time_tot", field) || !strcmp("tot_time", field)) { double *value = return_value_; *value = mem->time_tot; } else if (!strcmp("time_qp_sol", field) || !strcmp("time_qp", field)) { double *value = return_value_; *value = mem->time_qp_sol; } else if (!strcmp("time_qp_solver", field) || !strcmp("time_qp_solver_call", field)) { double *value = return_value_; *value = mem->time_qp_solver_call; } else if (!strcmp("time_qp_xcond", field)) { double *value = return_value_; *value = mem->time_qp_xcond; } else if (!strcmp("time_lin", field)) { double *value = return_value_; *value = mem->time_lin; } else if (!strcmp("time_reg", field)) { double *value = return_value_; *value = mem->time_reg; } else if (!strcmp("time_sim", field) || !strcmp("time_sim_ad", field) || !strcmp("time_sim_la", field)) { double tmp = 0.0; double *ptr = return_value_; int N = dims->N; int ii; for (ii=0; ii<N; ii++) { config->dynamics[ii]->memory_get(config->dynamics[ii], dims->dynamics[ii], mem->nlp_mem->dynamics[ii], field, &tmp); *ptr += tmp; } } else if (!strcmp("stat", field)) { double **value = return_value_; *value = mem->stat; } else if (!strcmp("statistics", field)) { int n_row = mem->stat_m<mem->sqp_iter+1 ? mem->stat_m : mem->sqp_iter+1; double *value = return_value_; for (int ii=0; ii<n_row; ii++) { value[ii+0] = ii; for (int jj=0; jj<mem->stat_n; jj++) value[ii+(jj+1)*n_row] = mem->stat[jj+ii*mem->stat_n]; } } else if (!strcmp("stat_m", field)) { int *value = return_value_; *value = mem->stat_m; } else if (!strcmp("stat_n", field)) { int *value = return_value_; *value = mem->stat_n; } else if (!strcmp("nlp_mem", field)) { void **value = return_value_; *value = mem->nlp_mem; } else if (!strcmp("qp_xcond_dims", field)) { void **value = return_value_; *value = dims->qp_solver->xcond_dims; } else if (!strcmp("nlp_res", field)) { ocp_nlp_res **value = return_value_; *value = mem->nlp_mem->nlp_res; } else if (!strcmp("qp_xcond_in", field)) { void **value = return_value_; *value = mem->nlp_mem->qp_solver_mem->xcond_qp_in; } else if (!strcmp("qp_xcond_out", field)) { void **value = return_value_; *value = mem->nlp_mem->qp_solver_mem->xcond_qp_out; } else if (!strcmp("qp_in", field)) { void **value = return_value_; *value = mem->nlp_mem->qp_in; } else if (!strcmp("qp_out", field)) { void **value = return_value_; *value = mem->nlp_mem->qp_out; } else if (!strcmp("qp_iter", field)) { config->qp_solver->memory_get(config->qp_solver, mem->nlp_mem->qp_solver_mem, "iter", return_value_); } else if (!strcmp("res_stat", field)) { double *value = return_value_; *value = mem->nlp_mem->nlp_res->inf_norm_res_stat; } else if (!strcmp("res_eq", field)) { double *value = return_value_; *value = mem->nlp_mem->nlp_res->inf_norm_res_eq; } else if (!strcmp("res_ineq", field)) { double *value = return_value_; *value = mem->nlp_mem->nlp_res->inf_norm_res_ineq; } else if (!strcmp("res_comp", field)) { double *value = return_value_; *value = mem->nlp_mem->nlp_res->inf_norm_res_comp; } else if (!strcmp("cost_value", field)) { double *value = return_value_; *value = mem->nlp_mem->cost_value; } else { printf("\nerror: field %s not available in ocp_nlp_sqp_get\n", field); exit(1); } } void ocp_nlp_sqp_opts_get(void *config_, void *dims_, void *opts_, const char *field, void *return_value_) { // ocp_nlp_config *config = config_; ocp_nlp_sqp_opts *opts = opts_; if (!strcmp("nlp_opts", field)) { void **value = return_value_; *value = opts->nlp_opts; } else { printf("\nerror: field %s not available in ocp_nlp_sqp_opts_get\n", field); exit(1); } } void ocp_nlp_sqp_work_get(void *config_, void *dims_, void *work_, const char *field, void *return_value_) { // ocp_nlp_config *config = config_; ocp_nlp_sqp_workspace *work = work_; if (!strcmp("nlp_work", field)) { void **value = return_value_; *value = work->nlp_work; } else { printf("\nerror: field %s not available in ocp_nlp_sqp_work_get\n", field); exit(1); } } void ocp_nlp_sqp_config_initialize_default(void *config_) { ocp_nlp_config *config = (ocp_nlp_config *) config_; config->opts_calculate_size = &ocp_nlp_sqp_opts_calculate_size; config->opts_assign = &ocp_nlp_sqp_opts_assign; config->opts_initialize_default = &ocp_nlp_sqp_opts_initialize_default; config->opts_update = &ocp_nlp_sqp_opts_update; config->opts_set = &ocp_nlp_sqp_opts_set; config->opts_set_at_stage = &ocp_nlp_sqp_opts_set_at_stage; config->memory_calculate_size = &ocp_nlp_sqp_memory_calculate_size; config->memory_assign = &ocp_nlp_sqp_memory_assign; config->workspace_calculate_size = &ocp_nlp_sqp_workspace_calculate_size; config->evaluate = &ocp_nlp_sqp; config->eval_param_sens = &ocp_nlp_sqp_eval_param_sens; config->config_initialize_default = &ocp_nlp_sqp_config_initialize_default; config->precompute = &ocp_nlp_sqp_precompute; config->get = &ocp_nlp_sqp_get; config->opts_get = &ocp_nlp_sqp_opts_get; config->work_get = &ocp_nlp_sqp_work_get; return; }

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 1999-2021 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/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; Quantum *q; 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++) { const Quantum *magick_restrict p; 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; 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++) { Quantum *magick_restrict q; 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++) { ssize_t x; if (status == MagickFalse) continue; for (x=0; x < (ssize_t) edge_image->columns; x++) { CannyInfo pixel; 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; 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++) { const Quantum *magick_restrict p; 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++) { const Quantum *magick_restrict p; 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; 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++) { 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++) { ssize_t y; for (y=0; y < (ssize_t) number_grays; y++) { 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++) { 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++) { ssize_t y; for (y=0; y < (ssize_t) number_grays; y++) { 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++) { 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++) { ssize_t y; ChannelStatistics pixel; (void) memset(&pixel,0,sizeof(pixel)); for (y=0; y < (ssize_t) number_grays; y++) { 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; 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++) { const Quantum *magick_restrict p; 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)) { 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++) { 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++) { const Quantum *magick_restrict p; Quantum *magick_restrict q; 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; 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); }

kmeans_clustering.c

#include "hclib.h" #ifdef __cplusplus #include "hclib_cpp.h" #include "hclib_system.h" #ifdef __CUDACC__ #include "hclib_cuda.h" #endif #endif /*****************************************************************************/ /*IMPORTANT: READ BEFORE DOWNLOADING, COPYING, INSTALLING OR USING. */ /*By downloading, copying, installing or using the software you agree */ /*to this license. If you do not agree to this license, do not download, */ /*install, copy or use the software. */ /* */ /* */ /*Copyright (c) 2005 Northwestern University */ /*All rights reserved. */ /*Redistribution of the software in source and binary forms, */ /*with or without modification, is permitted provided that the */ /*following conditions are met: */ /* */ /*1 Redistributions of source code must retain the above copyright */ /* notice, this list of conditions and the following disclaimer. */ /* */ /*2 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.*/ /* */ /*3 Neither the name of Northwestern University 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, NON-INFRINGEMENT AND */ /*FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL */ /*NORTHWESTERN UNIVERSITY OR ITS 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. */ /******************************************************************************/ /*************************************************************************/ /** File: kmeans_clustering.c **/ /** Description: Implementation of regular k-means clustering **/ /** algorithm **/ /** Author: Wei-keng Liao **/ /** ECE Department, Northwestern University **/ /** email: wkliao@ece.northwestern.edu **/ /** **/ /** Edited by: Jay Pisharath **/ /** Northwestern University. **/ /** **/ /** ================================================================ **/ /** **/ /** Edited by: Sang-Ha Lee **/ /** University of Virginia **/ /** **/ /** Description: No longer supports fuzzy c-means clustering; **/ /** only regular k-means clustering. **/ /** Simplified for main functionality: regular k-means **/ /** clustering. **/ /** **/ /*************************************************************************/ #include <stdio.h> #include <stdlib.h> #include <float.h> #include <math.h> #include "kmeans.h" #include <omp.h> #define RANDOM_MAX 2147483647 #ifndef FLT_MAX #define FLT_MAX 3.40282347e+38 #endif extern double wtime(void); extern int num_omp_threads; int find_nearest_point(float *pt, /* [nfeatures] */ int nfeatures, float *pts, /* [npts][nfeatures] */ int npts) { int index, i; float min_dist=FLT_MAX; /* find the cluster center id with min distance to pt */ for (i=0; i<npts; i++) { float dist; dist = euclid_dist_2(pt, pts + (i * nfeatures), nfeatures); /* no need square root */ if (dist < min_dist) { min_dist = dist; index = i; } } return(index); } /*----< euclid_dist_2() >----------------------------------------------------*/ /* multi-dimensional spatial Euclid distance square */ __inline float euclid_dist_2(float *pt1, float *pt2, int numdims) { int i; float ans=0.0; for (i=0; i<numdims; i++) ans += (pt1[i]-pt2[i]) * (pt1[i]-pt2[i]); return(ans); } /*----< kmeans_clustering() >---------------------------------------------*/ typedef struct _pragma173_omp_parallel { int i; int j; int (*k_ptr); int (*n_ptr); int index; int (*loop_ptr); int (*(*new_centers_len_ptr)); float (*(*(*new_centers_ptr))); float (*(*clusters_ptr)); float delta; double (*timing_ptr); int (*nthreads_ptr); int (*(*partial_new_centers_len_ptr)); float (*(*partial_new_centers_ptr)); float (*(*feature_ptr)); int nfeatures; int npoints; int nclusters; float (*threshold_ptr); int (*(*membership_ptr)); pthread_mutex_t reduction_mutex; } pragma173_omp_parallel; static void pragma173_omp_parallel_hclib_async(void *____arg, const int ___iter0); float* kmeans_clustering(float *feature, /* in: [npoints][nfeatures] */ int nfeatures, int npoints, int nclusters, float threshold, int *membership) /* out: [npoints] */ { int i, j, k, n=0, index, loop=0; int *new_centers_len; /* [nclusters]: no. of points in each cluster */ float **new_centers; /* [nclusters][nfeatures] */ float *clusters; /* out: [nclusters][nfeatures] */ float delta; double timing; int nthreads; int *partial_new_centers_len; float *partial_new_centers; nthreads = num_omp_threads; /* allocate space for returning variable clusters[] */ clusters = (float *)malloc(nclusters * nfeatures * sizeof(float)); /* randomly pick cluster centers */ for (i=0; i<nclusters; i++) { //n = (int)rand() % npoints; for (j=0; j<nfeatures; j++) clusters[i * nfeatures + j] = feature[n * nfeatures + j]; n++; } for (i=0; i<npoints; i++) membership[i] = -1; /* need to initialize new_centers_len and new_centers[0] to all 0 */ new_centers_len = (int*) calloc(nclusters, sizeof(int)); new_centers = (float**) malloc(nclusters * sizeof(float*)); new_centers[0] = (float*) calloc(nclusters * nfeatures, sizeof(float)); for (i=1; i<nclusters; i++) new_centers[i] = new_centers[i-1] + nfeatures; partial_new_centers_len = (int *)calloc(nthreads * nclusters, sizeof(int)); partial_new_centers = (float *)calloc(nthreads * nclusters * nfeatures, sizeof(float)); printf("num of threads = %d\n", num_omp_threads); do { delta = 0.0; { { pragma173_omp_parallel *new_ctx = (pragma173_omp_parallel *)malloc(sizeof(pragma173_omp_parallel)); new_ctx->i = i; new_ctx->j = j; new_ctx->k_ptr = &(k); new_ctx->n_ptr = &(n); new_ctx->index = index; new_ctx->loop_ptr = &(loop); new_ctx->new_centers_len_ptr = &(new_centers_len); new_ctx->new_centers_ptr = &(new_centers); new_ctx->clusters_ptr = &(clusters); new_ctx->delta = delta; new_ctx->timing_ptr = &(timing); new_ctx->nthreads_ptr = &(nthreads); new_ctx->partial_new_centers_len_ptr = &(partial_new_centers_len); new_ctx->partial_new_centers_ptr = &(partial_new_centers); new_ctx->feature_ptr = &(feature); new_ctx->nfeatures = nfeatures; new_ctx->npoints = npoints; new_ctx->nclusters = nclusters; new_ctx->threshold_ptr = &(threshold); new_ctx->membership_ptr = &(membership); new_ctx->delta = 0; const int init_err = pthread_mutex_init(&new_ctx->reduction_mutex, NULL); assert(init_err == 0); hclib_loop_domain_t domain[1]; domain[0].low = 0; domain[0].high = npoints; domain[0].stride = 1; domain[0].tile = -1; hclib_future_t *fut = hclib_forasync_future((void *)pragma173_omp_parallel_hclib_async, new_ctx, 1, domain, HCLIB_FORASYNC_MODE); hclib_future_wait(fut); free(new_ctx); delta = new_ctx->delta; } } /* end of #pragma omp parallel */ /* let the main thread perform the array reduction */ for (i=0; i<nclusters; i++) { for (j=0; j<nthreads; j++) { new_centers_len[i] += partial_new_centers_len[j * nclusters + i]; partial_new_centers_len[j * nclusters + i] = 0.0; for (k=0; k<nfeatures; k++) { new_centers[i][k] += partial_new_centers[j * nclusters * nfeatures + i * nfeatures + k]; partial_new_centers[j * nclusters * nfeatures + i * nfeatures + k] = 0.0; } } } /* replace old cluster centers with new_centers */ for (i=0; i<nclusters; i++) { for (j=0; j<nfeatures; j++) { if (new_centers_len[i] > 0) clusters[i * nfeatures + j] = new_centers[i][j] / new_centers_len[i]; new_centers[i][j] = 0.0; /* set back to 0 */ } new_centers_len[i] = 0; /* set back to 0 */ } } while (delta > threshold && loop++ < 500); free(new_centers[0]); free(new_centers); free(new_centers_len); return clusters; } static void pragma173_omp_parallel_hclib_async(void *____arg, const int ___iter0) { pragma173_omp_parallel *ctx = (pragma173_omp_parallel *)____arg; int i; i = ctx->i; int j; j = ctx->j; int index; index = ctx->index; float delta; delta = ctx->delta; int nfeatures; nfeatures = ctx->nfeatures; int npoints; npoints = ctx->npoints; int nclusters; nclusters = ctx->nclusters; hclib_start_finish(); do { i = ___iter0; { /* find the index of nestest cluster centers */ int tid = hclib_get_current_worker(); index = find_nearest_point((*(ctx->feature_ptr)) + (i * nfeatures), nfeatures, (*(ctx->clusters_ptr)), nclusters); /* if membership changes, increase delta by 1 */ if ((*(ctx->membership_ptr))[i] != index) delta += 1.0; /* assign the membership to object i */ (*(ctx->membership_ptr))[i] = index; /* update new cluster centers : sum of all objects located within */ (*(ctx->partial_new_centers_len_ptr))[tid * nclusters + index]++; for (j=0; j<nfeatures; j++) (*(ctx->partial_new_centers_ptr))[tid * nclusters * nfeatures + index * nfeatures + j] += (*(ctx->feature_ptr))[i * nfeatures + j]; } ; } while (0); const int lock_err = pthread_mutex_lock(&ctx->reduction_mutex); assert(lock_err == 0); ctx->delta += delta; const int unlock_err = pthread_mutex_unlock(&ctx->reduction_mutex); assert(unlock_err == 0); ; hclib_end_finish_nonblocking(); }

lslim_learn.c

/**************************************************************/ /*! \File lslim_learn.c \brief This is the file containing the fundamental functions to learn the model, used by LSLIM. \author Evangelia Christakopoulou \version 1.0 \date 2016 */ /**************************************************************/ #include<slim.h> /*****************************************************************************/ /*! \brief This function creates a new training matrix A'' and then calls the main function local_learn, for computing the model. Original training matrix A is of size n * m (rows * cols). An intermediate training matrix A' is created which has: nrows = rows of the original training matrix A ncols = (number_of_clusters) * cols of the original matrix A Every user has then exactly the nnzs of A which are copied to the cluster in which he belongs. For all the other clusters he has 0 entries. In order to be able to regularize properly, we add underneath A' a diagonal matrix which is of size: ncols * ncols. This diagonal matrix contains the regularization params across the diagonal (the local regularization ll). The final matrix is A''. Example: for 3 clusters: m m m n [ ] [ ] [ b ] n m [ ll ] * [ w ] = [ 0 ] m m [ ll ] [ ] [ 0 ] m m [ ll ] [ 0 ] m w is of size A'' 3m * 1. \param[in] ctrl The ctrl structure. \param[in] train The training data A. \param[in] participation The assignment of users to clusters. \param[in] prev_model The previous model (used to expedite the learning) \return model The model learnt. */ /*****************************************************************************/ gk_csr_t *lslim_learn(ctrl_t * ctrl, gk_csr_t * train, int *participation, gk_csr_t * prev_model) { int i, pos, j, offset, global_nnz; gk_csr_t *mat, *model = NULL; global_nnz = train->rowptr[train->nrows] - train->rowptr[0]; mat = gk_csr_Create(); mat->ncols = (ctrl->num_clusters) * train->ncols; mat->nrows = train->nrows + mat->ncols; mat->rowptr = gk_zmalloc(mat->nrows + 1, "gk_csr_Dep: local_rowptr"); mat->rowind = gk_imalloc(global_nnz + mat->ncols, "gk_csr_Dep: local_rowind"); mat->rowval = gk_fmalloc(global_nnz + mat->ncols, "gk_csr_Dep: local_rowval"); mat->rowptr[0] = 0; for (i = 0, pos = 0; i < train->nrows; i++) { /* Copying the nnzs of the user to the cluster to which he belongs */ offset = (participation[i]) * train->ncols; for (j = train->rowptr[i]; j < train->rowptr[i + 1]; j++) { mat->rowind[pos] = train->rowind[j] + offset; mat->rowval[pos] = train->rowval[j]; pos++; } mat->rowptr[i + 1] = pos; } /* Adding the diagonal matrix underneath A' */ /* Local regularization */ for (i = train->nrows; i < mat->nrows; i++, pos++) { mat->rowind[pos] = i - train->nrows; mat->rowval[pos] = ctrl->local_beta; mat->rowptr[i] = pos; } mat->rowptr[mat->nrows] = pos; gk_csr_CreateIndex(mat, GK_CSR_COL); gk_csr_CreateIndex(train, GK_CSR_COL); /* Learning the model */ model = lslim_local_learn(ctrl, train, mat, prev_model); gk_csr_Free(&mat); return model; } /**************************************************************/ /*! \brief Learning \details This routine contains the learning algorithm used by LSLIM. \param[in] ctrl A ctrl structure which contains all the parameters \param[in] orig_train The original training data (A) \param[in] train The training data (A'') \param[in] prev_model The previous model- used to speed up learning. It is optional argument. \return model The model returned. */ /**************************************************************/ gk_csr_t *lslim_local_learn(ctrl_t * ctrl, gk_csr_t * orig_train, gk_csr_t * train, gk_csr_t * prev_model) { int i, nr, nc, ni, pos, j, ii; int global_nnz; int basestart, baseend, datasize, step, starti, endi; gk_csr_t *mat = NULL; double *bl, *bu, *c; int *iinds, *jinds; float *vals; int *nnzs = NULL; int *rinds1 = NULL; int *rinds = NULL; int *rjinds = NULL; float *rvals = NULL; int rank = 0; int max_nnzs = 0; double tmr; int *rrowcnt = NULL; /* set up timers */ gk_clearwctimer(tmr); gk_startwctimer(tmr); /* constants used across all problems */ nr = train->nrows; nc = train->ncols; ni = train->ncols / (ctrl->num_clusters); /* mallocing */ bl = gk_dsmalloc(nc, ctrl->bl, "malloc bl"); /*lower bound */ bu = gk_dsmalloc(nc, ctrl->bu, "malloc bu"); /*upper bound */ c = gk_dmalloc(nc, "malloc c"); /*linear vector */ gk_dset(nc, ctrl->local_lambda, c); /*starting and ending columns */ basestart = (ctrl->starti >= 0) ? ctrl->starti : 0; baseend = (ctrl->endi >= 0) ? ctrl->endi : ni; datasize = baseend - basestart; step = (datasize / ctrl->num_procs) + (ctrl->id < (datasize % ctrl->num_procs) ? 1 : 0); starti = ((datasize / ctrl->num_procs) * ctrl->id) + gk_min(ctrl->id, datasize % ctrl->num_procs); endi = starti + step; if ((endi < datasize) && (ctrl->id == ctrl->num_procs - 1)) { endi = datasize; step = datasize - starti; } pos = 0; iinds = gk_ismalloc(step * nc, 0, "malloc iinds"); jinds = gk_ismalloc(step * nc, 0, "malloc jinds"); vals = gk_fsmalloc(step * nc, 0, "malloc vals"); /* go through all columns */ #pragma omp parallel num_threads(ctrl->num_threads) { int mypos; double *w, *b; wspace_t *myws; BCLS *ls; myws = (wspace_t *) gk_malloc(sizeof(wspace_t), "myws"); myws->mat = train; myws->ncols = ni; ls = bcls_create_prob(nr, nc); w = gk_dsmalloc(nc, 0, "malloc w"); b = gk_dsmalloc(nr, 0, "malloc b"); #pragma omp for private(i, j) schedule(dynamic) for (i = starti; i < endi; i++) { // this column is totally empty if (train->colptr[i + 1] - train->colptr[i] == 0) { continue; } /**********************************************************/ /* BCLS learning */ /**********************************************************/ /* get the i-th column from A */ for (j = orig_train->colptr[i]; j < orig_train->colptr[i + 1]; j++) { ii = orig_train->colind[j]; b[ii] = 1; } myws->max_bcls_niters = gk_min(ctrl->max_bcls_niters, 50 * (train->colptr[i + 1] - train->colptr[i])); gk_dset(nc, 0, w); // disable myws->acol = i; if (prev_model != NULL) { get_row(prev_model, i, w); } bcsol(ctrl, b, w, myws, bl, bu, 0, c, ls); for (j = orig_train->colptr[i]; j < orig_train->colptr[i + 1] - 1; j++) { ii = orig_train->colind[j]; b[ii] = 0; } /**********************************************************/ /* dump the data */ /**********************************************************/ /* compute the triplets */ #pragma omp critical { for (j = 0; j < nc; j++) { if (w[j] > EPSILON) { mypos = pos++; iinds[mypos] = i; jinds[mypos] = j; vals[mypos] = w[j]; } } } } // end of starti - endi bcls_free_prob(ls); gk_free((void **) &myws, (void **) &b, (void **) &w, LTERM); } gk_stopwctimer(tmr); /* if(ctrl->id == 0){ printf("time passed is %f\n", gk_getwctimer(tmr)); }*/ /**********************************************************/ /* Combine all the mat of the different processes to the total_mat with MPI */ /**********************************************************/ if (ctrl->id == 0) { nnzs = gk_imalloc(ctrl->num_procs, "malloc nnzs"); gk_iset(ctrl->num_procs, 0, nnzs); } MPI_Gather(&pos, 1, MPI_INT, nnzs, 1, MPI_INT, 0, MPI_COMM_WORLD); if (ctrl->id == 0) { global_nnz = 0; for (i = 0; i < ctrl->num_procs; i++) { global_nnz += nnzs[i]; } } MPI_Bcast(&global_nnz, 1, MPI_INT, 0, MPI_COMM_WORLD); /* Finding the max nnzs between all nodes. This covers the case when a node which is not 0 has a bigger iinds/jinds/vals matrix than the one in node 0 */ if (ctrl->id == 0) { max_nnzs = nnzs[0]; for (rank = 1; rank < ctrl->num_procs; rank++) if (nnzs[rank] > max_nnzs) max_nnzs = nnzs[rank]; } /* Each node creates its own row count. This gets sent to node 0, in order to create the total rowptr. */ if (global_nnz / ctrl->num_procs >= ni) { rrowcnt = gk_ismalloc(ni, 0, "rrowcnt"); for (i = 0; i < pos; i++) { rrowcnt[iinds[i]]++; } } /* Every node sends its own iinds, jinds and vals. */ if (ctrl->id != 0) { if (global_nnz / ctrl->num_procs < ni) { MPI_Send(iinds, pos, MPI_INT, 0, 0, MPI_COMM_WORLD); } else { MPI_Send(rrowcnt, ni, MPI_INT, 0, 0, MPI_COMM_WORLD); } MPI_Send(iinds, pos, MPI_INT, 0, 0, MPI_COMM_WORLD); MPI_Send(jinds, pos, MPI_INT, 0, 0, MPI_COMM_WORLD); MPI_Send(vals, pos, MPI_FLOAT, 0, 0, MPI_COMM_WORLD); } if (ctrl->id == 0) { if (global_nnz / ctrl->num_procs < ni) { rinds1 = gk_icopy(nnzs[0], iinds, gk_imalloc(max_nnzs, "rinds1")); } rinds = gk_icopy(nnzs[0], iinds, gk_imalloc(max_nnzs, "rinds")); rjinds = gk_icopy(nnzs[0], jinds, gk_imalloc(max_nnzs, "rjinds")); rvals = gk_fcopy(nnzs[0], vals, gk_fmalloc(max_nnzs, "rvals")); } gk_free((void **) &iinds, &jinds, &vals, &bl, &bu, &c, LTERM); /* Allocate and populate matrix */ mat = gk_csr_Create(); mat->nrows = ni; mat->ncols = nc; mat->rowptr = gk_zsmalloc(ni + 1, 0, "rowptr"); mat->rowind = gk_imalloc(global_nnz, "rowind"); mat->rowval = gk_fmalloc(global_nnz, "rowval"); if (ctrl->id == 0) { if (global_nnz / ctrl->num_procs < ni) { for (rank = 0; rank < ctrl->num_procs; rank++) { if (rank != 0) { MPI_Recv(rinds1, nnzs[rank], MPI_INT, rank, 0, MPI_COMM_WORLD, MPI_STATUS_IGNORE); } for (i = 0; i < nnzs[rank]; i++) { mat->rowptr[rinds1[i]]++; } } } else { for (rank = 0; rank < ctrl->num_procs; rank++) { if (rank != 0) { MPI_Recv(rrowcnt, ni, MPI_INT, rank, 0, MPI_COMM_WORLD, MPI_STATUS_IGNORE); } for (i = 0; i < ni; i++) { mat->rowptr[i] += rrowcnt[i]; } } } MAKECSR(i, mat->nrows, mat->rowptr); for (rank = 0; rank < ctrl->num_procs; rank++) { if (rank != 0) { MPI_Recv(rinds, nnzs[rank], MPI_INT, rank, 0, MPI_COMM_WORLD, MPI_STATUS_IGNORE); MPI_Recv(rjinds, nnzs[rank], MPI_INT, rank, 0, MPI_COMM_WORLD, MPI_STATUS_IGNORE); MPI_Recv(rvals, nnzs[rank], MPI_FLOAT, rank, 0, MPI_COMM_WORLD, MPI_STATUS_IGNORE); } for (i = 0; i < nnzs[rank]; i++) { mat->rowind[mat->rowptr[rinds[i]]] = rjinds[i]; mat->rowval[mat->rowptr[rinds[i]]] = rvals[i]; mat->rowptr[rinds[i]]++; } } SHIFTCSR(i, mat->nrows, mat->rowptr); gk_free((void **) &rinds, &rjinds, &rvals, &nnzs, LTERM); if (global_nnz / ctrl->num_procs < ni) { gk_free((void **) &rinds1, LTERM); } } if (rrowcnt != NULL) { gk_free((void **) &rrowcnt, LTERM); } /* Broadcast the matrix to the other nodes */ MPI_Bcast(mat->rowptr, ni + 1, MPI_LONG, 0, MPI_COMM_WORLD); MPI_Bcast(mat->rowind, global_nnz, MPI_INT, 0, MPI_COMM_WORLD); MPI_Bcast(mat->rowval, global_nnz, MPI_FLOAT, 0, MPI_COMM_WORLD); return mat; }

pr97289.c

/* PR middle-end/97289 */ /* { dg-do compile } */ /* { dg-require-weak "" } */ /* { dg-skip-if "" { "hppa*-*-hpux*" "*-*-aix*" "nvptx-*-*" } } */ void foo (void); static void bar (void) __attribute__ ((__weakref__ ("foo"))); void baz (void) { #pragma omp target bar (); }

