/* * mem-memcpy.c * * Simple memcpy() and memset() benchmarks * * Written by Hitoshi Mitake */ #include "../perf.h" #include "../util/util.h" #include "../util/parse-options.h" #include "../util/header.h" #include "../util/cloexec.h" #include "bench.h" #include "mem-memcpy-arch.h" #include "mem-memset-arch.h" #include #include #include #include #include #define K 1024 static const char *size_str = "1MB"; static const char *routine_str = "all"; static int iterations = 1; static bool use_cycles; static int cycles_fd; static const struct option options[] = { OPT_STRING('l', "size", &size_str, "1MB", "Specify the size of the memory buffers. " "Available units: B, KB, MB, GB and TB (upper and lower)"), OPT_STRING('r', "routine", &routine_str, "all", "Specify the routine to run, \"all\" runs all available routines"), OPT_INTEGER('i', "iterations", &iterations, "repeat memcpy() invocation this number of times"), OPT_BOOLEAN('c', "cycles", &use_cycles, "Use a cycles event instead of gettimeofday() to measure performance"), OPT_END() }; typedef void *(*memcpy_t)(void *, const void *, size_t); typedef void *(*memset_t)(void *, int, size_t); struct routine { const char *name; const char *desc; union { memcpy_t memcpy; memset_t memset; } fn; }; struct routine memcpy_routines[] = { { .name = "default", .desc = "Default memcpy() provided by glibc", .fn.memcpy = memcpy }, #ifdef HAVE_ARCH_X86_64_SUPPORT # define MEMCPY_FN(_fn, _name, _desc) {.name = _name, .desc = _desc, .fn.memcpy = _fn}, # include "mem-memcpy-x86-64-asm-def.h" # undef MEMCPY_FN #endif { NULL, } }; static const char * const bench_mem_memcpy_usage[] = { "perf bench mem memcpy ", NULL }; static struct perf_event_attr cycle_attr = { .type = PERF_TYPE_HARDWARE, .config = PERF_COUNT_HW_CPU_CYCLES }; static void init_cycles(void) { cycles_fd = sys_perf_event_open(&cycle_attr, getpid(), -1, -1, perf_event_open_cloexec_flag()); if (cycles_fd < 0 && errno == ENOSYS) die("No CONFIG_PERF_EVENTS=y kernel support configured?\n"); else BUG_ON(cycles_fd < 0); } static u64 get_cycles(void) { int ret; u64 clk; ret = read(cycles_fd, &clk, sizeof(u64)); BUG_ON(ret != sizeof(u64)); return clk; } static double timeval2double(struct timeval *ts) { return (double)ts->tv_sec + (double)ts->tv_usec / (double)1000000; } #define print_bps(x) do { \ if (x < K) \ printf(" %14lf B/Sec\n", x); \ else if (x < K * K) \ printf(" %14lfd KB/Sec\n", x / K); \ else if (x < K * K * K) \ printf(" %14lf MB/Sec\n", x / K / K); \ else \ printf(" %14lf GB/Sec\n", x / K / K / K); \ } while (0) struct bench_mem_info { const struct routine *routines; u64 (*do_cycles)(const struct routine *r, size_t size); double (*do_gettimeofday)(const struct routine *r, size_t size); const char *const *usage; }; static void __bench_mem_routine(struct bench_mem_info *info, int r_idx, size_t size, double size_total) { const struct routine *r = &info->routines[r_idx]; double result_bps = 0.0; u64 result_cycles = 0; printf("Routine %s (%s)\n", r->name, r->desc); if (bench_format == BENCH_FORMAT_DEFAULT) printf("# Copying %s Bytes ...\n\n", size_str); if (use_cycles) { result_cycles = info->do_cycles(r, size); } else { result_bps = info->do_gettimeofday(r, size); } switch (bench_format) { case BENCH_FORMAT_DEFAULT: if (use_cycles) { printf(" %14lf cycles/Byte\n", (double)result_cycles/size_total); } else { print_bps(result_bps); } break; case BENCH_FORMAT_SIMPLE: if (use_cycles) { printf("%lf\n", (double)result_cycles/size_total); } else { printf("%lf\n", result_bps); } break; default: BUG_ON(1); break; } } static int bench_mem_common(int argc, const char **argv, struct bench_mem_info *info) { int i; size_t size; double size_total; argc = parse_options(argc, argv, options, info->usage, 0); if (use_cycles) init_cycles(); size = (size_t)perf_atoll((char *)size_str); size_total = (double)size * iterations; if ((s64)size <= 0) { fprintf(stderr, "Invalid size:%s\n", size_str); return 1; } if (!strncmp(routine_str, "all", 3)) { for (i = 0; info->routines[i].name; i++) __bench_mem_routine(info, i, size, size_total); return 0; } for (i = 0; info->routines[i].name; i++) { if (!strcmp(info->routines[i].name, routine_str)) break; } if (!info->routines[i].name) { printf("Unknown routine: %s\n", routine_str); printf("Available routines...