/** * Copyright (c) 2016-present, Yann Collet, Facebook, Inc. * All rights reserved. * * This source code is licensed under the BSD-style license found in the * LICENSE file in the root directory of this source tree. An additional grant * of patent rights can be found in the PATENTS file in the same directory. */ /*-************************************ * Dependencies **************************************/ #include "util.h" /* Compiler options, UTIL_GetFileSize */ #include /* malloc */ #include /* fprintf, fopen, ftello64 */ #include /* strcmp */ #include /* log */ #include /* clock_t */ #include "mem.h" #define ZSTD_STATIC_LINKING_ONLY /* ZSTD_parameters, ZSTD_estimateCCtxSize */ #include "zstd.h" #include "datagen.h" #include "xxhash.h" /*-************************************ * Constants **************************************/ #define PROGRAM_DESCRIPTION "ZSTD parameters tester" #define AUTHOR "Yann Collet" #define WELCOME_MESSAGE "*** %s %s %i-bits, by %s (%s) ***\n", PROGRAM_DESCRIPTION, ZSTD_VERSION_STRING, (int)(sizeof(void*)*8), AUTHOR, __DATE__ #define KB *(1<<10) #define MB *(1<<20) #define GB *(1ULL<<30) #define NBLOOPS 2 #define TIMELOOP (2 * CLOCKS_PER_SEC) #define NB_LEVELS_TRACKED 30 static const size_t maxMemory = (sizeof(size_t)==4) ? (2 GB - 64 MB) : (size_t)(1ULL << ((sizeof(size_t)*8)-31)); #define COMPRESSIBILITY_DEFAULT 0.50 static const size_t sampleSize = 10000000; static const U32 g_grillDuration_s = 60000; /* about 16 hours */ static const clock_t g_maxParamTime = 15 * CLOCKS_PER_SEC; static const clock_t g_maxVariationTime = 60 * CLOCKS_PER_SEC; static const int g_maxNbVariations = 64; /*-************************************ * Macros **************************************/ #define DISPLAY(...) fprintf(stderr, __VA_ARGS__) /*-************************************ * Benchmark Parameters **************************************/ static U32 g_nbIterations = NBLOOPS; static double g_compressibility = COMPRESSIBILITY_DEFAULT; static U32 g_blockSize = 0; static U32 g_rand = 1; static U32 g_singleRun = 0; static U32 g_target = 0; static U32 g_noSeed = 0; static ZSTD_compressionParameters g_params = { 0, 0, 0, 0, 0, 0, ZSTD_greedy }; void BMK_SetNbIterations(int nbLoops) { g_nbIterations = nbLoops; DISPLAY("- %u iterations -\n", g_nbIterations); } /*-******************************************************* * Private functions *********************************************************/ static clock_t BMK_clockSpan(clock_t cStart) { return clock() - cStart; } /* works even if overflow ; max span ~ 30 mn */ static U32 BMK_timeSpan(time_t tStart) { return (U32)difftime(time(NULL), tStart); } /* accuracy in seconds only, span can be multiple years */ static size_t BMK_findMaxMem(U64 requiredMem) { size_t const step = 64 MB; void* testmem = NULL; requiredMem = (((requiredMem >> 26) + 1) << 26); if (requiredMem > maxMemory) requiredMem = maxMemory; requiredMem += 2*step; while (!testmem) { requiredMem -= step; testmem = malloc ((size_t)requiredMem); } free (testmem); return (size_t) (requiredMem - step); } static U32 FUZ_rotl32(U32 x, U32 r) { return ((x << r) | (x >> (32 - r))); } U32 FUZ_rand(U32* src) { const U32 prime1 = 2654435761U; const U32 prime2 = 2246822519U; U32 rand32 = *src; rand32 *= prime1; rand32 += prime2; rand32 = FUZ_rotl32(rand32, 13); *src = rand32; return rand32 >> 5; } /*-******************************************************* * Bench functions *********************************************************/ typedef struct { size_t cSize; double cSpeed; /* bytes / sec */ double dSpeed; } BMK_result_t; typedef struct { const char* srcPtr; size_t srcSize; char* cPtr; size_t cRoom; size_t cSize; char* resPtr; size_t resSize; } blockParam_t; #define MIN(a,b) ( (a) < (b) ? (a) : (b) ) static size_t BMK_benchParam(BMK_result_t* resultPtr, const void* srcBuffer, size_t srcSize, ZSTD_CCtx* ctx, const ZSTD_compressionParameters cParams) { const size_t blockSize = g_blockSize ? g_blockSize : srcSize; const U32 nbBlocks = (U32) ((srcSize + (blockSize-1)) / blockSize); blockParam_t* const blockTable = (blockParam_t*) malloc(nbBlocks * sizeof(blockParam_t)); const size_t maxCompressedSize = (size_t)nbBlocks * ZSTD_compressBound(blockSize); void* const compressedBuffer = malloc(maxCompressedSize); void* const resultBuffer = malloc(srcSize); ZSTD_parameters params; U32 Wlog = cParams.windowLog; U32 Clog = cParams.chainLog; U32 Hlog = cParams.hashLog; U32 Slog = cParams.searchLog; U32 Slength = cParams.searchLength; U32 Tlength = cParams.targetLength; ZSTD_strategy strat = cParams.strategy; char name[30] = { 0 }; U64 crcOrig; /* init result for early exit */ resultPtr->cSize = srcSize; resultPtr->cSpeed = 0.; resultPtr->dSpeed = 0.; /* Memory allocation & restrictions */ snprintf(name, 30, "Sw%02uc%02uh%02us%02ul%1ut%03uS%1u", Wlog, Clog, Hlog, Slog, Slength, Tlength, strat); if (!compressedBuffer || !resultBuffer || !blockTable) { DISPLAY("\nError: not enough memory!\n"); free(compressedBuffer); free(resultBuffer); free(blockTable); return 12; } /* Calculating input Checksum */ crcOrig = XXH64(srcBuffer, srcSize, 0); /* Init blockTable data */ { U32 i; size_t remaining = srcSize; const char* srcPtr = (const char*)srcBuffer; char* cPtr = (char*)compressedBuffer; char* resPtr = (char*)resultBuffer; for (i=0; i g_maxParamTime) break; } /* Compression */ DISPLAY("\r%1u-%s : %9u ->", loopNb, name, (U32)srcSize); memset(compressedBuffer, 0xE5, maxCompressedSize); nbLoops = 0; roundStart = clock(); while (clock() == roundStart); roundStart = clock(); while (BMK_clockSpan(roundStart) < TIMELOOP) { for (blockNb=0; blockNb", loopNb, name, (U32)srcSize); DISPLAY(" %9u (%4.3f),%7.1f MB/s", (U32)cSize, ratio, (double)srcSize / fastestC / 1000000.); resultPtr->cSize = cSize; resultPtr->cSpeed = (double)srcSize / fastestC; #if 1 /* Decompression */ memset(resultBuffer, 0xD6, srcSize); nbLoops = 0; roundStart = clock(); while (clock() == roundStart); roundStart = clock(); for ( ; BMK_clockSpan(roundStart) < TIMELOOP; nbLoops++) { for (blockNb=0; blockNb ", loopNb, name, (U32)srcSize); DISPLAY("%9u (%4.3f),%7.1f MB/s, ", (U32)cSize, ratio, (double)srcSize / fastestC / 1000000.); DISPLAY("%7.1f MB/s", (double)srcSize / fastestD / 1000000.); resultPtr->dSpeed = (double)srcSize / fastestD; /* CRC Checking */ { U64 const crcCheck = XXH64(resultBuffer, srcSize, 0); if (crcOrig!