dynmat.c

/* Copyright (C) 2015 Atsushi Togo */ /* All rights reserved. */ /* This file is part of phonopy. */ /* 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 phonopy project 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. */ #include <math.h> #include <stdlib.h> #include "dynmat.h" #define PI 3.14159265358979323846 static void get_dynmat_ij(double *dynamical_matrix, const int num_patom, const int num_satom, const double *fc, const double q[3], PHPYCONST double (*svecs)[27][3], const int *multi, const double *mass, const int *s2p_map, const int *p2s_map, PHPYCONST double (*charge_sum)[3][3], const int i, const int j); static void get_dm(double dm_real[3][3], double dm_imag[3][3], const int num_patom, const int num_satom, const double *fc, const double q[3], PHPYCONST double (*svecs)[27][3], const int *multi, const int *p2s_map, PHPYCONST double (*charge_sum)[3][3], const int i, const int j, const int k); static double get_dielectric_part(const double q_cart[3], PHPYCONST double dielectric[3][3]); static void get_KK(double *dd_part, /* [natom, 3, natom, 3, (real,imag)] */ PHPYCONST double (*G_list)[3], /* [num_G, 3] */ const int num_G, const int num_patom, const double q_cart[3], const double *q_direction_cart, PHPYCONST double dielectric[3][3], PHPYCONST double (*pos)[3], /* [num_patom, 3] */ const double lambda, const double tolerance); static void make_Hermitian(double *mat, const int num_band); static void multiply_borns(double *dd, const double *dd_in, const int num_patom, PHPYCONST double (*born)[3][3]); int dym_get_dynamical_matrix_at_q(double *dynamical_matrix, const int num_patom, const int num_satom, const double *fc, const double q[3], PHPYCONST double (*svecs)[27][3], const int *multi, const double *mass, const int *s2p_map, const int *p2s_map, PHPYCONST double (*charge_sum)[3][3], const int with_openmp) { int i, j, ij; if (with_openmp) { #pragma omp parallel for for (ij = 0; ij < num_patom * num_patom ; ij++) { get_dynmat_ij(dynamical_matrix, num_patom, num_satom, fc, q, svecs, multi, mass, s2p_map, p2s_map, charge_sum, ij / num_patom, /* i */ ij % num_patom); /* j */ } } else { for (i = 0; i < num_patom; i++) { for (j = 0; j < num_patom; j++) { get_dynmat_ij(dynamical_matrix, num_patom, num_satom, fc, q, svecs, multi, mass, s2p_map, p2s_map, charge_sum, i, j); } } } make_Hermitian(dynamical_matrix, num_patom * 3); return 0; } void dym_get_recip_dipole_dipole(double *dd, /* [natom, 3, natom, 3, (real,imag)] */ const double *dd_q0, /* [natom, 3, 3, (real,imag)] */ PHPYCONST double (*G_list)[3], /* [num_G, 3] */ const int num_G, const int num_patom, const double q_cart[3], const double *q_direction_cart, /* must be pointer */ PHPYCONST double (*born)[3][3], PHPYCONST double dielectric[3][3], PHPYCONST double (*pos)[3], /* [num_patom, 3] */ const double factor, /* 4pi/V*unit-conv */ const double lambda, const double tolerance) { int i, k, l, adrs, adrs_sum; double *dd_tmp; dd_tmp = NULL; dd_tmp = (double*) malloc(sizeof(double) * num_patom * num_patom * 18); for (i = 0; i < num_patom * num_patom * 18; i++) { dd[i] = 0; dd_tmp[i] = 0; } get_KK(dd_tmp, G_list, num_G, num_patom, q_cart, q_direction_cart, dielectric, pos, lambda, tolerance); multiply_borns(dd, dd_tmp, num_patom, born); for (i = 0; i < num_patom; i++) { for (k = 0; k < 3; k++) { /* alpha */ for (l = 0; l < 3; l++) { /* beta */ adrs = i * num_patom * 9 + k * num_patom * 3 + i * 3 + l; adrs_sum = i * 9 + k * 3 + l; dd[adrs * 2] -= dd_q0[adrs_sum * 2]; dd[adrs * 2 + 1] -= dd_q0[adrs_sum * 2 + 1]; } } } for (i = 0; i < num_patom * num_patom * 18; i++) { dd[i] *= factor; } /* This may not be necessary. */ /* make_Hermitian(dd, num_patom * 3); */ free(dd_tmp); dd_tmp = NULL; } void dym_get_recip_dipole_dipole_q0(double *dd_q0, /* [natom, 3, 3, (real,imag)] */ PHPYCONST double (*G_list)[3], /* [num_G, 3] */ const int num_G, const int num_patom, PHPYCONST double (*born)[3][3], PHPYCONST double dielectric[3][3], PHPYCONST double (*pos)[3], /* [num_patom, 3] */ const double lambda, const double tolerance) { int i, j, k, l, adrs_tmp, adrs, adrsT; double zero_vec[3]; double *dd_tmp1, *dd_tmp2; dd_tmp1 = NULL; dd_tmp1 = (double*) malloc(sizeof(double) * num_patom * num_patom * 18); dd_tmp2 = NULL; dd_tmp2 = (double*) malloc(sizeof(double) * num_patom * num_patom * 18); for (i = 0; i < num_patom * num_patom * 18; i++) { dd_tmp1[i] = 0; dd_tmp2[i] = 0; } zero_vec[0] = 0; zero_vec[1] = 0; zero_vec[2] = 0; get_KK(dd_tmp1, G_list, num_G, num_patom, zero_vec, NULL, dielectric, pos, lambda, tolerance); multiply_borns(dd_tmp2, dd_tmp1, num_patom, born); for (i = 0; i < num_patom * 18; i++) { dd_q0[i] = 0; } for (i = 0; i < num_patom; i++) { for (k = 0; k < 3; k++) { /* alpha */ for (l = 0; l < 3; l++) { /* beta */ adrs = i * 9 + k * 3 + l; for (j = 0; j < num_patom; j++) { adrs_tmp = i * num_patom * 9 + k * num_patom * 3 + j * 3 + l ; dd_q0[adrs * 2] += dd_tmp2[adrs_tmp * 2]; dd_q0[adrs * 2 + 1] += dd_tmp2[adrs_tmp * 2 + 1]; } } } } /* Summation over another atomic index */ /* for (j = 0; j < num_patom; j++) { */ /* for (k = 0; k < 3; k++) { /\* alpha *\/ */ /* for (l = 0; l < 3; l++) { /\* beta *\/ */ /* adrs = j * 9 + k * 3 + l; */ /* for (i = 0; i < num_patom; i++) { */ /* adrs_tmp = i * num_patom * 9 + k * num_patom * 3 + j * 3 + l ; */ /* dd_q0[adrs * 2] += dd_tmp2[adrs_tmp * 2]; */ /* dd_q0[adrs * 2 + 1] += dd_tmp2[adrs_tmp * 2 + 1]; */ /* } */ /* } */ /* } */ /* } */ for (i = 0; i < num_patom; i++) { for (k = 0; k < 3; k++) { /* alpha */ for (l = 0; l < 3; l++) { /* beta */ adrs = i * 9 + k * 3 + l; adrsT = i * 9 + l * 3 + k; dd_q0[adrs * 2] += dd_q0[adrsT * 2]; dd_q0[adrs * 2] /= 2; dd_q0[adrsT * 2] = dd_q0[adrs * 2]; dd_q0[adrs * 2 + 1] -= dd_q0[adrsT * 2 + 1]; dd_q0[adrs * 2 + 1] /= 2; dd_q0[adrsT * 2 + 1] = -dd_q0[adrs * 2 + 1]; } } } free(dd_tmp1); dd_tmp1 = NULL; free(dd_tmp2); dd_tmp2 = NULL; } void dym_get_charge_sum(double (*charge_sum)[3][3], const int num_patom, const double factor, /* 4pi/V*unit-conv and denominator */ const double q_cart[3], PHPYCONST double (*born)[3][3]) { int i, j, k, a, b; double (*q_born)[3]; q_born = (double (*)[3]) malloc(sizeof(double[3]) * num_patom); for (i = 0; i < num_patom; i++) { for (j = 0; j < 3; j++) { q_born[i][j] = 0; } } for (i = 0; i < num_patom; i++) { for (j = 0; j < 3; j++) { for (k = 0; k < 3; k++) { q_born[i][j] += q_cart[k] * born[i][k][j]; } } } for (i = 0; i < num_patom; i++) { for (j = 0; j < num_patom; j++) { for (a = 0; a < 3; a++) { for (b = 0; b < 3; b++) { charge_sum[i * num_patom + j][a][b] = q_born[i][a] * q_born[j][b] * factor; } } } } free(q_born); q_born = NULL; } /* fc[num_patom, num_satom, 3, 3] */ /* dm[num_comm_points, num_patom * 3, num_patom *3] */ /* comm_points[num_satom, num_patom, 27, 3] */ /* shortest_vectors[num_satom, num_patom, 27, 3] */ /* multiplicities[num_satom, num_patom] */ void dym_transform_dynmat_to_fc(double *fc, const double *dm, PHPYCONST double (*comm_points)[3], PHPYCONST double (*shortest_vectors)[27][3], const int *multiplicities, const double *masses, const int *s2pp_map, const int *fc_index_map, const int num_patom, const int num_satom) { int i, j, k, l, m, N, adrs, multi; double coef, phase, cos_phase, sin_phase; N = num_satom / num_patom; for (i = 0; i < num_patom * num_satom * 9; i++) { fc[i] = 0; } for (i = 0; i < num_patom; i++) { for (j = 0; j < num_satom; j++) { coef = sqrt(masses[i] * masses[s2pp_map[j]]) / N; for (k = 0; k < N; k++) { cos_phase = 0; sin_phase = 0; multi = multiplicities[j * num_patom + i]; for (l = 0; l < multi; l++) { phase = 0; for (m = 0; m < 3; m++) { phase -= comm_points[k][m] * shortest_vectors[j * num_patom + i][l][m]; } cos_phase += cos(phase * 2 * PI); sin_phase += sin(phase * 2 * PI); } cos_phase /= multi; sin_phase /= multi; for (l = 0; l < 3; l++) { for (m = 0; m < 3; m++) { adrs = k * num_patom * num_patom * 18 + i * num_patom * 18 + l * num_patom * 6 + s2pp_map[j] * 6 + m * 2; fc[fc_index_map[i] * num_satom * 9 + j * 9 + l * 3 + m] += (dm[adrs] * cos_phase - dm[adrs + 1] * sin_phase) * coef; } } } } } } static void get_dynmat_ij(double *dynamical_matrix, const int num_patom, const int num_satom, const double *fc, const double q[3], PHPYCONST double (*svecs)[27][3], const int *multi, const double *mass, const int *s2p_map, const int *p2s_map, PHPYCONST double (*charge_sum)[3][3], const int i, const int j) { int k, l, adrs; double mass_sqrt; double dm_real[3][3], dm_imag[3][3]; mass_sqrt = sqrt(mass[i] * mass[j]); for (k = 0; k < 3; k++) { for (l = 0; l < 3; l++) { dm_real[k][l] = 0; dm_imag[k][l] = 0; } } for (k = 0; k < num_satom; k++) { /* Lattice points of right index of fc */ if (s2p_map[k] != p2s_map[j]) { continue; } get_dm(dm_real, dm_imag, num_patom, num_satom, fc, q, svecs, multi, p2s_map, charge_sum, i, j, k); } for (k = 0; k < 3; k++) { for (l = 0; l < 3; l++) { adrs = (i * 3 + k) * num_patom * 3 + j * 3 + l; dynamical_matrix[adrs * 2] = dm_real[k][l] / mass_sqrt; dynamical_matrix[adrs * 2 + 1] = dm_imag[k][l] / mass_sqrt; } } } static void get_dm(double dm_real[3][3], double dm_imag[3][3], const int num_patom, const int num_satom, const double *fc, const double q[3], PHPYCONST double (*svecs)[27][3], const int *multi, const int *p2s_map, PHPYCONST double (*charge_sum)[3][3], const int i, const int j, const int k) { int l, m; double phase, cos_phase, sin_phase, fc_elem; cos_phase = 0; sin_phase = 0; for (l = 0; l < multi[k * num_patom + i]; l++) { phase = 0; for (m = 0; m < 3; m++) { phase += q[m] * svecs[k * num_patom + i][l][m]; } cos_phase += cos(phase * 2 * PI) / multi[k * num_patom + i]; sin_phase += sin(phase * 2 * PI) / multi[k * num_patom + i]; } for (l = 0; l < 3; l++) { for (m = 0; m < 3; m++) { if (charge_sum) { fc_elem = (fc[p2s_map[i] * num_satom * 9 + k * 9 + l * 3 + m] + charge_sum[i * num_patom + j][l][m]); } else { fc_elem = fc[p2s_map[i] * num_satom * 9 + k * 9 + l * 3 + m]; } dm_real[l][m] += fc_elem * cos_phase; dm_imag[l][m] += fc_elem * sin_phase; } } } static double get_dielectric_part(const double q_cart[3], PHPYCONST double dielectric[3][3]) { int i, j; double x[3]; double sum; for (i = 0; i < 3; i++) { x[i] = 0; for (j = 0; j < 3; j++) { x[i] += dielectric[i][j] * q_cart[j]; } } sum = 0; for (i = 0; i < 3; i++) { sum += q_cart[i] * x[i]; } return sum; } static void get_KK(double *dd_part, /* [natom, 3, natom, 3, (real,imag)] */ PHPYCONST double (*G_list)[3], /* [num_G, 3] */ const int num_G, const int num_patom, const double q_cart[3], const double *q_direction_cart, PHPYCONST double dielectric[3][3], PHPYCONST double (*pos)[3], /* [num_patom, 3] */ const double lambda, const double tolerance) { int i, j, k, l, g, adrs; double q_K[3]; double norm, cos_phase, sin_phase, phase, dielectric_part, exp_damp, L2; double KK[3][3]; L2 = 4 * lambda * lambda; /* sum over K = G + q and over G (i.e. q=0) */ /* q_direction has values for summation over K at Gamma point. */ /* q_direction is NULL for summation over G */ for (g = 0; g < num_G; g++) { norm = 0; for (i = 0; i < 3; i++) { q_K[i] = G_list[g][i] + q_cart[i]; norm += q_K[i] * q_K[i]; } if (sqrt(norm) < tolerance) { if (!q_direction_cart) { continue; } else { dielectric_part = get_dielectric_part(q_direction_cart, dielectric); for (i = 0; i < 3; i++) { for (j = 0; j < 3; j++) { KK[i][j] = q_direction_cart[i] * q_direction_cart[j] / dielectric_part; } } } } else { dielectric_part = get_dielectric_part(q_K, dielectric); exp_damp = exp(-dielectric_part / L2); for (i = 0; i < 3; i++) { for (j = 0; j < 3; j++) { KK[i][j] = q_K[i] * q_K[j] / dielectric_part * exp_damp; } } } for (i = 0; i < num_patom; i++) { for (j = 0; j < num_patom; j++) { phase = 0; for (k = 0; k < 3; k++) { /* For D-type dynamical matrix */ /* phase += (pos[i][k] - pos[j][k]) * q_K[k]; */ /* For C-type dynamical matrix */ phase += (pos[i][k] - pos[j][k]) * G_list[g][k]; } phase *= 2 * PI; cos_phase = cos(phase); sin_phase = sin(phase); for (k = 0; k < 3; k++) { for (l = 0; l < 3; l++) { adrs = i * num_patom * 9 + k * num_patom * 3 + j * 3 + l; dd_part[adrs * 2] += KK[k][l] * cos_phase; dd_part[adrs * 2 + 1] += KK[k][l] * sin_phase; } } } } } } static void make_Hermitian(double *mat, const int num_band) { int i, j, adrs, adrsT; for (i = 0; i < num_band; i++) { for (j = i; j < num_band; j++) { adrs = i * num_band + j * 1; adrs *= 2; adrsT = j * num_band + i * 1; adrsT *= 2; /* real part */ mat[adrs] += mat[adrsT]; mat[adrs] /= 2; /* imaginary part */ mat[adrs + 1] -= mat[adrsT+ 1]; mat[adrs + 1] /= 2; /* store */ mat[adrsT] = mat[adrs]; mat[adrsT + 1] = -mat[adrs + 1]; } } } static void multiply_borns(double *dd, const double *dd_in, const int num_patom, PHPYCONST double (*born)[3][3]) { int i, j, k, l, m, n, adrs, adrs_in; double zz; for (i = 0; i < num_patom; i++) { for (j = 0; j < num_patom; j++) { for (k = 0; k < 3; k++) { /* alpha */ for (l = 0; l < 3; l++) { /* beta */ adrs = i * num_patom * 9 + k * num_patom * 3 + j * 3 + l; for (m = 0; m < 3; m++) { /* alpha' */ for (n = 0; n < 3; n++) { /* beta' */ adrs_in = i * num_patom * 9 + m * num_patom * 3 + j * 3 + n ; zz = born[i][m][k] * born[j][n][l]; dd[adrs * 2] += dd_in[adrs_in * 2] * zz; dd[adrs * 2 + 1] += dd_in[adrs_in * 2 + 1] * zz; } } } } } } }

GB_unaryop__ainv_uint32_int32.c

//------------------------------------------------------------------------------ // GB_unaryop: hard-coded functions for each built-in unary operator //------------------------------------------------------------------------------ // SuiteSparse:GraphBLAS, Timothy A. Davis, (c) 2017-2019, 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__ainv_uint32_int32 // op(A') function: GB_tran__ainv_uint32_int32 // C type: uint32_t // A type: int32_t // cast: uint32_t cij = (uint32_t) aij // unaryop: cij = -aij #define GB_ATYPE \ int32_t #define GB_CTYPE \ uint32_t // aij = Ax [pA] #define GB_GETA(aij,Ax,pA) \ int32_t aij = Ax [pA] #define GB_CX(p) Cx [p] // unary operator #define GB_OP(z, x) \ z = -x ; // casting #define GB_CASTING(z, x) \ uint32_t z = (uint32_t) x ; // 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 (x, aij) ; \ GB_OP (GB_CX (pC), x) ; \ } // disable this operator and use the generic case if these conditions hold #define GB_DISABLE \ (GxB_NO_AINV || GxB_NO_UINT32 || GxB_NO_INT32) //------------------------------------------------------------------------------ // Cx = op (cast (Ax)): apply a unary operator //------------------------------------------------------------------------------ GrB_Info GB_unop__ainv_uint32_int32 ( uint32_t *restrict Cx, const int32_t *restrict Ax, int64_t anz, int nthreads ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else #pragma omp parallel for num_threads(nthreads) schedule(static) for (int64_t 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__ainv_uint32_int32 ( GrB_Matrix C, const GrB_Matrix A, int64_t *restrict *Rowcounts, GBI_single_iterator Iter, const int64_t *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

chain_access.c

#include <stdlib.h> #include <stdio.h> #include <omp.h> void use_pointer(int * p, int x) { *p = x; } int main() { int* ptr = (int*)malloc(sizeof(int)); *ptr = 0; #pragma omp parallel { use_pointer(ptr, 42); } printf("p: %d\n", *ptr); free(ptr); }

patchmodel.h

#ifndef CMT_PATCHMODEL_H #define CMT_PATCHMODEL_H #include <vector> #include <algorithm> #include <iostream> #include <cmath> #include "Eigen/Core" #include "utils.h" #include "distribution.h" #include "exception.h" #include "conditionaldistribution.h" #include "pcapreconditioner.h" #include "trainable.h" #include "tools.h" namespace CMT { using std::vector; using std::find; using std::distance; using std::cout; using std::endl; using std::min; using std::ceil; using Eigen::ArrayXXd; using Eigen::MatrixXd; using Eigen::Array; using Eigen::Dynamic; class PatchModelBase : public Distribution { public: using Distribution::logLikelihood; virtual ~PatchModelBase(); virtual int rows() const = 0; virtual int cols() const = 0; virtual int maxPCs() const = 0; virtual ArrayXXb inputMask() const = 0; virtual ArrayXXb outputMask() const = 0; virtual ArrayXXb inputMask(int i, int j) const = 0; virtual ArrayXXb outputMask(int i, int j) const = 0; virtual Tuples inputIndices(int i, int j) const = 0; virtual Tuples order() const = 0; virtual Array<double, 1, Dynamic> logLikelihood( int i, int j, const MatrixXd& data) const = 0; virtual ConditionalDistribution& operator()(int i, int j) = 0; virtual const ConditionalDistribution& operator()(int i, int j) const = 0; virtual AffinePreconditioner& preconditioner(int i, int j) = 0; virtual const AffinePreconditioner& preconditioner(int i, int j) const = 0; }; template <class CD, class PC = CMT::PCAPreconditioner> class PatchModel : public PatchModelBase { public: typedef typename CD::Parameters Parameters; PatchModel( int rows, int cols, const CD* model = 0, int maxPCs = -1); PatchModel( int rows, int cols, const ArrayXXb& inputMask, const ArrayXXb& outputMask, const CD* model = 0, int maxPCs = -1); PatchModel( int rows, int cols, const Tuples& order, const ArrayXXb& inputMask, const ArrayXXb& outputMask, const CD* model = 0, int maxPCs = -1); PatchModel( int rows, int cols, const Tuples& order, const CD* model = 0, int maxPCs = -1); virtual ~PatchModel(); int dim() const; int rows() const; int cols() const; int maxPCs() const; ArrayXXb inputMask() const; ArrayXXb outputMask() const; ArrayXXb inputMask(int i, int j) const; ArrayXXb outputMask(int i, int j) const; Tuples inputIndices(int i, int j) const; Tuples order() const; CD& operator()(int i, int j); const CD& operator()(int i, int j) const; PC& preconditioner(int i, int j); const PC& preconditioner(int i, int j) const; void setPreconditioner(int i, int j, const PC& preconditioner); void initialize( const MatrixXd& data, const Trainable::Parameters& params = Parameters()); bool train( const MatrixXd& data, const Trainable::Parameters& params = Parameters()); bool train( const MatrixXd& data, const MatrixXd& dataVal, const Trainable::Parameters& params = Parameters()); bool train( int i, int j, const MatrixXd& data, const Trainable::Parameters& params = Parameters()); bool train( int i, int j, const MatrixXd& data, const MatrixXd& dataVal, const Trainable::Parameters& params = Parameters()); Array<double, 1, Dynamic> logLikelihood(const MatrixXd& data) const; Array<double, 1, Dynamic> logLikelihood(int i, int j, const MatrixXd& data) const; MatrixXd sample(int num_samples) const; protected: int mRows; int mCols; int mMaxPCs; ArrayXXb mInputMask; ArrayXXb mOutputMask; Tuples mOutputIndices; vector<Tuples> mInputIndices; vector<CD> mConditionalDistributions; vector<PC*> mPreconditioners; int findIndex(int i, int j) const; bool indicesMatch(int i, int j) const; }; } /** * Constructs model which assumes image patches are generated pixel by pixel * in row-major order. * * @param rows number of rows of the image patch * @param cols number of columns of the image patch * @param model template which will be used to initialize other models * @param maxPCs used to reduce dimensionality of input to each model via PCA first */ template <class CD, class PC> CMT::PatchModel<CD, PC>::PatchModel( int rows, int cols, const CD* model, int maxPCs) : mRows(rows), mCols(cols), mMaxPCs(maxPCs) { mInputMask = ArrayXXb::Ones(2 * rows - 1, 2 * cols - 1); mInputMask(rows - 1, cols - 1) = false; mOutputMask = ArrayXXb::Zero(2 * rows - 1, 2 * cols - 1); mOutputMask(rows - 1, cols - 1) = true; // initialize conditional distributions for(int i = 0; i < mRows; ++i) for(int j = 0; j < mCols; ++j) { // compute indices of input to model predicting pixel (i, j) Tuples indices; for(Tuples::iterator it = mOutputIndices.begin(); it != mOutputIndices.end(); ++it) indices.push_back(*it); mInputIndices.push_back(indices); mOutputIndices.push_back(make_pair(i, j)); // dimensionality of input int dimIn = mMaxPCs < 0 ? indices.size() : min(static_cast<int>(indices.size()), mMaxPCs); // create model for pixel (i, j) if(model) if(dimIn == model->dimIn()) // given model fits input mConditionalDistributions.push_back(*model); else // given model doesn't fit input mConditionalDistributions.push_back(CD(dimIn, *model)); else // no model was given mConditionalDistributions.push_back(CD(dimIn)); mPreconditioners.push_back(0); } } /** * Constructs model which assumes image patches are generated pixel by pixel * in row-major order. * * @param rows number of rows of the image patch * @param cols number of columns of the image patch * @param inputMask mask used to constrain input to certain pixels * @param outputMask mask indicating the output pixel * @param model template which will be used to initialize other models * @param maxPCs used to reduce dimensionality of input to each model via PCA first */ template <class CD, class PC> CMT::PatchModel<CD, PC>::PatchModel( int rows, int cols, const ArrayXXb& inputMask, const ArrayXXb& outputMask, const CD* model, int maxPCs) : mRows(rows), mCols(cols), mMaxPCs(maxPCs), mInputMask(inputMask), mOutputMask(outputMask) { // compute locations of active pixels pair<Tuples, Tuples> inOutIndices = masksToIndices(inputMask, outputMask); Tuples& inputIndices = inOutIndices.first; Tuples& outputIndices = inOutIndices.second; if(outputIndices.size() > 1) throw Exception("Only one-dimensional outputs are currently supported."); int rowOffset = outputIndices[0].first; int colOffset = outputIndices[0].second; // initialize conditional distributions for(int i = 0; i < rows; ++i) for(int j = 0; j < cols; ++j) { // compute indices of causal neighborhood at pixel (i, j) Tuples indices; for(Tuples::iterator it = inputIndices.begin(); it != inputIndices.end(); ++it) { // location of input pixel in patch int m = i + it->first - rowOffset; int n = j + it->second - colOffset; if(m >= 0 && n >= 0 && m < mRows && n < mCols && m <= i && (n < j || m < i)) indices.push_back(make_pair(m, n)); } mInputIndices.push_back(indices); mOutputIndices.push_back(make_pair(i, j)); // dimensionality of input int dimIn = mMaxPCs < 0 ? indices.size() : min(static_cast<int>(indices.size()), mMaxPCs); // create model for pixel (i, j) if(model) if(dimIn == model->dimIn()) // given model fits input mConditionalDistributions.push_back(*model); else // given model doesn't fit input mConditionalDistributions.push_back(CD(dimIn, *model)); else // no model was given mConditionalDistributions.push_back(CD(dimIn)); mPreconditioners.push_back(0); } } /** * Constructs model which generates pixels in a prespecified order. * * @param rows number of rows of the image patch * @param cols number of columns of the image patch * @param order list of pixel locations * @param inputMask mask used to constrain input to certain pixels * @param outputMask mask indicating the output pixel * @param model template which will be used to initialize other models * @param maxPCs used to reduce dimensionality of input to each model via PCA first */ template <class CD, class PC> CMT::PatchModel<CD, PC>::PatchModel( int rows, int cols, const Tuples& order, const ArrayXXb& inputMask, const ArrayXXb& outputMask, const CD* model, int maxPCs) : mRows(rows), mCols(cols), mMaxPCs(maxPCs), mInputMask(inputMask), mOutputMask(outputMask), mOutputIndices(order) { if(order.size() != mRows * mCols) throw Exception("Invalid pixel order."); // compute location of output index Tuples outputIndices = maskToIndices(outputMask); if(outputIndices.size() > 1) throw Exception("Only one-dimensional outputs are currently supported."); int rowOffset = outputIndices[0].first; int colOffset = outputIndices[0].second; // initialize conditional distributions for(Tuples::iterator oit = mOutputIndices.begin(); oit != mOutputIndices.end(); ++oit) { // location of pixel in patch int i = oit->first; int j = oit->second; if(i < 0 || j < 0 || i >= mRows || j >= mCols) throw Exception("Invalid pixel location in list of pixels."); // compute indices of input to model predicting pixel (i, j) Tuples indices; for(Tuples::iterator iit = mOutputIndices.begin(); iit != oit; ++iit) { // location of input pixel in mask int m = iit->first - i + rowOffset; int n = iit->second - j + colOffset; // check if pixel is active in input mask if(m >= 0 && n >= 0 && m < inputMask.rows() && n < inputMask.cols()) if(inputMask(m, n)) indices.push_back(*iit); } mInputIndices.push_back(indices); // dimensionality of input int dimIn = mMaxPCs < 0 ? indices.size() : min(static_cast<int>(indices.size()), mMaxPCs); // create model for pixel (i, j) if(model) if(dimIn == model->dimIn()) // given model fits input mConditionalDistributions.push_back(*model); else // given model doesn't fit input mConditionalDistributions.push_back(CD(dimIn, *model)); else // no model was given mConditionalDistributions.push_back(CD(dimIn)); mPreconditioners.push_back(0); } } template <class CD, class PC> CMT::PatchModel<CD, PC>::PatchModel( int rows, int cols, const Tuples& order, const CD* model, int maxPCs) : mRows(rows), mCols(cols), mMaxPCs(maxPCs), mOutputIndices(order) { if(order.size() != mRows * mCols) throw Exception("Invalid pixel order."); mInputMask = ArrayXXb::Ones(2 * rows - 1, 2 * cols - 1); mInputMask(rows - 1, cols - 1) = false; mOutputMask = ArrayXXb::Zero(2 * rows - 1, 2 * cols - 1); mOutputMask(rows - 1, cols - 1) = true; // initialize conditional distributions for(Tuples::iterator oit = mOutputIndices.begin(); oit != mOutputIndices.end(); ++oit) { // location of pixel in patch int i = oit->first; int j = oit->second; if(i < 0 || j < 0 || i >= mRows || j >= mCols) throw Exception("Invalid pixel location in list of pixels."); // compute indices of input to model predicting pixel (i, j) Tuples indices; for(Tuples::iterator iit = mOutputIndices.begin(); iit != oit; ++iit) indices.push_back(*iit); mInputIndices.push_back(indices); // dimensionality of input int dimIn = mMaxPCs < 0 ? indices.size() : min(static_cast<int>(indices.size()), mMaxPCs); // create model for pixel (i, j) if(model) if(dimIn == model->dimIn()) // given model fits input mConditionalDistributions.push_back(*model); else // given model doesn't fit input mConditionalDistributions.push_back(CD(dimIn, *model)); else // no model was given mConditionalDistributions.push_back(CD(dimIn)); mPreconditioners.push_back(0); } } template <class CD, class PC> CMT::PatchModel<CD, PC>::~PatchModel() { for(int i = 0; i < mRows * mCols; ++i) if(mPreconditioners[i]) delete mPreconditioners[i]; } template <class CD, class PC> int CMT::PatchModel<CD, PC>::dim() const { return mRows * mCols; } template <class CD, class PC> int CMT::PatchModel<CD, PC>::rows() const { return mRows; } template <class CD, class PC> int CMT::PatchModel<CD, PC>::cols() const { return mCols; } template <class CD, class PC> int CMT::PatchModel<CD, PC>::maxPCs() const { return mMaxPCs; } template <class CD, class PC> Eigen::ArrayXXb CMT::PatchModel<CD, PC>::inputMask() const { return mInputMask; } template <class CD, class PC> Eigen::ArrayXXb CMT::PatchModel<CD, PC>::outputMask() const { return mOutputMask; } template <class CD, class PC> Eigen::ArrayXXb CMT::PatchModel<CD, PC>::inputMask(int i, int j) const { ArrayXXb inputMask = ArrayXXb::Zero(mRows, mCols); int k = findIndex(i, j); for(Tuples::const_iterator it = mInputIndices[k].begin(); it != mInputIndices[k].end(); ++it) inputMask(it->first, it->second) = true; return inputMask; } template <class CD, class PC> Eigen::ArrayXXb CMT::PatchModel<CD, PC>::outputMask(int i, int j) const { ArrayXXb outputMask = ArrayXXb::Zero(mRows, mCols); outputMask(i, j) = true; return outputMask; } template <class CD, class PC> CMT::Tuples CMT::PatchModel<CD, PC>::inputIndices(int i, int j) const { return mInputIndices[findIndex(i, j)]; } template <class CD, class PC> CMT::Tuples CMT::PatchModel<CD, PC>::order() const { return mOutputIndices; } template <class CD, class PC> CD& CMT::PatchModel<CD, PC>::operator()(int i, int j) { if(i < 0 || j < 0 || j >= mCols || i >= mRows) throw Exception("Invalid indices."); return mConditionalDistributions[findIndex(i, j)]; } template <class CD, class PC> const CD& CMT::PatchModel<CD, PC>::operator()(int i, int j) const { if(i < 0 || j < 0 || j >= mCols || i >= mRows) throw Exception("Invalid indices."); return mConditionalDistributions[findIndex(i, j)]; } template <class CD, class PC> PC& CMT::PatchModel<CD, PC>::preconditioner(int i, int j) { if(i < 0 || j < 0 || j >= mCols || i >= mRows) throw Exception("Invalid indices."); int k = findIndex(i, j); if(!mPreconditioners[k]) throw Exception("The model at this pixel has no preconditioner."); return *mPreconditioners[k]; } template <class CD, class PC> const PC& CMT::PatchModel<CD, PC>::preconditioner(int i, int j) const { if(i < 0 || j < 0 || j >= mCols || i >= mRows) throw Exception("Invalid indices."); int k = findIndex(i, j); if(!mPreconditioners[k]) throw Exception("The model for this pixel has no preconditioner."); return *mPreconditioners[k]; } template <class CD, class PC> void CMT::PatchModel<CD, PC>::setPreconditioner(int i, int j, const PC& preconditioner) { if(mMaxPCs < 0) return; if(i < 0 || j < 0 || j >= mCols || i >= mRows) throw Exception("Invalid indices."); int k = findIndex(i, j); if(preconditioner.dimIn() != mInputIndices[k].size() || preconditioner.dimInPre() != mConditionalDistributions[k].dimIn() || preconditioner.dimOutPre() != mConditionalDistributions[k].dimOut()) throw Exception("Preconditioner is incompatible with model."); PC* preconditionerOld = mPreconditioners[k]; mPreconditioners[k] = new PC(preconditioner); if(preconditionerOld) delete preconditionerOld; } template <class CD, class PC> void CMT::PatchModel<CD, PC>::initialize(const MatrixXd& data, const Trainable::Parameters& params) { for(int i = 0; i < mRows * mCols; ++i) { int m = mOutputIndices[i].first; int n = mOutputIndices[i].second; // assumes patch is stored in row-major order MatrixXd output = data.row(m * mCols + n); MatrixXd input(mInputIndices[i].size(), data.cols()); // subselect input from patches #pragma omp parallel for for(int j = 0; j < mInputIndices[i].size(); ++j) { // coordinates of j-th input to i-th model int m = mInputIndices[i][j].first; int n = mInputIndices[i][j].second; // assumes patch is stored in row-major order input.row(j) = data.row(m * mCols + n); } // initialize model if(mMaxPCs >= 0) { if(mPreconditioners[i]) delete mPreconditioners[i]; mPreconditioners[i] = new PC(input, output, 0., mMaxPCs); mConditionalDistributions[i].initialize( mPreconditioners[i]->operator()(input, output)); } else { mConditionalDistributions[i].initialize(input, output); } } } template <class CD, class PC> bool CMT::PatchModel<CD, PC>::train(const MatrixXd& data, const Trainable::Parameters& params) { bool converged = true; for(int i = 0; i < mRows * mCols; ++i) { // coordinates of i-th output pixels int m = mOutputIndices[i].first; int n = mOutputIndices[i].second; // assumes patch is stored in row-major order MatrixXd output = data.row(m * mCols + n); MatrixXd input(mInputIndices[i].size(), data.cols()); // check if an equivalent model has already been trained if(params.stationary) { bool copied = false; for(int j = i - 1; j >= 0; --j) if(indicesMatch(i, j)) { if(params.verbosity > 0) cout << "Copying model " << i / mCols << ", " << i % mCols << endl; // copy model mConditionalDistributions[i] = mConditionalDistributions[j]; // copy preconditioner if(mMaxPCs >= 0) mPreconditioners[i] = mPreconditioners[j]; copied = true; break; } if(copied) // don't train continue; } // extract inputs and outputs from patches #pragma omp parallel for for(int j = 0; j < mInputIndices[i].size(); ++j) { // coordinates of j-th input to i-th model int m = mInputIndices[i][j].first; int n = mInputIndices[i][j].second; // assumes patch is stored in row-major order input.row(j) = data.row(m * mCols + n); } if(params.verbosity > 0) cout << "Training model " << i / mCols << ", " << i % mCols << endl; if(mMaxPCs < 0) { converged &= mConditionalDistributions[i].train(input, output, params); } else { if(!mPreconditioners[i]) mPreconditioners[i] = new PC(input, output, 0., mMaxPCs); converged &= mConditionalDistributions[i].train( mPreconditioners[i]->operator()(input, output), params); } } return converged; } template <class CD, class PC> bool CMT::PatchModel<CD, PC>::train( const MatrixXd& data, const MatrixXd& dataVal, const Trainable::Parameters& params) { bool converged = true; for(int i = 0; i < mRows * mCols; ++i) { // coordinates of i-th output pixels int m = mOutputIndices[i].first; int n = mOutputIndices[i].second; // assumes patch is stored in row-major order MatrixXd output = data.row(m * mCols + n); MatrixXd input(mInputIndices[i].size(), data.cols()); MatrixXd outputVal = dataVal.row(m * mCols + n); MatrixXd inputVal(mInputIndices[i].size(), dataVal.cols()); // extract inputs and outputs from patches #pragma omp parallel for for(int j = 0; j < mInputIndices[i].size(); ++j) { // coordinates of j-th input to i-th model int m = mInputIndices[i][j].first; int n = mInputIndices[i][j].second; // assumes patch is stored in row-major order input.row(j) = data.row(m * mCols + n); inputVal.row(j) = dataVal.row(m * mCols + n); } if(params.verbosity > 0) cout << "Training model " << i / mCols << ", " << i % mCols << endl; if(mMaxPCs < 0) { converged &= mConditionalDistributions[i].train( input, output, inputVal, outputVal, params); } else { if(!mPreconditioners[i]) mPreconditioners[i] = new PC(input, output, 0., mMaxPCs); converged &= mConditionalDistributions[i].train( mPreconditioners[i]->operator()(input, output), mPreconditioners[i]->operator()(inputVal, outputVal), params); } } return converged; } template <class CD, class PC> bool CMT::PatchModel<CD, PC>::train(int i, int j, const MatrixXd& data, const Trainable::Parameters& params) { int k = findIndex(i, j); MatrixXd output = data.row(i * mCols + j); MatrixXd input(mInputIndices[k].size(), data.cols()); // extract inputs and outputs from patches #pragma omp parallel for for(int l = 0; l < mInputIndices[k].size(); ++l) { // coordinates of j-th input to i-th model int m = mInputIndices[k][l].first; int n = mInputIndices[k][l].second; // assumes patch is stored in row-major order input.row(l) = data.row(m * mCols + n); } if(mMaxPCs < 0) { return mConditionalDistributions[k].train(input, output, params); } else { if(!mPreconditioners[k]) mPreconditioners[k] = new PC(input, output, 0., mMaxPCs); return mConditionalDistributions[k].train( mPreconditioners[k]->operator()(input, output), params); } } template <class CD, class PC> bool CMT::PatchModel<CD, PC>::train( int i, int j, const MatrixXd& data, const MatrixXd& dataVal, const Trainable::Parameters& params) { int k = findIndex(i, j); // assumes patch is stored in row-major order MatrixXd output = data.row(i * mCols + j); MatrixXd input(mInputIndices[k].size(), data.cols()); MatrixXd outputVal = dataVal.row(i * mCols + j); MatrixXd inputVal(mInputIndices[k].size(), dataVal.cols()); // extract inputs and outputs from patches #pragma omp parallel for for(int l = 0; l < mInputIndices[k].size(); ++l) { // coordinates of j-th input to i-th model int m = mInputIndices[k][l].first; int n = mInputIndices[k][l].second; // assumes patch is stored in row-major order input.row(l) = data.row(m * mCols + n); inputVal.row(l) = dataVal.row(m * mCols + n); } if(mMaxPCs < 0) { return mConditionalDistributions[k].train( input, output, inputVal, outputVal, params); } else { if(!mPreconditioners[k]) mPreconditioners[k] = new PC(input, output, 0., mMaxPCs); return mConditionalDistributions[k].train( mPreconditioners[k]->operator()(input, output), mPreconditioners[k]->operator()(inputVal, outputVal), params); } } template <class CD, class PC> Eigen::Array<double, 1, Eigen::Dynamic> CMT::PatchModel<CD, PC>::logLikelihood( const MatrixXd& data) const { if(data.rows() != dim()) throw Exception("Data has wrong dimensionality."); if(mMaxPCs > -1) for(int i = 0; i < mRows * mCols; ++i) if(!mPreconditioners[i]) throw Exception("Model has to be initialized first."); Array<double, 1, Dynamic> logLik = Array<double, 1, Dynamic>::Zero(data.cols()); #pragma omp parallel for for(int i = 0; i < mRows * mCols; ++i) { int m = mOutputIndices[i].first; int n = mOutputIndices[i].second; // assumes patch is stored in row-major order MatrixXd output = data.row(m * mCols + n); MatrixXd input(mInputIndices[i].size(), data.cols()); for(int j = 0; j < mInputIndices[i].size(); ++j) { // coordinates of j-th input to i-th model int m = mInputIndices[i][j].first; int n = mInputIndices[i][j].second; // assumes patch is stored in row-major order input.row(j) = data.row(m * mCols + n); } Array<double, 1, Dynamic> logLik_; if(mMaxPCs < 0) logLik_ = mConditionalDistributions[i].logLikelihood(input, output); else logLik_ = mConditionalDistributions[i].logLikelihood( mPreconditioners[i]->operator()(input, output)) + mPreconditioners[i]->logJacobian(input, output); #pragma omp critical logLik += logLik_; } return logLik; } template <class CD, class PC> Eigen::Array<double, 1, Eigen::Dynamic> CMT::PatchModel<CD, PC>::logLikelihood( int i, int j, const MatrixXd& data) const { if(data.rows() != dim()) throw Exception("Data has wrong dimensionality."); int k = findIndex(i, j); Array<double, 1, Dynamic> logLik = Array<double, 1, Dynamic>::Zero(data.cols()); // assumes patch is stored in row-major order MatrixXd output = data.row(i * mCols + j); MatrixXd input(mInputIndices[k].size(), data.cols()); for(int l = 0; l < mInputIndices[k].size(); ++l) { // coordinates of j-th input to i-th model int m = mInputIndices[k][l].first; int n = mInputIndices[k][l].second; // assumes patch is stored in row-major order input.row(l) = data.row(m * mCols + n); } if(mMaxPCs < 0) { return mConditionalDistributions[k].logLikelihood(input, output); } else { if(!mPreconditioners[k]) throw Exception("Model has to be initialized first."); return mConditionalDistributions[k].logLikelihood( mPreconditioners[k]->operator()(input, output)) + mPreconditioners[k]->logJacobian(input, output); } } template<class CD, class PC> Eigen::MatrixXd CMT::PatchModel<CD, PC>::sample(int num_samples) const { MatrixXd samples = MatrixXd::Zero(mRows * mCols, num_samples); for(int i = 0; i < mRows * mCols; ++i) { MatrixXd input(mInputIndices[i].size(), num_samples); // construct input from already sampled patch for(int j = 0; j < mInputIndices[i].size(); ++j) { // coordinates of j-th input to i-th model int m = mInputIndices[i][j].first; int n = mInputIndices[i][j].second; // assumes patch is stored in row-major order input.row(j) = samples.row(m * mCols + n); } int m = mOutputIndices[i].first; int n = mOutputIndices[i].second; if(mMaxPCs < 0) { samples.row(m * mCols + n) = mConditionalDistributions[i].sample(input); } else { if(!mPreconditioners[i]) throw Exception("Model has to be initialized first."); MatrixXd inputPc = mPreconditioners[i]->operator()(input); MatrixXd outputPc = mConditionalDistributions[i].sample(inputPc); samples.row(m * mCols + n) = mPreconditioners[i]->inverse(inputPc, outputPc).second; } } return samples; } template<class CD, class PC> int CMT::PatchModel<CD, PC>::findIndex(int i, int j) const { // find index corresponding to pixel (i, j) Tuples::const_iterator it = find(mOutputIndices.begin(), mOutputIndices.end(), make_pair(i, j)); if(it == mOutputIndices.end()) throw Exception("Invalid indices"); return distance(mOutputIndices.begin(), it); } template<class CD, class PC> bool CMT::PatchModel<CD, PC>::indicesMatch(int i, int j) const { // check if indices are shifted versions of each other // assuming that indices are stored in the same order if(mInputIndices[i].size() != mInputIndices[j].size()) return false; if(mInputIndices[i].size() == 0) return true; int m = mOutputIndices[i].first - mOutputIndices[j].first; int n = mOutputIndices[i].second - mOutputIndices[j].second; for(int k = 0; k < mInputIndices[i].size(); ++k) { if(mInputIndices[j][k].first + m != mInputIndices[i][k].first) return false; if(mInputIndices[j][k].second + n != mInputIndices[i][k].second) return false; } return true; } #endif

