/* * xsum_bench - Benchmark functions for xxhsum * Copyright (C) 2013-2021 Yann Collet * * GPL v2 License * * 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 2 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, write to the Free Software Foundation, Inc., * 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA. * * You can contact the author at: * - xxHash homepage: https://www.xxhash.com * - xxHash source repository: https://github.com/Cyan4973/xxHash */ #include "xsum_output.h" /* XSUM_logLevel */ #include "xsum_bench.h" #include "xsum_sanity_check.h" /* XSUM_fillTestBuffer */ #include "xsum_os_specific.h" /* XSUM_getFileSize */ #ifndef XXH_STATIC_LINKING_ONLY # define XXH_STATIC_LINKING_ONLY #endif #include "../xxhash.h" #ifdef XXHSUM_DISPATCH # include "../xxh_x86dispatch.h" /* activate _dispatch() redirectors */ #endif #include /* malloc, free */ #include #include /* strlen, memcpy */ #include /* clock_t, clock, CLOCKS_PER_SEC */ #include /* errno */ #define TIMELOOP_S 1 #define TIMELOOP (TIMELOOP_S * CLOCKS_PER_SEC) /* target timing per iteration */ #define TIMELOOP_MIN (TIMELOOP / 2) /* minimum timing to validate a result */ #define MAX_MEM (2 GB - 64 MB) static clock_t XSUM_clockSpan( clock_t start ) { return clock() - start; /* works even if overflow; Typical max span ~ 30 mn */ } static size_t XSUM_findMaxMem(XSUM_U64 requiredMem) { size_t const step = 64 MB; void* testmem = NULL; requiredMem = (((requiredMem >> 26) + 1) << 26); requiredMem += 2*step; if (requiredMem > MAX_MEM) requiredMem = MAX_MEM; while (!testmem) { if (requiredMem > step) requiredMem -= step; else requiredMem >>= 1; testmem = malloc ((size_t)requiredMem); } free (testmem); /* keep some space available */ if (requiredMem > step) requiredMem -= step; else requiredMem >>= 1; return (size_t)requiredMem; } /* * A secret buffer used for benchmarking XXH3's withSecret variants. * * In order for the bench to be realistic, the secret buffer would need to be * pre-generated. * * Adding a pointer to the parameter list would be messy. */ static XSUM_U8 g_benchSecretBuf[XXH3_SECRET_SIZE_MIN]; /* * Wrappers for the benchmark. * * If you would like to add other hashes to the bench, create a wrapper and add * it to the g_hashesToBench table. It will automatically be added. */ typedef XSUM_U32 (*hashFunction)(const void* buffer, size_t bufferSize, XSUM_U32 seed); static XSUM_U32 localXXH32(const void* buffer, size_t bufferSize, XSUM_U32 seed) { return XXH32(buffer, bufferSize, seed); } static XSUM_U32 localXXH32_stream(const void* buffer, size_t bufferSize, XSUM_U32 seed) { XXH32_state_t state; (void)seed; XXH32_reset(&state, seed); XXH32_update(&state, buffer, bufferSize); return (XSUM_U32)XXH32_digest(&state); } static XSUM_U32 localXXH64(const void* buffer, size_t bufferSize, XSUM_U32 seed) { return (XSUM_U32)XXH64(buffer, bufferSize, seed); } static XSUM_U32 localXXH64_stream(const void* buffer, size_t bufferSize, XSUM_U32 seed) { XXH64_state_t state; (void)seed; XXH64_reset(&state, seed); XXH64_update(&state, buffer, bufferSize); return (XSUM_U32)XXH64_digest(&state); } static XSUM_U32 localXXH3_64b(const void* buffer, size_t bufferSize, XSUM_U32 seed) { (void)seed; return (XSUM_U32)XXH3_64bits(buffer, bufferSize); } static XSUM_U32 localXXH3_64b_seeded(const void* buffer, size_t bufferSize, XSUM_U32 seed) { return (XSUM_U32)XXH3_64bits_withSeed(buffer, bufferSize, seed); } static XSUM_U32 localXXH3_64b_secret(const