=crcCheck) { unsigned u; unsigned eBlockSize = (unsigned)(MIN(65536*2, blockSize)); DISPLAY("\n!!! WARNING !!! Invalid Checksum : %x != %x\n", (unsigned)crcOrig, (unsigned)crcCheck); for (u=0; u O_ratio) DISPLAY ("Decompression Memory : %5.3f @ %4.1f MB vs %5.3f @ %4.1f MB : not enough for level %i\n", W_ratio, (double)(W_DMemUsed) / 1024 / 1024, O_ratio, (double)(O_DMemUsed) / 1024 / 1024, cLevel); continue; } if (W_CMemUsed_note < O_CMemUsed_note) { /* uses too much memory for compression for too little benefit */ if (W_ratio > O_ratio) DISPLAY ("Compression Memory : %5.3f @ %4.1f MB vs %5.3f @ %4.1f MB : not enough for level %i\n", W_ratio, (double)(W_CMemUsed) / 1024 / 1024, O_ratio, (double)(O_CMemUsed) / 1024 / 1024, cLevel); continue; } if (W_CSpeed_note < O_CSpeed_note ) { /* too large compression speed difference for the compression benefit */ if (W_ratio > O_ratio) DISPLAY ("Compression Speed : %5.3f @ %4.1f MB/s vs %5.3f @ %4.1f MB/s : not enough for level %i\n", W_ratio, testResult.cSpeed / 1000000, O_ratio, winners[cLevel].result.cSpeed / 1000000., cLevel); continue; } if (W_DSpeed_note < O_DSpeed_note ) { /* too large decompression speed difference for the compression benefit */ if (W_ratio > O_ratio) DISPLAY ("Decompression Speed : %5.3f @ %4.1f MB/s vs %5.3f @ %4.1f MB/s : not enough for level %i\n", W_ratio, testResult.dSpeed / 1000000., O_ratio, winners[cLevel].result.dSpeed / 1000000., cLevel); continue; } if (W_ratio < O_ratio) DISPLAY("Solution %4.3f selected over %4.3f at level %i, due to better secondary statistics \n", W_ratio, O_ratio, cLevel); winners[cLevel].result = testResult; winners[cLevel].params = params; BMK_printWinner(stdout, cLevel, testResult, params, srcSize); better = 1; } } return better; } /* nullified useless params, to ensure count stats */ static ZSTD_compressionParameters* sanitizeParams(ZSTD_compressionParameters params) { g_params = params; if (params.strategy == ZSTD_fast) g_params.chainLog = 0, g_params.searchLog = 0; if (params.strategy == ZSTD_dfast) g_params.searchLog = 0; if (params.strategy != ZSTD_btopt && params.strategy != ZSTD_btopt2) g_params.targetLength = 0; return &g_params; } static void paramVariation(ZSTD_compressionParameters* ptr) { ZSTD_compressionParameters p; U32 validated = 0; while (!validated) { U32 nbChanges = (FUZ_rand(&g_rand) & 3) + 1; p = *ptr; for ( ; nbChanges ; nbChanges--) { const U32 changeID = FUZ_rand(&g_rand) % 14; switch(changeID) { case 0: p.chainLog++; break; case 1: p.chainLog--; break; case 2: p.hashLog++; break; case 3: p.hashLog--; break; case 4: p.searchLog++; break; case 5: p.searchLog--; break; case 6: p.windowLog++; break; case 7: p.windowLog--; break; case 8: p.searchLength++; break; case 9: p.searchLength--; break; case 10: p.strategy = (ZSTD_strategy)(((U32)p.strategy)+1); break; case 11: p.strategy = (ZSTD_strategy)(((U32)p.strategy)-1); break; case 12: p.targetLength *= 1 + ((double)(FUZ_rand(&g_rand)&255)) / 256.; break; case 13: p.targetLength /= 1 + ((double)(FUZ_rand(&g_rand)&255)) / 256.; break; } } validated = !ZSTD_isError(ZSTD_checkCParams(p)); } *ptr = p; } #define PARAMTABLELOG 25 #define PARAMTABLESIZE (1<> 3) & PARAMTABLEMASK] #define MAX(a,b) ( (a) > (b) ? (a) : (b) ) static void playAround(FILE* f, winnerInfo_t* winners, ZSTD_compressionParameters params, const void* srcBuffer, size_t srcSize, ZSTD_CCtx* ctx) { int nbVariations = 0; clock_t const clockStart = clock(); while (BMK_clockSpan(clockStart) < g_maxVariationTime) { ZSTD_compressionParameters p = params; if (nbVariations++ > g_maxNbVariations) break; paramVariation(&p); /* exclude faster if already played params */ if (FUZ_rand(&g_rand) & ((1 << NB_TESTS_PLAYED(p))-1)) continue; /* test */ NB_TESTS_PLAYED(p)++; if (!BMK_seed(winners, p, srcBuffer, srcSize, ctx)) continue; /* improvement found => search more */ BMK_printWinners(f, winners, srcSize); playAround(f, winners, p, srcBuffer, srcSize, ctx); } } static ZSTD_compressionParameters randomParams(void) { ZSTD_compressionParameters p; U32 validated = 0; while (!validated) { /* totally random entry */ p.chainLog = FUZ_rand(&g_rand) % (ZSTD_CHAINLOG_MAX+1 - ZSTD_CHAINLOG_MIN) + ZSTD_CHAINLOG_MIN; p.hashLog = FUZ_rand(&g_rand) % (ZSTD_HASHLOG_MAX+1 - ZSTD_HASHLOG_MIN) + ZSTD_HASHLOG_MIN; p.searchLog = FUZ_rand(&g_rand) % (ZSTD_SEARCHLOG_MAX+1 - ZSTD_SEARCHLOG_MIN) + ZSTD_SEARCHLOG_MIN; p.windowLog = FUZ_rand(&g_rand) % (ZSTD_WINDOWLOG_MAX+1 - ZSTD_WINDOWLOG_MIN) + ZSTD_WINDOWLOG_MIN; p.searchLength=FUZ_rand(&g_rand) % (ZSTD_SEARCHLENGTH_MAX+1 - ZSTD_SEARCHLENGTH_MIN) + ZSTD_SEARCHLENGTH_MIN; p.targetLength=FUZ_rand(&g_rand) % (ZSTD_TARGETLENGTH_MAX+1 - ZSTD_TARGETLENGTH_MIN) + ZSTD_TARGETLENGTH_MIN; p.strategy = (ZSTD_strategy) (FUZ_rand(&g_rand) % (ZSTD_btopt2 +1)); validated = !ZSTD_isError(ZSTD_checkCParams(p)); } return p; } static void BMK_selectRandomStart( FILE* f, winnerInfo_t* winners, const void* srcBuffer, size_t srcSize, ZSTD_CCtx* ctx) { U32 const id = (FUZ_rand(&g_rand) % (ZSTD_maxCLevel()+1)); if ((id==0) || (winners[id].params.windowLog==0)) { /* totally random entry */ ZSTD_compressionParameters const p = ZSTD_adjustCParams(randomParams(), srcSize, 0); playAround(f, winners, p, srcBuffer, srcSize, ctx); } else playAround(f, winners, winners[id].params, srcBuffer, srcSize, ctx); } static void BMK_benchMem(void* srcBuffer, size_t srcSize) { ZSTD_CCtx* const ctx = ZSTD_createCCtx(); ZSTD_compressionParameters params; winnerInfo_t winners[NB_LEVELS_TRACKED]; const char* const rfName = "grillResults.txt"; FILE* const f = fopen(rfName, "w"); const size_t blockSize = g_blockSize ? g_blockSize : srcSize; /* init */ if (ctx==NULL) { DISPLAY("ZSTD_createCCtx() failed \n"); exit(1); } memset(winners, 0, sizeof(winners)); if (f==NULL) { DISPLAY("error opening %s \n", rfName); exit(1); } if (g_singleRun) { BMK_result_t testResult; g_params = ZSTD_adjustCParams(g_params, srcSize, 0); BMK_benchParam(&testResult, srcBuffer, srcSize, ctx, g_params); DISPLAY("\n"); return; } if (g_target) g_cSpeedTarget[1] = g_target * 1000000; else { /* baseline config for level 1 */ BMK_result_t testResult; params = ZSTD_getCParams(1, blockSize, 0); BMK_benchParam(&testResult, srcBuffer, srcSize, ctx, params); g_cSpeedTarget[1] = (testResult.cSpeed * 31) / 32; } /* establish speed objectives (relative to level 1) */ { int i; for (i=2; i<=ZSTD_maxCLevel(); i++) g_cSpeedTarget[i] = (g_cSpeedTarget[i-1] * 25) / 32; } /* populate initial solution */ { const int maxSeeds = g_noSeed ? 