int_array.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_utilities.hpp" /****************************************************************************** * * Routines for hypre_IntArray struct for holding an array of integers * *****************************************************************************/ /*-------------------------------------------------------------------------- * hypre_IntArrayCreate *--------------------------------------------------------------------------*/ hypre_IntArray * hypre_IntArrayCreate( HYPRE_Int size ) { hypre_IntArray *array; array = hypre_CTAlloc(hypre_IntArray, 1, HYPRE_MEMORY_HOST); hypre_IntArrayData(array) = NULL; hypre_IntArraySize(array) = size; hypre_IntArrayMemoryLocation(array) = hypre_HandleMemoryLocation(hypre_handle()); return array; } /*-------------------------------------------------------------------------- * hypre_IntArrayDestroy *--------------------------------------------------------------------------*/ HYPRE_Int hypre_IntArrayDestroy( hypre_IntArray *array ) { HYPRE_Int ierr = 0; if (array) { HYPRE_MemoryLocation memory_location = hypre_IntArrayMemoryLocation(array); hypre_TFree(hypre_IntArrayData(array), memory_location); hypre_TFree(array, HYPRE_MEMORY_HOST); } return ierr; } /*-------------------------------------------------------------------------- * hypre_IntArrayInitialize *--------------------------------------------------------------------------*/ HYPRE_Int hypre_IntArrayInitialize_v2( hypre_IntArray *array, HYPRE_MemoryLocation memory_location ) { HYPRE_Int size = hypre_IntArraySize(array); HYPRE_Int ierr = 0; hypre_IntArrayMemoryLocation(array) = memory_location; /* Caveat: for pre-existing data, the memory location must be guaranteed * to be consistent with `memory_location' * Otherwise, mismatches will exist and problems will be encountered * when being used, and freed */ if ( !hypre_IntArrayData(array) ) { hypre_IntArrayData(array) = hypre_CTAlloc(HYPRE_Int, size, memory_location); } return ierr; } HYPRE_Int hypre_IntArrayInitialize( hypre_IntArray *array ) { HYPRE_Int ierr; ierr = hypre_IntArrayInitialize_v2( array, hypre_IntArrayMemoryLocation(array) ); return ierr; } /*-------------------------------------------------------------------------- * hypre_IntArrayCopy * copies data from x to y * if size of x is larger than y only the first size_y elements of x are * copied to y *--------------------------------------------------------------------------*/ HYPRE_Int hypre_IntArrayCopy( hypre_IntArray *x, hypre_IntArray *y ) { HYPRE_Int ierr = 0; size_t size = hypre_min( hypre_IntArraySize(x), hypre_IntArraySize(y) ); hypre_TMemcpy( hypre_IntArrayData(y), hypre_IntArrayData(x), HYPRE_Int, size, hypre_IntArrayMemoryLocation(y), hypre_IntArrayMemoryLocation(x) ); return ierr; } /*-------------------------------------------------------------------------- * hypre_IntArrayCloneDeep * Returns a complete copy of x - a deep copy, with its own copy of the data. *--------------------------------------------------------------------------*/ hypre_IntArray * hypre_IntArrayCloneDeep_v2( hypre_IntArray *x, HYPRE_MemoryLocation memory_location ) { HYPRE_Int size = hypre_IntArraySize(x); hypre_IntArray *y = hypre_IntArrayCreate( size ); hypre_IntArrayInitialize_v2(y, memory_location); hypre_IntArrayCopy( x, y ); return y; } hypre_IntArray * hypre_IntArrayCloneDeep( hypre_IntArray *x ) { return hypre_IntArrayCloneDeep_v2(x, hypre_IntArrayMemoryLocation(x)); } /*-------------------------------------------------------------------------- * hypre_IntArraySetConstantValues *--------------------------------------------------------------------------*/ HYPRE_Int hypre_IntArraySetConstantValues( hypre_IntArray *v, HYPRE_Int value ) { HYPRE_Int *array_data = hypre_IntArrayData(v); HYPRE_Int size = hypre_IntArraySize(v); HYPRE_Int ierr = 0; #if defined(HYPRE_USING_CUDA) || defined(HYPRE_USING_HIP) if (size > 0) { HYPRE_THRUST_CALL( fill_n, array_data, size, value ); } #else HYPRE_Int i; #if defined(HYPRE_USING_DEVICE_OPENMP) #pragma omp target teams distribute parallel for private(i) is_device_ptr(array_data) #elif defined(HYPRE_USING_OPENMP) #pragma omp parallel for private(i) HYPRE_SMP_SCHEDULE #endif for (i = 0; i < size; i++) { array_data[i] = value; } #endif /* defined(HYPRE_USING_CUDA) || defined(HYPRE_USING_HIP) */ #if defined(HYPRE_USING_GPU) hypre_SyncCudaComputeStream(hypre_handle()); #endif return ierr; }

EntityInitializer.h

// Copyright (c) 2004-2022 Tomáš Oberhuber et al. // // This file is part of TNL - Template Numerical Library (https://tnl-project.org/) // // SPDX-License-Identifier: MIT /*** * Authors: * Oberhuber Tomas, tomas.oberhuber@fjfi.cvut.cz * Zabka Vitezslav, zabkav@gmail.com */ #pragma once #include <TNL/Meshes/MeshDetails/initializer/EntitySeed.h> #include <TNL/Meshes/MeshDetails/initializer/SubentitySeedsCreator.h> #include <TNL/Atomic.h> #include <TNL/Algorithms/AtomicOperations.h> namespace TNL { namespace Meshes { template< typename MeshConfig > class Initializer; template< typename MeshConfig, typename SubdimensionTag, typename SuperdimensionTag, typename SuperentityTopology = typename MeshTraits< MeshConfig >::template EntityTraits< SuperdimensionTag::value >::EntityTopology, // storage in the superentity bool SubentityStorage = MeshConfig::subentityStorage( SuperdimensionTag::value, SubdimensionTag::value ), // storage in the subentity bool SuperentityStorage = MeshConfig::superentityStorage( SubdimensionTag::value, SuperdimensionTag::value ), // necessary to disambiguate the stop condition for specializations bool valid_dimension = ! std::is_same< SubdimensionTag, SuperdimensionTag >::value > class EntityInitializerLayer; template< typename MeshConfig, typename EntityTopology, bool SubvertexStorage = MeshConfig::subentityStorage( EntityTopology::dimension, 0 ) > class EntityInitializer : public EntityInitializerLayer< MeshConfig, DimensionTag< EntityTopology::dimension >, DimensionTag< MeshTraits< MeshConfig >::meshDimension > > { using BaseType = EntityInitializerLayer< MeshConfig, DimensionTag< EntityTopology::dimension >, DimensionTag< MeshTraits< MeshConfig >::meshDimension > >; using MeshTraitsType = MeshTraits< MeshConfig >; using EntityTraitsType = typename MeshTraitsType::template EntityTraits< EntityTopology::dimension >; using GlobalIndexType = typename MeshTraitsType::GlobalIndexType; using LocalIndexType = typename MeshTraitsType::LocalIndexType; using SeedType = EntitySeed< MeshConfig, EntityTopology >; using InitializerType = Initializer< MeshConfig >; using NeighborCountsArray = typename MeshTraitsType::NeighborCountsArray; using SeedMatrixType = typename EntityTraitsType::SeedMatrixType; public: static void initSubvertexMatrix( NeighborCountsArray& capacities, InitializerType& initializer ) { initializer.template initSubentityMatrix< EntityTopology::dimension, 0 >( capacities ); } static void initSubvertexMatrix( SeedMatrixType& seeds, InitializerType& initializer ) { auto& subvertexMatrix = initializer.template getSubentitiesMatrix< EntityTopology::dimension, 0 >(); subvertexMatrix = std::move( seeds.getMatrix() ); initializer.template initSubentitiesCounts< EntityTopology::dimension, 0 >( seeds.getEntityCornerCounts() ); } static void initEntity( const GlobalIndexType entityIndex, const SeedType& entitySeed, InitializerType& initializer ) { // this is necessary if we want to use existing entities instead of intermediate seeds to create subentity seeds for( LocalIndexType i = 0; i < entitySeed.getCornerIds().getSize(); i++ ) initializer.template setSubentityIndex< EntityTopology::dimension, 0 >( entityIndex, i, entitySeed.getCornerIds()[ i ] ); } }; template< typename MeshConfig, typename EntityTopology > class EntityInitializer< MeshConfig, EntityTopology, false > : public EntityInitializerLayer< MeshConfig, DimensionTag< EntityTopology::dimension >, DimensionTag< MeshTraits< MeshConfig >::meshDimension > > { using MeshTraitsType = MeshTraits< MeshConfig >; using EntityTraitsType = typename MeshTraitsType::template EntityTraits< EntityTopology::dimension >; using GlobalIndexType = typename MeshTraitsType::GlobalIndexType; using SeedType = EntitySeed< MeshConfig, EntityTopology >; using InitializerType = Initializer< MeshConfig >; using NeighborCountsArray = typename MeshTraitsType::NeighborCountsArray; using SeedMatrixType = typename EntityTraitsType::SeedMatrixType; public: static void initSubvertexMatrix( const NeighborCountsArray& capacities, InitializerType& initializer ) {} static void initSubvertexMatrix( SeedMatrixType& seeds, InitializerType& initializer ) {} static void initEntity( const GlobalIndexType entityIndex, const SeedType& entitySeed, InitializerType& initializer ) {} }; /**** * Mesh entity initializer layer with specializations * * SUBENTITY STORAGE SUPERENTITY STORAGE * TRUE TRUE */ template< typename MeshConfig, typename SubdimensionTag, typename SuperdimensionTag, typename SuperentityTopology > class EntityInitializerLayer< MeshConfig, SubdimensionTag, SuperdimensionTag, SuperentityTopology, true, true, true > : public EntityInitializerLayer< MeshConfig, SubdimensionTag, typename SuperdimensionTag::Decrement > { using BaseType = EntityInitializerLayer< MeshConfig, SubdimensionTag, typename SuperdimensionTag::Decrement >; using InitializerType = Initializer< MeshConfig >; using MeshType = typename InitializerType::MeshType; using MeshTraitsType = MeshTraits< MeshConfig >; using GlobalIndexType = typename MeshTraitsType::GlobalIndexType; using LocalIndexType = typename MeshTraitsType::LocalIndexType; using SubentityTraitsType = typename MeshTraitsType::template EntityTraits< SubdimensionTag::value >; using SubentityTopology = typename SubentityTraitsType::EntityTopology; using SuperentityTraitsType = typename MeshTraitsType::template EntityTraits< SuperdimensionTag::value >; using SubentitySeedsCreatorType = SubentitySeedsCreator< MeshConfig, SuperentityTopology, SubdimensionTag >; using SuperentityMatrixType = typename MeshTraitsType::SuperentityMatrixType; using NeighborCountsArray = typename MeshTraitsType::NeighborCountsArray; using SeedType = EntitySeed< MeshConfig, SubentityTopology >; public: static void initSuperentities( InitializerType& meshInitializer, MeshType& mesh ) { // std::cout << " Initiating superentities with dimension " << SuperdimensionTag::value << " for subentities with // dimension " << SubdimensionTag::value << " ... " << std::endl; const GlobalIndexType subentitiesCount = mesh.template getEntitiesCount< SubdimensionTag::value >(); const GlobalIndexType superentitiesCount = mesh.template getEntitiesCount< SuperdimensionTag::value >(); if( SubdimensionTag::value > 0 || std::is_same< SuperentityTopology, Topologies::Polyhedron >::value ) { NeighborCountsArray capacities( superentitiesCount ); Algorithms::ParallelFor< Devices::Host >::exec( GlobalIndexType{ 0 }, superentitiesCount, [ & ]( GlobalIndexType superentityIndex ) { capacities[ superentityIndex ] = SubentitySeedsCreatorType::getSubentitiesCount( meshInitializer, mesh, superentityIndex ); } ); meshInitializer.template initSubentityMatrix< SuperdimensionTag::value, SubdimensionTag::value >( capacities, subentitiesCount ); } // counter for superentities of each subentity auto& superentitiesCounts = meshInitializer.template getSuperentitiesCountsArray< SubdimensionTag::value, SuperdimensionTag::value >(); superentitiesCounts.setSize( subentitiesCount ); superentitiesCounts.setValue( 0 ); Algorithms::ParallelFor< Devices::Host >::exec( GlobalIndexType{ 0 }, superentitiesCount, [ & ]( GlobalIndexType superentityIndex ) { LocalIndexType i = 0; SubentitySeedsCreatorType::iterate( meshInitializer, mesh, superentityIndex, [ & ]( SeedType& seed ) { const GlobalIndexType subentityIndex = meshInitializer.findEntitySeedIndex( seed ); // Subentity indices for SubdimensionTag::value == 0 of non-polyhedral meshes were already set up from seeds if( SubdimensionTag::value > 0 || std::is_same< SuperentityTopology, Topologies::Polyhedron >::value ) meshInitializer.template setSubentityIndex< SuperdimensionTag::value, SubdimensionTag::value >( superentityIndex, i++, subentityIndex ); Algorithms::AtomicOperations< Devices::Host >::add( superentitiesCounts[ subentityIndex ], LocalIndexType{ 1 } ); } ); } ); // allocate superentities storage SuperentityMatrixType& matrix = meshInitializer.template getSuperentitiesMatrix< SubdimensionTag::value, SuperdimensionTag::value >(); matrix.setDimensions( subentitiesCount, superentitiesCount ); matrix.setRowCapacities( superentitiesCounts ); superentitiesCounts.setValue( 0 ); for( GlobalIndexType superentityIndex = 0; superentityIndex < superentitiesCount; superentityIndex++ ) { for( LocalIndexType i = 0; i < mesh.template getSubentitiesCount< SuperdimensionTag::value, SubdimensionTag::value >( superentityIndex ); i++ ) { const GlobalIndexType subentityIndex = mesh.template getSubentityIndex< SuperdimensionTag::value, SubdimensionTag::value >( superentityIndex, i ); auto row = matrix.getRow( subentityIndex ); row.setElement( superentitiesCounts[ subentityIndex ]++, superentityIndex, true ); } } BaseType::initSuperentities( meshInitializer, mesh ); } }; /**** * Mesh entity initializer layer with specializations * * SUBENTITY STORAGE SUPERENTITY STORAGE Subdimension Superdimension SUPERENTITY TOPOLOGY * TRUE TRUE 2 3 POLYHEDRON */ template< typename MeshConfig > class EntityInitializerLayer< MeshConfig, DimensionTag< 2 >, DimensionTag< 3 >, Topologies::Polyhedron, true, true, true > : public EntityInitializerLayer< MeshConfig, DimensionTag< 2 >, typename DimensionTag< 3 >::Decrement > { using SubdimensionTag = DimensionTag< 2 >; using SuperdimensionTag = DimensionTag< 3 >; using BaseType = EntityInitializerLayer< MeshConfig, SubdimensionTag, typename SuperdimensionTag::Decrement >; using InitializerType = Initializer< MeshConfig >; using MeshType = typename InitializerType::MeshType; using MeshTraitsType = MeshTraits< MeshConfig >; using GlobalIndexType = typename MeshTraitsType::GlobalIndexType; using LocalIndexType = typename MeshTraitsType::LocalIndexType; using SubentityTraitsType = typename MeshTraitsType::template EntityTraits< SubdimensionTag::value >; using SubentityTopology = typename SubentityTraitsType::EntityTopology; using SuperentityTraitsType = typename MeshTraitsType::template EntityTraits< SuperdimensionTag::value >; using SuperentityTopology = typename SuperentityTraitsType::EntityTopology; using SuperentityMatrixType = typename MeshTraitsType::SuperentityMatrixType; using NeighborCountsArray = typename MeshTraitsType::NeighborCountsArray; using SeedType = EntitySeed< MeshConfig, SubentityTopology >; public: static void initSuperentities( InitializerType& meshInitializer, MeshType& mesh ) { // std::cout << " Initiating superentities with dimension " << SuperdimensionTag::value << " for subentities with // dimension " << SubdimensionTag::value << " ... " << std::endl; const GlobalIndexType subentitiesCount = mesh.template getEntitiesCount< SubdimensionTag::value >(); const GlobalIndexType superentitiesCount = mesh.template getEntitiesCount< SuperdimensionTag::value >(); // counter for superentities of each subentity auto& superentitiesCounts = meshInitializer.template getSuperentitiesCountsArray< SubdimensionTag::value, SuperdimensionTag::value >(); superentitiesCounts.setSize( subentitiesCount ); superentitiesCounts.setValue( 0 ); auto& cellSeeds = meshInitializer.getCellSeeds(); for( GlobalIndexType superentityIndex = 0; superentityIndex < superentitiesCount; superentityIndex++ ) { const auto cellSeed = cellSeeds.getSeed( superentityIndex ); for( LocalIndexType i = 0; i < cellSeed.getCornersCount(); i++ ) { const GlobalIndexType subentityIndex = cellSeed.getCornerId( i ); superentitiesCounts[ subentityIndex ]++; } } auto& subvertexMatrix = meshInitializer.template getSubentitiesMatrix< SuperdimensionTag::value, SubdimensionTag::value >(); subvertexMatrix = std::move( cellSeeds.getMatrix() ); meshInitializer.template initSubentitiesCounts< SuperdimensionTag::value, SubdimensionTag::value >( cellSeeds.getEntityCornerCounts() ); // allocate superentities storage SuperentityMatrixType& matrix = meshInitializer.template getSuperentitiesMatrix< SubdimensionTag::value, SuperdimensionTag::value >(); matrix.setDimensions( subentitiesCount, superentitiesCount ); matrix.setRowCapacities( superentitiesCounts ); superentitiesCounts.setValue( 0 ); // initialize superentities storage for( GlobalIndexType superentityIndex = 0; superentityIndex < superentitiesCount; superentityIndex++ ) { for( LocalIndexType i = 0; i < mesh.template getSubentitiesCount< SuperdimensionTag::value, SubdimensionTag::value >( superentityIndex ); i++ ) { const GlobalIndexType subentityIndex = mesh.template getSubentityIndex< SuperdimensionTag::value, SubdimensionTag::value >( superentityIndex, i ); auto row = matrix.getRow( subentityIndex ); row.setElement( superentitiesCounts[ subentityIndex ]++, superentityIndex, true ); } } BaseType::initSuperentities( meshInitializer, mesh ); } }; /**** * Mesh entity initializer layer with specializations * * SUBENTITY STORAGE SUPERENTITY STORAGE * TRUE FALSE */ template< typename MeshConfig, typename SubdimensionTag, typename SuperdimensionTag, typename SuperentityTopology > class EntityInitializerLayer< MeshConfig, SubdimensionTag, SuperdimensionTag, SuperentityTopology, true, false, true > : public EntityInitializerLayer< MeshConfig, SubdimensionTag, typename SuperdimensionTag::Decrement > { using BaseType = EntityInitializerLayer< MeshConfig, SubdimensionTag, typename SuperdimensionTag::Decrement >; using InitializerType = Initializer< MeshConfig >; using MeshType = typename InitializerType::MeshType; using MeshTraitsType = MeshTraits< MeshConfig >; using GlobalIndexType = typename MeshTraitsType::GlobalIndexType; using LocalIndexType = typename MeshTraitsType::LocalIndexType; using SubentityTraitsType = typename MeshTraitsType::template EntityTraits< SubdimensionTag::value >; using SubentityTopology = typename SubentityTraitsType::EntityTopology; using SuperentityTraitsType = typename MeshTraitsType::template EntityTraits< SuperdimensionTag::value >; using SubentitySeedsCreatorType = SubentitySeedsCreator< MeshConfig, SuperentityTopology, SubdimensionTag >; using NeighborCountsArray = typename MeshTraitsType::NeighborCountsArray; using SeedType = EntitySeed< MeshConfig, SubentityTopology >; public: static void initSuperentities( InitializerType& meshInitializer, MeshType& mesh ) { // std::cout << " Initiating superentities with dimension " << SuperdimensionTag::value << " for subentities with // dimension " << SubdimensionTag::value << " ... " << std::endl; const GlobalIndexType subentitiesCount = mesh.template getEntitiesCount< SubdimensionTag::value >(); const GlobalIndexType superentitiesCount = mesh.template getEntitiesCount< SuperdimensionTag::value >(); if( SubdimensionTag::value > 0 || std::is_same< SuperentityTopology, Topologies::Polyhedron >::value ) { NeighborCountsArray capacities( superentitiesCount ); Algorithms::ParallelFor< Devices::Host >::exec( GlobalIndexType{ 0 }, superentitiesCount, [ & ]( GlobalIndexType superentityIndex ) { capacities[ superentityIndex ] = SubentitySeedsCreatorType::getSubentitiesCount( meshInitializer, mesh, superentityIndex ); } ); meshInitializer.template initSubentityMatrix< SuperdimensionTag::value, SubdimensionTag::value >( capacities, subentitiesCount ); Algorithms::ParallelFor< Devices::Host >::exec( GlobalIndexType{ 0 }, superentitiesCount, [ & ]( GlobalIndexType superentityIndex ) { LocalIndexType i = 0; SubentitySeedsCreatorType::iterate( meshInitializer, mesh, superentityIndex, [ & ]( SeedType& seed ) { const GlobalIndexType subentityIndex = meshInitializer.findEntitySeedIndex( seed ); meshInitializer.template setSubentityIndex< SuperdimensionTag::value, SubdimensionTag::value >( superentityIndex, i++, subentityIndex ); } ); } ); } BaseType::initSuperentities( meshInitializer, mesh ); } }; /**** * Mesh entity initializer layer with specializations * * SUBENTITY STORAGE SUPERENTITY STORAGE Subdimension Superdimension SUPERENTITY TOPOLOGY * TRUE FALSE 2 3 POLYHEDRON */ template< typename MeshConfig > class EntityInitializerLayer< MeshConfig, DimensionTag< 2 >, DimensionTag< 3 >, Topologies::Polyhedron, true, false, true > : public EntityInitializerLayer< MeshConfig, DimensionTag< 2 >, typename DimensionTag< 3 >::Decrement > { using SubdimensionTag = DimensionTag< 2 >; using SuperdimensionTag = DimensionTag< 3 >; using BaseType = EntityInitializerLayer< MeshConfig, SubdimensionTag, typename SuperdimensionTag::Decrement >; using InitializerType = Initializer< MeshConfig >; using MeshType = typename InitializerType::MeshType; using MeshTraitsType = MeshTraits< MeshConfig >; using GlobalIndexType = typename MeshTraitsType::GlobalIndexType; using LocalIndexType = typename MeshTraitsType::LocalIndexType; using SubentityTraitsType = typename MeshTraitsType::template EntityTraits< SubdimensionTag::value >; using SubentityTopology = typename SubentityTraitsType::EntityTopology; using SuperentityTraitsType = typename MeshTraitsType::template EntityTraits< SuperdimensionTag::value >; using SuperentityTopology = typename SuperentityTraitsType::EntityTopology; using NeighborCountsArray = typename MeshTraitsType::NeighborCountsArray; using SeedType = EntitySeed< MeshConfig, SubentityTopology >; public: static void initSuperentities( InitializerType& meshInitializer, MeshType& mesh ) { // std::cout << " Initiating superentities with dimension " << SuperdimensionTag::value << " for subentities with // dimension " << SubdimensionTag::value << " ... " << std::endl; auto& cellSeeds = meshInitializer.getCellSeeds(); auto& subvertexMatrix = meshInitializer.template getSubentitiesMatrix< SuperdimensionTag::value, SubdimensionTag::value >(); subvertexMatrix = std::move( cellSeeds.getMatrix() ); meshInitializer.template initSubentitiesCounts< SuperdimensionTag::value, SubdimensionTag::value >( cellSeeds.getEntityCornerCounts() ); BaseType::initSuperentities( meshInitializer, mesh ); } }; /**** * Mesh entity initializer layer with specializations * * SUBENTITY STORAGE SUPERENTITY STORAGE * FALSE TRUE */ template< typename MeshConfig, typename SubdimensionTag, typename SuperdimensionTag, typename SuperentityTopology > class EntityInitializerLayer< MeshConfig, SubdimensionTag, SuperdimensionTag, SuperentityTopology, false, true, true > : public EntityInitializerLayer< MeshConfig, SubdimensionTag, typename SuperdimensionTag::Decrement > { using BaseType = EntityInitializerLayer< MeshConfig, SubdimensionTag, typename SuperdimensionTag::Decrement >; using InitializerType = Initializer< MeshConfig >; using MeshType = typename InitializerType::MeshType; using MeshTraitsType = MeshTraits< MeshConfig >; using GlobalIndexType = typename MeshTraitsType::GlobalIndexType; using LocalIndexType = typename MeshTraitsType::LocalIndexType; using SubentityTraitsType = typename MeshTraitsType::template EntityTraits< SubdimensionTag::value >; using SubentityTopology = typename SubentityTraitsType::EntityTopology; using SuperentityTraitsType = typename MeshTraitsType::template EntityTraits< SuperdimensionTag::value >; using SubentitySeedsCreatorType = SubentitySeedsCreator< MeshConfig, SuperentityTopology, SubdimensionTag >; using SuperentityMatrixType = typename MeshTraitsType::SuperentityMatrixType; using SeedType = EntitySeed< MeshConfig, SubentityTopology >; public: static void initSuperentities( InitializerType& meshInitializer, MeshType& mesh ) { // std::cout << " Initiating superentities with dimension " << SuperdimensionTag::value << " for subentities with // dimension " << SubdimensionTag::value << " ... " << std::endl; const GlobalIndexType subentitiesCount = mesh.template getEntitiesCount< SubdimensionTag::value >(); const GlobalIndexType superentitiesCount = mesh.template getEntitiesCount< SuperdimensionTag::value >(); // counter for superentities of each subentity auto& superentitiesCounts = meshInitializer.template getSuperentitiesCountsArray< SubdimensionTag::value, SuperdimensionTag::value >(); superentitiesCounts.setSize( subentitiesCount ); superentitiesCounts.setValue( 0 ); Algorithms::ParallelFor< Devices::Host >::exec( GlobalIndexType{ 0 }, superentitiesCount, [ & ]( GlobalIndexType superentityIndex ) { SubentitySeedsCreatorType::iterate( meshInitializer, mesh, superentityIndex, [ & ]( SeedType& seed ) { const GlobalIndexType subentityIndex = meshInitializer.findEntitySeedIndex( seed ); Algorithms::AtomicOperations< Devices::Host >::add( superentitiesCounts[ subentityIndex ], LocalIndexType{ 1 } ); } ); } ); // allocate superentities storage SuperentityMatrixType& matrix = meshInitializer.template getSuperentitiesMatrix< SubdimensionTag::value, SuperdimensionTag::value >(); matrix.setDimensions( subentitiesCount, superentitiesCount ); matrix.setRowCapacities( superentitiesCounts ); superentitiesCounts.setValue( 0 ); // initialize superentities storage for( GlobalIndexType superentityIndex = 0; superentityIndex < superentitiesCount; superentityIndex++ ) { SubentitySeedsCreatorType::iterate( meshInitializer, mesh, superentityIndex, [ & ]( SeedType& seed ) { const GlobalIndexType subentityIndex = meshInitializer.findEntitySeedIndex( seed ); auto row = matrix.getRow( subentityIndex ); row.setElement( superentitiesCounts[ subentityIndex ]++, superentityIndex, true ); } ); } // Here is an attempt of parallelization of previous for cycle, that seemingly causes some kind of race condition /*Algorithms::ParallelFor< Devices::Host >::exec( GlobalIndexType{ 0 }, superentitiesCount, [&] ( GlobalIndexType superentityIndex ) { SubentitySeedsCreatorType::iterate( meshInitializer, mesh, superentityIndex, [&] ( SeedType& seed ) { const GlobalIndexType subentityIndex = meshInitializer.findEntitySeedIndex( seed ); auto row = matrix.getRow( subentityIndex ); LocalIndexType superentityCount; #pragma omp atomic capture { superentityCount = superentitiesCounts[ subentityIndex ]; superentitiesCounts[ subentityIndex ]++; } row.setElement( superentityCount, superentityIndex, true ); }); });*/ BaseType::initSuperentities( meshInitializer, mesh ); } }; template< typename MeshConfig, typename SubdimensionTag, typename SuperdimensionTag, typename SuperentityTopology > class EntityInitializerLayer< MeshConfig, SubdimensionTag, SuperdimensionTag, SuperentityTopology, false, false, true > : public EntityInitializerLayer< MeshConfig, SubdimensionTag, typename SuperdimensionTag::Decrement > {}; template< typename MeshConfig, typename SubdimensionTag, typename SuperentityTopology, bool SubentityStorage, bool SuperentityStorage > class EntityInitializerLayer< MeshConfig, SubdimensionTag, SubdimensionTag, SuperentityTopology, SubentityStorage, SuperentityStorage, false > { using InitializerType = Initializer< MeshConfig >; using MeshType = typename InitializerType::MeshType; public: static void initSuperentities( InitializerType& meshInitializer, MeshType& mesh ) {} }; } // namespace Meshes } // namespace TNL

hnsw.h

// Copyright 2017 Kakao Corp. <http://www.kakaocorp.com> // // 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. #pragma once /** @file */ #include <omp.h> #include <memory> #include <string> #include <utility> #include <vector> #include "hnsw_build.h" #include "hnsw_model.h" #include "hnsw_search.h" namespace n2 { class Hnsw { public: Hnsw(); /** * @brief Makes an instance of Hnsw Index. * @param dim: Dimension of vectors. * @param metric: An optional parameter to choose a distance metric. * ('angular' | 'L2' | 'dot') (default: 'angular'). * @return A new Hnsw index. */ Hnsw(int dim,std::string metric="angular"); Hnsw(const Hnsw& other); Hnsw(Hnsw&& other) noexcept; ~Hnsw(); Hnsw& operator=(const Hnsw& other); Hnsw& operator=(Hnsw&& other) noexcept; //////////////////////////////////////////// // Build /** * @brief Adds vector to Hnsw index. * @param data: A vector with dimension ``dim``. */ void AddData(const std::vector<float>& data); /** * @brief Set configurations by key/value pairs. * * To set configurations as default values, pass negative values to configuration parameters. */ void SetConfigs(const std::vector<std::pair<std::string, std::string>>& configs); /** * @brief Builds a hnsw graph with given configurations. * @param m: Max number of edges for nodes at level > 0 (default: 12). * @param max_m0: Max number of edges for nodes at level == 0 (default: 24). * @param ef_construction: Refer to HNSW paper for its role (default: 150). * @param n_threads: Number of threads for building index. * @param mult: Level multiplier (default value recommended) (default: 1/log(1.0*M)). * @param NeighborSelectingPolicy: Neighbor selecting policy. * @param GraphPostProcessing: Graph merging heuristic. * * To see other available values for ``neighbor_selecting`` and ``graph_merging``, * refer to NeighborSelectingPolicy() and GraphPostProcessing(). * @see Fit(), SetConfigs() */ void Build(int m=-1, int max_m0=-1, int ef_construction=-1, int n_threads=-1, float mult=-1, NeighborSelectingPolicy neighbor_selecting=NeighborSelectingPolicy::HEURISTIC, GraphPostProcessing graph_merging=GraphPostProcessing::SKIP, bool ensure_k=false); /** * @brief Builds a hnsw graph with given configurations. */ void Fit(); //////////////////////////////////////////// // Model /** * @brief Saves the index to disk. * @param fname: An index file name. */ bool SaveModel(const std::string& fname) const; /** * @brief Loads an index from disk. * @param fname: An index file name. * @param use_mmap: An optional parameter (default: true). * If this parameter is set, N2 loads model through mmap. */ bool LoadModel(const std::string& fname, const bool use_mmap=true); /** * @brief Unloads the loaded index file. */ void UnloadModel(); //////////////////////////////////////////// // Search inline void SearchByVector(const std::vector<float>& qvec, size_t k, size_t ef_search, std::vector<int>& result) { searcher_->SearchByVector(qvec, k, ef_search, ensure_k_, result); } /** * @brief Search k nearest items (as vectors) to a query item. * @param qvec: A query vector. * @param k: k value. * @param ef_search: (default: 50 * k). If you pass a negative value to ef_search, * ef_search will be set as the default value. * @param[out] result: ``k`` nearest items. */ inline void SearchByVector(const std::vector<float>& qvec, size_t k, size_t ef_search, std::vector<std::pair<int, float>>& result) { searcher_->SearchByVector(qvec, k, ef_search, ensure_k_, result); } inline void SearchById(int id, size_t k, size_t ef_search, std::vector<int>& result) { searcher_->SearchById(id, k, ef_search, ensure_k_, result); } /** * @brief Search k nearest items (as ids) to a query item. * @param id: A query id. * @param k: k value. * @param ef_search: (default: 50 * k). If you pass a negative value to ef_search, * ef_search will be set as the default value. * @param[out] result: ``k`` nearest items. */ inline void SearchById(int id, size_t k, size_t ef_search, std::vector<std::pair<int, float>>& result) { searcher_->SearchById(id, k, ef_search, ensure_k_, result); } inline void BatchSearchByVectors(const std::vector<std::vector<float>>& qvecs, size_t k, size_t ef_search, size_t n_threads, std::vector<std::vector<int>>& results) { BatchSearchByVectors_(qvecs, k, ef_search, n_threads, results); } /** * @brief Search k nearest items (as vectors) to each query item (batch search with multi-threads). * @param qvecs: Query vectors. * @param k: k value. * @param ef_search: (default: 50 * k). If you pass a negative value to ef_search, * ef_search will be set as the default value. * @param n_threads: Number of threads to use for search. * @param[out] result: vector of ``k`` nearest items for each input query item * in the order passed to parameter ``qvecs``. */ inline void BatchSearchByVectors(const std::vector<std::vector<float>>& qvecs, size_t k, size_t ef_search, size_t n_threads, std::vector<std::vector<std::pair<int, float>>>& results) { BatchSearchByVectors_(qvecs, k, ef_search, n_threads, results); } inline void BatchSearchByIds(const std::vector<int> ids, size_t k, size_t ef_search, size_t n_threads, std::vector<std::vector<int>>& results) { BatchSearchByIds_(ids, k, ef_search, n_threads, results); } /** * @brief Search k nearest items (as ids) to each query item (batch search with multi-threads). * @param ids: Query ids. * @param k: k value. * @param ef_search: (default: 50 * k). If you pass a negative value to ef_search, * ef_search will be set as the default value. * @param n_threads: Number of threads to use for search. * @param[out] result: vector of ``k`` nearest items for each input query item * in the order passed to parameter ``ids``. */ inline void BatchSearchByIds(const std::vector<int> ids, size_t k, size_t ef_search, size_t n_threads, std::vector<std::vector<std::pair<int, float>>>& results) { BatchSearchByIds_(ids, k, ef_search, n_threads, results); } //////////////////////////////////////////// // Build(Misc) /** * @brief Prints degree distributions. */ void PrintDegreeDist() const; /** * @brief Prints index configurations. */ void PrintConfigs() const; private: void InitSearcherAndSearcherPool_(); template<typename ResultType> void BatchSearchByVectors_(const std::vector<std::vector<float>>& qvecs, size_t k, size_t ef_search, size_t n_threads, ResultType& results) { results.resize(qvecs.size()); while (searcher_pool_.size() < n_threads) { searcher_pool_.push_back(HnswSearch::GenerateSearcher(model_, data_dim_, metric_)); } #pragma omp parallel num_threads(n_threads) { #pragma omp for schedule(runtime) for (size_t i = 0; i < qvecs.size(); ++i) { auto& s = searcher_pool_[omp_get_thread_num()]; s->SearchByVector(qvecs[i], k, ef_search, ensure_k_, results[i]); } } } template<typename ResultType> void BatchSearchByIds_(const std::vector<int> ids, size_t k, size_t ef_search, size_t n_threads, ResultType& results) { results.resize(ids.size()); while (searcher_pool_.size() < n_threads) { searcher_pool_.push_back(HnswSearch::GenerateSearcher(model_, data_dim_, metric_)); } #pragma omp parallel num_threads(n_threads) { #pragma omp for schedule(runtime) for (size_t i = 0; i < ids.size(); ++i) { auto& s = searcher_pool_[omp_get_thread_num()]; s->SearchById(ids[i], k, ef_search, ensure_k_, results[i]); } } } private: std::unique_ptr<HnswBuild> builder_; std::shared_ptr<const HnswModel> model_; std::shared_ptr<HnswSearch> searcher_; // for single-thread search std::vector<std::shared_ptr<HnswSearch>> searcher_pool_; // for multi-threads batch search size_t data_dim_; DistanceKind metric_; bool ensure_k_ = false; }; } // namespace n2

