/* -*- Mode: c; c-basic-offset: 4; indent-tabs-mode: t; tab-width: 8; -*- */ /* * Copyright © 2006 Mozilla Corporation * Copyright © 2006 Red Hat, Inc. * * Permission to use, copy, modify, distribute, and sell this software * and its documentation for any purpose is hereby granted without * fee, provided that the above copyright notice appear in all copies * and that both that copyright notice and this permission notice * appear in supporting documentation, and that the name of * the authors not be used in advertising or publicity pertaining to * distribution of the software without specific, written prior * permission. The authors make no representations about the * suitability of this software for any purpose. It is provided "as * is" without express or implied warranty. * * THE AUTHORS DISCLAIM ALL WARRANTIES WITH REGARD TO THIS * SOFTWARE, INCLUDING ALL IMPLIED WARRANTIES OF MERCHANTABILITY AND * FITNESS, IN NO EVENT SHALL THE AUTHORS BE LIABLE FOR ANY SPECIAL, * INDIRECT OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES WHATSOEVER * RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN ACTION * OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF OR * IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. * * Authors: Vladimir Vukicevic * Carl Worth */ #define _GNU_SOURCE 1 /* for sched_getaffinity() */ #include "../cairo-version.h" /* for the real version */ #include "cairo-perf.h" #include "cairo-stats.h" #include "cairo-boilerplate-getopt.h" /* For basename */ #ifdef HAVE_LIBGEN_H #include #endif #if HAVE_FCFINI #include #endif #ifdef HAVE_SCHED_H #include #endif #define CAIRO_PERF_ITERATIONS_DEFAULT 100 #define CAIRO_PERF_LOW_STD_DEV 0.03 #define CAIRO_PERF_STABLE_STD_DEV_COUNT 5 #define CAIRO_PERF_ITERATION_MS_DEFAULT 2000 #define CAIRO_PERF_ITERATION_MS_FAST 5 typedef struct _cairo_perf_case { CAIRO_PERF_DECL (*run); unsigned int min_size; unsigned int max_size; } cairo_perf_case_t; const cairo_perf_case_t perf_cases[]; static const char * _content_to_string (cairo_content_t content, cairo_bool_t similar) { switch (content|similar) { case CAIRO_CONTENT_COLOR: return "rgb"; case CAIRO_CONTENT_COLOR|1: return "rgb&"; case CAIRO_CONTENT_ALPHA: return "a"; case CAIRO_CONTENT_ALPHA|1: return "a&"; case CAIRO_CONTENT_COLOR_ALPHA: return "rgba"; case CAIRO_CONTENT_COLOR_ALPHA|1: return "rgba&"; default: return ""; } } static cairo_bool_t cairo_perf_has_similar (cairo_perf_t *perf) { cairo_surface_t *target; if (getenv ("CAIRO_TEST_SIMILAR") == NULL) return FALSE; /* exclude the image backend */ target = cairo_get_target (perf->cr); if (cairo_surface_get_type (target) == CAIRO_SURFACE_TYPE_IMAGE) return FALSE; return TRUE; } cairo_bool_t cairo_perf_can_run (cairo_perf_t *perf, const char *name, cairo_bool_t *is_explicit) { unsigned int i; if (is_explicit) *is_explicit = FALSE; if (perf->num_names == 0) return TRUE; for (i = 0; i < perf->num_names; i++) { if (strstr (name, perf->names[i])) { if (is_explicit) *is_explicit = FALSE; return TRUE; } } return FALSE; } static unsigned cairo_perf_calibrate (cairo_perf_t *perf, cairo_perf_func_t perf_func) { cairo_perf_ticks_t calibration, calibration_max; unsigned loops, min_loops; min_loops = 1; calibration = perf_func (perf->cr, perf->size, perf->size, min_loops); if (!perf->fast_and_sloppy) { calibration_max = perf->ms_per_iteration * 0.0001 / 4 * cairo_perf_ticks_per_second (); while (calibration < calibration_max) { min_loops *= 2; calibration = perf_func (perf->cr, perf->size, perf->size, min_loops); } } /* XXX * Compute the number of loops required for the timing * interval to be perf->ms_per_iteration milliseconds. This * helps to eliminate sampling variance due to timing and * other systematic errors. However, it also hides * synchronisation overhead as we attempt to process a large * batch of identical operations in a single shot. This can be * considered both good and bad... It would be good to perform * a more rigorous analysis of the synchronisation overhead, * that is to estimate the time for loop=0. */ loops = perf->ms_per_iteration * 0.001 * cairo_perf_ticks_per_second () * min_loops / calibration; min_loops = perf->fast_and_sloppy ? 1 : 10; if (loops < min_loops) loops = min_loops; return loops; } void cairo_perf_run (cairo_perf_t *perf, const char *name, cairo_perf_func_t perf_func, cairo_count_func_t count_func) { static cairo_bool_t first_run = TRUE; unsigned int i, similar, has_similar; cairo_perf_ticks_t *times; cairo_stats_t stats = {0.0, 0.0}; int low_std_dev_count; if (perf->list_only) { printf ("%s\n", name); return; } if (first_run) { if (perf->raw) { printf ("[ # ] %s.%-s %s %s %s ...\n", "backend", "content", "test-size", "ticks-per-ms", "time(ticks)"); } if (perf->summary) { fprintf (perf->summary, "[ # ] %8s.%-4s %28s %8s %8s %5s %5s %s %s\n", "backend", "content", "test-size", "min(ticks)", "min(ms)", "median(ms)", "stddev.", "iterations", "overhead"); } first_run = FALSE; } times = perf->times; if (getenv ("CAIRO_PERF_OUTPUT") != NULL) { /* check output */ char *filename; cairo_status_t status; xasprintf (&filename, "%s.%s.%s.%d.out.png", name, perf->target->name, _content_to_string (perf->target->content, 0), perf->size); cairo_save (perf->cr); perf_func (perf->cr, perf->size, perf->size, 1); cairo_restore (perf->cr); status = cairo_surface_write_to_png (cairo_get_target (perf->cr), filename); if (status) { fprintf (stderr, "Failed to generate output check '%s': %s\n", filename, cairo_status_to_string (status)); return; } free (filename); } has_similar = cairo_perf_has_similar (perf); for (similar = 0; similar <= has_similar; similar++) { unsigned loops; if (perf->summary) { fprintf (perf->summary, "[%3d] %8s.%-5s %26s.%-3d ", perf->test_number, perf->target->name, _content_to_string (perf->target->content, similar), name, perf->size); fflush (perf->summary); } /* We run one iteration in advance to warm caches and calibrate. */ cairo_perf_yield (); if (similar) cairo_push_group_with_content (perf->cr, cairo_boilerplate_content (perf->target->content)); else cairo_save (perf->cr); perf_func (perf->cr, perf->size, perf->size, 1); loops = cairo_perf_calibrate (perf, perf_func); if (similar) cairo_pattern_destroy (cairo_pop_group (perf->cr)); else cairo_restore (perf->cr); low_std_dev_count = 0; for (i =0; i < perf->iterations; i++) { cairo_perf_yield (); if (similar) cairo_push_group_with_content (perf->cr, cairo_boilerplate_content (perf->target->content)); else cairo_save (perf->cr); times[i] = perf_func (perf->cr, perf->size, perf->size, loops) / loops; if (similar) cairo_pattern_destroy (cairo_pop_group (perf->cr)); else cairo_restore (perf->cr); if (perf->raw) { if (i == 0) printf ("[*] %s.%s %s.