1 : ZSTD_maxCLevel(); int i; for (i=0; i<=maxSeeds; i++) { params = ZSTD_getCParams(i, blockSize, 0); BMK_seed(winners, params, srcBuffer, srcSize, ctx); } } BMK_printWinners(f, winners, srcSize); /* start tests */ { const time_t grillStart = time(NULL); do { BMK_selectRandomStart(f, winners, srcBuffer, srcSize, ctx); } while (BMK_timeSpan(grillStart) < g_grillDuration_s); } /* end summary */ BMK_printWinners(f, winners, srcSize); DISPLAY("grillParams operations completed \n"); /* clean up*/ fclose(f); ZSTD_freeCCtx(ctx); } static int benchSample(void) { void* origBuff; size_t const benchedSize = sampleSize; const char* const name = "Sample 10MiB"; /* Allocation */ origBuff = malloc(benchedSize); if (!origBuff) { DISPLAY("\nError: not enough memory!\n"); return 12; } /* Fill buffer */ RDG_genBuffer(origBuff, benchedSize, g_compressibility, 0.0, 0); /* bench */ DISPLAY("\r%79s\r", ""); DISPLAY("using %s %i%%: \n", name, (int)(g_compressibility*100)); BMK_benchMem(origBuff, benchedSize); free(origBuff); return 0; } int benchFiles(const char** fileNamesTable, int nbFiles) { int fileIdx=0; /* Loop for each file */ while (fileIdx inFileSize) benchedSize = (size_t)inFileSize; if (benchedSize < inFileSize) DISPLAY("Not enough memory for '%s' full size; testing %i MB only...\n", inFileName, (int)(benchedSize>>20)); origBuff = malloc(benchedSize); if (origBuff==NULL) { DISPLAY("\nError: not enough memory!\n"); fclose(inFile); return 12; } /* Fill input buffer */ DISPLAY("Loading %s... \r", inFileName); { size_t const readSize = fread(origBuff, 1, benchedSize, inFile); fclose(inFile); if(readSize != benchedSize) { DISPLAY("\nError: problem reading file '%s' !! \n", inFileName); free(origBuff); return 13; } } /* bench */ DISPLAY("\r%79s\r", ""); DISPLAY("using %s : \n", inFileName); BMK_benchMem(origBuff, benchedSize); /* clean */ free(origBuff); } return 0; } static void BMK_translateAdvancedParams(ZSTD_compressionParameters params) { DISPLAY("--zstd=windowLog=%u,chainLog=%u,hashLog=%u,searchLog=%u,searchLength=%u,targetLength=%u,strategy=%u \n", params.windowLog, params.chainLog, params.hashLog, params.searchLog, params.searchLength, params.targetLength, (U32)(params.strategy)); } /* optimizeForSize(): * targetSpeed : expressed in MB/s */ int optimizeForSize(const char* inFileName, U32 targetSpeed) { FILE* const inFile = fopen( inFileName, "rb" ); U64 const inFileSize = UTIL_getFileSize(inFileName); size_t benchedSize = BMK_findMaxMem(inFileSize*3) / 3; void* origBuff; /* Init */ if (inFile==NULL) { DISPLAY( "Pb opening %s\n", inFileName); return 11; } /* Memory allocation & restrictions */ if ((U64)benchedSize > inFileSize) benchedSize = (size_t)inFileSize; if (benchedSize < inFileSize) { DISPLAY("Not enough memory for '%s' \n", inFileName); fclose(inFile); return 11; } /* Alloc */ origBuff = malloc(benchedSize); if(!origBuff) { DISPLAY("\nError: not enough memory!\n"); fclose(inFile); return 12; } /* Fill input buffer */ DISPLAY("Loading %s... \r", inFileName); { size_t const readSize = fread(origBuff, 1, benchedSize, inFile); fclose(inFile); if(readSize != benchedSize) { DISPLAY("\nError: problem reading file '%s' !! \n", inFileName); free(origBuff); return 13; } } /* bench */ DISPLAY("\r%79s\r", ""); DISPLAY("optimizing for %s - limit speed %u MB/s \n", inFileName, targetSpeed); targetSpeed *= 1000000; { ZSTD_CCtx* const ctx = ZSTD_createCCtx(); winnerInfo_t winner; BMK_result_t candidate; const size_t blockSize = g_blockSize ? g_blockSize : benchedSize; /* init */ if (ctx==NULL) { DISPLAY("\n ZSTD_createCCtx error \n"); free(origBuff); return 14;} memset(&winner, 0, sizeof(winner)); winner.result.cSize = (size_t)(-1); /* find best solution from default params */ { const int maxSeeds = g_noSeed ? 