GB_unop__identity_fc32_int8.c

//------------------------------------------------------------------------------ // GB_unop: hard-coded functions for each built-in unary operator //------------------------------------------------------------------------------ // SuiteSparse:GraphBLAS, Timothy A. Davis, (c) 2017-2022, 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_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__identity_fc32_int8) // op(A') function: GB (_unop_tran__identity_fc32_int8) // C type: GxB_FC32_t // A type: int8_t // cast: GxB_FC32_t cij = GxB_CMPLXF ((float) (aij), 0) // unaryop: cij = aij #define GB_ATYPE \ int8_t #define GB_CTYPE \ GxB_FC32_t // aij = Ax [pA] #define GB_GETA(aij,Ax,pA) \ int8_t aij = Ax [pA] #define GB_CX(p) Cx [p] // unary operator #define GB_OP(z, x) \ z = x ; // casting #define GB_CAST(z, aij) \ GxB_FC32_t z = GxB_CMPLXF ((float) (aij), 0) ; // cij = op (aij) #define GB_CAST_OP(pC,pA) \ { \ /* aij = Ax [pA] */ \ int8_t aij = Ax [pA] ; \ /* Cx [pC] = op (cast (aij)) */ \ GxB_FC32_t z = GxB_CMPLXF ((float) (aij), 0) ; \ Cx [pC] = z ; \ } // disable this operator and use the generic case if these conditions hold #define GB_DISABLE \ (GxB_NO_IDENTITY || GxB_NO_FC32 || GxB_NO_INT8) //------------------------------------------------------------------------------ // Cx = op (cast (Ax)): apply a unary operator //------------------------------------------------------------------------------ GrB_Info GB (_unop_apply__identity_fc32_int8) ( GxB_FC32_t *Cx, // Cx and Ax may be aliased const int8_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 ; if (Ab == NULL) { #pragma omp parallel for num_threads(nthreads) schedule(static) for (p = 0 ; p < anz ; p++) { int8_t aij = Ax [p] ; GxB_FC32_t z = GxB_CMPLXF ((float) (aij), 0) ; Cx [p] = z ; } } 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 ; int8_t aij = Ax [p] ; GxB_FC32_t z = GxB_CMPLXF ((float) (aij), 0) ; Cx [p] = z ; } } return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // C = op (cast (A')): transpose, typecast, and apply a unary operator //------------------------------------------------------------------------------ GrB_Info GB (_unop_tran__identity_fc32_int8) ( 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

ompForTest.c

#include <stdlib.h> #include <stdio.h> #include <omp.h> int main(int argc, char const *argv[]) { omp_set_num_threads(4); #pragma omp parallel for for(int i = 0; i < 32; ++i) { printf("Thread #%d is working. i = %d\n", omp_get_thread_num(), i); } printf("Thread #%d is working.\n", omp_get_thread_num()); return 0; }

model.c

#include <cdnn/model.h> #include <cdnn/progressbar.h> __Model__ * m; void __init__(){ m->predicting = 0; m->testing=0; m->test_accuracy = 0.0; m->train_accuracy = 0.0; m->train_cost = 0.0; m->cross_val_accuracy = 0.0; m->iter_cost = 0.0; m->current_iter = 1; m->output = NULL; __initialize_params__(); } void __initialize_params__(){ Computation_Graph * temp = m->graph; temp = temp->next_layer; int index = 0; int flag = 0; if(!strcasecmp(m->optimizer,"adam")) flag = 1; if(!strcasecmp(m->optimizer,"adagrad")) flag = 2; if(!strcasecmp(m->optimizer,"rmsprop")) flag = 3; if(!strcasecmp(m->optimizer,"momentum")) flag = 4; while(temp!=NULL){ m->current_layer = temp; if(temp->type==DENSE){ temp->DENSE->initalize_params(); } if(flag==1 && temp->type!=LOSS){ int dims_dW[] = {temp->DENSE->weights->shape[0],temp->DENSE->weights->shape[1]}; int dims_db[] = {temp->DENSE->bias->shape[0],temp->DENSE->bias->shape[1]}; m->m_t_dW[index] = zeros(dims_dW); m->m_t_db[index] = zeros(dims_db); m->v_t_dW[index] = zeros(dims_dW); m->v_t_db[index] = zeros(dims_db); index++; } else if(flag==2 && temp->type!=LOSS){ int dims_dW[] = {temp->DENSE->weights->shape[0],temp->DENSE->weights->shape[1]}; int dims_db[] = {temp->DENSE->bias->shape[0],temp->DENSE->bias->shape[1]}; m->cache_dW[index] = zeros(dims_dW); m->cache_db[index] = zeros(dims_db); index++; } else if(flag==3 && temp->type!=LOSS){ int dims_dW[] = {temp->DENSE->weights->shape[0],temp->DENSE->weights->shape[1]}; int dims_db[] = {temp->DENSE->bias->shape[0],temp->DENSE->bias->shape[1]}; m->v_t_dW[index] = zeros(dims_dW); m->v_t_db[index] = zeros(dims_db); index++; } else if(flag==4 && temp->type!=LOSS){ int dims_dW[] = {temp->DENSE->weights->shape[0],temp->DENSE->weights->shape[1]}; int dims_db[] = {temp->DENSE->bias->shape[0],temp->DENSE->bias->shape[1]}; m->m_t_dW[index] = zeros(dims_dW); m->m_t_db[index] = zeros(dims_db); index++; } temp = temp->next_layer; } m->current_layer = m->graph; } void __forward__(){ Computation_Graph * temp = m->graph; while(temp!=NULL){ m->current_layer = temp; if(temp->type==INPUT) temp->INPUT->forward(); else if(temp->type==DENSE) temp->DENSE->forward(); else if(temp->type==LOSS) temp->LOSS->forward(); temp = temp->next_layer; } } void __backward__(){ Computation_Graph * temp = m->current_layer; while(temp->prev_layer!=NULL){ m->current_layer = temp; if(temp->type==INPUT) temp->INPUT->backward(); else if(temp->type==DENSE) temp->DENSE->backward(); else if(temp->type==LOSS) temp->LOSS->backward(); temp = temp->prev_layer; } } float calculate_accuracy(dARRAY * predicted, dARRAY * gnd_truth){ int success = 0; dARRAY * temp = (dARRAY*)malloc(sizeof(dARRAY)); temp->matrix = (float*)calloc(predicted->shape[0]*predicted->shape[1],sizeof(float)); for(int i = 0;i<predicted->shape[0]*predicted->shape[1];i++){ temp->matrix[i] = predicted->matrix[i]<0.5 ? 0 : 1; } temp->shape[0] = predicted->shape[0]; temp->shape[1] = predicted->shape[1]; for(int i = 0;i<predicted->shape[0]*predicted->shape[1];i++){ if(temp->matrix[i]==gnd_truth->matrix[i]) success++; } if(predicted->shape[0]!=1) success = success/predicted->shape[0]; free2d(temp); temp = NULL; return success/(float)predicted->shape[1]; } dARRAY * relu_val(dARRAY * linear_matrix){ dARRAY * relu_outf = NULL; relu_outf = (dARRAY*)malloc(sizeof(dARRAY)); relu_outf->matrix = (float*)calloc(linear_matrix->shape[0]*linear_matrix->shape[1],sizeof(float)); #pragma omp parallel for num_threads(8) shared(relu_outf,linear_matrix) for(int i=0;i<linear_matrix->shape[0]*linear_matrix->shape[1];i++) relu_outf->matrix[i] = linear_matrix->matrix[i]>(float)0.0 ?(float)linear_matrix->matrix[i] : (float)0.0; relu_outf->shape[0] = linear_matrix->shape[0]; relu_outf->shape[1] = linear_matrix->shape[1]; return relu_outf; } dARRAY * sigmoid_val(dARRAY * linear_matrix){ dARRAY * sigmoid_outf = NULL; sigmoid_outf = (dARRAY*)malloc(sizeof(dARRAY)); sigmoid_outf->matrix = (float*)calloc(linear_matrix->shape[0]*linear_matrix->shape[1],sizeof(float)); #pragma omp parallel for num_threads(8) shared(sigmoid_outf,linear_matrix) for(int i=0;i<linear_matrix->shape[0]*linear_matrix->shape[1];i++) sigmoid_outf->matrix[i] = (float)(1.0/(float)(1+exp((float)(-1.0*linear_matrix->matrix[i])))); sigmoid_outf->shape[0] = linear_matrix->shape[0]; sigmoid_outf->shape[1] = linear_matrix->shape[1]; return sigmoid_outf; } dARRAY * tanh_val(dARRAY * linear_matrix){ dARRAY * tanh_out = (dARRAY*)malloc(sizeof(dARRAY)); tanh_out->matrix = (float*)calloc(linear_matrix->shape[0]*linear_matrix->shape[1],sizeof(float)); #pragma omp parallel for num_threads(8) shared(tanh_out,linear_matrix) for(int i=0;i<linear_matrix->shape[0]*linear_matrix->shape[1];i++){ float exp_res1 = exp(linear_matrix->matrix[i]); float exp_res2 = exp(-1*linear_matrix->matrix[i]); tanh_out->matrix[i] = (exp_res1 - exp_res2)/(exp_res1 + exp_res2); } tanh_out->shape[0] = linear_matrix->shape[0]; tanh_out->shape[1] = linear_matrix->shape[1]; return tanh_out; } dARRAY * softmax_val(dARRAY * linear_matrix){ dARRAY * softmax_outf = NULL; dARRAY * exp_sub_max = exponentional(linear_matrix); dARRAY * div_factor = sum(exp_sub_max,0); softmax_outf = divison(exp_sub_max,div_factor); free2d(exp_sub_max); free2d(div_factor); exp_sub_max = div_factor = NULL; return softmax_outf; } dARRAY * calculate_val_test_acc(dARRAY * input_features,dARRAY * gnd_truth){ dARRAY * weight_input_res = NULL; dARRAY * output = NULL; dARRAY * activation_temp = NULL; Computation_Graph * temp = m->graph->next_layer; int layer=0; while(temp->type!=LOSS){ if(temp->prev_layer->type==INPUT){ weight_input_res = dot(temp->DENSE->weights, input_features); } else{ weight_input_res = dot(temp->DENSE->weights, activation_temp); } if(activation_temp!=NULL){ free2d(activation_temp); activation_temp = NULL; } dARRAY * Z = add(weight_input_res,temp->DENSE->bias); free2d(weight_input_res); weight_input_res = NULL; if(!strcasecmp(temp->DENSE->activation,"relu")){ activation_temp = relu_val(Z); free2d(Z); } else if(!strcasecmp(temp->DENSE->activation,"sigmoid")){ activation_temp = sigmoid_val(Z); free2d(Z); } else if(!strcasecmp(temp->DENSE->activation,"tanh")){ activation_temp = tanh_val(Z); free2d(Z); } else if(!strcasecmp(temp->DENSE->activation,"softmax")){ activation_temp = softmax_val(Z); free2d(Z); } else{ activation_temp = Z; } if(temp->next_layer->type==LOSS){ output = activation_temp; Z = NULL; } layer++; temp = temp->next_layer; Z = NULL; } if(m->predicting) return output; else{ float acc = calculate_accuracy(output,gnd_truth); if(m->testing) printf("Accuracy : %f\n",acc); free2d(output); output = NULL; dARRAY * return_val = (dARRAY*)malloc(sizeof(dARRAY)); return_val->matrix = (float*)calloc(1,sizeof(float)); return_val->matrix[0] = acc; return_val->shape[0] = 1; return_val->shape[1] = 1; if(m->testing) printf("Accuracy : %f\n",return_val->matrix[0]); return return_val; } } void dump_to_file(float * arr ,char * filename,char * mode){ struct stat st = {0}; if (stat("./bin/", &st) == -1) { mkdir("./bin/", 0700); } FILE * fp = NULL; fp = fopen(filename,mode); if(fp==NULL){ printf("\033[1;31mFile Error : \033[93mCould not open %s file!\033[0m\n",filename); exit(EXIT_FAILURE); } for(int i=0;i<m->num_iter*m->num_mini_batches;i++) fprintf(fp,"%f ",arr[i]); fclose(fp); } void __fit__(){ int i = 1; int index = 0; int iterations=0; int flag_cost = 0; float sum_cost = m->train_cost*m->current_iter; float sum_train_acc = m->train_accuracy*m->current_iter; float sum_train_val_acc = m->cross_val_accuracy*m->current_iter; float * train_cost_arr = (float*)calloc(m->num_iter==-1?1000000:m->num_iter*m->num_mini_batches,sizeof(float)); float * train_acc_arr = (float*)calloc(m->num_iter==-1?1000000:m->num_iter*m->num_mini_batches,sizeof(float)); float * val_acc_arr = NULL; if(m->Y_cv!=NULL && m->x_cv!=NULL){ val_acc_arr = (float*)calloc(m->num_iter==-1?1000000:m->num_iter*m->num_mini_batches,sizeof(float)); } if(m->num_iter==-1){ iterations = i; } else iterations = m->num_iter; signal(SIGINT,early_stopping_handler); while(i<=iterations){ flag_cost=0; int * shuffle = permutation(m->num_mini_batches); for(int mini_batch=0;mini_batch<m->num_mini_batches;mini_batch++){ m->current_mini_batch = shuffle[mini_batch]; __forward__(); sum_cost += m->iter_cost; sum_train_acc += calculate_accuracy(m->output,m->y_train_mini_batch[m->current_mini_batch]); dARRAY * temp = NULL; if(m->Y_cv!=NULL && m->x_cv!=NULL){ temp = calculate_val_test_acc(m->x_cv,m->Y_cv); sum_train_val_acc += temp->matrix[0]; } if(m->print_cost){ m->train_cost = i==m->current_iter ? sum_cost/(float)i : sum_cost/(float)m->current_iter; m->train_accuracy = i==m->current_iter ? sum_train_acc/(float)i : sum_train_acc/(float)m->current_iter; train_cost_arr[index] = m->train_cost; train_acc_arr[index] = m->train_accuracy; if(m->Y_cv!=NULL && m->x_cv!=NULL){ m->cross_val_accuracy = i==m->current_iter ? sum_train_val_acc/(float)i : sum_train_val_acc/(float)m->current_iter; val_acc_arr[index] = m->cross_val_accuracy; } printf("\033[96m%d. %d. Cost : \033[0m%f ",i,mini_batch,m->train_cost); printf("\033[96m train_acc : \033[0m%f ",m->train_accuracy); if(m->Y_cv!=NULL && m->x_cv!=NULL){ printf("\033[96m val_acc : \033[0m%f",m->cross_val_accuracy); } printf("\n"); if(train_cost_arr[index]>=2.5*train_cost_arr[0]){ printf("\033[96mCost is exploding hence exiting. Try reducing your learning rate and try again!\033[0m\n"); exit(EXIT_FAILURE); } index++; } __backward__(); if(!strcasecmp(m->optimizer,"adam")){ m->time_step += 1; adam(); } else if(!strcasecmp(m->optimizer,"rmsprop")){ RMSProp(); } else if(!strcasecmp(m->optimizer,"adagrad")){ adagrad(); } else if(!strcasecmp(m->optimizer,"sgd")){ SGD(); } else if(!strcasecmp(m->optimizer,"momentum")){ Momentum(); } else{ printf("Optimizer selected is not available\n"); exit(EXIT_FAILURE); } m->current_iter += 1; free(temp); temp = NULL; } if(m->ckpt_every!=-1 && (i%m->ckpt_every==0 || (i==m->num_iter && m->num_iter!=-1))){ time_t rawtime; struct tm * timeinfo; time ( &rawtime ); timeinfo = localtime ( &rawtime ); char buffer[1024]; snprintf(buffer,sizeof(buffer),"model_%d_%s.t7",i,asctime (timeinfo)); __save_model__(buffer); if(flag_cost==0){ dump_to_file(train_cost_arr,"./bin/cost.data","ab+"); dump_to_file(train_acc_arr,"./bin/train_acc.data","ab+"); if(m->x_cv!=NULL || m->Y_cv!=NULL) dump_to_file(val_acc_arr,"./bin/val_acc.data","wb+"); flag_cost=1; } } if(!flag_cost){ dump_to_file(train_cost_arr,"./bin/cost.data","ab+"); dump_to_file(train_acc_arr,"./bin/train_acc.data","ab+"); if(m->x_cv!=NULL || m->Y_cv!=NULL) dump_to_file(val_acc_arr,"./bin/val_acc.data","wb+"); } i++; if(m->num_iter==-1) iterations = i; free(shuffle); shuffle=NULL; } if(flag_cost==0){ dump_to_file(train_cost_arr,"./bin/cost.data","wb+"); dump_to_file(train_acc_arr,"./bin/train_acc.data","wb+"); if(m->x_cv!=NULL || m->Y_cv!=NULL) dump_to_file(val_acc_arr,"./bin/val_acc.data","wb+"); flag_cost=1; } } /** * Function that is used to initiate model training. */ void Fit(){ __fit__(); } void early_stopping_handler(){ printf("\nModel Saved!\n"); time_t rawtime; struct tm * timeinfo; time ( &rawtime ); timeinfo = localtime ( &rawtime ); char buffer[1024]; snprintf(buffer,sizeof(buffer),"model_%s.t7",asctime (timeinfo)); __save_model__(buffer); Destroy_Model(); exit(EXIT_SUCCESS); } dARRAY * __predict__(dARRAY * input_feature,int verbose){ m->graph->INPUT->A = input_feature; m->predicting = 1; dARRAY * prediction = calculate_val_test_acc(input_feature,NULL); dARRAY * prediction_trans = transpose(prediction); if(verbose){ printf("["); for(int i = 0;i<prediction_trans->shape[0];i++){ for(int j=0;j<prediction_trans->shape[1];j++){ if(j<prediction_trans->shape[1]-1) printf("%f, ",prediction_trans->matrix[i*prediction_trans->shape[1]+j]); else printf("%f",prediction_trans->matrix[i*prediction_trans->shape[1]+j]); } } printf("]\n"); } free2d(prediction); m->predicting=0; return prediction_trans; } /**! * Function that is used to test your model on arbitrary input_features. * @param input_feature Features to be passed to your model. * @param verbose Specifies whether or not to print the classification scores (verbose=1 or verbose=0) * @return Returns a dARRAY pointing to the output values of the model. */ dARRAY * Predict(dARRAY * input_feature,int verbose){ return __predict__(input_feature,verbose); } void __test__(){ if(m->x_test==NULL || m->Y_test==NULL){ printf("\033[1;31mDataset Error : \033[93mTest set has not been provided.\033[0m\n"); return; } dARRAY * acc = calculate_val_test_acc(m->x_test,m->Y_test); printf("\033[96mTest Accuracy : \033[0m%f\n",acc->matrix[0]); free2d(acc); acc = NULL; } /** * Function that is used to test your model against your test set. */ void Test(){ __test__(); } void __load_model__(char * filename){ if(strstr(filename,".t7")==NULL){ printf("\033[1;31mFileExtension Error : \033[93mPlease use \".t7\" extension only. Other extensions are not supported currently.\033[0m\n"); exit(EXIT_FAILURE); } dARRAY weights[m->number_of_layers-1]; dARRAY biases[m->number_of_layers-1]; Computation_Graph * temp = m->graph->next_layer; for(int i=0;i<m->number_of_layers-1 && temp!=NULL;i++){ weights[i].matrix = (float*)calloc(temp->DENSE->weights->shape[0]*temp->DENSE->weights->shape[1],sizeof(float)); biases[i].matrix = (float*)calloc(temp->DENSE->bias->shape[0]*temp->DENSE->bias->shape[1],sizeof(float)); temp = temp->next_layer; } temp = m->graph->next_layer; FILE * fp = NULL; fp = fopen(filename,"rb"); if(fp==NULL){ printf("\033[1;31mFile Error : \033[93mCould not open %s file!\033[0m\n",filename); exit(EXIT_FAILURE); } for(int i=0;i<m->number_of_layers-1;i++){ if(temp==NULL) printf("null\n"); for(int j=0;j<temp->DENSE->weights->shape[0]*temp->DENSE->weights->shape[1];j++){ fscanf(fp,"%f ",&weights[i].matrix[j]); } weights[i].shape[0] = temp->DENSE->weights->shape[0]; weights[i].shape[1] = temp->DENSE->weights->shape[1]; temp = temp->next_layer; } temp = m->graph->next_layer; for(int i=0;i<m->number_of_layers-1;i++){ for(int j=0;j<temp->DENSE->bias->shape[0]*temp->DENSE->bias->shape[1];j++){ fscanf(fp,"%f ",&biases[i].matrix[j]); } biases[i].shape[0] = temp->DENSE->bias->shape[0]; biases[i].shape[1] = temp->DENSE->bias->shape[1]; temp = temp->next_layer; } fscanf(fp,"%f ",&m->train_cost); fscanf(fp,"%f ",&m->train_accuracy); fscanf(fp,"%f ",&m->cross_val_accuracy); fscanf(fp,"%d ",&m->current_iter); fclose(fp); temp = m->graph->next_layer; int index = 0; while(temp!=NULL){ if(temp->DENSE->weights!=NULL) free2d(temp->DENSE->weights); if(temp->DENSE->bias!=NULL) free2d(temp->DENSE->bias); temp->DENSE->weights = NULL; temp->DENSE->bias = NULL; temp->DENSE->weights = (dARRAY*)malloc(sizeof(dARRAY)); temp->DENSE->weights->matrix = (float*)calloc(weights[index].shape[0]*weights[index].shape[1],sizeof(float)); temp->DENSE->bias = (dARRAY*)malloc(sizeof(dARRAY)); temp->DENSE->bias->matrix = (float*)calloc(biases[index].shape[0]*biases[index].shape[1],sizeof(float)); temp->DENSE->weights->matrix = weights[index].matrix; temp->DENSE->weights->shape[0] = weights[index].shape[0]; temp->DENSE->weights->shape[1] = weights[index].shape[1]; temp->DENSE->bias->matrix = biases[index].matrix; temp->DENSE->bias->shape[0] = biases[index].shape[0]; temp->DENSE->bias->shape[1] = biases[index].shape[1]; index++; temp = temp->next_layer; } temp = NULL; } /**! * Function that is used to load a model. * @param filename Name of the file where the model resides. */ void Load_Model(char * filename){ __load_model__(filename); } void __save_model__(char * filename){ if(strstr(filename,".t7")==NULL){ printf("\033[1;31mFileExtension Error : \033[93m%s uses a different extension. Please use \".t7\" extension only. Other extensions are not supported currently.\033[0m\n",filename); exit(EXIT_FAILURE); } FILE * fp = NULL; if( access(filename,F_OK)==0) { if(remove(filename)==0){} } fp = fopen(filename,"wb+"); if(fp==NULL){ printf("\033[1;31mFile Error : \033[93mCould not open %s file!\033[0m\n",filename); exit(EXIT_FAILURE); } Computation_Graph * temp = m->graph->next_layer; for(int i=0;i<m->number_of_layers-1;i++){ for(int j=0;j<temp->DENSE->weights->shape[0]*temp->DENSE->weights->shape[1];j++) fprintf(fp,"%f ",temp->DENSE->weights->matrix[j]); temp = temp->next_layer; } temp = m->graph->next_layer; for(int i=0;i<m->number_of_layers-1;i++){ for(int j=0;j<temp->DENSE->bias->shape[0]*temp->DENSE->bias->shape[1];j++) fprintf(fp,"%f ",temp->DENSE->bias->matrix[j]); temp = temp->next_layer; } fprintf(fp,"%f ",m->train_cost); fprintf(fp,"%f ",m->train_accuracy); fprintf(fp,"%f ",m->cross_val_accuracy); fprintf(fp,"%d ",m->current_iter-1); fclose(fp); fp = NULL; } /**! * Function that is used to save a model. * @param filename Name of the file where the model will be saved. */ void Save_Model(char * filename){ __save_model__(filename); } /**! * Function that is used to load X_train from file. * @param filename Name of the file where the X_train resides. * @param dims Dimensions of your training set (Features,Number of examples) */ dARRAY * load_x_train(char * filename,int * dims){ FILE * fp = NULL; fp = fopen(filename,"rb"); if(fp==NULL){ printf("\033[1;31mFile Error : \033[93mCould not open %s file!\033[0m\n",filename); exit(EXIT_FAILURE); } dARRAY * x_train = (dARRAY*)malloc(sizeof(dARRAY)); x_train->matrix = (float*)calloc(dims[0]*dims[1],sizeof(float)); progressbar * progress = progressbar_new("\033[1;32mLoading X_train :\033[0m",dims[1]); for(int j=0;j<dims[0]*dims[1];j++){ fscanf(fp,"%f ",&x_train->matrix[j]); if(j%dims[0]==0) progressbar_inc(progress); } progressbar_finish(progress); x_train->shape[0] = dims[1]; x_train->shape[1] = dims[0]; dARRAY * X_train = transpose(x_train); free2d(x_train); x_train = NULL; fclose(fp); return X_train; } /**! * Function that is used to load y_train from file. * @param filename Name of the file where the y_train resides. * @param dims Dimensions of your training set (Number of classes,Number of examples) */ dARRAY * load_y_train(char * filename,int * dims){ FILE * fp = NULL; fp = fopen(filename,"rb"); if(fp==NULL){ printf("\033[1;31mFile Error : \033[93mCould not open %s file!\033[0m\n",filename); exit(EXIT_FAILURE); } dARRAY * Y_train = (dARRAY*)malloc(sizeof(dARRAY)); Y_train->matrix = (float*)calloc(dims[0]*dims[1],sizeof(float)); progressbar * progress = progressbar_new("\033[1;32mLoading y_train :\033[0m",dims[1]); for(int j=0;j<dims[0]*dims[1];j++){ fscanf(fp,"%f ",&Y_train->matrix[j]); if(j%dims[0]==0) progressbar_inc(progress); } progressbar_finish(progress); Y_train->shape[0] = dims[1]; Y_train->shape[1] = dims[0]; dARRAY * y_train = transpose(Y_train); free2d(Y_train); Y_train = NULL; fclose(fp); return y_train; } /**! * Function that is used to load X_cv from file. * @param filename Name of the file where the X_cv resides. * @param dims Dimensions of your validation set (Features,Number of examples) */ dARRAY * load_x_cv(char * filename,int * dims){ FILE * fp = NULL; fp = fopen(filename,"rb"); if(fp==NULL){ printf("\033[1;31mFile Error : \033[93mCould not open %s file!\033[0m\n",filename); exit(EXIT_FAILURE); } dARRAY * x_cv = (dARRAY*)malloc(sizeof(dARRAY)); x_cv->matrix = (float*)calloc(dims[0]*dims[1],sizeof(float)); progressbar * progress = progressbar_new("\033[1;32mLoading X_cv :\033[0m",dims[1]); for(int j=0;j<dims[0]*dims[1];j++){ fscanf(fp,"%f ",&x_cv->matrix[j]); if(j%dims[0]==0) progressbar_inc(progress); } progressbar_finish(progress); x_cv->shape[0] = dims[1]; x_cv->shape[1] = dims[0]; dARRAY * X_CV = transpose(x_cv); free2d(x_cv); x_cv = NULL; fclose(fp); return X_CV; } /**! * Function that is used to load y_cv from file. * @param filename Name of the file where the y_cv resides. * @param dims Dimensions of your validation set (Number of classes,Number of examples) */ dARRAY * load_y_cv(char * filename,int * dims){ FILE * fp = NULL; fp = fopen(filename,"rb"); if(fp==NULL){ printf("\033[1;31mFile Error : \033[93mCould not open %s file!\033[0m\n",filename); exit(EXIT_FAILURE); } dARRAY * Y_cv = (dARRAY*)malloc(sizeof(dARRAY)); Y_cv->matrix = (float*)calloc(dims[0]*dims[1],sizeof(float)); progressbar * progress = progressbar_new("\033[1;32mLoading y_cv :\033[0m",dims[1]); for(int j=0;j<dims[0]*dims[1];j++){ fscanf(fp,"%f ",&Y_cv->matrix[j]); if(j%dims[0]==0) progressbar_inc(progress); } progressbar_finish(progress); Y_cv->shape[0] = dims[1]; Y_cv->shape[1] = dims[0]; dARRAY * y_cv = transpose(Y_cv); free2d(Y_cv); Y_cv = NULL; fclose(fp); return y_cv; } /**! * Function that is used to load X_test from file. * @param filename Name of the file where the X_test resides. * @param dims Dimensions of your test set (Features,Number of examples) */ dARRAY * load_x_test(char * filename,int * dims){ FILE * fp = NULL; fp = fopen(filename,"rb"); if(fp==NULL){ printf("\033[1;31mFile Error : \033[93m Could not open %s file!\033[0m\n",filename); exit(EXIT_FAILURE); } dARRAY * x_test_temp = (dARRAY*)malloc(sizeof(dARRAY)); x_test_temp->matrix = (float*)calloc(dims[0]*dims[1],sizeof(float)); progressbar * progress = progressbar_new("\033[1;32mLoading X_test :\033[0m",dims[1]); for(int j=0;j<dims[0]*dims[1];j++){ fscanf(fp,"%f ",&x_test_temp->matrix[j]); if(j%dims[0]==0) progressbar_inc(progress); } progressbar_finish(progress); x_test_temp->shape[0] = dims[1]; x_test_temp->shape[1] = dims[0]; dARRAY * x_test = transpose(x_test_temp); free2d(x_test_temp); x_test_temp = NULL; fclose(fp); return x_test; } /**! * Function that is used to load y_test from file. * @param filename Name of the file where the y_test resides. * @param dims Dimensions of your test set (Number of classes,Number of examples) */ dARRAY * load_y_test(char * filename,int * dims){ FILE * fp = NULL; fp = fopen(filename,"rb"); if(fp==NULL){ printf("\033[1;31mFile Error : \033[93mCould not open %s file!\033[0m\n",filename); exit(EXIT_FAILURE); } dARRAY * Y_test = (dARRAY*)malloc(sizeof(dARRAY)); Y_test->matrix = (float*)calloc(dims[0]*dims[1],sizeof(float)); progressbar * progress = progressbar_new("\033[1;32mLoading y_test :\033[0m",dims[1]); for(int j=0;j<dims[0]*dims[1];j++){ fscanf(fp,"%f ",&Y_test->matrix[j]); if(j%dims[0]==0) progressbar_inc(progress); } progressbar_finish(progress); Y_test->shape[0] = dims[1]; Y_test->shape[1] = dims[0]; dARRAY * y_test = transpose(Y_test); free2d(Y_test); Y_test = NULL; fclose(fp); return y_test; } dARRAY * load_image(char * filename,int * dims){ FILE * fp = NULL; fp = fopen(filename,"rb"); if(fp==NULL){ printf("\033[1;31mFile Error : \033[93m Could not open %s file!\033[0m\n",filename); exit(EXIT_FAILURE); } dARRAY * image = (dARRAY*)malloc(sizeof(dARRAY)); image->matrix = (float*)calloc(dims[0]*dims[1],sizeof(float)); for(int j=0;j<dims[0]*dims[1];j++){ fscanf(fp,"%f ",&image->matrix[j]); } image->shape[0] = dims[0]; image->shape[1] = dims[1]; fclose(fp); fp=NULL; return image; } void create_mini_batches(){ if(m->x_train->shape[1]!=m->Y_train->shape[1]){ printf("\033[1;31mShape Error : \033[93mNumber of examples in X_train[%d,\033[1;31m%d\033[93m] != Y_train[%d,\033[1;31m%d\033[93m]!\033[0m\n",m->x_train->shape[0],m->x_train->shape[1],m->Y_train->shape[0],m->Y_train->shape[1]); exit(EXIT_FAILURE); } if(m->mini_batch_size>m->Y_train->shape[1]){ printf("\033[1;31mMini Batch Error : \033[93mNumber of examples in train_set is less than the mini_batch_size specified!\033[1;31m [examples:%d < mini_batch_size: %d]\033[93m\nPlease make sure that the mini batch size is less than or equal to the number of examples in train_set.\033[0m\n",m->x_train->shape[1],m->mini_batch_size); exit(EXIT_FAILURE); } if(m->x_train->shape[1]==0 || m->Y_train->shape[1]==0){ printf("\033[1;31mShape Error : \033[93mDataset Empty!\033m[0m\n"); exit(EXIT_FAILURE); } int num_mini_batches = (m->x_train->shape[1]%m->mini_batch_size==0)?\ m->x_train->shape[1]/m->mini_batch_size :\ (int)floor(m->x_train->shape[1]/m->mini_batch_size) + 1; m->x_train_mini_batch = (dARRAY**)malloc(sizeof(dARRAY*)*num_mini_batches); m->y_train_mini_batch = (dARRAY**)malloc(sizeof(dARRAY*)*num_mini_batches); m->num_mini_batches = num_mini_batches; int remaining_mem_block = (m->x_train->shape[1]-((num_mini_batches-1)*m->mini_batch_size)); for(int i=0;i<num_mini_batches;i++){ m->x_train_mini_batch[i] = NULL; m->y_train_mini_batch[i] = NULL; } dARRAY * X_train = transpose(m->x_train); dARRAY * Y_train = transpose(m->Y_train); free2d(m->x_train); free2d(m->Y_train); m->x_train = NULL; m->Y_train = NULL; progressbar * progress = progressbar_new("\033[1;32mCreating Mini Batches :\033[0m",num_mini_batches*2); for(int i=0;i<num_mini_batches;i++){ int row = 0; dARRAY * temp = (dARRAY*)malloc(sizeof(dARRAY)); temp->matrix = (float*)calloc(m->mini_batch_size*X_train->shape[1],sizeof(float)); if(i<num_mini_batches-1 || num_mini_batches==1){ temp->shape[0] = m->mini_batch_size; temp->shape[1] = X_train->shape[1]; for(int j=i*m->mini_batch_size;j<(i+1)*m->mini_batch_size && j<X_train->shape[0];j++){ for(int k = 0;k<X_train->shape[1];k++){ temp->matrix[row*X_train->shape[1]+k] = X_train->matrix[j*X_train->shape[1]+k]; } row++; } } else{ temp->shape[0] = remaining_mem_block; temp->shape[1] = X_train->shape[1]; for(int j=i*m->mini_batch_size;j<X_train->shape[0] && j<X_train->shape[0];j++){ for(int k = 0;k<X_train->shape[1];k++){ temp->matrix[row*X_train->shape[1]+k] = X_train->matrix[j*X_train->shape[1]+k]; } row++; } } m->x_train_mini_batch[i] = transpose(temp); free2d(temp); temp = NULL; progressbar_inc(progress); } for(int i=0;i<num_mini_batches;i++){ int row = 0; dARRAY * temp = (dARRAY*)malloc(sizeof(dARRAY)); temp->matrix = (float*)calloc(m->mini_batch_size*Y_train->shape[1],sizeof(float)); if(i<num_mini_batches-1 || num_mini_batches==1){ temp->shape[0] = m->mini_batch_size; temp->shape[1] = Y_train->shape[1]; for(int j=i*m->mini_batch_size;j<(i+1)*m->mini_batch_size && j<Y_train->shape[0];j++){ for(int k = 0;k<Y_train->shape[1];k++){ temp->matrix[row*Y_train->shape[1]+k] = Y_train->matrix[j*Y_train->shape[1]+k]; } row++; } } else{ temp->shape[0] = remaining_mem_block; temp->shape[1] = Y_train->shape[1]; for(int j=i*m->mini_batch_size;j<Y_train->shape[0] && j<Y_train->shape[0];j++){ for(int k = 0;k<Y_train->shape[1];k++){ temp->matrix[row*Y_train->shape[1]+k] = Y_train->matrix[j*Y_train->shape[1]+k]; } row++; } } m->y_train_mini_batch[i] = transpose(temp); free2d(temp); temp = NULL; progressbar_inc(progress); } progressbar_finish(progress); } void __summary__(){} long int get_total_params(){ long int total_params = 0; Computation_Graph * temp = m->graph->next_layer; while(temp!=NULL){ if(temp->type==DENSE){ total_params+= temp->DENSE->weights->shape[0]*temp->DENSE->weights->shape[1]; total_params+= temp->DENSE->bias->shape[0]*temp->DENSE->bias->shape[1]; } temp = temp->next_layer; } return total_params; } void (Create_Model)(){ m = NULL; m = (__Model__*)malloc(sizeof(__Model__)); m->graph = NULL; m->graph = NULL; m->current_layer = NULL; m->number_of_layers = 0; m->input_size = 0; m->output_size = 0; } void segfault_handler(){ exit(EXIT_SUCCESS); } void (Destroy_Model)(){ signal(SIGSEGV,segfault_handler); destroy_Graph(m->graph); if(m->x_cv!=NULL) free2d(m->x_cv); if(m->Y_cv!=NULL) free2d(m->Y_cv); if(m->x_test!=NULL) free2d(m->x_test); if(m->Y_test!=NULL) free2d(m->Y_test); for(int i=0;i<m->number_of_layers;i++){ if(m->m_t_dW[i] != NULL) free2d(m->m_t_dW[i]); if(m->m_t_db[i] != NULL) free2d(m->m_t_db[i]); if(m->v_t_dW[i] != NULL) free2d(m->v_t_dW[i]); if(m->v_t_db[i] != NULL) free2d(m->v_t_db[i]); if(m->cache_dW[i] != NULL) free2d(m->cache_dW[i]); if(m->cache_db[i] != NULL) free2d(m->cache_db[i]); m->m_t_dW[i] = NULL; m->v_t_dW[i] = NULL; m->m_t_db[i] = NULL; m->v_t_db[i] = NULL; m->cache_dW[i] = NULL; m->cache_db[i] = NULL; } for(int i=0;i<m->num_mini_batches;i++){ if(m->x_train_mini_batch[i]!=NULL) free2d(m->x_train_mini_batch[i]); if(m->y_train_mini_batch[i]!=NULL) free2d(m->y_train_mini_batch[i]); m->x_train_mini_batch[i] = NULL; m->y_train_mini_batch[i] = NULL; } free(m->x_train_mini_batch); free(m->y_train_mini_batch); m->x_train_mini_batch = NULL; m->y_train_mini_batch = NULL; m->x_train = NULL; m->Y_train = NULL; m->x_cv = NULL; m->x_test = NULL; m->Y_test = NULL; m->Y_cv = NULL; m->output = NULL; free(m); m = NULL; } void dump_image(dARRAY * images,char * filename){ FILE * fp = NULL; fp = fopen(filename,"a+"); if(fp==NULL){ exit(EXIT_FAILURE); } else{ dARRAY * temp = transpose(images); for(int i=0;i<temp->shape[0];i++){ for(int j=0;j<temp->shape[1];j++){ fprintf(fp,"%lf ",temp->matrix[i*temp->shape[1]+j]); } } free2d(temp); temp = NULL; } } void (Model)(Model_args model_args){ get_safe_nn_threads(); if(model_args.X_train==NULL || model_args.y_train==NULL){ printf("\033[1;31mDataset Error : \033[93mNo dataset passed to the model constructor.\033[0m\n"); exit(EXIT_FAILURE); } m->x_train = model_args.X_train; m->x_test = model_args.X_test; m->x_cv = model_args.X_cv; m->Y_train = model_args.y_train; m->Y_test = model_args.y_test; m->Y_cv = model_args.y_cv; m->ckpt_every = model_args.checkpoint_every; //initialize regualrization hyperparameters m->loss = model_args.loss; m->lambda = model_args.weight_decay; m->regularization = model_args.regularization; m->num_of_training_examples = m->x_train->shape[1]; //initialize hyperparameters for various optimizers m->optimizer = model_args.optimizer; // Optimizer choice m->learning_rate = model_args.lr; // hyperparameter for step size for optimization algorithm m->time_step = 0; // timestep - required for Adam update, for bias correction m->beta = model_args.beta; //hyperparameter - used for RMSProp, Denotes Decay_rate for weighted average m->beta1 = model_args.beta1; // hyperparameter - used for Adam and RMSProp, Decay rate for estimation of first moment m->beta2 = model_args.beta2; // hyperparameter - used for Adam, Decay rate used for estimation of second moment. m->epsilon = 1e-8; // small value to prevent divison by zero during parameter updates for(int i=0;i<m->number_of_layers;i++){ m->m_t_dW[i] = NULL; // for Adam and RMSProp - to calculate first moment m->v_t_dW[i] = NULL; // for Adam - to calculate second moment m->m_t_db[i] = NULL; m->v_t_db[i] = NULL; m->cache_dW[i] = NULL; // for AdaGrad m->cache_db[i] = NULL; } m->mini_batch_size = model_args.batch_size; m->num_iter = model_args.epochs; create_mini_batches(); if(!strcasecmp(m->loss,"cross_entropy_loss")) cross_entropy_loss(); if(!strcasecmp(m->loss,"MSELoss")) MSELoss(); m->input_size = m->x_train_mini_batch[0]->shape[0]; m->print_cost = model_args.print_cost; m->init = __init__; m->forward = __forward__; m->backward = __backward__; m->load_model = __load_model__; m->save_model = __save_model__; m->fit = __fit__; // m->predict = __predict__; m->summary = __summary__; m->test = __test__; m->init(); m->total_parameters = get_total_params(); }

