/* * mem-memcpy.c * * memcpy: Simple memory copy in various ways * * Written by Hitoshi Mitake <mitake@dcl.info.waseda.ac.jp> */ #include <ctype.h> #include "../perf.h" #include "../util/util.h" #include "../util/parse-options.h" #include "../util/header.h" #include "bench.h" #include "mem-memcpy-arch.h" #include <stdio.h> #include <stdlib.h> #include <string.h> #include <sys/time.h> #include <errno.h> #define K 1024 static const char *length_str = "1MB"; static const char *routine = "default"; static bool use_clock; static int clock_fd; static bool only_prefault; static bool no_prefault; static const struct option options[] = { OPT_STRING('l', "length", &length_str, "1MB", "Specify length of memory to copy. " "available unit: B, MB, GB (upper and lower)"), OPT_STRING('r', "routine", &routine, "default", "Specify routine to copy"), OPT_BOOLEAN('c', "clock", &use_clock, "Use CPU clock for measuring"), OPT_BOOLEAN('o', "only-prefault", &only_prefault, "Show only the result with page faults before memcpy()"), OPT_BOOLEAN('n', "no-prefault", &no_prefault, "Show only the result without page faults before memcpy()"), OPT_END() }; typedef void *(*memcpy_t)(void *, const void *, size_t); struct routine { const char *name; const char *desc; memcpy_t fn; }; struct routine routines[] = { { "default", "Default memcpy() provided by glibc", memcpy }, #ifdef ARCH_X86_64 #define MEMCPY_FN(fn, name, desc) { name, desc, fn }, #include "mem-memcpy-x86-64-asm-def.h" #undef MEMCPY_FN #endif { NULL, NULL, NULL } }; static const char * const bench_mem_memcpy_usage[] = { "perf bench mem memcpy <options>", NULL }; static struct perf_event_attr clock_attr = { .type = PERF_TYPE_HARDWARE, .config = PERF_COUNT_HW_CPU_CYCLES }; static void init_clock(void) { clock_fd = sys_perf_event_open(&clock_attr, getpid(), -1, -1, 0); if (clock_fd < 0 && errno == ENOSYS) die("No CONFIG_PERF_EVENTS=y kernel support configured?\n"); else BUG_ON(clock_fd < 0); } static u64 get_clock(void) { int ret; u64 clk; ret = read(clock_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; } static void alloc_mem(void **dst, void **src, size_t length) { *dst = zalloc(length); if (!dst) die("memory allocation failed - maybe length is too large?\n"); *src = zalloc(length); if (!src) die("memory allocation failed - maybe length is too large?\n"); } static u64 do_memcpy_clock(memcpy_t fn, size_t len, bool prefault) { u64 clock_start = 0ULL, clock_end = 0ULL; void *src = NULL, *dst = NULL; alloc_mem(&src, &dst, len); if (prefault) fn(dst, src, len); clock_start = get_clock(); fn(dst, src, len); clock_end = get_clock(); free(src); free(dst); return clock_end - clock_start; } static double do_memcpy_gettimeofday(memcpy_t fn, size_t len, bool prefault) { struct timeval tv_start, tv_end, tv_diff; void *src = NULL, *dst = NULL; alloc_mem(&src, &dst, len); if (prefault) fn(dst, src, len); gettimeofday(&tv_start, NULL); fn(dst, src, len); gettimeofday(&tv_end, NULL); timersub(&tv_end, &tv_start, &tv_diff); free(src); free(dst); return (double)((double)len / timeval2double(&tv_diff)); } #define pf (no_prefault ? 0 : 1) #define print_bps(x) do { \ if (x < K) \ printf(" %14lf B/Sec", x); \ else if (x < K * K) \ printf(" %14lfd KB/Sec", x / K); \ else if (x < K * K * K) \ printf(" %14lf MB/Sec", x / K / K); \ else \ printf(" %14lf GB/Sec", x / K / K / K); \ } while (0) int bench_mem_memcpy(int argc, const char **argv, const char *prefix __used) { int i; size_t len; double result_bps[2]; u64 result_clock[2]; argc = parse_options(argc, argv, options, bench_mem_memcpy_usage, 0); if (use_clock) init_clock(); len = (size_t)perf_atoll((char *)length_str); result_clock[0] = result_clock[1] = 0ULL; result_bps[0] = result_bps[1] = 0.0; if ((s64)len <= 0) { fprintf(stderr, "Invalid length:%s\n", length_str); return 1; } /* same to without specifying either of prefault and no-prefault */ if (only_prefault && no_prefault) only_prefault = no_prefault = false; for (i = 0; routines[i].name; i++) { if (!strcmp(routines[i].name, routine)) break; } if (!routines[i].name) { printf("Unknown routine:%s\n", routine); printf("Available routines...\n"); for (i = 0; routines[i].name; i++) { printf("\t%s ... %s\n", routines[i].name, routines[i].desc); } return 1; } if (bench_format == BENCH_FORMAT_DEFAULT) printf("# Copying %s Bytes ...\n\n", length_str); if (!only_prefault && !no_prefault) { /* show both of results */ if (use_clock) { result_clock[0] = do_memcpy_clock(routines[i].fn, len, false); result_clock[1] = do_memcpy_clock(routines[i].fn, len, true); } else { result_bps[0] = do_memcpy_gettimeofday(routines[i].fn, len, false); result_bps[1] = do_memcpy_gettimeofday(routines[i].fn, len, true); } } else { if (use_clock) { result_clock[pf] = do_memcpy_clock(routines[i].fn, len, only_prefault); } else { result_bps[pf] = do_memcpy_gettimeofday(routines[i].fn, len, only_prefault); } } switch (bench_format) { case BENCH_FORMAT_DEFAULT: if (!only_prefault && !no_prefault) { if (use_clock) { printf(" %14lf Clock/Byte\n", (double)result_clock[0] / (double)len); printf(" %14lf Clock/Byte (with prefault)\n", (double)result_clock[1] / (double)len); } else { print_bps(result_bps[0]); printf("\n"); print_bps(result_bps[1]); printf(" (with prefault)\n"); } } else { if (use_clock) { printf(" %14lf Clock/Byte", (double)result_clock[pf] / (double)len); } else print_bps(result_bps[pf]); printf("%s\n", only_prefault ? " (with prefault)" : ""); } break; case BENCH_FORMAT_SIMPLE: if (!only_prefault && !no_prefault) { if (use_clock) { printf("%lf %lf\n", (double)result_clock[0] / (double)len, (double)result_clock[1] / (double)len); } else { printf("%lf %lf\n", result_bps[0], result_bps[1]); } } else { if (use_clock) { printf("%lf\n", (double)result_clock[pf] / (double)len); } else printf("%lf\n", result_bps[pf]); } break; default: /* reaching this means there's some disaster: */ die("unknown format: %d\n", bench_format); break; } return 0; }