zstd/programs/bench.c

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/*
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* Copyright (c) 2016-present, Yann Collet, Facebook, Inc.
* All rights reserved.
*
* This source code is licensed under both the BSD-style license (found in the
* LICENSE file in the root directory of this source tree) and the GPLv2 (found
* in the COPYING file in the root directory of this source tree).
* You may select, at your option, one of the above-listed licenses.
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*/
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/* **************************************
* Tuning parameters
****************************************/
#ifndef BMK_TIMETEST_DEFAULT_S /* default minimum time per test */
#define BMK_TIMETEST_DEFAULT_S 3
#endif
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/* **************************************
* Compiler Warnings
****************************************/
#ifdef _MSC_VER
# pragma warning(disable : 4127) /* disable: C4127: conditional expression is constant */
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#endif
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/* *************************************
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* Includes
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***************************************/
#include "platform.h" /* Large Files support */
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#include "util.h" /* UTIL_getFileSize, UTIL_sleep */
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#include <stdlib.h> /* malloc, free */
#include <string.h> /* memset */
#include <stdio.h> /* fprintf, fopen */
#include <assert.h> /* assert */
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#include "mem.h"
#define ZSTD_STATIC_LINKING_ONLY
#include "zstd.h"
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#include "datagen.h" /* RDG_genBuffer */
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#include "xxhash.h"
#include "bench.h"
#include "zstd_errors.h"
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/* *************************************
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* Constants
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***************************************/
#ifndef ZSTD_GIT_COMMIT
# define ZSTD_GIT_COMMIT_STRING ""
#else
# define ZSTD_GIT_COMMIT_STRING ZSTD_EXPAND_AND_QUOTE(ZSTD_GIT_COMMIT)
#endif
#define TIMELOOP_MICROSEC (1*1000000ULL) /* 1 second */
#define TIMELOOP_NANOSEC (1*1000000000ULL) /* 1 second */
#define ACTIVEPERIOD_MICROSEC (70*TIMELOOP_MICROSEC) /* 70 seconds */
#define COOLPERIOD_SEC 10
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#define KB *(1 <<10)
#define MB *(1 <<20)
#define GB *(1U<<30)
static const size_t maxMemory = (sizeof(size_t)==4) ?
/* 32-bit */ (2 GB - 64 MB) :
/* 64-bit */ (size_t)(1ULL << ((sizeof(size_t)*8)-31));
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/* *************************************
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* console display
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***************************************/
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#define DISPLAY(...) fprintf(stderr, __VA_ARGS__)
#define DISPLAYLEVEL(l, ...) if (displayLevel>=l) { DISPLAY(__VA_ARGS__); }
/* 0 : no display; 1: errors; 2 : + result + interaction + warnings; 3 : + progression; 4 : + information */
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static const U64 g_refreshRate = SEC_TO_MICRO / 6;
static UTIL_time_t g_displayClock = UTIL_TIME_INITIALIZER;
#define DISPLAYUPDATE(l, ...) { if (displayLevel>=l) { \
if ((UTIL_clockSpanMicro(g_displayClock) > g_refreshRate) || (displayLevel>=4)) \
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{ g_displayClock = UTIL_getTime(); DISPLAY(__VA_ARGS__); \
if (displayLevel>=4) fflush(stderr); } } }
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/* *************************************
* Exceptions
***************************************/
#ifndef DEBUG
# define DEBUG 0
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#endif
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#define DEBUGOUTPUT(...) { if (DEBUG) DISPLAY(__VA_ARGS__); }
#define EXM_THROW_INT(errorNum, ...) { \
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DEBUGOUTPUT("%s: %i: \n", __FILE__, __LINE__); \
DISPLAYLEVEL(1, "Error %i : ", errorNum); \
DISPLAYLEVEL(1, __VA_ARGS__); \
DISPLAYLEVEL(1, " \n"); \
return errorNum; \
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}
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#define RETURN_ERROR(errorNum, retType, ...) { \
retType r; \
memset(&r, 0, sizeof(retType)); \
DEBUGOUTPUT("%s: %i: \n", __FILE__, __LINE__); \
DISPLAYLEVEL(1, "Error %i : ", errorNum); \
DISPLAYLEVEL(1, __VA_ARGS__); \
DISPLAYLEVEL(1, " \n"); \
r.tag = errorNum; \
return r; \
}
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/* error without displaying */
#define RETURN_QUIET_ERROR(errorNum, retType, ...) { \