v_p_strategy.h

// // Project Name: KratosPFEMFluidDynamicsApplication $ // Last modified by: $Author: AFranci $ // Date: $Date: January 2016 $ // Revision: $Revision: 0.0 $ // // #ifndef KRATOS_V_P_STRATEGY_H #define KRATOS_V_P_STRATEGY_H #include "includes/define.h" #include "includes/model_part.h" #include "includes/deprecated_variables.h" #include "utilities/openmp_utils.h" #include "processes/process.h" #include "solving_strategies/schemes/scheme.h" #include "solving_strategies/strategies/solving_strategy.h" #include "custom_utilities/mesher_utilities.hpp" #include "custom_utilities/boundary_normals_calculation_utilities.hpp" #include "custom_utilities/solver_settings.h" #include "pfem_fluid_dynamics_application_variables.h" #include <stdio.h> #include <math.h> namespace Kratos { ///@addtogroup PFEMFluidDynamicsApplication ///@{ ///@name Kratos Globals ///@{ ///@} ///@name Type Definitions ///@{ ///@} ///@name Enum's ///@{ ///@} ///@name Functions ///@{ ///@} ///@name Kratos Classes ///@{ template <class TSparseSpace, class TDenseSpace, class TLinearSolver> class VPStrategy : public SolvingStrategy<TSparseSpace, TDenseSpace> { public: ///@name Type Definitions ///@{ KRATOS_CLASS_POINTER_DEFINITION(VPStrategy); typedef SolvingStrategy<TSparseSpace, TDenseSpace> BaseType; typedef TwoStepVPSolverSettings<TSparseSpace, TDenseSpace, TLinearSolver> SolverSettingsType; ///@} ///@name Life Cycle ///@{ VPStrategy(ModelPart &rModelPart, SolverSettingsType &rSolverConfig) : BaseType(rModelPart) { std::cout << "VPStrategy INITIALIZE STRATEGY" << std::endl; InitializeStrategy(rSolverConfig); } VPStrategy(ModelPart &rModelPart, typename TLinearSolver::Pointer pVelocityLinearSolver, typename TLinearSolver::Pointer pPressureLinearSolver, bool ReformDofSet = true, unsigned int DomainSize = 2) : BaseType(rModelPart) { KRATOS_TRY; KRATOS_CATCH(""); } /// Destructor. virtual ~VPStrategy() {} virtual int Check() override { return false; } virtual bool SolveSolutionStep() override { return false; } virtual void FinalizeSolutionStep() override {} virtual void InitializeSolutionStep() override {} void UpdateTopology(ModelPart &rModelPart, unsigned int echoLevel) { KRATOS_TRY; this->CalculateDisplacementsAndPorosity(); BaseType::MoveMesh(); KRATOS_CATCH(""); } void SetBlockedAndIsolatedFlags() { KRATOS_TRY; ModelPart &rModelPart = BaseType::GetModelPart(); const unsigned int dimension = rModelPart.ElementsBegin()->GetGeometry().WorkingSpaceDimension(); #pragma omp parallel { ModelPart::ElementIterator ElemBegin; ModelPart::ElementIterator ElemEnd; OpenMPUtils::PartitionedIterators(rModelPart.Elements(), ElemBegin, ElemEnd); for (ModelPart::ElementIterator itElem = ElemBegin; itElem != ElemEnd; ++itElem) { unsigned int numNodes = itElem->GetGeometry().size(); std::vector<array_1d<double, 3>> nodesCoordinates; nodesCoordinates.resize(numNodes); (itElem)->Set(BLOCKED, false); (itElem)->Set(ISOLATED, false); unsigned int freeSurfaceNodes = 0; unsigned int freeSurfaceRigidNodes = 0; unsigned int rigidNodes = 0; unsigned int isolatedNodes = 0; for (unsigned int i = 0; i < numNodes; i++) { if (itElem->GetGeometry()[i].Is(FREE_SURFACE)) { freeSurfaceNodes++; if (itElem->GetGeometry()[i].Is(RIGID)) { freeSurfaceRigidNodes++; } } else if (itElem->GetGeometry()[i].Is(RIGID)) { rigidNodes++; } nodesCoordinates[i] = itElem->GetGeometry()[i].Coordinates(); ElementWeakPtrVectorType &neighb_elems = itElem->GetGeometry()[i].GetValue(NEIGHBOUR_ELEMENTS); if (neighb_elems.size() == 1) { isolatedNodes++; } } if (dimension == 3) { double a1 = 0; //slope x for plane on the first triangular face of the tetrahedra (nodes A,B,C) double b1 = 0; //slope y for plane on the first triangular face of the tetrahedra (nodes A,B,C) double c1 = 0; //slope z for plane on the first triangular face of the tetrahedra (nodes A,B,C) a1 = (nodesCoordinates[1][1] - nodesCoordinates[0][1]) * (nodesCoordinates[2][2] - nodesCoordinates[0][2]) - (nodesCoordinates[2][1] - nodesCoordinates[0][1]) * (nodesCoordinates[1][2] - nodesCoordinates[0][2]); b1 = (nodesCoordinates[1][2] - nodesCoordinates[0][2]) * (nodesCoordinates[2][0] - nodesCoordinates[0][0]) - (nodesCoordinates[2][2] - nodesCoordinates[0][2]) * (nodesCoordinates[1][0] - nodesCoordinates[0][0]); c1 = (nodesCoordinates[1][0] - nodesCoordinates[0][0]) * (nodesCoordinates[2][1] - nodesCoordinates[0][1]) - (nodesCoordinates[2][0] - nodesCoordinates[0][0]) * (nodesCoordinates[1][1] - nodesCoordinates[0][1]); double a2 = 0; //slope x for plane on the second triangular face of the tetrahedra (nodes A,B,D) double b2 = 0; //slope y for plane on the second triangular face of the tetrahedra (nodes A,B,D) double c2 = 0; //slope z for plane on the second triangular face of the tetrahedra (nodes A,B,D) a2 = (nodesCoordinates[1][1] - nodesCoordinates[0][1]) * (nodesCoordinates[3][2] - nodesCoordinates[0][2]) - (nodesCoordinates[3][1] - nodesCoordinates[0][1]) * (nodesCoordinates[1][2] - nodesCoordinates[0][2]); b2 = (nodesCoordinates[1][2] - nodesCoordinates[0][2]) * (nodesCoordinates[3][0] - nodesCoordinates[0][0]) - (nodesCoordinates[3][2] - nodesCoordinates[0][2]) * (nodesCoordinates[1][0] - nodesCoordinates[0][0]); c2 = (nodesCoordinates[1][0] - nodesCoordinates[0][0]) * (nodesCoordinates[3][1] - nodesCoordinates[0][1]) - (nodesCoordinates[3][0] - nodesCoordinates[0][0]) * (nodesCoordinates[1][1] - nodesCoordinates[0][1]); double a3 = 0; //slope x for plane on the third triangular face of the tetrahedra (nodes B,C,D) double b3 = 0; //slope y for plane on the third triangular face of the tetrahedra (nodes B,C,D) double c3 = 0; //slope z for plane on the third triangular face of the tetrahedra (nodes B,C,D) a3 = (nodesCoordinates[1][1] - nodesCoordinates[2][1]) * (nodesCoordinates[3][2] - nodesCoordinates[2][2]) - (nodesCoordinates[3][1] - nodesCoordinates[2][1]) * (nodesCoordinates[1][2] - nodesCoordinates[2][2]); b3 = (nodesCoordinates[1][2] - nodesCoordinates[2][2]) * (nodesCoordinates[3][0] - nodesCoordinates[2][0]) - (nodesCoordinates[3][2] - nodesCoordinates[2][2]) * (nodesCoordinates[1][0] - nodesCoordinates[2][0]); c3 = (nodesCoordinates[1][0] - nodesCoordinates[2][0]) * (nodesCoordinates[3][1] - nodesCoordinates[2][1]) - (nodesCoordinates[3][0] - nodesCoordinates[2][0]) * (nodesCoordinates[1][1] - nodesCoordinates[2][1]); double a4 = 0; //slope x for plane on the fourth triangular face of the tetrahedra (nodes A,C,D) double b4 = 0; //slope y for plane on the fourth triangular face of the tetrahedra (nodes A,C,D) double c4 = 0; //slope z for plane on the fourth triangular face of the tetrahedra (nodes A,C,D) a4 = (nodesCoordinates[0][1] - nodesCoordinates[2][1]) * (nodesCoordinates[3][2] - nodesCoordinates[2][2]) - (nodesCoordinates[3][1] - nodesCoordinates[2][1]) * (nodesCoordinates[0][2] - nodesCoordinates[2][2]); b4 = (nodesCoordinates[0][2] - nodesCoordinates[2][2]) * (nodesCoordinates[3][0] - nodesCoordinates[2][0]) - (nodesCoordinates[3][2] - nodesCoordinates[2][2]) * (nodesCoordinates[0][0] - nodesCoordinates[2][0]); c4 = (nodesCoordinates[0][0] - nodesCoordinates[2][0]) * (nodesCoordinates[3][1] - nodesCoordinates[2][1]) - (nodesCoordinates[3][0] - nodesCoordinates[2][0]) * (nodesCoordinates[0][1] - nodesCoordinates[2][1]); double cosAngle12 = (a1 * a2 + b1 * b2 + c1 * c2) / (sqrt(pow(a1, 2) + pow(b1, 2) + pow(c1, 2)) * sqrt(pow(a2, 2) + pow(b2, 2) + pow(c2, 2))); double cosAngle13 = (a1 * a3 + b1 * b3 + c1 * c3) / (sqrt(pow(a1, 2) + pow(b1, 2) + pow(c1, 2)) * sqrt(pow(a3, 2) + pow(b3, 2) + pow(c3, 2))); double cosAngle14 = (a1 * a4 + b1 * b4 + c1 * c4) / (sqrt(pow(a1, 2) + pow(b1, 2) + pow(c1, 2)) * sqrt(pow(a4, 2) + pow(b4, 2) + pow(c4, 2))); double cosAngle23 = (a3 * a2 + b3 * b2 + c3 * c2) / (sqrt(pow(a3, 2) + pow(b3, 2) + pow(c3, 2)) * sqrt(pow(a2, 2) + pow(b2, 2) + pow(c2, 2))); double cosAngle24 = (a4 * a2 + b4 * b2 + c4 * c2) / (sqrt(pow(a4, 2) + pow(b4, 2) + pow(c4, 2)) * sqrt(pow(a2, 2) + pow(b2, 2) + pow(c2, 2))); double cosAngle34 = (a4 * a3 + b4 * b3 + c4 * c3) / (sqrt(pow(a4, 2) + pow(b4, 2) + pow(c4, 2)) * sqrt(pow(a3, 2) + pow(b3, 2) + pow(c3, 2))); if ((fabs(cosAngle12) > 0.99 || fabs(cosAngle13) > 0.99 || fabs(cosAngle14) > 0.99 || fabs(cosAngle23) > 0.99 || fabs(cosAngle24) > 0.99 || fabs(cosAngle34) > 0.99) && (freeSurfaceNodes == numNodes) && isolatedNodes > 1) { (itElem)->Set(BLOCKED, true); // std::cout << "in the strategy BLOCKED ELEMENT: " << (itElem)->Id() << std::endl; } else if ((fabs(cosAngle12) > 0.995 || fabs(cosAngle13) > 0.995 || fabs(cosAngle14) > 0.995 || fabs(cosAngle23) > 0.995 || fabs(cosAngle24) > 0.995 || fabs(cosAngle34) > 0.995) && (freeSurfaceNodes == numNodes) && isolatedNodes == 1) { (itElem)->Set(BLOCKED, true); // std::cout << "in the strategy BLOCKED ELEMENT: " << (itElem)->Id() << std::endl; } else if ((fabs(cosAngle12) > 0.999 || fabs(cosAngle13) > 0.999 || fabs(cosAngle14) > 0.999 || fabs(cosAngle23) > 0.999 || fabs(cosAngle24) > 0.999 || fabs(cosAngle34) > 0.999) && (freeSurfaceNodes == numNodes)) { (itElem)->Set(BLOCKED, true); // std::cout << "in the strategy BLOCKED ELEMENT: " << (itElem)->Id() << std::endl; } } if (freeSurfaceNodes == numNodes && rigidNodes == 0 && isolatedNodes >= (numNodes - 1)) { (itElem)->Set(ISOLATED, true); (itElem)->Set(BLOCKED, false); } } } KRATOS_CATCH(""); } void CalculatePressureVelocity() { ModelPart &rModelPart = BaseType::GetModelPart(); ProcessInfo &rCurrentProcessInfo = rModelPart.GetProcessInfo(); const double timeInterval = rCurrentProcessInfo[DELTA_TIME]; unsigned int timeStep = rCurrentProcessInfo[STEP]; for (ModelPart::NodeIterator i = rModelPart.NodesBegin(); i != rModelPart.NodesEnd(); ++i) { if (timeStep == 1) { (i)->FastGetSolutionStepValue(PRESSURE_VELOCITY, 0) = 0; (i)->FastGetSolutionStepValue(PRESSURE_VELOCITY, 1) = 0; } else { double &CurrentPressure = (i)->FastGetSolutionStepValue(PRESSURE, 0); double &PreviousPressure = (i)->FastGetSolutionStepValue(PRESSURE, 1); double &CurrentPressureVelocity = (i)->FastGetSolutionStepValue(PRESSURE_VELOCITY, 0); CurrentPressureVelocity = (CurrentPressure - PreviousPressure) / timeInterval; } } } void CalculatePressureAcceleration() { ModelPart &rModelPart = BaseType::GetModelPart(); ProcessInfo &rCurrentProcessInfo = rModelPart.GetProcessInfo(); const double timeInterval = rCurrentProcessInfo[DELTA_TIME]; unsigned int timeStep = rCurrentProcessInfo[STEP]; for (ModelPart::NodeIterator i = rModelPart.NodesBegin(); i != rModelPart.NodesEnd(); ++i) { if (timeStep == 1) { (i)->FastGetSolutionStepValue(PRESSURE_ACCELERATION, 0) = 0; (i)->FastGetSolutionStepValue(PRESSURE_ACCELERATION, 1) = 0; } else { double &CurrentPressureVelocity = (i)->FastGetSolutionStepValue(PRESSURE_VELOCITY, 0); double &PreviousPressureVelocity = (i)->FastGetSolutionStepValue(PRESSURE_VELOCITY, 1); double &CurrentPressureAcceleration = (i)->FastGetSolutionStepValue(PRESSURE_ACCELERATION, 0); CurrentPressureAcceleration = (CurrentPressureVelocity - PreviousPressureVelocity) / timeInterval; } } } virtual void CalculateTemporalVariables() { ModelPart &rModelPart = BaseType::GetModelPart(); ProcessInfo &rCurrentProcessInfo = rModelPart.GetProcessInfo(); for (ModelPart::NodeIterator i = rModelPart.NodesBegin(); i != rModelPart.NodesEnd(); ++i) { array_1d<double, 3> &CurrentVelocity = (i)->FastGetSolutionStepValue(VELOCITY, 0); array_1d<double, 3> &PreviousVelocity = (i)->FastGetSolutionStepValue(VELOCITY, 1); array_1d<double, 3> &CurrentAcceleration = (i)->FastGetSolutionStepValue(ACCELERATION, 0); array_1d<double, 3> &PreviousAcceleration = (i)->FastGetSolutionStepValue(ACCELERATION, 1); /* if((i)->IsNot(ISOLATED) || (i)->Is(SOLID)){ */ if ((i)->IsNot(ISOLATED) && ((i)->IsNot(RIGID) || (i)->Is(SOLID))) { UpdateAccelerations(CurrentAcceleration, CurrentVelocity, PreviousAcceleration, PreviousVelocity); } else if ((i)->Is(RIGID)) { array_1d<double, 3> Zeros(3, 0.0); (i)->FastGetSolutionStepValue(ACCELERATION, 0) = Zeros; (i)->FastGetSolutionStepValue(ACCELERATION, 1) = Zeros; } else { (i)->FastGetSolutionStepValue(PRESSURE, 0) = 0.0; (i)->FastGetSolutionStepValue(PRESSURE, 1) = 0.0; (i)->FastGetSolutionStepValue(PRESSURE_VELOCITY, 0) = 0.0; (i)->FastGetSolutionStepValue(PRESSURE_VELOCITY, 1) = 0.0; (i)->FastGetSolutionStepValue(PRESSURE_ACCELERATION, 0) = 0.0; (i)->FastGetSolutionStepValue(PRESSURE_ACCELERATION, 1) = 0.0; if ((i)->SolutionStepsDataHas(VOLUME_ACCELERATION)) { array_1d<double, 3> &VolumeAcceleration = (i)->FastGetSolutionStepValue(VOLUME_ACCELERATION); (i)->FastGetSolutionStepValue(ACCELERATION, 0) = VolumeAcceleration; (i)->FastGetSolutionStepValue(VELOCITY, 0) += VolumeAcceleration * rCurrentProcessInfo[DELTA_TIME]; } } const double timeInterval = rCurrentProcessInfo[DELTA_TIME]; unsigned int timeStep = rCurrentProcessInfo[STEP]; if (timeStep == 1) { (i)->FastGetSolutionStepValue(PRESSURE_VELOCITY, 0) = 0; (i)->FastGetSolutionStepValue(PRESSURE_VELOCITY, 1) = 0; (i)->FastGetSolutionStepValue(PRESSURE_ACCELERATION, 0) = 0; (i)->FastGetSolutionStepValue(PRESSURE_ACCELERATION, 1) = 0; } else { double &CurrentPressure = (i)->FastGetSolutionStepValue(PRESSURE, 0); double &PreviousPressure = (i)->FastGetSolutionStepValue(PRESSURE, 1); double &CurrentPressureVelocity = (i)->FastGetSolutionStepValue(PRESSURE_VELOCITY, 0); double &CurrentPressureAcceleration = (i)->FastGetSolutionStepValue(PRESSURE_ACCELERATION, 0); CurrentPressureAcceleration = CurrentPressureVelocity / timeInterval; CurrentPressureVelocity = (CurrentPressure - PreviousPressure) / timeInterval; CurrentPressureAcceleration += -CurrentPressureVelocity / timeInterval; } } } void CalculateAccelerations() { ModelPart &rModelPart = BaseType::GetModelPart(); ProcessInfo &rCurrentProcessInfo = rModelPart.GetProcessInfo(); for (ModelPart::NodeIterator i = rModelPart.NodesBegin(); i != rModelPart.NodesEnd(); ++i) { array_1d<double, 3> &CurrentVelocity = (i)->FastGetSolutionStepValue(VELOCITY, 0); array_1d<double, 3> &PreviousVelocity = (i)->FastGetSolutionStepValue(VELOCITY, 1); array_1d<double, 3> &CurrentAcceleration = (i)->FastGetSolutionStepValue(ACCELERATION, 0); array_1d<double, 3> &PreviousAcceleration = (i)->FastGetSolutionStepValue(ACCELERATION, 1); /* if((i)->IsNot(ISOLATED) || (i)->Is(SOLID)){ */ if ((i)->IsNot(ISOLATED) && ((i)->IsNot(RIGID) || (i)->Is(SOLID))) { UpdateAccelerations(CurrentAcceleration, CurrentVelocity, PreviousAcceleration, PreviousVelocity); } else if ((i)->Is(RIGID)) { array_1d<double, 3> Zeros(3, 0.0); (i)->FastGetSolutionStepValue(ACCELERATION, 0) = Zeros; (i)->FastGetSolutionStepValue(ACCELERATION, 1) = Zeros; } else { (i)->FastGetSolutionStepValue(PRESSURE, 0) = 0.0; (i)->FastGetSolutionStepValue(PRESSURE, 1) = 0.0; (i)->FastGetSolutionStepValue(PRESSURE_VELOCITY, 0) = 0.0; (i)->FastGetSolutionStepValue(PRESSURE_VELOCITY, 1) = 0.0; (i)->FastGetSolutionStepValue(PRESSURE_ACCELERATION, 0) = 0.0; (i)->FastGetSolutionStepValue(PRESSURE_ACCELERATION, 1) = 0.0; if ((i)->SolutionStepsDataHas(VOLUME_ACCELERATION)) { array_1d<double, 3> &VolumeAcceleration = (i)->FastGetSolutionStepValue(VOLUME_ACCELERATION); (i)->FastGetSolutionStepValue(ACCELERATION, 0) = VolumeAcceleration; (i)->FastGetSolutionStepValue(VELOCITY, 0) += VolumeAcceleration * rCurrentProcessInfo[DELTA_TIME]; } } } } inline void UpdateAccelerations(array_1d<double, 3> &CurrentAcceleration, const array_1d<double, 3> &CurrentVelocity, array_1d<double, 3> &PreviousAcceleration, const array_1d<double, 3> &PreviousVelocity) { ModelPart &rModelPart = BaseType::GetModelPart(); ProcessInfo &rCurrentProcessInfo = rModelPart.GetProcessInfo(); double Dt = rCurrentProcessInfo[DELTA_TIME]; noalias(CurrentAcceleration) = 2.0 * (CurrentVelocity - PreviousVelocity) / Dt - PreviousAcceleration; } virtual void CalculateDisplacementsAndPorosity() { ModelPart &rModelPart = BaseType::GetModelPart(); ProcessInfo &rCurrentProcessInfo = rModelPart.GetProcessInfo(); const double TimeStep = rCurrentProcessInfo[DELTA_TIME]; for (ModelPart::NodeIterator i = rModelPart.NodesBegin(); i != rModelPart.NodesEnd(); ++i) { array_1d<double, 3> &CurrentVelocity = (i)->FastGetSolutionStepValue(VELOCITY, 0); array_1d<double, 3> &PreviousVelocity = (i)->FastGetSolutionStepValue(VELOCITY, 1); array_1d<double, 3> &CurrentDisplacement = (i)->FastGetSolutionStepValue(DISPLACEMENT, 0); array_1d<double, 3> &PreviousDisplacement = (i)->FastGetSolutionStepValue(DISPLACEMENT, 1); /* if( i->IsFixed(DISPLACEMENT_X) == false ) */ CurrentDisplacement[0] = 0.5 * TimeStep * (CurrentVelocity[0] + PreviousVelocity[0]) + PreviousDisplacement[0]; /* if( i->IsFixed(DISPLACEMENT_Y) == false ) */ CurrentDisplacement[1] = 0.5 * TimeStep * (CurrentVelocity[1] + PreviousVelocity[1]) + PreviousDisplacement[1]; /* if( i->IsFixed(DISPLACEMENT_Z) == false ) */ CurrentDisplacement[2] = 0.5 * TimeStep * (CurrentVelocity[2] + PreviousVelocity[2]) + PreviousDisplacement[2]; // currentFluidFractionRate = (currentFluidFraction - previousFluidFraction)/TimeStep; } } virtual void UpdateStressStrain() {} virtual void Clear() override {} ///@} ///@name Access ///@{ virtual void SetEchoLevel(int Level) override { BaseType::SetEchoLevel(Level); } ///@} ///@name Inquiry ///@{ ///@} ///@name Input and output ///@{ /// Turn back information as a string. std::string Info() const override { std::stringstream buffer; buffer << "VPStrategy"; return buffer.str(); } /// Print information about this object. void PrintInfo(std::ostream &rOStream) const override { rOStream << "VPStrategy"; } /// Print object's data. void PrintData(std::ostream &rOStream) const override { } ///@} ///@name Friends ///@{ ///@} protected: ///@name Protected Life Cycle ///@{ ///@} ///@name Protected static Member Variables ///@{ ///@} ///@name Protected member Variables ///@{ ///@} ///@name Protected Operators ///@{ ///@} ///@name Protected Operations ///@{ /// Calculate the coefficients for time iteration. /** * @param rCurrentProcessInfo ProcessInfo instance from the fluid ModelPart. Must contain DELTA_TIME variables. */ virtual bool SolveMomentumIteration(unsigned int it, unsigned int maxIt, bool &fixedTimeStep, double &velocityNorm) { return false; } virtual bool SolveContinuityIteration(unsigned int it, unsigned int maxIt, double &NormP) { return false; } void ComputeErrorL2Norm(double tensilStressSign) //tensilStressSign = 1.0 for FIC, tensilStressSign = -1.0 for FS { ModelPart &rModelPart = BaseType::GetModelPart(); const ProcessInfo &rCurrentProcessInfo = rModelPart.GetProcessInfo(); const double currentTime = rCurrentProcessInfo[TIME]; const unsigned int dimension = rModelPart.ElementsBegin()->GetGeometry().WorkingSpaceDimension(); long double sumErrorL2Velocity = 0; long double sumErrorL2VelocityX = 0; long double sumErrorL2VelocityY = 0; long double sumErrorL2Pressure = 0; long double sumErrorL2TauXX = 0; long double sumErrorL2TauYY = 0; long double sumErrorL2TauXY = 0; #pragma omp parallel { ModelPart::ElementIterator ElemBegin; ModelPart::ElementIterator ElemEnd; OpenMPUtils::PartitionedIterators(rModelPart.Elements(), ElemBegin, ElemEnd); for (ModelPart::ElementIterator itElem = ElemBegin; itElem != ElemEnd; ++itElem) { Element::GeometryType &geometry = itElem->GetGeometry(); long double nodalArea = 0; if (dimension == 2) { nodalArea = geometry.Area() / 3.0; } else if (dimension == 3) { nodalArea = geometry.Volume() * 0.25; } long double bariPosX = 0; long double bariPosY = 0; long double eleErrorL2Velocity = 0; long double eleErrorL2VelocityX = 0; long double eleErrorL2VelocityY = 0; long double eleErrorL2Pressure = 0; //ShapeFunctionDerivativesArrayType DN_DX; Matrix NContainer; NContainer = geometry.ShapeFunctionsValues(GeometryData::IntegrationMethod::GI_GAUSS_1); const Vector &N = row(NContainer, 0); const unsigned int NumNodes = geometry.size(); double elementalPressure = N[0] * geometry(0)->FastGetSolutionStepValue(PRESSURE); double elementalVelocityX = N[0] * geometry(0)->FastGetSolutionStepValue(VELOCITY_X); double elementalVelocityY = N[0] * geometry(0)->FastGetSolutionStepValue(VELOCITY_Y); ; for (unsigned int i = 1; i < NumNodes; i++) { elementalPressure += N[i] * geometry(i)->FastGetSolutionStepValue(PRESSURE); elementalVelocityX += N[i] * geometry(i)->FastGetSolutionStepValue(VELOCITY_X); elementalVelocityY += N[i] * geometry(i)->FastGetSolutionStepValue(VELOCITY_Y); } for (unsigned int i = 0; i < geometry.size(); i++) { const long double nodalPosX = geometry(i)->X(); const long double nodalPosY = geometry(i)->Y(); bariPosX += nodalPosX / 3.0; bariPosY += nodalPosY / 3.0; } const long double posX = bariPosX; const long double posY = bariPosY; long double expectedVelocityX = pow(posX, 2) * (1.0 - posX) * (1.0 - posX) * (2.0 * posY - 6.0 * pow(posY, 2) + 4.0 * pow(posY, 3)); long double expectedVelocityY = -pow(posY, 2) * (1.0 - posY) * (1.0 - posY) * (2.0 * posX - 6.0 * pow(posX, 2) + 4.0 * pow(posX, 3)); long double expectedPressure = -tensilStressSign * posX * (1.0 - posX); eleErrorL2VelocityX = elementalVelocityX - expectedVelocityX; eleErrorL2VelocityY = elementalVelocityY - expectedVelocityY; eleErrorL2Pressure = elementalPressure - expectedPressure; sumErrorL2VelocityX += pow(eleErrorL2VelocityX, 2) * geometry.Area(); sumErrorL2VelocityY += pow(eleErrorL2VelocityY, 2) * geometry.Area(); sumErrorL2Pressure += pow(eleErrorL2Pressure, 2) * geometry.Area(); const long double tauXX = 0; // itElem->GetValue(ELEMENTAL_DEVIATORIC_STRESS_XX); const long double tauYY = 0; // itElem->GetValue(ELEMENTAL_DEVIATORIC_STRESS_YY); const long double tauXY = 0; // itElem->GetValue(ELEMENTAL_DEVIATORIC_STRESS_XY); long double expectedTauXX = 2.0 * (-4.0 * (1.0 - bariPosX) * bariPosX * (-1.0 + 2.0 * bariPosX) * bariPosY * (1.0 - 3.0 * bariPosY + 2.0 * pow(bariPosY, 2))); long double expectedTauYY = 2.0 * (4.0 * bariPosX * (1.0 - 3.0 * bariPosX + 2.0 * pow(bariPosX, 2)) * (1.0 - bariPosY) * bariPosY * (-1.0 + 2.0 * bariPosY)); long double expectedTauXY = (2.0 * (1.0 - 6.0 * bariPosY + 6.0 * pow(bariPosY, 2)) * (1.0 - bariPosX) * (1.0 - bariPosX) * pow(bariPosX, 2) - 2.0 * (1.0 - 6.0 * bariPosX + 6.0 * pow(bariPosX, 2)) * (1.0 - bariPosY) * (1 - bariPosY) * pow(bariPosY, 2)); long double nodalErrorTauXX = tauXX - expectedTauXX; long double nodalErrorTauYY = tauYY - expectedTauYY; long double nodalErrorTauXY = tauXY - expectedTauXY; sumErrorL2TauXX += pow(nodalErrorTauXX, 2) * geometry.Area(); sumErrorL2TauYY += pow(nodalErrorTauYY, 2) * geometry.Area(); sumErrorL2TauXY += pow(nodalErrorTauXY, 2) * geometry.Area(); } } long double errorL2Velocity = sqrt(sumErrorL2Velocity); long double errorL2VelocityX = sqrt(sumErrorL2VelocityX); long double errorL2VelocityY = sqrt(sumErrorL2VelocityY); long double errorL2Pressure = sqrt(sumErrorL2Pressure); long double errorL2TauXX = sqrt(sumErrorL2TauXX); long double errorL2TauYY = sqrt(sumErrorL2TauYY); long double errorL2TauXY = sqrt(sumErrorL2TauXY); std::ofstream myfileVelocity; myfileVelocity.open("errorL2VelocityFile.txt", std::ios::app); myfileVelocity << currentTime << "\t" << errorL2Velocity << "\n"; myfileVelocity.close(); std::ofstream myfileVelocityX; myfileVelocityX.open("errorL2VelocityXFile.txt", std::ios::app); myfileVelocityX << currentTime << "\t" << errorL2VelocityX << "\n"; myfileVelocityX.close(); std::ofstream myfileVelocityY; myfileVelocityY.open("errorL2VelocityYFile.txt", std::ios::app); myfileVelocityY << currentTime << "\t" << errorL2VelocityY << "\n"; myfileVelocityY.close(); std::ofstream myfilePressure; myfilePressure.open("errorL2PressureFile.txt", std::ios::app); myfilePressure << currentTime << "\t" << errorL2Pressure << "\n"; myfilePressure.close(); std::ofstream myfileTauXX; myfileTauXX.open("errorL2TauXXFile.txt", std::ios::app); myfileTauXX << currentTime << "\t" << errorL2TauXX << "\n"; myfileTauXX.close(); std::ofstream myfileTauYY; myfileTauYY.open("errorL2TauYYFile.txt", std::ios::app); myfileTauYY << currentTime << "\t" << errorL2TauYY << "\n"; myfileTauYY.close(); std::ofstream myfileTauXY; myfileTauXY.open("errorL2TauXYFile.txt", std::ios::app); myfileTauXY << currentTime << "\t" << errorL2TauXY << "\n"; myfileTauXY.close(); } void ComputeErrorL2NormCasePoiseuille() { ModelPart &rModelPart = BaseType::GetModelPart(); const ProcessInfo &rCurrentProcessInfo = rModelPart.GetProcessInfo(); const double currentTime = rCurrentProcessInfo[TIME]; const unsigned int dimension = rModelPart.ElementsBegin()->GetGeometry().WorkingSpaceDimension(); double sumErrorL2VelocityTheta = 0; double sumErrorL2TauTheta = 0; double r_in = 0.2; double R_out = 0.5; double kappa = r_in / R_out; double omega = 0.5; double viscosity = 100.0; #pragma omp parallel { ModelPart::ElementIterator ElemBegin; ModelPart::ElementIterator ElemEnd; OpenMPUtils::PartitionedIterators(rModelPart.Elements(), ElemBegin, ElemEnd); for (ModelPart::ElementIterator itElem = ElemBegin; itElem != ElemEnd; ++itElem) { Element::GeometryType &geometry = itElem->GetGeometry(); long double nodalArea = 0; if (dimension == 2) { nodalArea = geometry.Area() / 3.0; } else if (dimension == 3) { nodalArea = geometry.Volume() * 0.25; } long double bariPosX = 0; long double bariPosY = 0; long double eleErrorL2Velocity = 0; long double eleErrorL2VelocityX = 0; long double eleErrorL2VelocityY = 0; long double eleErrorL2Pressure = 0; //ShapeFunctionDerivativesArrayType DN_DX; Matrix NContainer; NContainer = geometry.ShapeFunctionsValues(GeometryData::IntegrationMethod::GI_GAUSS_1); //this->CalculateGeometryData(DN_DX,NContainer,GaussWeights); const Vector &N = row(NContainer, 0); // itElem->EvaluateInPoint(elementalPressure,PRESSURE,N); const unsigned int NumNodes = geometry.size(); double elementalPressure = N[0] * geometry(0)->FastGetSolutionStepValue(PRESSURE); double elementalVelocityX = N[0] * geometry(0)->FastGetSolutionStepValue(VELOCITY_X); double elementalVelocityY = N[0] * geometry(0)->FastGetSolutionStepValue(VELOCITY_Y); ; for (unsigned int i = 1; i < NumNodes; i++) { elementalPressure += N[i] * geometry(i)->FastGetSolutionStepValue(PRESSURE); elementalVelocityX += N[i] * geometry(i)->FastGetSolutionStepValue(VELOCITY_X); elementalVelocityY += N[i] * geometry(i)->FastGetSolutionStepValue(VELOCITY_Y); } for (unsigned int i = 0; i < geometry.size(); i++) { // index = i*dimension; const long double nodalPosX = geometry(i)->X(); const long double nodalPosY = geometry(i)->Y(); bariPosX += nodalPosX / 3.0; bariPosY += nodalPosY / 3.0; } const long double posX = bariPosX; const long double posY = bariPosY; const double rPos = sqrt(pow(posX, 2) + pow(posY, 2)); const double cosalfa = posX / rPos; const double sinalfa = posY / rPos; const double sin2alfa = 2.0 * cosalfa * sinalfa; const double cos2alfa = 1.0 - 2.0 * pow(sinalfa, 2); double expectedVelocityTheta = pow(kappa, 2) * omega * R_out / (1.0 - pow(kappa, 2)) * (R_out / rPos - rPos / R_out); double computedVelocityTheta = sqrt(pow(elementalVelocityX, 2) + pow(elementalVelocityY, 2)); double nodalErrorVelocityTheta = computedVelocityTheta - expectedVelocityTheta; const long double tauXX = 0; // itElem->GetValue(ELEMENTAL_DEVIATORIC_STRESS_XX); const long double tauYY = 0; // itElem->GetValue(ELEMENTAL_DEVIATORIC_STRESS_YY); const long double tauXY = 0; // itElem->GetValue(ELEMENTAL_DEVIATORIC_STRESS_XY); double expectedTauTheta = (2.0 * viscosity * pow(kappa, 2) * omega * pow(R_out, 2)) / (1.0 - pow(kappa, 2)) / pow(rPos, 2); double computedTauTheta = (tauXX - tauYY) * sin2alfa / 2.0 - tauXY * cos2alfa; double nodalErrorTauTheta = computedTauTheta - expectedTauTheta; sumErrorL2VelocityTheta += pow(nodalErrorVelocityTheta, 2) * geometry.Area(); sumErrorL2TauTheta += pow(nodalErrorTauTheta, 2) * geometry.Area(); } } double errorL2VelocityTheta = sqrt(sumErrorL2VelocityTheta); double errorL2TauTheta = sqrt(sumErrorL2TauTheta); std::ofstream myfileVelocity; myfileVelocity.open("errorL2Poiseuille.txt", std::ios::app); myfileVelocity << currentTime << "\t" << errorL2VelocityTheta << "\t" << errorL2TauTheta << "\n"; myfileVelocity.close(); } double ComputeVelocityNorm() { ModelPart &rModelPart = BaseType::GetModelPart(); const int n_nodes = rModelPart.NumberOfNodes(); double NormV = 0.00; #pragma omp parallel for reduction(+ \ : NormV) for (int i_node = 0; i_node < n_nodes; ++i_node) { const auto it_node = rModelPart.NodesBegin() + i_node; const auto &r_vel = it_node->FastGetSolutionStepValue(VELOCITY); for (unsigned int d = 0; d < 3; ++d) { NormV += r_vel[d] * r_vel[d]; } } NormV = BaseType::GetModelPart().GetCommunicator().GetDataCommunicator().SumAll(NormV); NormV = sqrt(NormV); const double zero_tol = 1.0e-12; if (NormV < zero_tol) NormV = 1.00; return NormV; } double ComputePressureNorm() { ModelPart &rModelPart = BaseType::GetModelPart(); const int n_nodes = rModelPart.NumberOfNodes(); double NormP = 0.00; #pragma omp parallel for reduction(+ \ : NormP) for (int i_node = 0; i_node < n_nodes; ++i_node) { const auto it_node = rModelPart.NodesBegin() + i_node; const double Pr = it_node->FastGetSolutionStepValue(PRESSURE); NormP += Pr * Pr; } NormP = BaseType::GetModelPart().GetCommunicator().GetDataCommunicator().SumAll(NormP); NormP = sqrt(NormP); const double zero_tol = 1.0e-12; if (NormP < zero_tol) NormP = 1.00; return NormP; } virtual bool CheckVelocityConvergence(const double NormDv, double &errorNormDv) { return false; } virtual bool CheckPressureConvergence(const double NormDp, double &errorNormDp, double &NormP) { return false; } virtual bool FixTimeStepMomentum(const double DvErrorNorm, bool &fixedTimeStep) { return false; } virtual bool CheckMomentumConvergence(const double DvErrorNorm, bool &fixedTimeStep) { return false; } virtual bool FixTimeStepContinuity(const double DvErrorNorm, bool &fixedTimeStep) { return false; } virtual bool CheckContinuityConvergence(const double DvErrorNorm, bool &fixedTimeStep) { return false; } ///@} ///@name Protected Access ///@{ ///@} ///@name Protected Inquiry ///@{ ///@} ///@name Protected LifeCycle ///@{ ///@} ///@name Static Member Variables ///@{ ///@} ///@name Member Variables ///@{ // Fractional step index. /* 1 : Momentum step (calculate fractional step velocity) * 2-3 : Unused (reserved for componentwise calculation of frac step velocity) * 4 : Pressure step * 5 : Computation of projections * 6 : End of step velocity */ // unsigned int mStepId; ///@} ///@name Private Operators ///@{ ///@} ///@name Private Operations ///@{ virtual void InitializeStrategy(SolverSettingsType &rSolverConfig) { KRATOS_TRY; KRATOS_CATCH(""); } ///@} ///@name Private Access ///@{ ///@} ///@name Private Inquiry ///@{ ///@} ///@name Un accessible methods ///@{ /// Assignment operator. VPStrategy &operator=(VPStrategy const &rOther) {} /// Copy constructor. VPStrategy(VPStrategy const &rOther) {} ///@} }; /// Class VPStrategy ///@} ///@name Type Definitions ///@{ ///@} ///@} // addtogroup } // namespace Kratos. #endif // KRATOS_V_P_STRATEGY_H