void* buffer, size_t bufferSize, XSUM_U32 seed) { (void)seed; return (XSUM_U32)XXH3_64bits_withSecret(buffer, bufferSize, g_benchSecretBuf, sizeof(g_benchSecretBuf)); } static XSUM_U32 localXXH3_128b(const void* buffer, size_t bufferSize, XSUM_U32 seed) { (void)seed; return (XSUM_U32)(XXH3_128bits(buffer, bufferSize).low64); } static XSUM_U32 localXXH3_128b_seeded(const void* buffer, size_t bufferSize, XSUM_U32 seed) { return (XSUM_U32)(XXH3_128bits_withSeed(buffer, bufferSize, seed).low64); } static XSUM_U32 localXXH3_128b_secret(const void* buffer, size_t bufferSize, XSUM_U32 seed) { (void)seed; return (XSUM_U32)(XXH3_128bits_withSecret(buffer, bufferSize, g_benchSecretBuf, sizeof(g_benchSecretBuf)).low64); } static XSUM_U32 localXXH3_stream(const void* buffer, size_t bufferSize, XSUM_U32 seed) { XXH3_state_t state; (void)seed; XXH3_64bits_reset(&state); XXH3_64bits_update(&state, buffer, bufferSize); return (XSUM_U32)XXH3_64bits_digest(&state); } static XSUM_U32 localXXH3_stream_seeded(const void* buffer, size_t bufferSize, XSUM_U32 seed) { XXH3_state_t state; XXH3_INITSTATE(&state); XXH3_64bits_reset_withSeed(&state, (XXH64_hash_t)seed); XXH3_64bits_update(&state, buffer, bufferSize); return (XSUM_U32)XXH3_64bits_digest(&state); } static XSUM_U32 localXXH128_stream(const void* buffer, size_t bufferSize, XSUM_U32 seed) { XXH3_state_t state; (void)seed; XXH3_128bits_reset(&state); XXH3_128bits_update(&state, buffer, bufferSize); return (XSUM_U32)(XXH3_128bits_digest(&state).low64); } static XSUM_U32 localXXH128_stream_seeded(const void* buffer, size_t bufferSize, XSUM_U32 seed) { XXH3_state_t state; XXH3_INITSTATE(&state); XXH3_128bits_reset_withSeed(&state, (XXH64_hash_t)seed); XXH3_128bits_update(&state, buffer, bufferSize); return (XSUM_U32)(XXH3_128bits_digest(&state).low64); } typedef struct { const char* name; hashFunction func; } hashInfo; static const hashInfo g_hashesToBench[] = { { "XXH32", &localXXH32 }, { "XXH64", &localXXH64 }, { "XXH3_64b", &localXXH3_64b }, { "XXH3_64b w/seed", &localXXH3_64b_seeded }, { "XXH3_64b w/secret", &localXXH3_64b_secret }, { "XXH128", &localXXH3_128b }, { "XXH128 w/seed", &localXXH3_128b_seeded }, { "XXH128 w/secret", &localXXH3_128b_secret }, { "XXH32_stream", &localXXH32_stream }, { "XXH64_stream", &localXXH64_stream }, { "XXH3_stream", &localXXH3_stream }, { "XXH3_stream w/seed",&localXXH3_stream_seeded }, { "XXH128_stream", &localXXH128_stream }, { "XXH128_stream w/seed",&localXXH128_stream_seeded }, }; #define NB_HASHFUNC (sizeof(g_hashesToBench) / sizeof(*g_hashesToBench)) #define NB_TESTFUNC (1 + 2 * NB_HASHFUNC) int const g_nbTestFunctions = NB_TESTFUNC; char g_testIDs[NB_TESTFUNC] = { 0 }; const char k_testIDs_default[NB_TESTFUNC] = { 0, 1 /*XXH32*/, 0, 1 /*XXH64*/, 0, 1 /*XXH3*/, 0, 0, 0, 0, 0, 1 /*XXH128*/ }; int g_nbIterations = NBLOOPS_DEFAULT; #define HASHNAME_MAX 29 static void XSUM_benchHash(hashFunction h, const char* hName, int testID, const void* buffer, size_t bufferSize) { XSUM_U32 nbh_perIteration = (XSUM_U32)((300 MB) / (bufferSize+1)) + 1; /* first iteration conservatively aims for 300 MB/s */ int iterationNb, nbIterations = g_nbIterations + !g_nbIterations /* min 1 */; double fastestH = 100000000.; assert(HASHNAME_MAX > 2); XSUM_logVerbose(2, "\r%80s\r", ""); /* Clean display line */ for (iterationNb = 1; iterationNb <= nbIterations; iterationNb++) { XSUM_U32 r=0; clock_t cStart; XSUM_logVerbose(2, "%2i-%-*.