retType r; \
memset(&r, 0, sizeof(retType)); \
DEBUGOUTPUT("%s: %i: \n", __FILE__, __LINE__); \
DEBUGOUTPUT("Error %i : ", errorNum); \
DEBUGOUTPUT(__VA_ARGS__); \
DEBUGOUTPUT(" \n"); \
r.tag = errorNum; \
return r; \
}
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/* *************************************
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* Benchmark Parameters
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***************************************/
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BMK_advancedParams_t BMK_initAdvancedParams(void) {
BMK_advancedParams_t const res = {
BMK_both, /* mode */
BMK_TIMETEST_DEFAULT_S, /* nbSeconds */
0, /* blockSize */
0, /* nbWorkers */
0, /* realTime */
0, /* additionalParam */
0, /* ldmFlag */
0, /* ldmMinMatch */
0, /* ldmHashLog */
0, /* ldmBuckSizeLog */
0 /* ldmHashEveryLog */
};
return res;
}
/* ********************************************************
* Bench functions
**********************************************************/
typedef struct {
const void* srcPtr;
size_t srcSize;
void* cPtr;
size_t cRoom;
size_t cSize;
void* resPtr;
size_t resSize;
} blockParam_t;
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#undef MIN
#undef MAX
#define MIN(a,b) ((a) < (b) ? (a) : (b))
#define MAX(a,b) ((a) > (b) ? (a) : (b))
static void BMK_initCCtx(ZSTD_CCtx* ctx,
const void* dictBuffer, size_t dictBufferSize, int cLevel,
const ZSTD_compressionParameters* comprParams, const BMK_advancedParams_t* adv) {
ZSTD_CCtx_reset(ctx);
ZSTD_CCtx_resetParameters(ctx);
if (adv->nbWorkers==1) {
ZSTD_CCtx_setParameter(ctx, ZSTD_p_nbWorkers, 0);
} else {
ZSTD_CCtx_setParameter(ctx, ZSTD_p_nbWorkers, adv->nbWorkers);
}
ZSTD_CCtx_setParameter(ctx, ZSTD_p_compressionLevel, cLevel);
ZSTD_CCtx_setParameter(ctx, ZSTD_p_enableLongDistanceMatching, adv->ldmFlag);
ZSTD_CCtx_setParameter(ctx, ZSTD_p_ldmMinMatch, adv->ldmMinMatch);
ZSTD_CCtx_setParameter(ctx, ZSTD_p_ldmHashLog, adv->ldmHashLog);
ZSTD_CCtx_setParameter(ctx, ZSTD_p_ldmBucketSizeLog, adv->ldmBucketSizeLog);
ZSTD_CCtx_setParameter(ctx, ZSTD_p_ldmHashEveryLog, adv->ldmHashEveryLog);
ZSTD_CCtx_setParameter(ctx, ZSTD_p_windowLog, comprParams->windowLog);
ZSTD_CCtx_setParameter(ctx, ZSTD_p_hashLog, comprParams->hashLog);
ZSTD_CCtx_setParameter(ctx, ZSTD_p_chainLog, comprParams->chainLog);
ZSTD_CCtx_setParameter(ctx, ZSTD_p_searchLog, comprParams->searchLog);
ZSTD_CCtx_setParameter(ctx, ZSTD_p_minMatch, comprParams->searchLength);
ZSTD_CCtx_setParameter(ctx, ZSTD_p_targetLength, comprParams->targetLength);
ZSTD_CCtx_setParameter(ctx, ZSTD_p_compressionStrategy, comprParams->strategy);
ZSTD_CCtx_loadDictionary(ctx, dictBuffer, dictBufferSize);
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}
static void BMK_initDCtx(ZSTD_DCtx* dctx,
const void* dictBuffer, size_t dictBufferSize) {
ZSTD_DCtx_reset(dctx);
ZSTD_DCtx_loadDictionary(dctx, dictBuffer, dictBufferSize);
}
typedef struct {
ZSTD_CCtx* cctx;
const void* dictBuffer;
size_t dictBufferSize;
int cLevel;
const ZSTD_compressionParameters* comprParams;
const BMK_advancedParams_t* adv;
} BMK_initCCtxArgs;
static size_t local_initCCtx(void* payload) {
BMK_initCCtxArgs* ag = (BMK_initCCtxArgs*)payload;
BMK_initCCtx(ag->cctx, ag->dictBuffer, ag->dictBufferSize, ag->cLevel, ag->comprParams, ag->adv);
return 0;
}
typedef struct {
ZSTD_DCtx* dctx;
const void* dictBuffer;
size_t dictBufferSize;
} BMK_initDCtxArgs;
static size_t local_initDCtx(void* payload) {
BMK_initDCtxArgs* ag = (BMK_initDCtxArgs*)payload;
BMK_initDCtx(ag->dctx, ag->dictBuffer, ag->dictBufferSize);
return 0;
}
/* `addArgs` is the context */
static size_t local_defaultCompress(
const void* srcBuffer, size_t srcSize,
void* dstBuffer, size_t dstSize,
void* addArgs)
{
size_t moreToFlush = 1;
ZSTD_CCtx* const cctx = (ZSTD_CCtx*)addArgs;
ZSTD_inBuffer in;
ZSTD_outBuffer out;
in.src = srcBuffer; in.size = srcSize; in.pos = 0;
out.dst = dstBuffer; out.size = dstSize; out.pos = 0;
while (moreToFlush) {
if(out.pos == out.size) {
return (size_t)-ZSTD_error_dstSize_tooSmall;
}
moreToFlush = ZSTD_compress_generic(cctx, &out, &in, ZSTD_e_end);
if (ZSTD_isError(moreToFlush)) {
return moreToFlush;
}
}
return out.pos;
}
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/* `addArgs` is the context */
static size_t local_defaultDecompress(
const void* srcBuffer, size_t srcSize,
void* dstBuffer, size_t dstSize,
void* addArgs)
{
size_t moreToFlush = 1;
ZSTD_DCtx* const dctx = (ZSTD_DCtx*)addArgs;
ZSTD_inBuffer in;
ZSTD_outBuffer out;
in.src = srcBuffer; in.size = srcSize; in.pos = 0;
out.dst = dstBuffer; out.size = dstSize; out.pos = 0;
while (moreToFlush) {
if(out.pos == out.size) {
return (size_t)-ZSTD_error_dstSize_tooSmall;
}
moreToFlush = ZSTD_decompress_generic(dctx, &out, &in);
if (ZSTD_isError(moreToFlush)) {
return moreToFlush;
}
}
return out.pos;
}
/*=== Benchmarking an arbitrary function ===*/
int BMK_isSuccessful_runOutcome(BMK_runOutcome_t outcome)
{
return outcome.tag == 0;
}
/* warning : this function will stop program execution if outcome is invalid !