nco_ply_lst.c

/* $Header$ */ /* Purpose: Functions that manipulate lists of polygons */ /* Copyright (C) 2018--present Charlie Zender This file is part of NCO, the netCDF Operators. NCO is free software. You may redistribute and/or modify NCO under the terms of the 3-Clause BSD License with exceptions described in the LICENSE file */ #include "nco_ply_lst.h" void nco_poly_re_org_lst( /* for each poly_sct* in list re-order points so that first point is the leftermost point */ poly_sct **pl_lst, int arr_nbr) { int idx=0; int jdx=0; int max_crn_nbr=0; double *lcl_dp_x; double *lcl_dp_y; /* max crn_nbr */ for(idx=0 ; idx<arr_nbr ;idx++) if( pl_lst[idx]->crn_nbr > max_crn_nbr ) max_crn_nbr = pl_lst[idx]->crn_nbr; lcl_dp_x=(double*)nco_calloc(max_crn_nbr, sizeof(double)); lcl_dp_y=(double*)nco_calloc(max_crn_nbr, sizeof(double)); for(idx=0; idx<arr_nbr; idx++) { int lcl_min=0; int crn_nbr=pl_lst[idx]->crn_nbr; double x_min=1.0e-30; /* de-reference */ poly_sct *pl=pl_lst[idx]; /* find index of min X value */ for(jdx=0; jdx<crn_nbr; jdx++) if( pl->dp_x[jdx] < x_min ) { x_min=pl->dp_x[jdx]; lcl_min=jdx;} /* first point already x_min so do nothing */ if( lcl_min == 0) continue; for(jdx=0; jdx<crn_nbr; jdx++) { lcl_dp_x[jdx]=pl->dp_x[(jdx+lcl_min)%crn_nbr]; lcl_dp_y[jdx]=pl->dp_y[(jdx+lcl_min)%crn_nbr]; } /* copy over values */ memcpy(pl->dp_x, lcl_dp_x, (size_t)crn_nbr*sizeof(double)); memcpy(pl->dp_y, lcl_dp_y, (size_t)crn_nbr*sizeof(double)); } lcl_dp_x=(double*)nco_free(lcl_dp_x); lcl_dp_y=(double*)nco_free(lcl_dp_y); return; } poly_sct ** /* [O] [nbr] size of array */ nco_poly_lst_mk( double *area, /* I [sr] Area of source grid */ int *msk, /* I [flg] Mask on source grid */ double *lat_ctr, /* I [dgr] Latitude centers of source grid */ double *lon_ctr, /* I [dgr] Longitude centers of source grid */ double *lat_crn, /* I [dgr] Latitude corners of source grid */ double *lon_crn, /* I [dgr] Longitude corners of source grid */ size_t grd_sz, /* I [nbr] Number of elements in single layer of source grid */ long grd_crn_nbr, /* I [nbr] Maximum number of corners in source gridcell */ nco_grd_lon_typ_enm grd_lon_typ, /* I [num] if not nil then split cells that straddle Greenwich or Dateline */ poly_typ_enm pl_typ, int *pl_nbr) { const char fnc_nm[]="nco_poly_lst_mk()"; int idx=0; int idx_cnt=0; int cnt_wrp_good=0; nco_bool bwrp; double *lat_ptr=lat_crn; double *lon_ptr=lon_crn; /* buffers used in nco-poly_re_org() */ double lcl_dp_x[VP_MAX]={0}; double lcl_dp_y[VP_MAX]={0}; poly_sct *pl; poly_sct *pl_wrp_left; poly_sct *pl_wrp_right; poly_sct **pl_lst; /* start with twice the grid size as we may be splitting the cells along the Greenwich meridian or dateline */ /* realloc at the end */ pl_lst=(poly_sct**)nco_malloc( sizeof (poly_sct*) * grd_sz *2 ); // printf("About to print poly sct grd_sz=%d grd_crn_nbr=%d\n", grd_sz, grd_crn_nbr); for(idx=0;idx<grd_sz; idx++) { /* check mask and area */ if( msk[idx]==0 || area[idx] == 0.0) continue; pl=nco_poly_init_lst(pl_typ, grd_crn_nbr,0, idx, lon_ptr, lat_ptr); lon_ptr+=(size_t)grd_crn_nbr; lat_ptr+=(size_t)grd_crn_nbr; /* if poly is less than a triangle then null is returned*/ if(!pl) continue; /* add min max */ nco_poly_minmax_add(pl, grd_lon_typ, False); nco_poly_re_org(pl, lcl_dp_x, lcl_dp_y); /* use Charlie's formula */ nco_poly_area_add(pl); //if(pl->dp_x_minmax[0] <0.0 || (pl->dp_x_minmax[1] - pl->dp_x_minmax[0]) > 30 ) if( !(pl->dp_x_minmax[1] - pl->dp_x_minmax[0] < 180.0 && lon_ctr[idx] >= pl->dp_x_minmax[0] && lon_ctr[idx] <= pl->dp_x_minmax[1] )) { (void)fprintf(stdout, "/***%s: %s: invalid polygon to follow *******?", nco_prg_nm_get(), fnc_nm); nco_poly_prn(pl, 0); pl=nco_poly_free(pl); continue; } //fprintf(stdout,"/***** input polygon pl lon center=%f convex=%s\n ********************/\n", lon_ctr[idx], (nco_poly_is_convex(pl) ? "True": "False") ); //nco_poly_prn(pl, 0); /* check for wrapping -center outside min/max range */ bwrp=( lon_ctr[idx] < pl->dp_x_minmax[0] || lon_ctr[idx] > pl->dp_x_minmax[1] ); if( grd_lon_typ == nco_grd_lon_nil || grd_lon_typ == nco_grd_lon_unk ) { if( !bwrp ) { pl_lst[idx_cnt++]=pl; } else { (void)fprintf(stdout, "%s: polygon(%d) wrapped - but grd_lon_typ not specified \n", nco_prg_nm_get(), idx); (void)fprintf(stdout, "/*******************************************/\n"); pl=nco_poly_free(pl); } continue; } /* if we are here then grd_lon_typ specifys a grid type */ if( !bwrp) { pl_lst[idx_cnt++]=pl; } /* cell width exceeds max so assume wrapping */ else if( nco_poly_wrp_splt(pl, grd_lon_typ, &pl_wrp_left, &pl_wrp_right ) == NCO_NOERR ) { fprintf(stdout,"/***** pl, wrp_left, wrp_right ********************/\n"); if(pl_wrp_left) { nco_poly_re_org(pl_wrp_left, lcl_dp_x, lcl_dp_y); pl_lst[idx_cnt++]=pl_wrp_left; nco_poly_prn(pl_wrp_left, 2); } if(pl_wrp_right) { nco_poly_re_org(pl_wrp_right, lcl_dp_x, lcl_dp_y); pl_lst[idx_cnt++]=pl_wrp_right; nco_poly_prn(pl_wrp_right, 2); } pl=nco_poly_free(pl); fprintf(stdout,"/**********************************/\n"); cnt_wrp_good++; } else { if(nco_dbg_lvl_get() >= nco_dbg_std ){ (void)fprintf(stdout, "%s: split wrapping didn't work on this polygon(%d)\n", nco_prg_nm_get(), idx ); (void)fprintf(stdout, "/********************************/\n"); } pl=nco_poly_free(pl); } } if(nco_dbg_lvl_get() >= nco_dbg_std ) (void)fprintf(stdout, "%s: %s size input list(%lu), size output list(%d), num of split polygons(%d)\n", nco_prg_nm_get(),fnc_nm, grd_sz, idx_cnt, cnt_wrp_good); pl_lst=(poly_sct**)nco_realloc( pl_lst, (size_t)idx_cnt * sizeof (poly_sct*) ); *pl_nbr=idx_cnt; return pl_lst; } poly_sct ** /* [O] [nbr] size of array */ nco_poly_lst_mk_rll( double *area, /* I [sr] Area of source grid */ int *msk, /* I [flg] Mask on source grid */ double *lat_ctr, /* I [dgr] Latitude centers of source grid */ double *lon_ctr, /* I [dgr] Longitude centers of source grid */ double *lat_crn, /* I [dgr] Latitude corners of source grid */ double *lon_crn, /* I [dgr] Longitude corners of source grid */ size_t grd_sz, /* I [nbr] Number of elements in single layer of source grid */ long grd_crn_nbr, /* I [nbr] Maximum number of corners in source gridcell */ nco_grd_lon_typ_enm grd_lon_typ) /* I [num] */ { int idx=0; int wrp_cnt=0; int wrp_y_cnt=0; int msk_cnt=0; const char fnc_nm[]="nco_poly_lst_mk_rll()"; nco_bool bwrp; /* no polar caps on a RLL grid */ nco_bool bchk_caps=False; double tot_area=0.0; double *lat_ptr=lat_crn; double *lon_ptr=lon_crn; poly_sct *pl=(poly_sct*)NULL_CEWI; /* contains plain struct sct with bmsk=False; */ poly_sct *pl_msk=((poly_sct*)NULL_CEWI); poly_sct **pl_lst; /* list size is grd_sz - invalid or masked polygons are repesented by a poly_sct->bmsk=False */ pl_lst=(poly_sct**)nco_malloc( sizeof (poly_sct*) * grd_sz); pl_msk=nco_poly_init(); pl_msk->bmsk=False; /* filter out wrapped lon cells */ if( grd_lon_typ == nco_grd_lon_nil || grd_lon_typ == nco_grd_lon_unk || grd_lon_typ == nco_grd_lon_bb ) bwrp=False; else bwrp=True; // printf("About to print poly sct grd_sz=%d grd_crn_nbr=%d\n", grd_sz, grd_crn_nbr); for(idx=0;idx<grd_sz; idx++) { /* check mask and area */ if(area[idx] == 0.0 ) { pl_lst[idx]= nco_poly_dpl(pl_msk); msk_cnt++; continue; } pl=nco_poly_init_lst(poly_rll, grd_crn_nbr,0, idx, lon_ptr, lat_ptr); lon_ptr+=(size_t)grd_crn_nbr; lat_ptr+=(size_t)grd_crn_nbr; /* if poly is less than a triangle then null is returned*/ if(!pl ) { if(nco_dbg_lvl_get()>= nco_dbg_dev) fprintf(stderr, "%s(): WARNING cell(id=%d) less than a triange\n", fnc_nm, idx); pl_lst[idx]= nco_poly_dpl(pl_msk); msk_cnt++; continue; } /* add centroid from input */ pl->dp_x_ctr=lon_ctr[idx]; pl->dp_y_ctr=lat_ctr[idx]; /* pop shp */ nco_poly_shp_pop(pl); /* add min max */ nco_poly_minmax_add(pl, grd_lon_typ, bchk_caps); /* if coords cannot deal with wrapping */ if( pl->bwrp && bwrp==False ) { pl=nco_poly_free(pl); pl_lst[idx]= nco_poly_dpl(pl_msk); msk_cnt++; continue; } /* The area of an RLL grid needs to be re-calculated as we have to take account of lines of latitude as great circles */ nco_poly_area_add(pl); /* area NOT set so add to the area - nb this will be eventually written to the map file in nco_map_mk */ if(area[idx]==-1.0) area[idx]=pl->area; /* we still need the area even though its masked */ if(!msk[idx]) pl->bmsk=False; /* simple center of a rll cell - should always be inside of polygon */ nco_poly_ctr_add(pl, grd_lon_typ); if(nco_dbg_lvl_get()>= nco_dbg_dev ) if(pl->bwrp) nco_poly_prn(pl,0); /* for debugging */ tot_area+=pl->area; /* for debugging total number of wrapped cells */ wrp_cnt+=pl->bwrp; pl_lst[idx]=pl; } if(nco_dbg_lvl_get() >= nco_dbg_dev ) (void)fprintf(stderr, "%s: %s size input list(%lu), size output list(%lu) total area=%.15e num wrapped= %d num caps=%d num masked=%d\n", nco_prg_nm_get(),fnc_nm, grd_sz, grd_sz, tot_area, wrp_cnt, wrp_y_cnt, msk_cnt); pl_msk=nco_poly_free(pl_msk); return pl_lst; } poly_sct ** /* [O] [nbr] size of array */ nco_poly_lst_mk_sph( double *area, /* I [sr] Area of source grid */ int *msk, /* I [flg] Mask on source grid */ double *lat_ctr, /* I [dgr] Latitude centers of source grid */ double *lon_ctr, /* I [dgr] Longitude centers of source grid */ double *lat_crn, /* I [dgr] Latitude corners of source grid */ double *lon_crn, /* I [dgr] Longitude corners of source grid */ size_t grd_sz, /* I [nbr] Number of elements in single layer of source grid */ long grd_crn_nbr, /* I [nbr] Maximum number of corners in source gridcell */ nco_grd_lon_typ_enm grd_lon_typ) /* I [num] */ { int idx=0; int wrp_cnt=0; int wrp_y_cnt=0; int msk_cnt=0; const char fnc_nm[]="nco_poly_lst_mk_sph()"; nco_bool bwrp; /* check to see if cell is a polar cap */ nco_bool bchk_caps=True; double tot_area=0.0; double *lat_ptr=lat_crn; double *lon_ptr=lon_crn; /* buffers used in nco-poly_re_org() */ poly_sct *pl=(poly_sct*)NULL_CEWI; /* contains plain struct sct with bmsk=False; */ poly_sct *pl_msk=((poly_sct*)NULL_CEWI); poly_sct **pl_lst; /* list size is grd_sz - invalid or masked polygons are repesented by a poly_sct->bmsk=False */ pl_lst=(poly_sct**)nco_malloc( sizeof (poly_sct*) * grd_sz); pl_msk=nco_poly_init(); pl_msk->bmsk=False; /* filter out wrapped lon cells */ if( grd_lon_typ == nco_grd_lon_nil || grd_lon_typ == nco_grd_lon_unk || grd_lon_typ == nco_grd_lon_bb ) bwrp=False; else bwrp=True; // printf("About to print poly sct grd_sz=%d grd_crn_nbr=%d\n", grd_sz, grd_crn_nbr); for(idx=0;idx<grd_sz; idx++) { /* check area */ if(area[idx] == 0.0 ) { pl_lst[idx]= nco_poly_dpl(pl_msk); msk_cnt++; continue; } pl=nco_poly_init_lst(poly_sph, grd_crn_nbr,0, idx, lon_ptr, lat_ptr); lon_ptr+=(size_t)grd_crn_nbr; lat_ptr+=(size_t)grd_crn_nbr; /* if poly is less than a triangle then null is returned*/ if(!pl ) { if(nco_dbg_lvl_get()>= nco_dbg_dev) fprintf(stderr, "%s(): WARNING cell(id=%d) less than a triange\n", fnc_nm, idx); pl_lst[idx]= nco_poly_dpl(pl_msk); msk_cnt++; continue; } /* add centroid from input */ pl->dp_x_ctr=lon_ctr[idx]; pl->dp_y_ctr=lat_ctr[idx]; /* pop shp */ nco_poly_shp_pop(pl); /* add min max */ nco_poly_minmax_add(pl, grd_lon_typ, bchk_caps); /* if coords cannot deal with wrapping */ if( pl->bwrp && bwrp==False ) { pl=nco_poly_free(pl); pl_lst[idx]= nco_poly_dpl(pl_msk); msk_cnt++; continue; } /* The area of an RLL grid needs to be re-calculated as we have to take account of lines of latitude as great circles */ nco_poly_area_add(pl); /* area NOT set so add to the area - nb this will be eventually written to the map file in nco_map_mk */ if(area[idx]==-1.0) area[idx]=pl->area; /* fxm:2019-06-07 - there is a problem using the polygon center as a control point as * for some RLL grids the center of a polar triangle can be the pole */ /* The centroid can be outside of a convex polygon * for nco_sph_intersect_pre() to work correctly it requires a point INSIDE the convex polygon * So we use a custom function : * just remember FROM HERE on that the pl->dp_x_ctr, pl->dp_y_ctr iS NOT the Centroid * */ /* if(nco_sph_inside_mk(pl,pControl )) { pl->dp_x_ctr=R2D(pControl[3]); pl->dp_y_ctr=R2D(pControl[4]); } else nco_poly_ctr_add(pl, grd_lon_typ); */ /* even if masked we still need the area */ if(!msk[idx]) { /* pl_lst[idx]=nco_poly_dpl(pl_msk); pl_lst[idx]->area=pl->area; msk_cnt++; pl=nco_poly_free(pl); continue; */ pl->bmsk=False; msk_cnt++; } if(nco_dbg_lvl_get()>= nco_dbg_dev ) if(pl->bwrp) nco_poly_prn(pl,0); /* for debugging */ tot_area+=pl->area; /* for debugging total number of wrapped cells */ wrp_cnt+=pl->bwrp; wrp_y_cnt+=pl->bwrp_y; pl_lst[idx]=pl; } if(nco_dbg_lvl_get() >= nco_dbg_dev ) (void)fprintf(stderr, "%s: %s size input list(%lu), size output list(%lu) total area=%.15e num wrapped= %d num caps=%d num masked=%d\n", nco_prg_nm_get(),fnc_nm, grd_sz, grd_sz, tot_area, wrp_cnt, wrp_y_cnt, msk_cnt); pl_msk=nco_poly_free(pl_msk); return pl_lst; } poly_sct ** nco_poly_lst_free( poly_sct **pl_lst, int arr_nbr) { int idx; for(idx=0; idx<arr_nbr; idx++) pl_lst[idx]=nco_poly_free(pl_lst[idx]); pl_lst=(poly_sct**)nco_free(pl_lst); return pl_lst; } void nco_poly_set_priority( int nbr_lst, KDPriority *list){ int idx; for(idx=0;idx<nbr_lst;idx++){ list[idx].dist = 1.1; list[idx].elem = (KDElem*)NULL; } return ; } poly_sct ** nco_poly_lst_mk_vrl_crt( /* create overlap mesh for crt polygons */ poly_sct **pl_lst_in, int pl_cnt_in, KDTree *rtree, int *pl_cnt_vrl_ret){ /* just duplicate output list to overlap */ size_t idx; size_t jdx; int max_nbr_vrl=1000; int pl_cnt_vrl=0; //nco_bool bSort=True; const char fnc_nm[]="nco_poly_mk_vrl_crt()"; /* buffers used in nco-poly_re_org() */ double lcl_dp_x[VP_MAX]={0}; double lcl_dp_y[VP_MAX]={0}; kd_box size; poly_sct ** pl_lst_vrl=NULL_CEWI; KDPriority *list; list = (KDPriority *)nco_calloc(sizeof(KDPriority),(size_t)max_nbr_vrl); printf("INFO - entered function nco_poly_mk_vrl\n"); /* start main loop over input polygons */ for(idx=0 ; idx<pl_cnt_in ;idx++ ) { int cnt_vrl=0; int cnt_vrl_on=0; (void)nco_poly_set_priority(max_nbr_vrl,list); /* get bounds of polygon in */ size[KD_LEFT] = pl_lst_in[idx]->dp_x_minmax[0]; size[KD_RIGHT] = pl_lst_in[idx]->dp_x_minmax[1]; size[KD_BOTTOM] = pl_lst_in[idx]->dp_y_minmax[0]; size[KD_TOP] = pl_lst_in[idx]->dp_y_minmax[1]; /* find overlapping polygons */ // cnt_vrl=kd_nearest_intersect(rtree, size, max_nbr_vrl,list,bSort ); /* nco_poly_prn(2, pl_lst_in[idx] ); */ for(jdx=0; jdx <cnt_vrl ;jdx++){ poly_sct *pl_vrl=(poly_sct*)NULL_CEWI; poly_sct *pl_out=(poly_sct*)list[jdx].elem->item; ; // nco_poly_prn(2, pl_out); /* check for polygon in polygon first */ if( nco_crt_poly_in_poly(pl_lst_in[idx], pl_out) == pl_out->crn_nbr ) { //fprintf(stderr,"%s: using poly_in_poly()\n", fnc_nm); pl_vrl=nco_poly_dpl(pl_out); } else pl_vrl= nco_poly_vrl_do(pl_lst_in[idx], pl_out, 0, (char*)NULL); if(pl_vrl){ nco_poly_re_org(pl_vrl, lcl_dp_x, lcl_dp_y); /* add area */ nco_poly_area_add(pl_vrl); /* shp not needed */ nco_poly_shp_free(pl_vrl); pl_lst_vrl=(poly_sct**)nco_realloc(pl_lst_vrl, sizeof(poly_sct*) * (pl_cnt_vrl+1)); pl_lst_vrl[pl_cnt_vrl]=pl_vrl; pl_cnt_vrl++; cnt_vrl_on++; if(nco_poly_is_convex(pl_vrl) == False ) { fprintf(stderr,"%s: %s vrl polygon convex=0 vrl ,in convex=%d ,out convex=%d\n", nco_prg_nm_get(), fnc_nm, nco_poly_is_convex(pl_lst_in[idx]), nco_poly_is_convex(pl_out) ); nco_poly_prn(pl_vrl, 2); nco_poly_prn(pl_lst_in[idx], 2); nco_poly_prn(pl_out, 2); } //fprintf(stderr,"Overlap polygon to follow\n"); //nco_poly_prn(2, pl_vrl); } } if( nco_dbg_lvl_get() >= nco_dbg_dev ) (void) fprintf(stderr, "%s: total overlaps=%d for polygon %lu - potential overlaps=%d actual overlaps=%d\n", nco_prg_nm_get(), pl_cnt_vrl, idx, cnt_vrl, cnt_vrl_on); } list = (KDPriority *)nco_free(list); /* return size of list */ *pl_cnt_vrl_ret=pl_cnt_vrl; return pl_lst_vrl; } void ** nco_poly_lst_mk_vrl( /* create overlap mesh for sph polygons */ poly_sct **pl_lst_in, int pl_cnt_in, nco_grd_lon_typ_enm grd_lon_typ, poly_typ_enm pl_typ, KDTree **tree, int nbr_tr, int lst_out_typ, int *pl_cnt_vrl_ret){ /* just duplicate output list to overlap */ const char fnc_nm[]="nco_poly_lst_mk_vrl()"; nco_bool bDirtyRats=False; nco_bool bSort=True; int pl_cnt_vrl=0; int thr_idx=0; int pl_cnt_dbg=0; int tot_nan_cnt=0; int tot_wrp_cnt=0; /* approx number of input cells each thread will process */ int thr_quota; /* reporting step */ int thr_quota_step; size_t idx; // size_t ldx; int lcl_thr_nbr; omp_mem_sct *mem_lst=NULL_CEWI; double tot_area=0.0; void **void_lst_vrl=NULL_CEWI; poly_sct **pl_lst_dbg=NULL_CEWI; FILE * const fp_stderr=stderr; lcl_thr_nbr=omp_get_max_threads(); mem_lst=(omp_mem_sct*)nco_malloc(sizeof(omp_mem_sct)*lcl_thr_nbr); for(idx=0;idx<lcl_thr_nbr;idx++){ mem_lst[idx].pl_lst=NULL_CEWI; mem_lst[idx].wgt_lst=NULL_CEWI; mem_lst[idx].blk_nbr=0; mem_lst[idx].pl_cnt=0; mem_lst[idx].kd_cnt=0; mem_lst[idx].kd_blk_nbr=0; mem_lst[idx].idx_cnt=0; mem_lst[idx].kd_list=NULL_CEWI; /* mem_lst[idx].kd_list=(KDPriority **)nco_malloc(sizeof(KDPriority*)*(size_t)(NCO_VRL_BLOCKSIZE)); for(ldx=0;ldx<NCO_VRL_BLOCKSIZE;ldx++) mem_lst[idx].kd_list[ldx]=(KDPriority*)nco_calloc(1, sizeof(KDPriority) ); */ /* remember this modifies kd_list, kd_blk_nbr */ kd_list_realloc(&mem_lst[idx],1 ); } thr_quota=pl_cnt_in/lcl_thr_nbr; thr_quota_step=thr_quota/20; if( thr_quota_step <2000 ) thr_quota_step=2000; /* NB: "OpenMP notes" section of nco_rgr.c has detailed discussion of these settings Henry, please keep the variables in alphabetical order within a clause and remember to update Intel */ #ifdef __GNUG__ # define GCC_LIB_VERSION ( __GNUC__ * 100 + __GNUC_MINOR__ * 10 + __GNUC_PATCHLEVEL__ ) # if GCC_LIB_VERSION < 490 # define GXX_OLD_OPENMP_SHARED_TREATMENT 1 # endif /* 480 */ #endif /* !__GNUC__ */ #if defined(__INTEL_COMPILER) # pragma omp parallel for private(idx,thr_idx) schedule(dynamic,40) shared(bDirtyRats,bSort,grd_lon_typ,nbr_tr,pl_cnt_dbg,pl_typ,tree,tot_nan_cnt,tot_wrp_cnt) #else /* !__INTEL_COMPILER */ # ifdef GXX_OLD_OPENMP_SHARED_TREATMENT # pragma omp parallel for default(none) private(idx,thr_idx) shared(bDirtyRats,bSort,grd_lon_typ,nbr_tr,pl_cnt_dbg,pl_typ,tree,tot_nan_cnt,tot_wrp_cnt) # else /* !old g++ */ # pragma omp parallel for private(idx,thr_idx) schedule(dynamic,40) shared(bDirtyRats,bSort,grd_lon_typ,mem_lst, nbr_tr,pl_cnt_dbg,pl_typ,tree,tot_nan_cnt,tot_wrp_cnt) # endif /* !old g++ */ #endif /* !