\n"); for (i = 0; info->routines[i].name; i++) { printf("\t%s ... %s\n", info->routines[i].name, info->routines[i].desc); } return 1; } __bench_mem_routine(info, i, size, size_total); return 0; } static void memcpy_alloc_mem(void **dst, void **src, size_t size) { *dst = zalloc(size); if (!*dst) die("memory allocation failed - maybe size is too large?\n"); *src = zalloc(size); if (!*src) die("memory allocation failed - maybe size is too large?\n"); /* Make sure to always prefault zero pages even if MMAP_THRESH is crossed: */ memset(*src, 0, size); } static u64 do_memcpy_cycles(const struct routine *r, size_t size) { u64 cycle_start = 0ULL, cycle_end = 0ULL; void *src = NULL, *dst = NULL; memcpy_t fn = r->fn.memcpy; int i; memcpy_alloc_mem(&dst, &src, size); /* * We prefault the freshly allocated memory range here, * to not measure page fault overhead: */ fn(dst, src, size); cycle_start = get_cycles(); for (i = 0; i < iterations; ++i) fn(dst, src, size); cycle_end = get_cycles(); free(src); free(dst); return cycle_end - cycle_start; } static double do_memcpy_gettimeofday(const struct routine *r, size_t size) { struct timeval tv_start, tv_end, tv_diff; memcpy_t fn = r->fn.memcpy; void *src = NULL, *dst = NULL; int i; memcpy_alloc_mem(&dst, &src, size); /* * We prefault the freshly allocated memory range here, * to not measure page fault overhead: */ fn(dst, src, size); BUG_ON(gettimeofday(&tv_start, NULL)); for (i = 0; i < iterations; ++i) fn(dst, src, size); BUG_ON(gettimeofday(&tv_end, NULL)); timersub(&tv_end, &tv_start, &tv_diff); free(src); free(dst); return (double)(((double)size * iterations) / timeval2double(&tv_diff)); } int bench_mem_memcpy(int argc, const char **argv, const char *prefix __maybe_unused) { struct bench_mem_info info = { .routines = memcpy_routines, .do_cycles = do_memcpy_cycles, .do_gettimeofday = do_memcpy_gettimeofday, .usage = bench_mem_memcpy_usage, }; return bench_mem_common(argc, argv, &info); } static void memset_alloc_mem(void **dst, size_t size) { *dst = zalloc(size); if (!*dst) die("memory allocation failed - maybe size is too large?\n"); } static u64 do_memset_cycles(const struct routine *r, size_t size) { u64 cycle_start = 0ULL, cycle_end = 0ULL; memset_t fn = r->fn.memset; void *dst = NULL; int i; memset_alloc_mem(&dst, size); /* * We prefault the freshly allocated memory range here, * to not measure page fault overhead: */ fn(dst, -1, size); cycle_start = get_cycles(); for (i = 0; i < iterations; ++i) fn(dst, i, size); cycle_end = get_cycles(); free(dst); return cycle_end - cycle_start; } static double do_memset_gettimeofday(const struct routine *r, size_t size) { struct timeval tv_start, tv_end, tv_diff; memset_t fn = r->fn.memset; void *dst = NULL; int i; memset_alloc_mem(&dst, size); /* * We prefault the freshly allocated memory range here, * to not measure page fault overhead: */ fn(dst, -1, size); BUG_ON(gettimeofday(&tv_start, NULL)); for (i = 0; i < iterations; ++i) fn(dst, i, size); BUG_ON(gettimeofday(&tv_end, NULL)); timersub(&tv_end, &tv_start, &tv_diff); free(dst); return (double)(((double)size * iterations) / timeval2double(&tv_diff)); } static const char * const bench_mem_memset_usage[] = { "perf bench mem memset ", NULL }; static const struct routine memset_routines[] = { { .name = "default", .desc = "Default memset() provided by glibc", .fn.memset = memset }, #ifdef HAVE_ARCH_X86_64_SUPPORT # define MEMSET_FN(_fn, _name, _desc) { .name = _name, .desc = _desc, .fn.memset = _fn }, # include "mem-memset-x86-64-asm-def.h" # undef MEMSET_FN #endif { NULL, } }; int bench_mem_memset(int argc, const char **argv, const char *prefix __maybe_unused) { struct bench_mem_info info = { .routines = memset_routines, .do_cycles = do_memset_cycles, .do_gettimeofday = do_memset_gettimeofday, .usage = bench_mem_memset_usage, }; return bench_mem_common(argc, argv, &info); }