* check outcome validity first, using BMK_isValid_runResult() */
BMK_runTime_t BMK_extract_runTime(BMK_runOutcome_t outcome)
{
assert(outcome.tag == 0);
return outcome.internal_never_use_directly;
}
static BMK_runOutcome_t BMK_setValid_runTime(BMK_runTime_t runTime)
{
BMK_runOutcome_t outcome;
outcome.tag = 0;
outcome.internal_never_use_directly = runTime;
return outcome;
}
/* initFn will be measured once, benchFn will be measured `nbLoops` times */
/* initFn is optional, provide NULL if none */
/* benchFn must return size_t field compliant with ZSTD_isError for error valuee */
/* takes # of blocks and list of size & stuff for each. */
/* can report result of benchFn for each block into blockResult. */
/* blockResult is optional, provide NULL if this information is not required */
/* note : time per loop could be zero if run time < timer resolution */
BMK_runOutcome_t BMK_benchFunction(
BMK_benchFn_t benchFn, void* benchPayload,
BMK_initFn_t initFn, void* initPayload,
size_t blockCount,
const void* const * srcBlockBuffers, const size_t* srcBlockSizes,
void* const * dstBlockBuffers, const size_t* dstBlockCapacities,
size_t* blockResults,
unsigned nbLoops)
{
size_t dstSize = 0;
U64 totalTime;
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if(!nbLoops) {
RETURN_QUIET_ERROR(1, BMK_runOutcome_t, "nbLoops must be nonzero ");
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}
/* init */
{ size_t i;
for(i = 0; i < blockCount; i++) {
memset(dstBlockBuffers[i], 0xE5, dstBlockCapacities[i]); /* warm up and erase result buffer */
}
#if 0
/* based on testing these seem to lower accuracy of multiple calls of 1 nbLoops vs 1 call of multiple nbLoops
* (Makes former slower)
*/
UTIL_sleepMilli(5); /* give processor time to other processes */
UTIL_waitForNextTick();
#endif
}
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/* benchmark loop */
{ UTIL_time_t const clockStart = UTIL_getTime();
unsigned loopNb, blockNb;
if (initFn != NULL) initFn(initPayload);
for (loopNb = 0; loopNb < nbLoops; loopNb++) {
for (blockNb = 0; blockNb < blockCount; blockNb++) {
size_t const res = benchFn(srcBlockBuffers[blockNb], srcBlockSizes[blockNb],
dstBlockBuffers[blockNb], dstBlockCapacities[blockNb],
benchPayload);
if(ZSTD_isError(res)) {
RETURN_QUIET_ERROR(2, BMK_runOutcome_t,
"Function benchmark failed on block %u of size %u : %s",
blockNb, (U32)dstBlockCapacities[blockNb], ZSTD_getErrorName(res));
} else if (loopNb == 0) {
dstSize += res;
if (blockResults != NULL) blockResults[blockNb] = res;
dstSize += res;
} }
} /* for (loopNb = 0; loopNb < nbLoops; loopNb++) */
totalTime = UTIL_clockSpanNano(clockStart);
}
{ BMK_runTime_t rt;
rt.nanoSecPerRun = totalTime / nbLoops;
rt.sumOfReturn = dstSize;
return BMK_setValid_runTime(rt);
}
}
/* ==== Benchmarking any function, providing intermediate results ==== */
struct BMK_timedFnState_s {
U64 timeSpent_ns;
U64 timeBudget_ns;
BMK_runTime_t fastestRun;
unsigned nbLoops;
UTIL_time_t coolTime;
}; /* typedef'd to BMK_timedFnState_t within bench.h */
BMK_timedFnState_t* BMK_createTimedFnState(unsigned nbSeconds) {
BMK_timedFnState_t* const r = (BMK_timedFnState_t*)malloc(sizeof(*r));
if (r == NULL) return NULL; /* malloc() error */
BMK_resetTimedFnState(r, nbSeconds);
return r;
}
void BMK_resetTimedFnState(BMK_timedFnState_t* r, unsigned nbSeconds) {
r->timeSpent_ns = 0;
r->timeBudget_ns = (U64)nbSeconds * TIMELOOP_NANOSEC;
r->fastestRun.nanoSecPerRun = (U64)(-1LL);
r->fastestRun.sumOfReturn = (size_t)(-1LL);
r->nbLoops = 1;
r->coolTime = UTIL_getTime();
}
void BMK_freeTimedFnState(BMK_timedFnState_t* state) {
free(state);
}
/* check first if the return structure represents an error or a valid result */
int BMK_isSuccessful_timedFnOutcome(BMK_timedFnOutcome_t outcome)
{
return (outcome.tag < 2);
}
/* extract intermediate results from variant type.
* note : this function will abort() program execution if result is not valid.
* check result validity first, by using BMK_isSuccessful_timedFnOutcome() */
BMK_runTime_t BMK_extract_timedFnResult(BMK_timedFnOutcome_t outcome)
{
assert(outcome.tag < 2);
return outcome.internal_never_use_directly;
}
/* Tells if nb of seconds set in timedFnState for all runs is spent.