1 : ZSTD_maxCLevel(); int i; for (i=1; i<=maxSeeds; i++) { ZSTD_compressionParameters const CParams = ZSTD_getCParams(i, blockSize, 0); BMK_benchParam(&candidate, origBuff, benchedSize, ctx, CParams); if (candidate.cSpeed < targetSpeed) break; if ( (candidate.cSize < winner.result.cSize) | ((candidate.cSize == winner.result.cSize) & (candidate.cSpeed > winner.result.cSpeed)) ) { winner.params = CParams; winner.result = candidate; BMK_printWinner(stdout, i, winner.result, winner.params, benchedSize); } } } BMK_printWinner(stdout, 99, winner.result, winner.params, benchedSize); BMK_translateAdvancedParams(winner.params); /* start tests */ { time_t const grillStart = time(NULL); do { ZSTD_compressionParameters params = winner.params; paramVariation(¶ms); if ((FUZ_rand(&g_rand) & 31) == 3) params = randomParams(); /* totally random config to improve search space */ params = ZSTD_adjustCParams(params, blockSize, 0); /* exclude faster if already played set of params */ if (FUZ_rand(&g_rand) & ((1 << NB_TESTS_PLAYED(params))-1)) continue; /* test */ NB_TESTS_PLAYED(params)++; BMK_benchParam(&candidate, origBuff, benchedSize, ctx, params); /* improvement found => new winner */ if ( (candidate.cSpeed > targetSpeed) & ( (candidate.cSize < winner.result.cSize) | ((candidate.cSize == winner.result.cSize) & (candidate.cSpeed > winner.result.cSpeed)) ) ) { winner.params = params; winner.result = candidate; BMK_printWinner(stdout, 99, winner.result, winner.params, benchedSize); BMK_translateAdvancedParams(winner.params); } } while (BMK_timeSpan(grillStart) < g_grillDuration_s); } /* end summary */ BMK_printWinner(stdout, 99, winner.result, winner.params, benchedSize); DISPLAY("grillParams size - optimizer completed \n"); /* clean up*/ ZSTD_freeCCtx(ctx); } free(origBuff); return 0; } static int usage(const char* exename) { DISPLAY( "Usage :\n"); DISPLAY( " %s [arg] file\n", exename); DISPLAY( "Arguments :\n"); DISPLAY( " file : path to the file used as reference (if none, generates a compressible sample)\n"); DISPLAY( " -H/-h : Help (this text + advanced options)\n"); return 0; } static int usage_advanced(void) { DISPLAY( "\nAdvanced options :\n"); DISPLAY( " -T# : set level 1 speed objective \n"); DISPLAY( " -B# : cut input into blocks of size # (default : single block) \n"); DISPLAY( " -i# : iteration loops [1-9](default : %i) \n", NBLOOPS); DISPLAY( " -O# : find Optimized parameters for # MB/s compression speed (default : 0) \n"); DISPLAY( " -S : Single run \n"); DISPLAY( " -P# : generated sample compressibility (default : %.1f%%) \n", COMPRESSIBILITY_DEFAULT * 100); return 0; } static int badusage(const char* exename) { DISPLAY("Wrong parameters\n"); usage(exename); return 1; } int main(int argc, const char** argv) { int i, filenamesStart=0, result; const char* exename=argv[0]; const char* input_filename=0; U32 optimizer = 0; U32 main_pause = 0; U32 targetSpeed = 0; /* checks */ if (NB_LEVELS_TRACKED <= ZSTD_maxCLevel()) { DISPLAY("Error : NB_LEVELS_TRACKED <= ZSTD_maxCLevel() \n"); exit(1); } /* Welcome message */ DISPLAY(WELCOME_MESSAGE); if (argc<1) { badusage(exename); return 1; } for(i=1; i='0') & (argument[0] <='9')) g_nbIterations = *argument++ - '0'; break; /* Sample compressibility (when no file provided) */ case 'P': argument++; { U32 proba32 = 0; while ((argument[0]>= '0') & (argument[0]<= '9')) proba32 = (proba32*10) + (*argument++ - '0'); g_compressibility = (double)proba32 / 100.; } break; case 'O': argument++; optimizer=1; targetSpeed = 0; while ((*argument >= '0') & (*argument <= '9')) targetSpeed = (targetSpeed*10) + (*argument++ - '0'); break; /* Run Single conf */ case 'S': g_singleRun = 1; argument++; g_params = ZSTD_getCParams(2, g_blockSize, 0); for ( ; ; ) { switch(*argument) { case 'w': g_params.windowLog = 0; argument++; while ((*argument>= '0') && (*argument<='9')) g_params.windowLog *= 10, g_params.windowLog += *argument++ - '0'; continue; case 'c': g_params.chainLog = 0; argument++; while ((*argument>= '0') && (*argument<='9')) g_params.chainLog *= 10, g_params.chainLog += *argument++ - '0'; continue; case 'h': g_params.hashLog = 0; argument++; while ((*argument>= '0') && (*argument<='9')) g_params.hashLog *= 10, g_params.hashLog += *argument++ - '0'; continue; case 's': g_params.searchLog = 0; argument++; while ((*argument>= '0') && (*argument<='9')) g_params.searchLog *= 10, g_params.searchLog += *argument++ - '0'; continue; case 'l': /* search length */ g_params.searchLength = 0; argument++; while ((*argument>= '0') && (*argument<='9')) g_params.searchLength *= 10, g_params.searchLength += *argument++ - '0'; continue; case 't': /* target length */ g_params.targetLength = 0; argument++; while ((*argument>= '0') && (*argument<='9')) g_params.targetLength *= 10, g_params.targetLength += *argument++ - '0'; continue; case 'S': /* strategy */ argument++; while ((*argument>= '0') && (*argument<='9')) g_params.strategy = (ZSTD_strategy)(*argument++ - '0'); continue; case 'L': { int cLevel = 0; argument++; while ((*argument>= '0') && (*argument<='9')) cLevel *= 10, cLevel += *argument++ - '0'; g_params = ZSTD_getCParams(cLevel, g_blockSize, 0); continue; } default : ; } break; } break; /* target level1 speed objective, in MB/s */ case 'T': argument++; g_target = 0; while ((*argument >= '0') && (*argument <= '9')) g_target = (g_target*10) + (*argument++ - '0'); break; /* cut input into blocks */ case 'B': g_blockSize = 0; argument++; while ((*argument >='0') & (*argument <='9')) g_blockSize = (g_blockSize*10) + (*argument++ - '0'); if (*argument=='K') g_blockSize<<=10, argument++; /* allows using KB notation */ if (*argument=='M') g_blockSize<<=20, argument++; if (*argument=='B') argument++; DISPLAY("using %u KB block size \n", g_blockSize>>10); break; /* Unknown command */ default : return badusage(exename); } } continue; } /* if (argument[0]=='-') */ /* first provided filename is input */ if (!input_filename) { input_filename=argument; filenamesStart=i; continue; } } if (filenamesStart==0) result = benchSample(); else { if (optimizer) result = optimizeForSize(input_filename, targetSpeed); else result = benchFiles(argv+filenamesStart, argc-filenamesStart); } if (main_pause) { int unused; printf("press enter...\n"); unused = getchar(); (void)unused; } return result; }