*s : %10u ->\r", iterationNb, HASHNAME_MAX, HASHNAME_MAX, hName, (unsigned)bufferSize); cStart = clock(); while (clock() == cStart); /* starts clock() at its exact beginning */ cStart = clock(); { XSUM_U32 u; for (u=0; u (double)(4000U<<20)) nbh_perSecond = (double)(4000U<<20); /* avoid overflow */ nbh_perIteration = (XSUM_U32)nbh_perSecond; } /* g_nbIterations==0 => quick evaluation, no claim of accuracy */ if (g_nbIterations>0) { iterationNb--; /* new round for a more accurate speed evaluation */ continue; } } if (ticksPerHash < fastestH) fastestH = ticksPerHash; if (fastestH>0.) { /* avoid div by zero */ XSUM_logVerbose(2, "%2i-%-*.*s : %10u -> %8.0f it/s (%7.1f MB/s) \r", iterationNb, HASHNAME_MAX, HASHNAME_MAX, hName, (unsigned)bufferSize, (double)1 / fastestH, ((double)bufferSize / (1 MB)) / fastestH); } } { double nbh_perSecond = (1 / fastestH) + 1; if (nbh_perSecond > (double)(4000U<<20)) nbh_perSecond = (double)(4000U<<20); /* avoid overflow */ nbh_perIteration = (XSUM_U32)nbh_perSecond; } } XSUM_logVerbose(1, "%2i#%-*.*s : %10u -> %8.0f it/s (%7.1f MB/s) \n", testID, HASHNAME_MAX, HASHNAME_MAX, hName, (unsigned)bufferSize, (double)1 / fastestH, ((double)bufferSize / (1 MB)) / fastestH); if (XSUM_logLevel<1) XSUM_logVerbose(0, "%u, ", (unsigned)((double)1 / fastestH)); } /* * Allocates a string containing s1 and s2 concatenated. Acts like strdup. * The result must be freed. */ static char* XSUM_strcatDup(const char* s1, const char* s2) { assert(s1 != NULL); assert(s2 != NULL); { size_t len1 = strlen(s1); size_t len2 = strlen(s2); char* buf = (char*)malloc(len1 + len2 + 1); if (buf != NULL) { /* strcpy(buf, s1) */ memcpy(buf, s1, len1); /* strcat(buf, s2) */ memcpy(buf + len1, s2, len2 + 1); } return buf; } } /*! * XSUM_benchMem(): * buffer: Must be 16-byte aligned. * The real allocated size of buffer is supposed to be >= (bufferSize+3). * returns: 0 on success, 1 if error (invalid mode selected) */ static void XSUM_benchMem(const void* buffer, size_t bufferSize) { assert((((size_t)buffer) & 15) == 0); /* ensure alignment */ XSUM_fillTestBuffer(g_benchSecretBuf, sizeof(g_benchSecretBuf)); { int i; for (i = 1; i < (int)NB_TESTFUNC; i++) { int const hashFuncID = (i-1) / 2; assert(g_hashesToBench[hashFuncID].name != NULL); if (g_testIDs[i] == 0) continue; /* aligned */ if ((i % 2) == 1) { XSUM_benchHash(g_hashesToBench[hashFuncID].func, g_hashesToBench[hashFuncID].name, i, buffer, bufferSize); } /* unaligned */ if ((i % 2) == 0) { /* Append "unaligned". */ char* const hashNameBuf = XSUM_strcatDup(g_hashesToBench[hashFuncID].name, " unaligned"); assert(hashNameBuf != NULL); XSUM_benchHash(g_hashesToBench[hashFuncID].func, hashNameBuf, i, ((const char*)buffer)+3, bufferSize); free(hashNameBuf); } } } } static size_t XSUM_selectBenchedSize(const char* fileName) { XSUM_U64 const inFileSize = XSUM_getFileSize(fileName); size_t benchedSize = (size_t) XSUM_findMaxMem(inFileSize); if ((XSUM_U64)benchedSize > inFileSize) benchedSize = (size_t)inFileSize; if (benchedSize < inFileSize) { XSUM_log("Not enough memory for '%s' full size; testing %i MB only...\n", fileName, (int)(benchedSize>>20)); } return benchedSize; } int XSUM_benchFiles(const char* fileNamesTable[], int nbFiles) { int fileIdx; for (fileIdx=0; fileIdx 10 KB) { XSUM_logVerbose(1, "%u KB", (unsigned)(keySize >> 10)); } else { XSUM_logVerbose(1, "%u bytes", (unsigned)keySize); } XSUM_logVerbose(1, "... \n"); XSUM_benchMem(alignedBuffer, keySize); free(buffer); } return 0; }