__INTEL_COMPILER */ for(idx=0;idx<pl_cnt_in;idx++){ nco_bool bSplit=False; int vrl_cnt = 0; int vrl_cnt_on = 0; int nan_cnt=0; int wrp_cnt=0; size_t jdx; double vrl_area = 0.0; kd_box size1; kd_box size2; // (void) nco_poly_set_priority(max_nbr_vrl, list); thr_idx=omp_get_thread_num(); if (0 && nco_dbg_lvl_get() >= nco_dbg_dev) fprintf(fp_stderr, "%s(): idx=%lu thr=%d\n",fnc_nm, idx, thr_idx); if(pl_lst_in[idx]->bmsk==False) goto cont_msk; /* need to iterate mem_lst diagnostics at end of loop*/ mem_lst[thr_idx].kd_cnt=0; if(mem_lst[thr_idx].kd_blk_nbr > 1) kd_list_realloc( &mem_lst[thr_idx],1); /* if a wrapped polygon then split and do two searches */ bSplit=nco_poly_minmax_split(pl_lst_in[idx],grd_lon_typ,size1,size2); if(bSplit){ vrl_cnt=kd_nearest_intersect(tree, nbr_tr, size1, &mem_lst[thr_idx], False); vrl_cnt=kd_nearest_intersect(tree, nbr_tr, size2, &mem_lst[thr_idx], False); }else{ vrl_cnt=kd_nearest_intersect(tree, nbr_tr, size1, &mem_lst[thr_idx], False); } /* nco_poly_prn(2, pl_lst_in[idx] ); */ /* nb this func below sorts list - and then places duplicates at the end, then returns the new size */ if(vrl_cnt) vrl_cnt=kd_list_sort_omp(&mem_lst[thr_idx],vrl_cnt); for(jdx=0;jdx<vrl_cnt;jdx++){ poly_sct *pl_vrl = NULL_CEWI; poly_sct *pl_out = (poly_sct *) mem_lst[thr_idx].kd_list[jdx]->elem->item; /* for area debug only */ mem_lst[thr_idx].kd_list[jdx]->area=-1.0; mem_lst[thr_idx].kd_list[jdx]->dbg_sng[0]='\0'; /* if (pl_lst_in[idx]->pl_typ != pl_out->pl_typ) { fprintf(stderr, "%s: %s poly type mismatch\n", nco_prg_nm_get(), fnc_nm); continue; } */ if(pl_typ== poly_rll){ pl_vrl = nco_poly_vrl_do(pl_lst_in[idx], pl_out, 0, (char*)NULL); /* if pl_vrl is NULL from, nco_poly_do_vrl() then there are 3 possible senario's * * 1) pl_lst_in[idx] and pl_out are seperate and distinct * * 2) pl_lst_in[idx] is entirely inside pl_out. * to check for this it is sufficent to check the * the minmax bounds and then also check that a single vertex * from pl_lst_in[idx] is inside pl_out * * 3) pl_out is entirely inside pl_lst_in[idx] * check minmax bounds then check a single vertex from * pl_out */ if(!pl_vrl){ if(nco_poly_in_poly_minmax(pl_lst_in[idx],pl_out)) pl_vrl=nco_poly_dpl(pl_out); else if(nco_poly_in_poly_minmax(pl_out,pl_lst_in[idx])) pl_vrl=nco_poly_dpl(pl_lst_in[idx]); } if(pl_vrl){ /* add area nb also sets wrapping */ nco_poly_minmax_add(pl_vrl, grd_lon_typ, False); /* REMEMBER poly_rll area uses minmax limits AND NOT VERTEX's */ nco_poly_area_add(pl_vrl); } } if(pl_typ == poly_sph){ int lret=0; int lret2=0; /* [flg] set by nco_sph_intersect_pre - if True it means that scan hase detected a genuine intersection so * so no need to do further processing */ nco_bool bGenuine=False; nco_bool bBadArea=False; char in_sng[VP_MAX]; char out_sng[VP_MAX]; int flg_snp_to=2; in_sng[0]='\0'; out_sng[0]='\0'; nco_sph_intersect_pre(pl_lst_in[idx], pl_out, in_sng); if(0 && nco_dbg_lvl_get() >= nco_dbg_dev) (void)fprintf(stderr,"%s:%s(): sp_sng=%s \n",nco_prg_nm_get(),fnc_nm, in_sng ); lret = nco_sph_process_pre(pl_out, in_sng, &bGenuine); switch(lret){ case 1: pl_vrl = nco_poly_dpl(pl_out); break; case 2: pl_vrl = nco_poly_vrl_do(pl_lst_in[idx], pl_out, flg_snp_to, (char *)NULL); break; case 3: pl_vrl = nco_poly_vrl_do(pl_lst_in[idx], pl_out, flg_snp_to, in_sng); break; case 4: pl_vrl = nco_poly_vrl_do(pl_lst_in[idx], pl_out, flg_snp_to, (char*)NULL); break; case 5: pl_vrl = nco_poly_vrl_do(pl_lst_in[idx], pl_out, flg_snp_to, in_sng); break; } if(pl_vrl){ double min_area= (pl_out->area < pl_lst_in[idx]->area ? pl_out->area : pl_lst_in[idx]->area); /* add area nb also sets wrapping */ nco_poly_minmax_add(pl_vrl, grd_lon_typ, False); /* REMEMBER poly_rll area uses minmax limits AND NOT VERTEX's */ nco_poly_area_add(pl_vrl); if( isnan( pl_vrl->area) || pl_vrl->area == 0.0 || (pl_vrl->area - min_area)/ min_area > 1.0e-04 ){ pl_vrl = nco_poly_free(pl_vrl); bBadArea=True; } } /* swap args around and try again */ if(!pl_vrl && ((bGenuine == False && lret != 1) || bBadArea)){ flg_snp_to=1; nco_sph_intersect_pre(pl_out, pl_lst_in[idx], out_sng); lret2 = nco_sph_process_pre(pl_lst_in[idx], out_sng, &bGenuine); switch(lret2){ case 1: pl_vrl = nco_poly_dpl(pl_lst_in[idx]); break; case 2: pl_vrl = nco_poly_vrl_do(pl_out, pl_lst_in[idx], flg_snp_to, (char *)NULL); break; case 3: pl_vrl = nco_poly_vrl_do(pl_out, pl_lst_in[idx], flg_snp_to, out_sng); break; case 4: pl_vrl = nco_poly_vrl_do(pl_out, pl_lst_in[idx], flg_snp_to, (char*)NULL); break; case 5: pl_vrl = nco_poly_vrl_do(pl_out, pl_lst_in[idx], flg_snp_to, out_sng); break; } if(pl_vrl){ nco_poly_minmax_add(pl_vrl, grd_lon_typ, False); nco_poly_area_add(pl_vrl); } } if(bDirtyRats) sprintf(mem_lst[thr_idx].kd_list[jdx]->dbg_sng, "lret=%d in_sng=%s lret2=%d out_sng=%s\n",lret, in_sng, lret2, out_sng); if(bDirtyRats && pl_vrl && !nco_sph_is_convex(pl_vrl->shp,pl_vrl->crn_nbr)){ (void) fprintf(stderr, "/************* concave overlap plygon***********/\n"); nco_poly_prn(pl_lst_in[idx],0); nco_poly_prn(pl_out,0); nco_poly_prn(pl_vrl, 0); (void) fprintf(stderr, "/***********************************************/\n"); } } /* end if poly_sph */ if (pl_vrl) { // nco_poly_re_org(pl_vrl, lcl_dp_x, lcl_dp_y); /* add aprropriate id's */ pl_vrl->src_id = pl_lst_in[idx]->src_id; pl_vrl->dst_id = pl_out->src_id; /* shp not needed */ nco_poly_shp_free(pl_vrl); /* calculate weight -simple ratio of areas */ pl_vrl->wgt=pl_vrl->area / pl_out->area; /* add lat/lon centers */ nco_poly_ctr_add(pl_vrl, grd_lon_typ); wrp_cnt+=pl_vrl->bwrp; if(isnan(pl_vrl->area) || pl_vrl->area == 0.0){ nan_cnt++; pl_vrl->area=0.0; pl_vrl=nco_poly_free(pl_vrl); continue; } /* for input polygon wgt is used to calculate frac_a */ pl_lst_in[idx]->wgt+= ( pl_vrl->area / pl_lst_in[idx]->area ); /* #ifdef _OPENMP #pragma omp critical #endif { pl_out->wgt+=pl_vrl->wgt; } */ vrl_area += pl_vrl->area; mem_lst[thr_idx].kd_list[jdx]->area=pl_vrl->area; if( mem_lst[thr_idx].blk_nbr * NCO_VRL_BLOCKSIZE < mem_lst[thr_idx].pl_cnt + 1){ if(lst_out_typ == 1) mem_lst[thr_idx].wgt_lst= (wgt_sct**)nco_realloc(mem_lst[thr_idx].wgt_lst, sizeof(wgt_sct*) * ++mem_lst[thr_idx].blk_nbr * NCO_VRL_BLOCKSIZE ); else if(lst_out_typ == 2) mem_lst[thr_idx].pl_lst= (poly_sct**)nco_realloc(mem_lst[thr_idx].pl_lst, sizeof(poly_sct*) * ++mem_lst[thr_idx].blk_nbr * NCO_VRL_BLOCKSIZE); } if(lst_out_typ==1) { wgt_sct *wgt_lcl=(wgt_sct*)nco_calloc(1,sizeof(wgt_sct)); wgt_lcl->src_id=pl_vrl->src_id; wgt_lcl->dst_id=pl_vrl->dst_id; wgt_lcl->area=pl_vrl->area; wgt_lcl->wgt=pl_vrl->wgt; mem_lst[thr_idx].wgt_lst[mem_lst[thr_idx].pl_cnt++] =wgt_lcl; pl_vrl=nco_poly_free(pl_vrl); } else if(lst_out_typ==2 ) mem_lst[thr_idx].pl_lst[mem_lst[thr_idx].pl_cnt++] = pl_vrl; vrl_cnt_on++; /* for area debug only */ } } /* end jdx */ if (nco_dbg_lvl_get() >= nco_dbg_dev) { #ifdef _OPENMP #pragma omp critical #endif { tot_nan_cnt += nan_cnt; tot_wrp_cnt += wrp_cnt; tot_area += vrl_area; } /* end OMP critical */ /* area diff by more than 10% */ int kdx; double eps = 1.0e-8; double frc = vrl_area / pl_lst_in[idx]->area; if (frc < (1 - eps) || frc > 1 + eps) { (void) fprintf(fp_stderr, "%s: polygon %lu - potential overlaps=%d actual overlaps=%d area_in=%.10e vrl_area=%.10e adiff=%.15e bSplit=%d\n", nco_prg_nm_get(), idx, vrl_cnt, vrl_cnt_on, pl_lst_in[idx]->area, vrl_area, (pl_lst_in[idx]->area - vrl_area), bSplit); if(bDirtyRats){ //if (pl_lst_in[idx]->bwrp ) { if (1) { (void) fprintf(fp_stderr, "# /** following pl_lst_in[%lu] **/\n", idx); nco_poly_prn(pl_lst_in[idx], 0); (void) fprintf(fp_stderr, "# /** overlaps to follow **/\n"); for (kdx = 0; kdx < vrl_cnt; kdx++) { nco_poly_prn((poly_sct *) mem_lst[thr_idx].kd_list[kdx]->elem->item, 0); (void)fprintf(fp_stderr, "# vrl_area=%.15e\n",mem_lst[thr_idx].kd_list[kdx]->area ); (void)fprintf(fp_stderr, "# dbg_sng=%s\n",mem_lst[thr_idx].kd_list[kdx]->dbg_sng ); } (void) fprintf(stderr, "/************* end dirty rats ***************/\n"); } if(1 && vrl_cnt_on > 0 && lst_out_typ == 2){ pl_lst_dbg = (poly_sct **) nco_realloc(pl_lst_dbg, sizeof(poly_sct *) * (pl_cnt_dbg + vrl_cnt_on)); /* write overlaps maybe */ for (kdx = 0; kdx < vrl_cnt_on; kdx++){ poly_sct * lcl_poly=mem_lst[thr_idx].pl_lst[mem_lst[thr_idx].pl_cnt - vrl_cnt_on + kdx]; if(lcl_poly->src_id== pl_lst_in[idx]->src_id ) pl_lst_dbg[pl_cnt_dbg++] = nco_poly_dpl(lcl_poly); } } } } } /* end dbg */ cont_msk: ; /* output some usefull tracking stuff - not debug but informative */ if ( ++mem_lst[thr_idx].idx_cnt % thr_quota_step == 0 && nco_dbg_lvl_get() >=3 ) (void)fprintf(fp_stderr, "%s: thread %d has processed %2.2f%% (%ld) of src cells quota and output %ld overlap cells\n", nco_prg_nm_get(), thr_idx, (float)mem_lst[thr_idx].idx_cnt/(float)thr_quota *100.0, mem_lst[thr_idx].idx_cnt, mem_lst[thr_idx].pl_cnt ); } /* end for idx */ /* turn tot_area into a % of 4*PI */ /* tot_area = tot_area / 4.0 / M_PI *100.0; */ /* final report */ if (nco_dbg_lvl_get() >= nco_dbg_dev) (void) fprintf(stderr, "%s: total overlaps=%d, total_area=%.15f (area=%3.10f%%) total num wrapped= %d total nan nbr=%d \n", nco_prg_nm_get(), pl_cnt_vrl, tot_area, tot_area /4.0 / M_PI *100.0, tot_wrp_cnt, tot_nan_cnt); /* write filtered polygons to file */ if(bDirtyRats && pl_cnt_dbg){ nco_msh_poly_lst_wrt("tst-wrt-dbg.nc", pl_lst_dbg, pl_cnt_dbg, grd_lon_typ,NC_FORMAT_NETCDF4); pl_lst_dbg=(poly_sct **)nco_poly_lst_free(pl_lst_dbg, pl_cnt_dbg); } /* concatenate memory list, place results into first member list */ nco_mem_lst_cat(mem_lst, lcl_thr_nbr); /* free up kd_list's */ for(idx=0;idx<lcl_thr_nbr;idx++) kd_list_realloc(&mem_lst[idx],0); *pl_cnt_vrl_ret=mem_lst[0].pl_cnt; if(lst_out_typ == 1) void_lst_vrl=(void **)mem_lst[0].wgt_lst; else if(lst_out_typ == 2) void_lst_vrl=(void **)mem_lst[0].pl_lst; mem_lst=(omp_mem_sct*)nco_free(mem_lst); /* REMEMBER the void type can be a wgt_sct** array or a poly_sct** array * wgt_sct is a subset of poly_sct - with simple members */ return void_lst_vrl; } /* check areas - nb WARNING modifies area in pl_lst_in and pl_lst_out */ void nco_poly_lst_chk( poly_sct **pl_lst_in, int pl_cnt_in, poly_sct **pl_lst_out, int pl_cnt_out, poly_sct **pl_lst_vrl, int pl_cnt_vrl) { int id; int idx; int jdx; double epsilon=1.0e-8; const char fnc_nm[]="nco_poly_lst_chk()"; for(idx=0;idx<pl_cnt_vrl;idx++) { id=pl_lst_vrl[idx]->src_id; for(jdx=0;jdx<pl_cnt_in;jdx++) if(pl_lst_in[jdx]->src_id==id) break; if(jdx < pl_cnt_in ) pl_lst_in[jdx]->area-=pl_lst_vrl[idx]->area; } fprintf(stderr, "%s():WARNING following is list of incomplete src cells, by src_id no\n",fnc_nm); for(idx=0;idx<pl_cnt_in;idx++) if( fabs( pl_lst_in[idx]->area) > epsilon) fprintf(stderr, "src_id=%d area=%.10f\n", pl_lst_in[idx]->src_id, pl_lst_in[idx]->area ); for(idx=0;idx<pl_cnt_vrl;idx++) { id=pl_lst_vrl[idx]->dst_id; for(jdx=0;jdx<pl_cnt_out;jdx++) if(pl_lst_out[jdx]->src_id==id) break; if(jdx < pl_cnt_out ) pl_lst_out[jdx]->area-=pl_lst_vrl[idx]->area; } fprintf(stderr, "%s():WARNING following is list of incomplete dst cells, by src_id no\n",fnc_nm); for(idx=0;idx<pl_cnt_out;idx++) if( fabs( pl_lst_out[idx]->area) > epsilon) fprintf(stderr, "src_id=%d area=%.10f\n", pl_lst_out[idx]->src_id, pl_lst_out[idx]->area ); return; } poly_sct ** nco_poly_lst_chk_dbg( poly_sct **pl_lst, int pl_cnt, poly_sct **pl_lst_vrl, int pl_cnt_vrl, int io_flg, /* [flg] 0 - use src_id from vrl, 1 - use dst_id from vrl */ int *pl_cnt_dbg) /* size of output dbg grid */ { int id; int idx; int jdx; int pl_nbr_dbg=0; double epsilon=1.0e-12; double *area=NULL_CEWI; nco_bool is_lst_cnt=False; /* if true then pl_cnt matches max src_id There are no missing records from NetCDF SCRIP input */ is_lst_cnt=( pl_cnt== pl_lst[pl_cnt-1]->src_id +1); poly_sct **pl_lst_dbg=NULL_CEWI; const char fnc_nm[]="nco_poly_lst_chk_dbg()"; area=(double*)nco_malloc(sizeof(double)*pl_cnt); for(idx=0;idx<pl_cnt;idx++) if(!pl_lst[idx]->bmsk) area[idx]=0.0; else area[idx]=pl_lst[idx]->area; for(idx=0;idx<pl_cnt_vrl;idx++) { id = (io_flg ? pl_lst_vrl[idx]->dst_id : pl_lst_vrl[idx]->src_id); if(is_lst_cnt ) area[id] -= pl_lst_vrl[idx]->area; else { for (jdx = 0; jdx < pl_cnt; jdx++) if (pl_lst[jdx]->src_id == id) break; if (jdx < pl_cnt) area[jdx] -= pl_lst_vrl[idx]->area; } } for(idx=0;idx<pl_cnt;idx++) { if (fabs(area[idx]) > epsilon) { if (nco_dbg_lvl_get() >= nco_dbg_dev) fprintf(stderr, "%s() src_id=%d area=%.15e\n", fnc_nm, pl_lst[idx]->src_id, area[idx]); pl_lst_dbg = (poly_sct **) nco_realloc(pl_lst_dbg, sizeof(poly_sct*) * (pl_nbr_dbg + 1)); pl_lst_dbg[pl_nbr_dbg] = nco_poly_dpl(pl_lst[idx]); pl_nbr_dbg++; } } area=(double*)nco_free(area); *pl_cnt_dbg=pl_nbr_dbg; return pl_lst_dbg; } /* stub function */ #ifdef TEMP wgt_sct ** nco_poly_lst_mk_idw_sph( rgr_sct *const rgr_nfo, poly_sct **pl_lst_out, int pl_cnt, nco_grd_lon_typ_enm grd_lon_typ, KDTree **tree, int nbr_tr, int *wgt_cnt_bln_ret) { } #endif wgt_sct ** nco_poly_lst_mk_idw_sph( rgr_sct *const rgr_nfo, poly_sct **pl_lst_out, int pl_cnt, nco_grd_lon_typ_enm grd_lon_typ, KDTree **tree, int nbr_tr, int *wgt_cnt_bln_ret) { /* just duplicate output list to overlap */ const char fnc_nm[] = "nco_poly_lst_mk_idw_sph()"; int thr_idx = 0; /* approx number of input cells each thread will process */ int thr_quota; /* reporting step */ int thr_quota_step; /* max number of nearest neighbours to consider - nr-reference from rgr_nfo */ int const max_nbr_idw=20; int nbr_idw=0; double pow_idw=0.0; double min_dist=1.0e-12; double min_wgt=1.0e-20; poly_typ_enm pl_typ; size_t idx; int lcl_thr_nbr; omp_mem_sct *mem_lst = NULL_CEWI; wgt_sct **wgt_lst_idw = NULL_CEWI; FILE *const fp_stderr = stderr; pl_typ = pl_lst_out[0]->pl_typ; lcl_thr_nbr = omp_get_max_threads(); nbr_idw= ( rgr_nfo->xtr_nsp > max_nbr_idw ? max_nbr_idw : rgr_nfo->xtr_nsp ); pow_idw=rgr_nfo->xtr_xpn; mem_lst = (omp_mem_sct *) nco_malloc(sizeof(omp_mem_sct) * lcl_thr_nbr); for (idx = 0; idx < lcl_thr_nbr; idx++) { mem_lst[idx].pl_lst = NULL_CEWI; mem_lst[idx].wgt_lst = NULL_CEWI; mem_lst[idx].blk_nbr = 0; mem_lst[idx].pl_cnt = 0; mem_lst[idx].kd_list = NULL_CEWI; mem_lst[idx].kd_cnt = 0; mem_lst[idx].kd_blk_nbr = 0; mem_lst[idx].idx_cnt = 0; kd_list_realloc(&mem_lst[idx],1); } thr_quota = pl_cnt / lcl_thr_nbr; thr_quota_step = thr_quota / 20; if (thr_quota_step < 2000) thr_quota_step = 2000; /* NB: "OpenMP notes" section of nco_rgr.c has detailed discussion of these settings Henry, please keep the variables in alphabetical order within a clause and remember to update Intel */ #ifdef __GNUG__ # define GCC_LIB_VERSION ( __GNUC__ * 100 + __GNUC_MINOR__ * 10 + __GNUC_PATCHLEVEL__ ) # if GCC_LIB_VERSION < 490 # define GXX_OLD_OPENMP_SHARED_TREATMENT 1 # endif /* 480 */ #endif /* !__GNUC__ */ #if defined(__INTEL_COMPILER) # pragma omp parallel for private(idx,thr_idx) schedule(dynamic,40) shared(grd_lon_typ,nbr_tr,pl_typ,tree) #else /* !__INTEL_COMPILER */ # ifdef GXX_OLD_OPENMP_SHARED_TREATMENT # pragma omp parallel for default(none) private(idx,thr_idx) shared(bDirtyRats,grd_lon_typ,max_nbr_vrl,nbr_tr,pl_cnt_dbg,pl_typ,tree,tot_nan_cnt,tot_wrp_cnt) # else /* !old g++ */ # pragma omp parallel for private(idx,thr_idx) schedule(dynamic,40) shared(grd_lon_typ,nbr_tr,pl_typ,tree) # endif /* !old g++ */ #endif /* !__INTEL_COMPILER */ for (idx = 0; idx < pl_cnt; idx++) { double dp_x_wrp; /* used to do a wrapped lon search */ double wgt_ttl=0.0; int nbr_idw_cnt; /* equal to or less than nbr_nni */ wgt_sct wgt_pre[max_nbr_idw]; wgt_sct * wgt_lcl=NULL_CEWI; poly_sct *pl=NULL_CEWI; size_t jdx; size_t kdx; size_t nbr_lst_lcl; // (void) nco_poly_set_priority(max_nbr_vrl, list); thr_idx = omp_get_thread_num(); if (0 && nco_dbg_lvl_get() >= nco_dbg_dev) fprintf(fp_stderr, "%s(): idx=%lu thr=%d\n", fnc_nm, idx, thr_idx); if (pl_lst_out[idx]->bmsk == False) continue; mem_lst[thr_idx].kd_cnt = 0; if (mem_lst[thr_idx].kd_blk_nbr > 1) kd_list_realloc(&mem_lst[thr_idx], 1); /* get bounds of polygon in */ //bSplit = nco_poly_minmax_split(pl_lst_out[idx], grd_lon_typ, size1, size2); dp_x_wrp=KD_DBL_MAX; for(kdx=0;kdx<nbr_tr;kdx++) kd_nearest(tree[kdx], pl_lst_out[idx]->dp_x_ctr, pl_lst_out[idx]->dp_y_ctr, pl_typ, nbr_idw, &mem_lst[thr_idx].kd_list[0] + nbr_idw *kdx ); nbr_lst_lcl=nbr_idw*nbr_tr; switch(grd_lon_typ) { case nco_grd_lon_nil: case nco_grd_lon_unk: case nco_grd_lon_Grn_ctr: case nco_grd_lon_Grn_wst: case nco_grd_lon_bb: if(pl_lst_out[idx]->dp_x_ctr <180.0) dp_x_wrp=pl_lst_out[idx]->dp_x_ctr+360.0; else if(pl_lst_out[idx]->dp_x_ctr >180.0) dp_x_wrp=pl_lst_out[idx]->dp_x_ctr-360.0; break; case nco_grd_lon_180_wst: case nco_grd_lon_180_ctr: if(pl_lst_out[idx]->dp_x_ctr <0.0) dp_x_wrp=pl_lst_out[idx]->dp_x_ctr+360.0; else if(pl_lst_out[idx]->dp_x_ctr >0.0) dp_x_wrp=pl_lst_out[idx]->dp_x_ctr-360.0; break; } if(dp_x_wrp != KD_DBL_MAX) { for (kdx = 0; kdx < nbr_tr; kdx++) kd_nearest(tree[kdx], dp_x_wrp, pl_lst_out[idx]->dp_y_ctr, pl_typ, nbr_idw, &mem_lst[thr_idx].kd_list[0] + nbr_lst_lcl+nbr_idw * kdx); nbr_lst_lcl+=nbr_idw*nbr_tr; } if(nbr_tr >1 ) qsort((void *)mem_lst[thr_idx].kd_list, nbr_lst_lcl, sizeof(KDPriority*), kd_priority_cmp_dist); /* remember kd list sorted according to distance */ /* check first member distance if min then output singleton */ if(mem_lst[thr_idx].kd_list[0]->dist <= min_dist) { pl=(poly_sct*)mem_lst[thr_idx].kd_list[0]->elem->item; wgt_lcl=(wgt_sct*)nco_malloc(sizeof(wgt_sct)); wgt_lcl->src_id=pl->src_id; wgt_lcl->dst_id=pl_lst_out[idx]->src_id; wgt_lcl->area=pl->area; wgt_lcl->dist=mem_lst[thr_idx].kd_list[0]->dist; wgt_lcl->wgt=1.0; if( mem_lst[thr_idx].blk_nbr * NCO_VRL_BLOCKSIZE < mem_lst[thr_idx].pl_cnt +1 ) mem_lst[thr_idx].wgt_lst= (wgt_sct**)nco_realloc(mem_lst[thr_idx].wgt_lst, sizeof(wgt_sct*) * ++mem_lst[thr_idx].blk_nbr * NCO_VRL_BLOCKSIZE ); mem_lst[thr_idx].wgt_lst[mem_lst[thr_idx].pl_cnt++] =wgt_lcl; if (nco_dbg_lvl_get() >= nco_dbg_dev) (void)fprintf(fp_stderr,"%s:%s: singleton x_ctr=%f y_ctr=%f\n", nco_prg_nm_get(), fnc_nm, pl_lst_out[idx]->dp_x_ctr, pl_lst_out[idx]->dp_y_ctr ); }else{ /* check for duplicates in first nbr_nni by sorting again with ->item !!!*/ // kd_priority_list_sort(mem_lst[thr_idx].kd_list,nbr_idw, nbr_idw,&nbr_idw_cnt ); nbr_idw_cnt=kd_list_sort_omp(&mem_lst[thr_idx], nbr_idw); if (nco_dbg_lvl_get() >= nco_dbg_dev && nbr_idw_cnt < nbr_idw ) (void)fprintf(fp_stderr,"%s:%s: nbr_nni_cnt=%d x_ctr=%f y_ctr=%f\n", nco_prg_nm_get(), fnc_nm, nbr_idw_cnt, pl_lst_out[idx]->dp_x_ctr, pl_lst_out[idx]->dp_y_ctr ); /* output at least one */ for (jdx = 0; jdx < nbr_idw_cnt; jdx++) { pl = (poly_sct *) mem_lst[thr_idx].kd_list[jdx]->elem->item; /* remember src is in tree and dst is in list */ wgt_pre[jdx].src_id = pl->src_id; wgt_pre[jdx].dst_id = pl_lst_out[idx]->src_id; wgt_pre[jdx].area = pl->area; wgt_pre[jdx].dist = mem_lst[thr_idx].kd_list[jdx]->dist; /* use dist squared */ wgt_pre[jdx].wgt = 1.0 / pow(wgt_pre[jdx].dist, pow_idw); } /* find weights total */ for (jdx = 0; jdx < nbr_idw_cnt; jdx++) wgt_ttl += wgt_pre[jdx].wgt; /* normalize weights */ for (jdx = 0; jdx < nbr_idw_cnt; jdx++) wgt_pre[jdx].wgt /= wgt_ttl; for (jdx = 0; jdx < nbr_idw_cnt; jdx++) { if (wgt_pre[jdx].wgt < min_wgt) continue; wgt_lcl = (wgt_sct *) nco_malloc(sizeof(wgt_sct)); *wgt_lcl = wgt_pre[jdx]; if (mem_lst[thr_idx].blk_nbr * NCO_VRL_BLOCKSIZE < mem_lst[thr_idx].pl_cnt + 1) mem_lst[thr_idx].wgt_lst = (wgt_sct **) nco_realloc(mem_lst[thr_idx].wgt_lst,sizeof(wgt_sct *) * ++mem_lst[thr_idx].blk_nbr *NCO_VRL_BLOCKSIZE); mem_lst[thr_idx].wgt_lst[mem_lst[thr_idx].pl_cnt++] = wgt_lcl; //(void)fprintf(stderr,"%s: weight(%lu)=%f ",fnc_nm, mem_lst[thr_idx].pl_cnt, wgt_lcl->wgt); } /* end jdx */ } /* output some usefull tracking stuff - not debug but informative */ if ( ++mem_lst[thr_idx].idx_cnt % thr_quota_step == 0 && nco_dbg_lvl_get() >=3 ) (void)fprintf(fp_stderr, "%s: thread %d has processed %2.2f%% (%ld) of src cells quota and output %ld overlap cells\n", nco_prg_nm_get(), thr_idx, (float)mem_lst[thr_idx].idx_cnt/(float)thr_quota *100.0, mem_lst[thr_idx].idx_cnt, mem_lst[thr_idx].pl_cnt ); } /* end idx */ nco_mem_lst_cat(mem_lst, lcl_thr_nbr); /* free up kd_list's */ for(idx=0;idx<lcl_thr_nbr;idx++) kd_list_realloc(&mem_lst[idx],0); wgt_lst_idw=mem_lst[0].wgt_lst; *wgt_cnt_bln_ret=mem_lst[0].pl_cnt; mem_lst=(omp_mem_sct*)nco_free(mem_lst); return wgt_lst_idw; } /* !nco_poly_lst_mk_idw_sph() */ void nco_poly_lst_ctr_add( poly_sct **pl_lst, int pl_cnt, int ctr_typ) { int idx; double pControl[NBR_SPH]; for(idx=0;idx<pl_cnt;idx++) { if(pl_lst[idx]->crn_nbr <3 || pl_lst[idx]->area==0.0 ) continue; if(ctr_typ==1){ nco_sph_inside_mk(pl_lst[idx], pControl); pl_lst[idx]->dp_x_ctr=R2D(pControl[3]); pl_lst[idx]->dp_y_ctr=R2D(pControl[4]); } } return; } /* !nco_poly_lst_ctr_add() */ void nco_mem_lst_cat( omp_mem_sct *mem_lst, int sz_lst) { int idx; int i_typ; size_t tot_cnt = 0; if(mem_lst->wgt_lst) i_typ = 1; else if(mem_lst->pl_lst) i_typ = 2; else i_typ=0; /* quick return if list empty */ if(!i_typ) return; /* find total size of lists */ for (idx = 0; idx < sz_lst; idx++) tot_cnt += mem_lst[idx].pl_cnt; if(!tot_cnt) return; else if( i_typ==1 ){ wgt_sct **tmp_wgt_lst = NULL; tmp_wgt_lst = mem_lst[0].wgt_lst = (wgt_sct **) nco_realloc(mem_lst[0].wgt_lst, sizeof(wgt_sct *) * tot_cnt); tmp_wgt_lst += mem_lst[0].pl_cnt; for (idx = 1; idx < sz_lst; idx++) { if (mem_lst[idx].wgt_lst) { memcpy(tmp_wgt_lst, mem_lst[idx].wgt_lst, sizeof(wgt_sct *) * mem_lst[idx].pl_cnt); tmp_wgt_lst += mem_lst[idx].pl_cnt; /* free up list */ mem_lst[idx].wgt_lst = (wgt_sct **) nco_free(mem_lst[idx].wgt_lst); } } } else if(i_typ==2) { poly_sct **tmp_ply_lst = NULL; tmp_ply_lst = mem_lst[0].pl_lst = (poly_sct **) nco_realloc(mem_lst[0].pl_lst, sizeof(poly_sct *) * tot_cnt); tmp_ply_lst += mem_lst[0].pl_cnt; for (idx = 1; idx < sz_lst; idx++) { if (mem_lst[idx].pl_lst) { memcpy(tmp_ply_lst, mem_lst[idx].pl_lst, sizeof(poly_sct *) * mem_lst[idx].pl_cnt); tmp_ply_lst += mem_lst[idx].pl_cnt; /* free up list */ mem_lst[idx].pl_lst = (poly_sct **) nco_free(mem_lst[idx].pl_lst); } } } /* update first list with total */ mem_lst[0].pl_cnt=tot_cnt; return; } /* !nco_mem_lst_cat() */