* note : this function will return 1 if BMK_benchFunctionTimed() has actually errored. */
int BMK_isCompleted_timedFnOutcome(BMK_timedFnOutcome_t outcome)
{
return (outcome.tag >= 1);
}
#define MINUSABLETIME (TIMELOOP_NANOSEC / 2) /* 0.5 seconds */
BMK_timedFnOutcome_t BMK_benchFunctionTimed(
BMK_timedFnState_t* cont,
BMK_benchFn_t benchFn, void* benchPayload,
BMK_initFn_t initFn, void* initPayload,
size_t blockCount,
const void* const* srcBlockBuffers, const size_t* srcBlockSizes,
void * const * dstBlockBuffers, const size_t * dstBlockCapacities,
size_t* blockResults)
{
int completed = 0;
BMK_timedFnOutcome_t r;
BMK_runTime_t bestRunTime = cont->fastestRun;
r.tag = 2; /* error by default */
while (!completed) {
BMK_runOutcome_t runResult;
/* Overheat protection */
if (UTIL_clockSpanMicro(cont->coolTime) > ACTIVEPERIOD_MICROSEC) {
DEBUGOUTPUT("\rcooling down ... \r");
UTIL_sleep(COOLPERIOD_SEC);
cont->coolTime = UTIL_getTime();
}
/* reinitialize capacity */
runResult = BMK_benchFunction(benchFn, benchPayload,
initFn, initPayload,
blockCount,
srcBlockBuffers, srcBlockSizes,
dstBlockBuffers, dstBlockCapacities,
blockResults,
cont->nbLoops);
if(!BMK_isSuccessful_runOutcome(runResult)) { /* error : move out */
r.tag = 2;
return r;
}
{ BMK_runTime_t const newRunTime = BMK_extract_runTime(runResult);
U64 const loopDuration_ns = newRunTime.nanoSecPerRun * cont->nbLoops;
cont->timeSpent_ns += loopDuration_ns;
/* estimate nbLoops for next run to last approximately 1 second */
if (loopDuration_ns > (TIMELOOP_NANOSEC / 50)) {
U64 const fastestRun_ns = MIN(bestRunTime.nanoSecPerRun, newRunTime.nanoSecPerRun);
cont->nbLoops = (U32)(TIMELOOP_NANOSEC / fastestRun_ns) + 1;
} else {
/* previous run was too short : blindly increase workload by x multiplier */
const unsigned multiplier = 10;
assert(cont->nbLoops < ((unsigned)-1) / multiplier); /* avoid overflow */
cont->nbLoops *= multiplier;
}
if(loopDuration_ns < MINUSABLETIME) {
/* don't report results for which benchmark run time was too small : increased risks of rounding errors */
assert(completed == 0);
continue;
} else {
if(newRunTime.nanoSecPerRun < bestRunTime.nanoSecPerRun) {
bestRunTime = newRunTime;
}
completed = 1;
}
}
} /* while (!completed) */
r.tag = (cont->timeSpent_ns >= cont->timeBudget_ns); /* report if time budget is spent */
r.internal_never_use_directly = bestRunTime;
return r;
}
/* ================================================================= */
/* Benchmark Zstandard, mem-to-mem scenarios */
/* ================================================================= */
int BMK_isSuccessful_benchOutcome(BMK_benchOutcome_t outcome)
{
return outcome.tag == 0;
}
BMK_benchResult_t BMK_extract_benchResult(BMK_benchOutcome_t outcome)
{
assert(outcome.tag == 0);
return outcome.internal_never_use_directly;
}
static BMK_benchOutcome_t BMK_benchOutcome_error()
{
BMK_benchOutcome_t b;
memset(&b, 0, sizeof(b));
b.tag = 1;
return b;
}
static BMK_benchOutcome_t BMK_benchOutcome_setValidResult(BMK_benchResult_t result)
{
BMK_benchOutcome_t b;
b.tag = 0;
b.internal_never_use_directly = result;
return b;
}
/* benchMem with no allocation */
static BMK_benchOutcome_t BMK_benchMemAdvancedNoAlloc(
const void** srcPtrs, size_t* srcSizes,
void** cPtrs, size_t* cCapacities, size_t* cSizes,
void** resPtrs, size_t* resSizes,
void** resultBufferPtr, void* compressedBuffer,
size_t maxCompressedSize,
BMK_timedFnState_t* timeStateCompress,
BMK_timedFnState_t* timeStateDecompress,
const void* srcBuffer, size_t srcSize,
const size_t* fileSizes, unsigned nbFiles,
const int cLevel, const ZSTD_compressionParameters* comprParams,
const void* dictBuffer, size_t dictBufferSize,
ZSTD_CCtx* cctx, ZSTD_DCtx* dctx,
int displayLevel, const char* displayName,
const BMK_advancedParams_t* adv)
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{
size_t const blockSize = ((adv->blockSize>=32 && (adv->mode != BMK_decodeOnly)) ? adv->blockSize : srcSize) + (!srcSize); /* avoid div by 0 */
BMK_benchResult_t benchResult;
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size_t const loadedCompressedSize = srcSize;
size_t cSize = 0;
double ratio = 0.;
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U32 nbBlocks;
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assert(cctx != NULL); assert(dctx != NULL);
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/* init */
if (strlen(displayName)>17) displayName += strlen(displayName) - 17; /* display last 17 characters */
if (adv->mode == BMK_decodeOnly) { /* benchmark only decompression : source must be already compressed */
const char* srcPtr = (const char*)srcBuffer;
U64 totalDSize64 = 0;
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U32 fileNb;
for (fileNb=0; fileNb<nbFiles; fileNb++) {