%d %g", perf->target->name, _content_to_string (perf->target->content, similar), name, perf->size, cairo_perf_ticks_per_second () / 1000.0); printf (" %lld", (long long) times[i]); } else if (! perf->exact_iterations) { if (i > 0) { _cairo_stats_compute (&stats, times, i+1); if (stats.std_dev <= CAIRO_PERF_LOW_STD_DEV) { low_std_dev_count++; if (low_std_dev_count >= CAIRO_PERF_STABLE_STD_DEV_COUNT) break; } else { low_std_dev_count = 0; } } } } if (perf->raw) printf ("\n"); if (perf->summary) { _cairo_stats_compute (&stats, times, i); if (count_func != NULL) { double count = count_func (perf->cr, perf->size, perf->size); fprintf (perf->summary, "%10lld %#8.3f %#8.3f %#5.2f%% %3d: %.2f\n", (long long) stats.min_ticks, (stats.min_ticks * 1000.0) / cairo_perf_ticks_per_second (), (stats.median_ticks * 1000.0) / cairo_perf_ticks_per_second (), stats.std_dev * 100.0, stats.iterations, count * cairo_perf_ticks_per_second () / stats.min_ticks); } else { fprintf (perf->summary, "%10lld %#8.3f %#8.3f %#5.2f%% %3d\n", (long long) stats.min_ticks, (stats.min_ticks * 1000.0) / cairo_perf_ticks_per_second (), (stats.median_ticks * 1000.0) / cairo_perf_ticks_per_second (), stats.std_dev * 100.0, stats.iterations); } fflush (perf->summary); } perf->test_number++; } } static void usage (const char *argv0) { fprintf (stderr, "Usage: %s [-l] [-r] [-v] [-i iterations] [test-names ...]\n" " %s -l\n" "\n" "Run the cairo performance test suite over the given tests (all by default)\n" "The command-line arguments are interpreted as follows:\n" "\n" " -r raw; display each time measurement instead of summary statistics\n" " -v verbose; in raw mode also show the summaries\n" " -i iterations; specify the number of iterations per test case\n" " -l list only; just list selected test case names without executing\n" "\n" "If test names are given they are used as sub-string matches so a command\n" "such as \"cairo-perf text\" can be used to run all text test cases.\n", argv0, argv0); } static void parse_options (cairo_perf_t *perf, int argc, char *argv[]) { int c; const char *iters; const char *ms = NULL; char *end; int verbose = 0; if ((iters = getenv("CAIRO_PERF_ITERATIONS")) && *iters) perf->iterations = strtol(iters, NULL, 0); else perf->iterations = CAIRO_PERF_ITERATIONS_DEFAULT; perf->exact_iterations = 0; perf->fast_and_sloppy = FALSE; perf->ms_per_iteration = CAIRO_PERF_ITERATION_MS_DEFAULT; if ((ms = getenv("CAIRO_PERF_ITERATION_MS")) && *ms) { perf->ms_per_iteration = atof(ms); } perf->raw = FALSE; perf->list_only = FALSE; perf->names = NULL; perf->num_names = 0; perf->summary = stdout; while (1) { c = _cairo_getopt (argc, argv, "i:lrvf"); if (c == -1) break; switch (c) { case 'i': perf->exact_iterations = TRUE; perf->iterations = strtoul (optarg, &end, 10); if (*end != '\0') { fprintf (stderr, "Invalid argument for -i (not an integer): %s\n", optarg); exit (1); } break; case 'l': perf->list_only = TRUE; break; case 'r': perf->raw = TRUE; perf->summary = NULL; break; case 'f': perf->fast_and_sloppy = TRUE; if (ms == NULL) perf->ms_per_iteration = CAIRO_PERF_ITERATION_MS_FAST; break; case 'v': verbose = 1; break; default: fprintf (stderr, "Internal error: unhandled option: %c\n", c); /* fall-through */ case '?': usage (argv[0]); exit (1); } } if (verbose && perf->summary == NULL) perf->summary = stderr; if (optind < argc) { perf->names = &argv[optind]; perf->num_names = argc - optind; } } static int check_cpu_affinity (void) { #ifdef HAVE_SCHED_GETAFFINITY cpu_set_t affinity; int i, cpu_count; if (sched_getaffinity(0, sizeof(affinity), &affinity)) { perror("sched_getaffinity"); return -1; } for(i = 0, cpu_count = 0; i < CPU_SETSIZE; ++i) { if (CPU_ISSET(i, &affinity)) ++cpu_count; } if (cpu_count > 1) { fputs( "WARNING: cairo-perf has not been bound to a single CPU.