residualbased_predictorcorrector_velocity_bossak_scheme_turbulent.h

// | / | // ' / __| _` | __| _ \ __| // . \ | ( | | ( |\__ ` // _|\_\_| \__,_|\__|\___/ ____/ // Multi-Physics // // License: BSD License // Kratos default license: kratos/license.txt // // Main authors: Jordi Cotela // #if !defined(KRATOS_RESIDUALBASED_PREDICTOR_CORRECTOR_VELOCITY_BOSSAK_TURBULENT_SCHEME ) #define KRATOS_RESIDUALBASED_PREDICTOR_CORRECTOR_VELOCITY_BOSSAK_TURBULENT_SCHEME /* System includes */ /* External includes */ #include "boost/smart_ptr.hpp" /* Project includes */ #include "includes/define.h" #include "includes/model_part.h" #include "includes/deprecated_variables.h" #include "solving_strategies/schemes/scheme.h" #include "includes/variables.h" #include "includes/cfd_variables.h" #include "containers/array_1d.h" #include "utilities/openmp_utils.h" #include "utilities/dof_updater.h" #include "utilities/coordinate_transformation_utilities.h" #include "processes/process.h" namespace Kratos { /**@name Kratos Globals */ /*@{ */ /*@} */ /**@name Type Definitions */ /*@{ */ /*@} */ /**@name Enum's */ /*@{ */ /*@} */ /**@name Functions */ /*@{ */ /*@} */ /**@name Kratos Classes */ /*@{ */ /// Bossak time scheme for the incompressible flow problem. /** This class provides a second order time scheme of the generalized-alpha Newmark family of methods. It also includes code required to implement slip conditions on the incompressible flow problem and provides the possibility of using a RANS model by passing a turbulence model as an argument to the constructor. This time scheme is intended to be used in combination with elements of type ASGS2D, ASGS3D, VMS or derived classes. To use the slip condition, set the SLIP flag on slip wall nodes. To use a wall law in combination with the slip condition, use MonolithicWallCondition to mesh the boundary @see ASGS2D, ASGS3D, VMS, MonolithicWallConditon */ template<class TSparseSpace, class TDenseSpace //= DenseSpace<double> > class ResidualBasedPredictorCorrectorVelocityBossakSchemeTurbulent : public Scheme<TSparseSpace, TDenseSpace> { public: /**@name Type Definitions */ /*@{ */ KRATOS_CLASS_POINTER_DEFINITION(ResidualBasedPredictorCorrectorVelocityBossakSchemeTurbulent); typedef Scheme<TSparseSpace, TDenseSpace> BaseType; typedef typename BaseType::TDataType TDataType; typedef typename BaseType::DofsArrayType DofsArrayType; typedef typename Element::DofsVectorType DofsVectorType; typedef typename BaseType::TSystemMatrixType TSystemMatrixType; typedef typename BaseType::TSystemVectorType TSystemVectorType; typedef typename BaseType::LocalSystemVectorType LocalSystemVectorType; typedef typename BaseType::LocalSystemMatrixType LocalSystemMatrixType; typedef Element::GeometryType GeometryType; /*@} */ /**@name Life Cycle */ /*@{ */ /** Constructor without a turbulence model */ ResidualBasedPredictorCorrectorVelocityBossakSchemeTurbulent( double NewAlphaBossak, double MoveMeshStrategy, unsigned int DomainSize) : Scheme<TSparseSpace, TDenseSpace>(), mRotationTool(DomainSize,DomainSize+1,SLIP), // Second argument is number of matrix rows per node: monolithic elements have velocity and pressure dofs. mrPeriodicIdVar(Kratos::Variable<int>::StaticObject()) { //default values for the Newmark Scheme mAlphaBossak = NewAlphaBossak; mBetaNewmark = 0.25 * pow((1.00 - mAlphaBossak), 2); mGammaNewmark = 0.5 - mAlphaBossak; mMeshVelocity = MoveMeshStrategy; //Allocate auxiliary memory int NumThreads = OpenMPUtils::GetNumThreads(); mMass.resize(NumThreads); mDamp.resize(NumThreads); mvel.resize(NumThreads); macc.resize(NumThreads); maccold.resize(NumThreads); } /** Constructor without a turbulence model with periodic conditions */ ResidualBasedPredictorCorrectorVelocityBossakSchemeTurbulent( double NewAlphaBossak, unsigned int DomainSize, const Variable<int>& rPeriodicIdVar) : Scheme<TSparseSpace, TDenseSpace>(), mRotationTool(DomainSize,DomainSize+1,SLIP), // Second argument is number of matrix rows per node: monolithic elements have velocity and pressure dofs. mrPeriodicIdVar(rPeriodicIdVar) { //default values for the Newmark Scheme mAlphaBossak = NewAlphaBossak; mBetaNewmark = 0.25 * pow((1.00 - mAlphaBossak), 2); mGammaNewmark = 0.5 - mAlphaBossak; mMeshVelocity = 0.0; //Allocate auxiliary memory int NumThreads = OpenMPUtils::GetNumThreads(); mMass.resize(NumThreads); mDamp.resize(NumThreads); mvel.resize(NumThreads); macc.resize(NumThreads); maccold.resize(NumThreads); } /** Constructor without a turbulence model */ ResidualBasedPredictorCorrectorVelocityBossakSchemeTurbulent( double NewAlphaBossak, double MoveMeshStrategy, unsigned int DomainSize, Kratos::Flags& rSlipFlag) : Scheme<TSparseSpace, TDenseSpace>(), mRotationTool(DomainSize,DomainSize+1,rSlipFlag), // Second argument is number of matrix rows per node: monolithic elements have velocity and pressure dofs. mrPeriodicIdVar(Kratos::Variable<int>::StaticObject()) { //default values for the Newmark Scheme mAlphaBossak = NewAlphaBossak; mBetaNewmark = 0.25 * pow((1.00 - mAlphaBossak), 2); mGammaNewmark = 0.5 - mAlphaBossak; mMeshVelocity = MoveMeshStrategy; //Allocate auxiliary memory int NumThreads = OpenMPUtils::GetNumThreads(); mMass.resize(NumThreads); mDamp.resize(NumThreads); mvel.resize(NumThreads); macc.resize(NumThreads); maccold.resize(NumThreads); } /** Constructor with a turbulence model */ ResidualBasedPredictorCorrectorVelocityBossakSchemeTurbulent( double NewAlphaBossak, double MoveMeshStrategy, unsigned int DomainSize, Process::Pointer pTurbulenceModel) : Scheme<TSparseSpace, TDenseSpace>(), mRotationTool(DomainSize,DomainSize+1,SLIP), // Second argument is number of matrix rows per node: monolithic elements have velocity and pressure dofs mrPeriodicIdVar(Kratos::Variable<int>::StaticObject()), mpTurbulenceModel(pTurbulenceModel) { //default values for the Newmark Scheme mAlphaBossak = NewAlphaBossak; mBetaNewmark = 0.25 * pow((1.00 - mAlphaBossak), 2); mGammaNewmark = 0.5 - mAlphaBossak; mMeshVelocity = MoveMeshStrategy; //Allocate auxiliary memory int NumThreads = OpenMPUtils::GetNumThreads(); mMass.resize(NumThreads); mDamp.resize(NumThreads); mvel.resize(NumThreads); macc.resize(NumThreads); maccold.resize(NumThreads); } /** Constructor with a turbulence model and relaxation factor */ ResidualBasedPredictorCorrectorVelocityBossakSchemeTurbulent( double NewAlphaBossak, double MoveMeshStrategy, unsigned int DomainSize, const double RelaxationFactor, Process::Pointer pTurbulenceModel) : Scheme<TSparseSpace, TDenseSpace>(), mRotationTool(DomainSize,DomainSize+1,SLIP), // Second argument is number of matrix rows per node: monolithic elements have velocity and pressure dofs mrPeriodicIdVar(Kratos::Variable<int>::StaticObject()), mpTurbulenceModel(pTurbulenceModel) { //default values for the Newmark Scheme mAlphaBossak = NewAlphaBossak; mBetaNewmark = 0.25 * pow((1.00 - mAlphaBossak), 2); mGammaNewmark = 0.5 - mAlphaBossak; mMeshVelocity = MoveMeshStrategy; mRelaxationFactor = RelaxationFactor; //Allocate auxiliary memory int NumThreads = OpenMPUtils::GetNumThreads(); mMass.resize(NumThreads); mDamp.resize(NumThreads); mvel.resize(NumThreads); macc.resize(NumThreads); maccold.resize(NumThreads); } /** Destructor. */ ~ResidualBasedPredictorCorrectorVelocityBossakSchemeTurbulent() override { } /*@} */ /**@name Operators */ /*@{ */ /** Performing the update of the solution. */ //*************************************************************************** void Update(ModelPart& r_model_part, DofsArrayType& rDofSet, TSystemMatrixType& A, TSystemVectorType& Dv, TSystemVectorType& b) override { KRATOS_TRY; mRotationTool.RotateVelocities(r_model_part); TSparseSpace::InplaceMult(Dv, mRelaxationFactor); mpDofUpdater->UpdateDofs(rDofSet,Dv); mRotationTool.RecoverVelocities(r_model_part); AdditionalUpdateOperations(r_model_part, rDofSet, A, Dv, b); KRATOS_CATCH("") } //*************************************************************************** void AdditionalUpdateOperations(ModelPart& rModelPart, DofsArrayType& rDofSet, TSystemMatrixType& A, TSystemVectorType& Dv, TSystemVectorType& b) { KRATOS_TRY int NumThreads = OpenMPUtils::GetNumThreads(); OpenMPUtils::PartitionVector NodePartition; OpenMPUtils::DivideInPartitions(rModelPart.Nodes().size(), NumThreads, NodePartition); //updating time derivatives (nodally for efficiency) #pragma omp parallel { array_1d<double, 3 > DeltaVel; int k = OpenMPUtils::ThisThread(); ModelPart::NodeIterator NodesBegin = rModelPart.NodesBegin() + NodePartition[k]; ModelPart::NodeIterator NodesEnd = rModelPart.NodesBegin() + NodePartition[k + 1]; for (ModelPart::NodeIterator itNode = NodesBegin; itNode != NodesEnd; itNode++) { noalias(DeltaVel) = (itNode)->FastGetSolutionStepValue(VELOCITY) - (itNode)->FastGetSolutionStepValue(VELOCITY, 1); array_1d<double, 3 > & CurrentAcceleration = (itNode)->FastGetSolutionStepValue(ACCELERATION, 0); array_1d<double, 3 > & OldAcceleration = (itNode)->FastGetSolutionStepValue(ACCELERATION, 1); UpdateAcceleration(CurrentAcceleration, DeltaVel, OldAcceleration); if (mMeshVelocity == 2)//Lagrangian { if((itNode)->FastGetSolutionStepValue(IS_LAGRANGIAN_INLET) < 1e-15) { array_1d<double, 3 > & CurrentDisplacement = (itNode)->FastGetSolutionStepValue(DISPLACEMENT, 0); array_1d<double, 3 > & OldDisplacement = (itNode)->FastGetSolutionStepValue(DISPLACEMENT, 1); array_1d<double, 3 > & OldVelocity = (itNode)->FastGetSolutionStepValue(VELOCITY, 1); noalias(itNode->FastGetSolutionStepValue(MESH_VELOCITY)) = itNode->FastGetSolutionStepValue(VELOCITY); UpdateDisplacement(CurrentDisplacement, OldDisplacement, OldVelocity, OldAcceleration, CurrentAcceleration); } else { noalias(itNode->FastGetSolutionStepValue(MESH_VELOCITY)) = ZeroVector(3); noalias(itNode->FastGetSolutionStepValue(DISPLACEMENT)) = ZeroVector(3); } } } } KRATOS_CATCH("") } //*************************************************************************** //predicts the solution at the current step as // v = vold void Predict(ModelPart& rModelPart, DofsArrayType& rDofSet, TSystemMatrixType& A, TSystemVectorType& Dv, TSystemVectorType& b) override { // if (rModelPart.GetCommunicator().MyPID() == 0) // std::cout << "prediction" << std::endl; int NumThreads = OpenMPUtils::GetNumThreads(); OpenMPUtils::PartitionVector NodePartition; OpenMPUtils::DivideInPartitions(rModelPart.Nodes().size(), NumThreads, NodePartition); #pragma omp parallel { //array_1d<double, 3 > DeltaDisp; int k = OpenMPUtils::ThisThread(); ModelPart::NodeIterator NodesBegin = rModelPart.NodesBegin() + NodePartition[k]; ModelPart::NodeIterator NodesEnd = rModelPart.NodesBegin() + NodePartition[k + 1]; for (ModelPart::NodeIterator itNode = NodesBegin; itNode != NodesEnd; itNode++) { array_1d<double, 3 > & OldVelocity = (itNode)->FastGetSolutionStepValue(VELOCITY, 1); double& OldPressure = (itNode)->FastGetSolutionStepValue(PRESSURE, 1); //predicting velocity //ATTENTION::: the prediction is performed only on free nodes array_1d<double, 3 > & CurrentVelocity = (itNode)->FastGetSolutionStepValue(VELOCITY); double& CurrentPressure = (itNode)->FastGetSolutionStepValue(PRESSURE); if ((itNode->pGetDof(VELOCITY_X))->IsFree()) (CurrentVelocity[0]) = OldVelocity[0]; if (itNode->pGetDof(VELOCITY_Y)->IsFree()) (CurrentVelocity[1]) = OldVelocity[1]; if (itNode->HasDofFor(VELOCITY_Z)) if (itNode->pGetDof(VELOCITY_Z)->IsFree()) (CurrentVelocity[2]) = OldVelocity[2]; if (itNode->pGetDof(PRESSURE)->IsFree()) CurrentPressure = OldPressure; // updating time derivatives ::: please note that displacements and // their time derivatives can not be consistently fixed separately array_1d<double, 3 > DeltaVel; noalias(DeltaVel) = CurrentVelocity - OldVelocity; array_1d<double, 3 > & OldAcceleration = (itNode)->FastGetSolutionStepValue(ACCELERATION, 1); array_1d<double, 3 > & CurrentAcceleration = (itNode)->FastGetSolutionStepValue(ACCELERATION); UpdateAcceleration(CurrentAcceleration, DeltaVel, OldAcceleration); if (mMeshVelocity == 2) //Lagrangian { array_1d<double, 3 > & OldDisplacement = (itNode)->FastGetSolutionStepValue(DISPLACEMENT, 1); array_1d<double, 3 > & CurrentDisplacement = (itNode)->FastGetSolutionStepValue(DISPLACEMENT, 0); if((itNode)->FastGetSolutionStepValue(IS_LAGRANGIAN_INLET) < 1e-15) { noalias(itNode->FastGetSolutionStepValue(MESH_VELOCITY)) = itNode->FastGetSolutionStepValue(VELOCITY); UpdateDisplacement(CurrentDisplacement, OldDisplacement, OldVelocity, OldAcceleration, CurrentAcceleration); } else { itNode->FastGetSolutionStepValue(MESH_VELOCITY_X) = 0.0; itNode->FastGetSolutionStepValue(MESH_VELOCITY_Y) = 0.0; itNode->FastGetSolutionStepValue(DISPLACEMENT_X) = 0.0; itNode->FastGetSolutionStepValue(DISPLACEMENT_Y) = 0.0; } } } } // if (rModelPart.GetCommunicator().MyPID() == 0) // std::cout << "end of prediction" << std::endl; } //*************************************************************************** /** this function is designed to be called in the builder and solver to introduce the selected time integration scheme. It "asks" the matrix needed to the element and performs the operations needed to introduce the seected time integration scheme. this function calculates at the same time the contribution to the LHS and to the RHS of the system */ void CalculateSystemContributions( Element& rCurrentElement, LocalSystemMatrixType& LHS_Contribution, LocalSystemVectorType& RHS_Contribution, Element::EquationIdVectorType& EquationId, const ProcessInfo& CurrentProcessInfo) override { KRATOS_TRY int k = OpenMPUtils::ThisThread(); //Initializing the non linear iteration for the current element rCurrentElement.InitializeNonLinearIteration(CurrentProcessInfo); //basic operations for the element considered rCurrentElement.CalculateLocalSystem(LHS_Contribution, RHS_Contribution, CurrentProcessInfo); rCurrentElement.CalculateMassMatrix(mMass[k], CurrentProcessInfo); rCurrentElement.CalculateLocalVelocityContribution(mDamp[k], RHS_Contribution, CurrentProcessInfo); rCurrentElement.EquationIdVector(EquationId, CurrentProcessInfo); //adding the dynamic contributions (statics is already included) AddDynamicsToLHS(LHS_Contribution, mDamp[k], mMass[k], CurrentProcessInfo); AddDynamicsToRHS(rCurrentElement, RHS_Contribution, mDamp[k], mMass[k], CurrentProcessInfo); // If there is a slip condition, apply it on a rotated system of coordinates mRotationTool.Rotate(LHS_Contribution,RHS_Contribution,rCurrentElement.GetGeometry()); mRotationTool.ApplySlipCondition(LHS_Contribution,RHS_Contribution,rCurrentElement.GetGeometry()); KRATOS_CATCH("") } void CalculateRHSContribution( Element& rCurrentElement, LocalSystemVectorType& RHS_Contribution, Element::EquationIdVectorType& EquationId, const ProcessInfo& CurrentProcessInfo) override { int k = OpenMPUtils::ThisThread(); //Initializing the non linear iteration for the current element rCurrentElement.InitializeNonLinearIteration(CurrentProcessInfo); //basic operations for the element considered rCurrentElement.CalculateRightHandSide(RHS_Contribution, CurrentProcessInfo); rCurrentElement.CalculateMassMatrix(mMass[k], CurrentProcessInfo); rCurrentElement.CalculateLocalVelocityContribution(mDamp[k], RHS_Contribution, CurrentProcessInfo); rCurrentElement.EquationIdVector(EquationId, CurrentProcessInfo); //adding the dynamic contributions (static is already included) AddDynamicsToRHS(rCurrentElement, RHS_Contribution, mDamp[k], mMass[k], CurrentProcessInfo); // If there is a slip condition, apply it on a rotated system of coordinates mRotationTool.Rotate(RHS_Contribution,rCurrentElement.GetGeometry()); mRotationTool.ApplySlipCondition(RHS_Contribution,rCurrentElement.GetGeometry()); } /** functions totally analogous to the precedent but applied to the "condition" objects */ void CalculateSystemContributions( Condition& rCurrentCondition, LocalSystemMatrixType& LHS_Contribution, LocalSystemVectorType& RHS_Contribution, Element::EquationIdVectorType& EquationId, const ProcessInfo& CurrentProcessInfo) override { KRATOS_TRY int k = OpenMPUtils::ThisThread(); rCurrentCondition.InitializeNonLinearIteration(CurrentProcessInfo); rCurrentCondition.CalculateLocalSystem(LHS_Contribution, RHS_Contribution, CurrentProcessInfo); rCurrentCondition.CalculateMassMatrix(mMass[k], CurrentProcessInfo); //rCurrentCondition.CalculateDampingMatrix(VelocityBossakAuxiliaries::mDamp,CurrentProcessInfo); rCurrentCondition.CalculateLocalVelocityContribution(mDamp[k], RHS_Contribution, CurrentProcessInfo); rCurrentCondition.EquationIdVector(EquationId, CurrentProcessInfo); AddDynamicsToLHS(LHS_Contribution, mDamp[k], mMass[k], CurrentProcessInfo); AddDynamicsToRHS(rCurrentCondition, RHS_Contribution, mDamp[k], mMass[k], CurrentProcessInfo); // Rotate contributions (to match coordinates for slip conditions) mRotationTool.Rotate(LHS_Contribution,RHS_Contribution,rCurrentCondition.GetGeometry()); mRotationTool.ApplySlipCondition(LHS_Contribution,RHS_Contribution,rCurrentCondition.GetGeometry()); KRATOS_CATCH("") } void CalculateRHSContribution( Condition& rCurrentCondition, LocalSystemVectorType& RHS_Contribution, Element::EquationIdVectorType& EquationId, const ProcessInfo& rCurrentProcessInfo) override { KRATOS_TRY; int k = OpenMPUtils::ThisThread(); //Initializing the non linear iteration for the current condition rCurrentCondition.InitializeNonLinearIteration(rCurrentProcessInfo); //basic operations for the element considered rCurrentCondition.CalculateRightHandSide(RHS_Contribution,rCurrentProcessInfo); rCurrentCondition.CalculateMassMatrix(mMass[k],rCurrentProcessInfo); //rCurrentCondition.CalculateDampingMatrix(VelocityBossakAuxiliaries::mDamp,CurrentProcessInfo); rCurrentCondition.CalculateLocalVelocityContribution(mDamp[k], RHS_Contribution,rCurrentProcessInfo); rCurrentCondition.EquationIdVector(EquationId,rCurrentProcessInfo); //adding the dynamic contributions (static is already included) AddDynamicsToRHS(rCurrentCondition, RHS_Contribution, mDamp[k], mMass[k],rCurrentProcessInfo); // Rotate contributions (to match coordinates for slip conditions) mRotationTool.Rotate(RHS_Contribution,rCurrentCondition.GetGeometry()); mRotationTool.ApplySlipCondition(RHS_Contribution,rCurrentCondition.GetGeometry()); KRATOS_CATCH(""); } //************************************************************************************* //************************************************************************************* void InitializeSolutionStep(ModelPart& r_model_part, TSystemMatrixType& A, TSystemVectorType& Dx, TSystemVectorType& b) override { ProcessInfo& CurrentProcessInfo = r_model_part.GetProcessInfo(); Scheme<TSparseSpace, TDenseSpace>::InitializeSolutionStep(r_model_part, A, Dx, b); double DeltaTime = CurrentProcessInfo[DELTA_TIME]; KRATOS_ERROR_IF(DeltaTime < 1.0e-12) << "Detected delta_time = 0 in the Bossak scheme. Check if the time step is created correctly for the current model part" << std::endl; //initializing constants ma0 = 1.0 / (mGammaNewmark * DeltaTime); ma1 = DeltaTime * mBetaNewmark / mGammaNewmark; ma2 = (-1 + mGammaNewmark) / mGammaNewmark; ma3 = DeltaTime; ma4 = pow(DeltaTime, 2)*(-2.0 * mBetaNewmark + 1.0) / 2.0; ma5 = pow(DeltaTime, 2) * mBetaNewmark; mam = (1.0 - mAlphaBossak) / (mGammaNewmark * DeltaTime); } //************************************************************************************* //************************************************************************************* void FinalizeNonLinIteration(ModelPart &rModelPart, TSystemMatrixType &A, TSystemVectorType &Dx, TSystemVectorType &b) override { const auto& r_current_process_info = rModelPart.GetProcessInfo(); if (mpTurbulenceModel) // If not null mpTurbulenceModel->Execute(); //if orthogonal subscales are computed if (r_current_process_info[OSS_SWITCH] == 1.0) { KRATOS_INFO("Bossak Scheme") << "Computing OSS projections" << std::endl; const int nnodes = static_cast<int>(rModelPart.Nodes().size()); auto nbegin = rModelPart.NodesBegin(); #pragma omp parallel for firstprivate(nbegin,nnodes) for(int i=0; i<nnodes; ++i) { auto ind = nbegin + i; noalias(ind->FastGetSolutionStepValue(ADVPROJ)) = ZeroVector(3); ind->FastGetSolutionStepValue(DIVPROJ) = 0.0; ind->FastGetSolutionStepValue(NODAL_AREA) = 0.0; }//end of loop over nodes //loop on nodes to compute ADVPROJ CONVPROJ NODALAREA array_1d<double, 3 > output = ZeroVector(3); const int nel = static_cast<int>(rModelPart.Elements().size()); auto elbegin = rModelPart.ElementsBegin(); #pragma omp parallel for firstprivate(elbegin,nel,output) for(int i=0; i<nel; ++i) { auto elem = elbegin + i; elem->Calculate(ADVPROJ, output, r_current_process_info); } rModelPart.GetCommunicator().AssembleCurrentData(NODAL_AREA); rModelPart.GetCommunicator().AssembleCurrentData(DIVPROJ); rModelPart.GetCommunicator().AssembleCurrentData(ADVPROJ); // Correction for periodic conditions this->PeriodicConditionProjectionCorrection(rModelPart); #pragma omp parallel for firstprivate(nbegin,nnodes) for(int i=0; i<nnodes; ++i) { auto ind = nbegin + i; if (ind->FastGetSolutionStepValue(NODAL_AREA) == 0.0) { ind->FastGetSolutionStepValue(NODAL_AREA) = 1.0; //KRATOS_WATCH("*********ATTENTION: NODAL AREA IS ZERRROOOO************"); } const double Area = ind->FastGetSolutionStepValue(NODAL_AREA); ind->FastGetSolutionStepValue(ADVPROJ) /= Area; ind->FastGetSolutionStepValue(DIVPROJ) /= Area; } } } void FinalizeSolutionStep(ModelPart &rModelPart, TSystemMatrixType &A, TSystemVectorType &Dx, TSystemVectorType &b) override { Element::EquationIdVectorType EquationId; LocalSystemVectorType RHS_Contribution; LocalSystemMatrixType LHS_Contribution; const ProcessInfo& CurrentProcessInfo = rModelPart.GetProcessInfo(); //for (ModelPart::NodeIterator itNode = rModelPart.NodesBegin(); itNode != rModelPart.NodesEnd(); ++itNode) #pragma omp parallel for for(int k = 0; k<static_cast<int>(rModelPart.Nodes().size()); k++) { auto itNode = rModelPart.NodesBegin() + k; (itNode->FastGetSolutionStepValue(REACTION)).clear(); // calculating relaxed acceleration const array_1d<double, 3 > & CurrentAcceleration = (itNode)->FastGetSolutionStepValue(ACCELERATION, 0); const array_1d<double, 3 > & OldAcceleration = (itNode)->FastGetSolutionStepValue(ACCELERATION, 1); const array_1d<double, 3> relaxed_acceleration = (1 - mAlphaBossak) * CurrentAcceleration + mAlphaBossak * OldAcceleration; (itNode)->SetValue(RELAXED_ACCELERATION, relaxed_acceleration); } //for (ModelPart::ElementsContainerType::ptr_iterator itElem = rModelPart.Elements().ptr_begin(); itElem != rModelPart.Elements().ptr_end(); ++itElem) #pragma omp parallel for firstprivate(EquationId,RHS_Contribution,LHS_Contribution) for(int k = 0; k<static_cast<int>(rModelPart.Elements().size()); k++) { auto itElem = rModelPart.Elements().ptr_begin()+k; int thread_id = OpenMPUtils::ThisThread(); (*itElem)->InitializeNonLinearIteration(CurrentProcessInfo); //KRATOS_WATCH(LHS_Contribution); //basic operations for the element considered (*itElem)->CalculateLocalSystem(LHS_Contribution, RHS_Contribution, CurrentProcessInfo); //std::cout << rCurrentElement->Id() << " RHS = " << RHS_Contribution << std::endl; (*itElem)->CalculateMassMatrix(mMass[thread_id], CurrentProcessInfo); (*itElem)->CalculateLocalVelocityContribution(mDamp[thread_id], RHS_Contribution, CurrentProcessInfo); (*itElem)->EquationIdVector(EquationId, CurrentProcessInfo); //adding the dynamic contributions (statics is already included) AddDynamicsToLHS(LHS_Contribution, mDamp[thread_id], mMass[thread_id], CurrentProcessInfo); AddDynamicsToRHS(**itElem, RHS_Contribution, mDamp[thread_id], mMass[thread_id], CurrentProcessInfo); GeometryType& rGeom = (*itElem)->GetGeometry(); unsigned int NumNodes = rGeom.PointsNumber(); unsigned int Dimension = rGeom.WorkingSpaceDimension(); unsigned int index = 0; for (unsigned int i = 0; i < NumNodes; i++) { auto& reaction = rGeom[i].FastGetSolutionStepValue(REACTION); double& target_value0 = reaction[0]; const double& origin_value0 = RHS_Contribution[index++]; #pragma omp atomic target_value0 -= origin_value0; double& target_value1 = reaction[1]; const double& origin_value1 = RHS_Contribution[index++]; #pragma omp atomic target_value1 -= origin_value1; if (Dimension == 3) { double& target_value2 = reaction[2]; const double& origin_value2 = RHS_Contribution[index++]; #pragma omp atomic target_value2 -= origin_value2; } // rGeom[i].FastGetSolutionStepValue(REACTION_X,0) -= RHS_Contribution[index++]; // rGeom[i].FastGetSolutionStepValue(REACTION_Y,0) -= RHS_Contribution[index++]; // if (Dimension == 3) rGeom[i].FastGetSolutionStepValue(REACTION_Z,0) -= RHS_Contribution[index++]; index++; // skip pressure dof } } rModelPart.GetCommunicator().AssembleCurrentData(REACTION); // Base scheme calls FinalizeSolutionStep method of elements and conditions Scheme<TSparseSpace, TDenseSpace>::FinalizeSolutionStep(rModelPart, A, Dx, b); } //************************************************************************************************ //************************************************************************************************ /// Free memory allocated by this object. void Clear() override { this->mpDofUpdater->Clear(); } /*@} */ /**@name Operations */ /*@{ */ /*@} */ /**@name Access */ /*@{ */ /*@} */ /**@name Inquiry */ /*@{ */ /*@} */ /**@name Friends */ /*@{ */ /*@} */ protected: /**@name Protected static Member Variables */ /*@{ */ /*@} */ /**@name Protected member Variables */ /*@{ */ double mAlphaBossak; double mBetaNewmark; double mGammaNewmark; double mMeshVelocity; double mRelaxationFactor = 1.0; double ma0; double ma1; double ma2; double ma3; double ma4; double ma5; double mam; std::vector< Matrix > mMass; std::vector< Matrix > mDamp; std::vector< Vector > mvel; std::vector< Vector > macc; std::vector< Vector > maccold; /*@} */ /**@name Protected Operators*/ /*@{ */ /** On periodic boundaries, the nodal area and the values to project need to take into account contributions from elements on * both sides of the boundary. This is done using the conditions and the non-historical nodal data containers as follows:\n * 1- The partition that owns the PeriodicCondition adds the values on both nodes to their non-historical containers.\n * 2- The non-historical containers are added across processes, communicating the right value from the condition owner to all partitions.\n * 3- The value on all periodic nodes is replaced by the one received in step 2. */ void PeriodicConditionProjectionCorrection(ModelPart& rModelPart) { const int num_nodes = rModelPart.NumberOfNodes(); const int num_conditions = rModelPart.NumberOfConditions(); #pragma omp parallel for for (int i = 0; i < num_nodes; i++) { auto it_node = rModelPart.NodesBegin() + i; it_node->SetValue(NODAL_AREA,0.0); it_node->SetValue(ADVPROJ,ZeroVector(3)); it_node->SetValue(DIVPROJ,0.0); } #pragma omp parallel for for (int i = 0; i < num_conditions; i++) { auto it_cond = rModelPart.ConditionsBegin() + i; if(it_cond->Is(PERIODIC)) { this->AssemblePeriodicContributionToProjections(it_cond->GetGeometry()); } } rModelPart.GetCommunicator().AssembleNonHistoricalData(NODAL_AREA); rModelPart.GetCommunicator().AssembleNonHistoricalData(ADVPROJ); rModelPart.GetCommunicator().AssembleNonHistoricalData(DIVPROJ); #pragma omp parallel for for (int i = 0; i < num_nodes; i++) { auto it_node = rModelPart.NodesBegin() + i; this->CorrectContributionsOnPeriodicNode(*it_node); } } void AssemblePeriodicContributionToProjections(Geometry< Node<3> >& rGeometry) { unsigned int nodes_in_cond = rGeometry.PointsNumber(); double nodal_area = 0.0; array_1d<double,3> momentum_projection = ZeroVector(3); double mass_projection = 0.0; for ( unsigned int i = 0; i < nodes_in_cond; i++ ) { auto& r_node = rGeometry[i]; nodal_area += r_node.FastGetSolutionStepValue(NODAL_AREA); noalias(momentum_projection) += r_node.FastGetSolutionStepValue(ADVPROJ); mass_projection += r_node.FastGetSolutionStepValue(DIVPROJ); } for ( unsigned int i = 0; i < nodes_in_cond; i++ ) { auto& r_node = rGeometry[i]; /* Note that this loop is expected to be threadsafe in normal conditions, * since each node should belong to a single periodic link. However, I am * setting the locks for openmp in case that we try more complicated things * in the future (like having different periodic conditions for different * coordinate directions). */ r_node.SetLock(); r_node.GetValue(NODAL_AREA) = nodal_area; noalias(r_node.GetValue(ADVPROJ)) = momentum_projection; r_node.GetValue(DIVPROJ) = mass_projection; r_node.UnSetLock(); } } void CorrectContributionsOnPeriodicNode(Node<3>& rNode) { if (rNode.GetValue(NODAL_AREA) != 0.0) // Only periodic nodes will have a non-historical NODAL_AREA set. { rNode.FastGetSolutionStepValue(NODAL_AREA) = rNode.GetValue(NODAL_AREA); noalias(rNode.FastGetSolutionStepValue(ADVPROJ)) = rNode.GetValue(ADVPROJ); rNode.FastGetSolutionStepValue(DIVPROJ) = rNode.GetValue(DIVPROJ); } } //********************************************************************************* //Updating first time Derivative //********************************************************************************* void UpdateDisplacement(array_1d<double, 3 > & CurrentDisplacement, const array_1d<double, 3 > & OldDisplacement, const array_1d<double, 3 > & OldVelocity, const array_1d<double, 3 > & OldAcceleration, const array_1d<double, 3 > & CurrentAcceleration) { noalias(CurrentDisplacement) = OldDisplacement + ma3 * OldVelocity + ma4 * OldAcceleration + ma5*CurrentAcceleration; } //************************************************************************** void UpdateAcceleration(array_1d<double, 3 > & CurrentAcceleration, const array_1d<double, 3 > & DeltaVel, const array_1d<double, 3 > & OldAcceleration) { noalias(CurrentAcceleration) = ma0 * DeltaVel + ma2 * OldAcceleration; } //**************************************************************************** /** Kdyn = am*M + D + a1*K */ void AddDynamicsToLHS(LocalSystemMatrixType& LHS_Contribution, LocalSystemMatrixType& D, LocalSystemMatrixType& M, const ProcessInfo& CurrentProcessInfo) { //multipling time scheme factor LHS_Contribution *= ma1; // adding mass contribution to the dynamic stiffness if (M.size1() != 0) // if M matrix declared { noalias(LHS_Contribution) += mam*M; } //adding damping contribution if (D.size1() != 0) // if M matrix declared { noalias(LHS_Contribution) += D; } } //**************************************************************************** /// Add Bossak contributions from the inertial term to the RHS vector. /** This essentially performs bdyn = b - M*acc for the current element. * Note that viscous/pressure contributions to the RHS are expected to be added by the element itself. * @param[in] rCurrentElement The fluid element we are assembling. * @param[in/out] rRHS_Contribution The right hand side term where the contribution will be added. * @param[in] rD The elemental velocity/pressure LHS matrix. * @param[in] rM The elemental acceleration LHS matrix. * @param[in] rCurrentProcessInfo ProcessInfo instance for the containing ModelPart. */ void AddDynamicsToRHS( Element& rCurrentElement, LocalSystemVectorType& rRHS_Contribution, LocalSystemMatrixType& rD, LocalSystemMatrixType& rM, const ProcessInfo& rCurrentProcessInfo) { //adding inertia contribution if (rM.size1() != 0) { int k = OpenMPUtils::ThisThread(); rCurrentElement.GetSecondDerivativesVector(macc[k], 0); (macc[k]) *= (1.00 - mAlphaBossak); rCurrentElement.GetSecondDerivativesVector(maccold[k], 1); noalias(macc[k]) += mAlphaBossak * maccold[k]; noalias(rRHS_Contribution) -= prod(rM, macc[k]); } } /// Add Bossak contributions from the inertial term to the RHS vector. /** This essentially performs bdyn = b - M*acc for the current condition. * Note that viscous/pressure contributions to the RHS are expected to be added by the element condition. * @param[in] rCurrentCondition The fluid condition we are assembling. * @param[in/out] rRHS_Contribution The right hand side term where the contribution will be added. * @param[in] rD The elemental velocity/pressure LHS matrix. * @param[in] rM The elemental acceleration LHS matrix. * @param[in] rCurrentProcessInfo ProcessInfo instance for the containing ModelPart. */ void AddDynamicsToRHS( Condition& rCurrentCondition, LocalSystemVectorType& rRHS_Contribution, LocalSystemMatrixType& D, LocalSystemMatrixType& rM, const ProcessInfo& rCurrentProcessInfo) { //adding inertia contribution if (rM.size1() != 0) { int k = OpenMPUtils::ThisThread(); rCurrentCondition.GetSecondDerivativesVector(macc[k], 0); (macc[k]) *= (1.00 - mAlphaBossak); rCurrentCondition.GetSecondDerivativesVector(maccold[k], 1); noalias(macc[k]) += mAlphaBossak * maccold[k]; noalias(rRHS_Contribution) -= prod(rM, macc[k]); } } /*@} */ /**@name Protected Operations*/ /*@{ */ /*@} */ /**@name Protected Access */ /*@{ */ /*@} */ /**@name Protected Inquiry */ /*@{ */ /*@} */ /**@name Protected LifeCycle */ /*@{ */ /*@} */ private: /**@name Static Member Variables */ /*@{ */ /*@} */ /**@name Member Variables */ /*@{ */ CoordinateTransformationUtils<LocalSystemMatrixType,LocalSystemVectorType,double> mRotationTool; const Variable<int>& mrPeriodicIdVar; Process::Pointer mpTurbulenceModel; typename TSparseSpace::DofUpdaterPointerType mpDofUpdater = TSparseSpace::CreateDofUpdater(); /*@} */ /**@name Private Operators*/ /*@{ */ /*@} */ /**@name Private Operations*/ /*@{ */ /*@} */ /**@name Private Access */ /*@{ */ /*@} */ /**@name Private Inquiry */ /*@{ */ /*@} */ /**@name Un accessible methods */ /*@{ */ /*@} */ }; /* Class Scheme */ /*@} */ /**@name Type Definitions */ /*@{ */ /*@} */ } /* namespace Kratos.*/ #endif /* KRATOS_RESIDUALBASED_PREDICTOR_CORRECTOR_BOSSAK_SCHEME defined */

main.c

/* * Copyright (c) 2007-12 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, Haldeneggsteig 4, CH-8092 Zurich. Attn: Systems Group. */ #include <barrelfish/barrelfish.h> #include <omp.h> #include <xomp/xomp.h> #include <flounder/flounder_support_ump.h> #include "xomptest.h" void do_process(uint32_t *src, uint32_t *dst) { if (src == NULL || dst == 0) { return; } #pragma omp parallel for for (int j = 0; j < IT; j++) { for (int i = 0; i < MAX; i += IT) { dst[i + j] = src[i + j]; } } } int main(int argc, char *argv[]) { errval_t err; xomp_wid_t wid; err = xomp_worker_parse_cmdline(argc, argv, &wid); switch (err_no(err)) { case SYS_ERR_OK: debug_printf("XOMP Test started. (WORKER) %u\n", argc); err = xomp_worker_init(wid); if (err_is_fail(err)) { USER_PANIC_ERR(err, "could not initialize the worker\n"); } break; case XOMP_ERR_BAD_INVOCATION: debug_printf("XOMP Test started. (MASTER) %u\n", argc); err = start_master(argc, argv); if (err_is_fail(err)) { USER_PANIC_ERR(err, "start_master"); } break; default: break; } if (err_is_fail(err)) { USER_PANIC_ERR(err, "during initialization"); } while (1) { messages_wait_and_handle_next(); } return 0; }