U64 const fSize64 = ZSTD_findDecompressedSize(srcPtr, fileSizes[fileNb]);
if (fSize64==0) RETURN_ERROR(32, BMK_benchOutcome_t, "Impossible to determine original size ");
totalDSize64 += fSize64;
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srcPtr += fileSizes[fileNb];
}
{ size_t const decodedSize = (size_t)totalDSize64;
assert((U64)decodedSize == totalDSize64); /* check overflow */
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free(*resultBufferPtr);
*resultBufferPtr = malloc(decodedSize);
if (!(*resultBufferPtr)) {
RETURN_ERROR(33, BMK_benchOutcome_t, "not enough memory");
}
if (totalDSize64 > decodedSize) { /* size_t overflow */
free(*resultBufferPtr);
RETURN_ERROR(32, BMK_benchOutcome_t, "original size is too large");
}
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cSize = srcSize;
srcSize = decodedSize;
ratio = (double)srcSize / (double)cSize;
}
}
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/* Init data blocks */
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{ const char* srcPtr = (const char*)srcBuffer;
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char* cPtr = (char*)compressedBuffer;
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char* resPtr = (char*)(*resultBufferPtr);
U32 fileNb;
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for (nbBlocks=0, fileNb=0; fileNb<nbFiles; fileNb++) {
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size_t remaining = fileSizes[fileNb];
U32 const nbBlocksforThisFile = (adv->mode == BMK_decodeOnly) ? 1 : (U32)((remaining + (blockSize-1)) / blockSize);
U32 const blockEnd = nbBlocks + nbBlocksforThisFile;
for ( ; nbBlocks<blockEnd; nbBlocks++) {
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size_t const thisBlockSize = MIN(remaining, blockSize);
srcPtrs[nbBlocks] = srcPtr;
srcSizes[nbBlocks] = thisBlockSize;
cPtrs[nbBlocks] = cPtr;
cCapacities[nbBlocks] = (adv->mode == BMK_decodeOnly) ? thisBlockSize : ZSTD_compressBound(thisBlockSize);
resPtrs[nbBlocks] = resPtr;
resSizes[nbBlocks] = (adv->mode == BMK_decodeOnly) ? (size_t) ZSTD_findDecompressedSize(srcPtr, thisBlockSize) : thisBlockSize;
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srcPtr += thisBlockSize;
cPtr += cCapacities[nbBlocks];
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resPtr += thisBlockSize;
remaining -= thisBlockSize;
}
}
}
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/* warmimg up `compressedBuffer` */
if (adv->mode == BMK_decodeOnly) {
memcpy(compressedBuffer, srcBuffer, loadedCompressedSize);
} else {
RDG_genBuffer(compressedBuffer, maxCompressedSize, 0.10, 0.50, 1);
}
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/* Bench */
{ U64 const crcOrig = (adv->mode == BMK_decodeOnly) ? 0 : XXH64(srcBuffer, srcSize, 0);
# define NB_MARKS 4
const char* marks[NB_MARKS] = { " |", " /", " =", " \\" };
U32 markNb = 0;
int compressionCompleted = (adv->mode == BMK_decodeOnly);
int decompressionCompleted = (adv->mode == BMK_compressOnly);
BMK_initCCtxArgs cctxprep;
BMK_initDCtxArgs dctxprep;
cctxprep.cctx = cctx;
cctxprep.dictBuffer = dictBuffer;
cctxprep.dictBufferSize = dictBufferSize;
cctxprep.cLevel = cLevel;
cctxprep.comprParams = comprParams;
cctxprep.adv = adv;
dctxprep.dctx = dctx;
dctxprep.dictBuffer = dictBuffer;
dctxprep.dictBufferSize = dictBufferSize;
DISPLAYLEVEL(2, "\r%70s\r", ""); /* blank line */
DISPLAYLEVEL(2, "%2s-%-17.17s :%10u ->\r", marks[markNb], displayName, (U32)srcSize);
while (!(compressionCompleted && decompressionCompleted)) {
if (!compressionCompleted) {
BMK_runTime_t cResult;
BMK_timedFnOutcome_t const cOutcome =
BMK_benchFunctionTimed(timeStateCompress,
&local_defaultCompress, (void*)cctx,
&local_initCCtx, (void*)&cctxprep,
nbBlocks,
srcPtrs, srcSizes,
cPtrs, cCapacities,
cSizes);
if (!BMK_isSuccessful_timedFnOutcome(cOutcome)) {
return BMK_benchOutcome_error();
}
cResult = BMK_extract_timedFnResult(cOutcome);
ratio = (double)(srcSize / cResult.sumOfReturn);
{ int const ratioAccuracy = (ratio < 10.) ? 3 : 2;
cSize = cResult.sumOfReturn;
benchResult.cSpeed = (srcSize * TIMELOOP_NANOSEC / cResult.nanoSecPerRun);
benchResult.cSize = cSize;
ratio = (double)srcSize / cSize;
markNb = (markNb+1) % NB_MARKS;
DISPLAYLEVEL(2, "%2s-%-17.17s :%10u ->%10u (%5.*f),%6.*f MB/s\r",
marks[markNb], displayName, (U32)srcSize, (U32)cSize,
ratioAccuracy, ratio,
benchResult.cSpeed < (10 MB) ? 2 : 1, (double)benchResult.cSpeed / (1 MB));
}
}
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if(!decompressionCompleted) {
BMK_runTime_t dResult;
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BMK_timedFnOutcome_t const dOutcome =
BMK_benchFunctionTimed(timeStateDecompress,
&local_defaultDecompress, (void*)(dctx),
&local_initDCtx, (void*)&dctxprep,
nbBlocks,
(const void* const*)cPtrs, cSizes,