\n", stderr); return -1; } return 0; #else fputs( "WARNING: Cannot check CPU affinity for this platform.\n", stderr); return -1; #endif } static void cairo_perf_fini (cairo_perf_t *perf) { cairo_boilerplate_free_targets (perf->targets); cairo_boilerplate_fini (); free (perf->times); cairo_debug_reset_static_data (); #if HAVE_FCFINI FcFini (); #endif } int main (int argc, char *argv[]) { int i, j; cairo_perf_t perf; cairo_surface_t *surface; parse_options (&perf, argc, argv); if (check_cpu_affinity()) { fputs( "NOTICE: cairo-perf and the X server should be bound to CPUs (either the same\n" "or separate) on SMP systems. Not doing so causes random results when the X\n" "server is moved to or from cairo-perf's CPU during the benchmarks:\n" "\n" " $ sudo taskset -cp 0 $(pidof X)\n" " $ taskset -cp 1 $$\n" "\n" "See taskset(1) for information about changing CPU affinity.\n", stderr); } perf.targets = cairo_boilerplate_get_targets (&perf.num_targets, NULL); perf.times = xmalloc (perf.iterations * sizeof (cairo_perf_ticks_t)); for (i = 0; i < perf.num_targets; i++) { const cairo_boilerplate_target_t *target = perf.targets[i]; if (! target->is_measurable) continue; perf.target = target; perf.test_number = 0; for (j = 0; perf_cases[j].run; j++) { const cairo_perf_case_t *perf_case = &perf_cases[j]; for (perf.size = perf_case->min_size; perf.size <= perf_case->max_size; perf.size *= 2) { void *closure; surface = (target->create_surface) (NULL, target->content, perf.size, perf.size, perf.size, perf.size, CAIRO_BOILERPLATE_MODE_PERF, 0, &closure); if (surface == NULL) { fprintf (stderr, "Error: Failed to create target surface: %s\n", target->name); continue; } cairo_perf_timer_set_synchronize (target->synchronize, closure); perf.cr = cairo_create (surface); perf_case->run (&perf, perf.cr, perf.size, perf.size); if (cairo_status (perf.cr)) { fprintf (stderr, "Error: Test left cairo in an error state: %s\n", cairo_status_to_string (cairo_status (perf.cr))); } cairo_destroy (perf.cr); cairo_surface_destroy (surface); if (target->cleanup) target->cleanup (closure); } } } cairo_perf_fini (&perf); return 0; } const cairo_perf_case_t perf_cases[] = { { paint, 64, 512}, { paint_with_alpha, 64, 512}, { fill, 64, 512}, { stroke, 64, 512}, { text, 64, 512}, { glyphs, 64, 512}, { mask, 64, 512}, { disjoint, 64, 512}, { hatching, 64, 512}, { tessellate, 100, 100}, { subimage_copy, 16, 512}, { hash_table, 16, 16}, { pattern_create_radial, 16, 16}, { zrusin, 415, 415}, { world_map, 800, 800}, { box_outline, 100, 100}, { mosaic, 800, 800 }, { long_lines, 100, 100}, { unaligned_clip, 100, 100}, { rectangles, 512, 512}, { rounded_rectangles, 512, 512}, { long_dashed_lines, 512, 512}, { composite_checker, 16, 512}, { twin, 800, 800}, { dragon, 1024, 1024 }, { pythagoras_tree, 768, 768 }, { intersections, 512, 512 }, { many_strokes, 64, 512 }, { many_fills, 64, 512 }, { spiral, 512, 512 }, { wave, 500, 500 }, { NULL } };