resPtrs, resSizes,
NULL);
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if(!BMK_isSuccessful_timedFnOutcome(dOutcome)) {
return BMK_benchOutcome_error();
}
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dResult = BMK_extract_timedFnResult(dOutcome);
{ int const ratioAccuracy = (ratio < 10.) ? 3 : 2;
benchResult.dSpeed = (srcSize * TIMELOOP_NANOSEC / dResult.nanoSecPerRun);
markNb = (markNb+1) % NB_MARKS;
DISPLAYLEVEL(2, "%2s-%-17.17s :%10u ->%10u (%5.*f),%6.*f MB/s ,%6.1f MB/s \r",
marks[markNb], displayName, (U32)srcSize, (U32)benchResult.cSize,
ratioAccuracy, ratio,
benchResult.cSpeed < (10 MB) ? 2 : 1, (double)benchResult.cSpeed / (1 MB),
(double)benchResult.dSpeed / (1 MB));
}
}
}
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/* CRC Checking */
{ const BYTE* resultBuffer = (const BYTE*)(*resultBufferPtr);
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U64 const crcCheck = XXH64(resultBuffer, srcSize, 0);
if ((adv->mode == BMK_both) && (crcOrig!=crcCheck)) {
size_t u;
DISPLAY("!!! WARNING !!! %14s : Invalid Checksum : %x != %x \n", displayName, (unsigned)crcOrig, (unsigned)crcCheck);
for (u=0; u<srcSize; u++) {
if (((const BYTE*)srcBuffer)[u] != resultBuffer[u]) {
U32 segNb, bNb, pos;
size_t bacc = 0;
DISPLAY("Decoding error at pos %u ", (U32)u);
for (segNb = 0; segNb < nbBlocks; segNb++) {
if (bacc + srcSizes[segNb] > u) break;
bacc += srcSizes[segNb];
}
pos = (U32)(u - bacc);
bNb = pos / (128 KB);
DISPLAY("(sample %u, block %u, pos %u) \n", segNb, bNb, pos);
if (u>5) {
int n;
DISPLAY("origin: ");
for (n=-5; n<0; n++) DISPLAY("%02X ", ((const BYTE*)srcBuffer)[u+n]);
DISPLAY(" :%02X: ", ((const BYTE*)srcBuffer)[u]);
for (n=1; n<3; n++) DISPLAY("%02X ", ((const BYTE*)srcBuffer)[u+n]);
DISPLAY(" \n");
DISPLAY("decode: ");
for (n=-5; n<0; n++) DISPLAY("%02X ", resultBuffer[u+n]);
DISPLAY(" :%02X: ", resultBuffer[u]);
for (n=1; n<3; n++) DISPLAY("%02X ", resultBuffer[u+n]);
DISPLAY(" \n");
}
break;
}
if (u==srcSize-1) { /* should never happen */
DISPLAY("no difference detected\n");
}
}
}
} /* CRC Checking */
if (displayLevel == 1) { /* hidden display mode -q, used by python speed benchmark */
double const cSpeed = (double)benchResult.cSpeed / (1 MB);
double const dSpeed = (double)benchResult.dSpeed / (1 MB);
if (adv->additionalParam) {
DISPLAY("-%-3i%11i (%5.3f) %6.2f MB/s %6.1f MB/s %s (param=%d)\n", cLevel, (int)cSize, ratio, cSpeed, dSpeed, displayName, adv->additionalParam);
} else {
DISPLAY("-%-3i%11i (%5.3f) %6.2f MB/s %6.1f MB/s %s\n", cLevel, (int)cSize, ratio, cSpeed, dSpeed, displayName);
}
}
DISPLAYLEVEL(2, "%2i#\n", cLevel);
} /* Bench */
benchResult.cMem = (1ULL << (comprParams->windowLog)) + ZSTD_sizeof_CCtx(cctx);
return BMK_benchOutcome_setValidResult(benchResult);
}
BMK_benchOutcome_t BMK_benchMemAdvanced(const void* srcBuffer, size_t srcSize,
void* dstBuffer, size_t dstCapacity,
const size_t* fileSizes, unsigned nbFiles,
const int cLevel, const ZSTD_compressionParameters* comprParams,
const void* dictBuffer, size_t dictBufferSize,
int displayLevel, const char* displayName, const BMK_advancedParams_t* adv)
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{
int const dstParamsError = !dstBuffer ^ !dstCapacity; /* must be both NULL or none */
size_t const blockSize = ((adv->blockSize>=32 && (adv->mode != BMK_decodeOnly)) ? adv->blockSize : srcSize) + (!srcSize) /* avoid div by 0 */ ;
U32 const maxNbBlocks = (U32) ((srcSize + (blockSize-1)) / blockSize) + nbFiles;
/* these are the blockTable parameters, just split up */
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const void ** const srcPtrs = (const void**)malloc(maxNbBlocks * sizeof(void*));
size_t* const srcSizes = (size_t*)malloc(maxNbBlocks * sizeof(size_t));
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void ** const cPtrs = (void**)malloc(maxNbBlocks * sizeof(void*));
size_t* const cSizes = (size_t*)malloc(maxNbBlocks * sizeof(size_t));
size_t* const cCapacities = (size_t*)malloc(maxNbBlocks * sizeof(size_t));
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void ** const resPtrs = (void**)malloc(maxNbBlocks * sizeof(void*));
size_t* const resSizes = (size_t*)malloc(maxNbBlocks * sizeof(size_t));
BMK_timedFnState_t* timeStateCompress = BMK_createTimedFnState(adv->nbSeconds);
BMK_timedFnState_t* timeStateDecompress = BMK_createTimedFnState(adv->nbSeconds);
ZSTD_CCtx* const cctx = ZSTD_createCCtx();
ZSTD_DCtx* const dctx = ZSTD_createDCtx();
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const size_t maxCompressedSize = dstCapacity ? dstCapacity : ZSTD_compressBound(srcSize) + (maxNbBlocks * 1024);
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void* const internalDstBuffer = dstBuffer ? NULL : malloc(maxCompressedSize);
void* const compressedBuffer = dstBuffer ? dstBuffer : internalDstBuffer;
BMK_benchOutcome_t outcome = BMK_benchOutcome_error(); /* error by default */
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void* resultBuffer = srcSize ? malloc(srcSize) : NULL;
int allocationincomplete = !srcPtrs || !srcSizes || !cPtrs ||
!cSizes || !cCapacities || !resPtrs || !resSizes ||
!timeStateCompress || !timeStateDecompress ||
!cctx || !dctx ||
!compressedBuffer || !resultBuffer;
if (!allocationincomplete && !dstParamsError) {
outcome = BMK_benchMemAdvancedNoAlloc(srcPtrs, srcSizes,
cPtrs, cCapacities, cSizes,
resPtrs, resSizes,
&resultBuffer,
compressedBuffer, maxCompressedSize,
timeStateCompress, timeStateDecompress,
srcBuffer, srcSize,
fileSizes, nbFiles,
cLevel, comprParams,
dictBuffer, dictBufferSize,
cctx, dctx,
displayLevel, displayName, adv);
}
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/* clean up */
BMK_freeTimedFnState(timeStateCompress);
BMK_freeTimedFnState(timeStateDecompress);
ZSTD_freeCCtx(cctx);
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ZSTD_freeDCtx(dctx);
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free(internalDstBuffer);
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free(resultBuffer);
free((void*)srcPtrs);
free(srcSizes);
free(cPtrs);
free(cSizes);
free(cCapacities);
free(resPtrs);
free(resSizes);
if(allocationincomplete) {
RETURN_ERROR(31, BMK_benchOutcome_t, "allocation error : not enough memory");
}
if(dstParamsError) {
RETURN_ERROR(32, BMK_benchOutcome_t, "Dst parameters not coherent");
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}
return outcome;
}
BMK_benchOutcome_t BMK_benchMem(const void* srcBuffer, size_t srcSize,
const size_t* fileSizes, unsigned nbFiles,
int cLevel, const ZSTD_compressionParameters* comprParams,
const void* dictBuffer, size_t dictBufferSize,
int displayLevel, const char* displayName) {
BMK_advancedParams_t const adv = BMK_initAdvancedParams();
return BMK_benchMemAdvanced(srcBuffer, srcSize,
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NULL, 0,
fileSizes, nbFiles,
cLevel, comprParams,
dictBuffer, dictBufferSize,
displayLevel, displayName, &adv);
}
static BMK_benchOutcome_t BMK_benchCLevel(const void* srcBuffer, size_t benchedSize,
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const size_t* fileSizes, unsigned nbFiles,
int cLevel, const ZSTD_compressionParameters* comprParams,
const void* dictBuffer, size_t dictBufferSize,
int displayLevel, const char* displayName,
BMK_advancedParams_t const * const adv)
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{
const char* pch = strrchr(displayName, '\\'); /* Windows */
if (!pch) pch = strrchr(displayName, '/'); /* Linux */
if (pch) displayName = pch+1;
if (adv->realTime) {
DISPLAYLEVEL(2, "Note : switching to real-time priority \n");
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SET_REALTIME_PRIORITY;
}
if (displayLevel == 1 && !adv->additionalParam) /* --quiet mode */
DISPLAY("bench %s %s: input %u bytes, %u seconds, %u KB blocks\n",
ZSTD_VERSION_STRING, ZSTD_GIT_COMMIT_STRING,
(U32)benchedSize, adv->nbSeconds, (U32)(adv->blockSize>>10));
return BMK_benchMemAdvanced(srcBuffer, benchedSize,
NULL, 0,
fileSizes, nbFiles,
cLevel, comprParams,
dictBuffer, dictBufferSize,
displayLevel, displayName, adv);
}
BMK_benchOutcome_t BMK_syntheticTest(int cLevel, double compressibility,
const ZSTD_compressionParameters* compressionParams,
int displayLevel, const BMK_advancedParams_t* adv)
{
char name[20] = {0};
size_t const benchedSize = 10000000;
void* srcBuffer;
BMK_benchOutcome_t res;
if (cLevel > ZSTD_maxCLevel()) {
RETURN_ERROR(15, BMK_benchOutcome_t, "Invalid Compression Level");
}
/* Memory allocation */
srcBuffer = malloc(benchedSize);
if (!srcBuffer) RETURN_ERROR(21, BMK_benchOutcome_t, "not enough memory");
/* Fill input buffer */
RDG_genBuffer(srcBuffer, benchedSize, compressibility, 0.0, 0);
/* Bench */
snprintf (name, sizeof(name), "Synthetic %2u%%", (unsigned)(compressibility*100));
res = BMK_benchCLevel(srcBuffer, benchedSize,
&benchedSize /* ? */, 1 /* ? */,
cLevel, compressionParams,
NULL, 0, /* dictionary */
displayLevel, name, adv);
/* clean up */
free(srcBuffer);
return res;
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}
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static size_t BMK_findMaxMem(U64 requiredMem)
{
size_t const step = 64 MB;
BYTE* testmem = NULL;
requiredMem = (((requiredMem >> 26) + 1) << 26);
requiredMem += step;
if (requiredMem > maxMemory) requiredMem = maxMemory;
do {
testmem = (BYTE*)malloc((size_t)requiredMem);
requiredMem -= step;
} while (!testmem && requiredMem > 0);
free(testmem);
return (size_t)(requiredMem);
}
/*! BMK_loadFiles() :
* Loads `buffer` with content of files listed within `fileNamesTable`.
* At most, fills `buffer` entirely. */
static int BMK_loadFiles(void* buffer, size_t bufferSize,
size_t* fileSizes, const char* const * const fileNamesTable,
unsigned nbFiles, int displayLevel)
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{
size_t pos = 0, totalSize = 0;
unsigned n;
for (n=0; n<nbFiles; n++) {
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FILE* f;
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U64 fileSize = UTIL_getFileSize(fileNamesTable[n]);
if (UTIL_isDirectory(fileNamesTable[n])) {
DISPLAYLEVEL(2, "Ignoring %s directory... \n", fileNamesTable[n]);
fileSizes[n] = 0;
continue;
}
if (fileSize == UTIL_FILESIZE_UNKNOWN) {
DISPLAYLEVEL(2, "Cannot evaluate size of %s, ignoring ... \n", fileNamesTable[n]);
fileSizes[n] = 0;
continue;
}
f = fopen(fileNamesTable[n], "rb");
if (f==NULL) EXM_THROW_INT(10, "impossible to open file %s", fileNamesTable[n]);
DISPLAYUPDATE(2, "Loading %s... \r", fileNamesTable[n]);
if (fileSize > bufferSize-pos) fileSize = bufferSize-pos, nbFiles=n; /* buffer too small - stop after this file */
{ size_t const readSize = fread(((char*)buffer)+pos, 1, (size_t)fileSize, f);
if (readSize != (size_t)fileSize) EXM_THROW_INT(11, "could not read %s", fileNamesTable[n]);
pos += readSize; }
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fileSizes[n] = (size_t)fileSize;
totalSize += (size_t)fileSize;
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fclose(f);
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}
if (totalSize == 0) EXM_THROW_INT(12, "no data to bench");
return 0;
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}
BMK_benchOutcome_t BMK_benchFilesAdvanced(
const char* const * fileNamesTable, unsigned nbFiles,
const char* dictFileName, int cLevel,
const ZSTD_compressionParameters* compressionParams,
int displayLevel, const BMK_advancedParams_t* adv)
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{
void* srcBuffer = NULL;
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size_t benchedSize;
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void* dictBuffer = NULL;
size_t dictBufferSize = 0;
size_t* fileSizes = NULL;
BMK_benchOutcome_t res = BMK_benchOutcome_error(); /* error by default */
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U64 const totalSizeToLoad = UTIL_getTotalFileSize(fileNamesTable, nbFiles);
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if (!nbFiles) {
RETURN_ERROR(14, BMK_benchOutcome_t, "No Files to Benchmark");
}
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if (cLevel > ZSTD_maxCLevel()) {
RETURN_ERROR(15, BMK_benchOutcome_t, "Invalid Compression Level");
}
fileSizes = (size_t*)calloc(nbFiles, sizeof(size_t));
if (!fileSizes) RETURN_ERROR(12, BMK_benchOutcome_t, "not enough memory for fileSizes");
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/* Load dictionary */
if (dictFileName != NULL) {
U64 const dictFileSize = UTIL_getFileSize(dictFileName);
if (dictFileSize > 64 MB) {
free(fileSizes);
RETURN_ERROR(10, BMK_benchOutcome_t, "dictionary file %s too large", dictFileName);
}
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dictBufferSize = (size_t)dictFileSize;
dictBuffer = malloc(dictBufferSize);
if (dictBuffer==NULL) {
free(fileSizes);
RETURN_ERROR(11, BMK_benchOutcome_t, "not enough memory for dictionary (%u bytes)",
(U32)dictBufferSize);
}
{ int const errorCode = BMK_loadFiles(dictBuffer, dictBufferSize,
fileSizes, &dictFileName /*?*/,
1 /*?*/, displayLevel);
if (errorCode) {
res = BMK_benchOutcome_error();
goto _cleanUp;
} }
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}
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/* Memory allocation & restrictions */
benchedSize = BMK_findMaxMem(totalSizeToLoad * 3) / 3;
if ((U64)benchedSize > totalSizeToLoad) benchedSize = (size_t)totalSizeToLoad;
if (benchedSize < totalSizeToLoad)
DISPLAY("Not enough memory; testing %u MB only...\n", (U32)(benchedSize >> 20));
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srcBuffer = benchedSize ? malloc(benchedSize) : NULL;
if (!srcBuffer) {
free(dictBuffer);
free(fileSizes);
RETURN_ERROR(12, BMK_benchOutcome_t, "not enough memory");
}
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/* Load input buffer */
{ int const errorCode = BMK_loadFiles(srcBuffer, benchedSize,
fileSizes, fileNamesTable, nbFiles,
displayLevel);
if (errorCode) {
res = BMK_benchOutcome_error();
goto _cleanUp;
} }
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/* Bench */
{ char mfName[20] = {0};
snprintf (mfName, sizeof(mfName), " %u files", nbFiles);
{ const char* const displayName = (nbFiles > 1) ? mfName : fileNamesTable[0];
res = BMK_benchCLevel(srcBuffer, benchedSize,
fileSizes, nbFiles,
cLevel, compressionParams,
dictBuffer, dictBufferSize,
displayLevel, displayName,
adv);
} }
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_cleanUp:
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free(srcBuffer);
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free(dictBuffer);
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free(fileSizes);
return res;
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}
BMK_benchOutcome_t BMK_benchFiles(
const char* const * fileNamesTable, unsigned nbFiles,
const char* dictFileName,
int cLevel, const ZSTD_compressionParameters* compressionParams,
int displayLevel)
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{
BMK_advancedParams_t const adv = BMK_initAdvancedParams();
return BMK_benchFilesAdvanced(fileNamesTable, nbFiles, dictFileName, cLevel, compressionParams, displayLevel, &adv);
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}