zstd/programs/zbufftest.c

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/*
Fuzzer test tool for zstd_buffered
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Copyright (C) Yann Collet 2015-2016
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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 :
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- ZSTD homepage : https://www.zstd.net/
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*/
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/*-************************************
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* Compiler specific
**************************************/
#ifdef _MSC_VER /* Visual Studio */
# define _CRT_SECURE_NO_WARNINGS /* fgets */
# pragma warning(disable : 4127) /* disable: C4127: conditional expression is constant */
# pragma warning(disable : 4146) /* disable: C4146: minus unsigned expression */
#endif
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/*-************************************
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* Includes
**************************************/
#include <stdlib.h> /* free */
#include <stdio.h> /* fgets, sscanf */
#include <sys/timeb.h> /* timeb */
#include <string.h> /* strcmp */
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#include "mem.h"
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#include "zbuff.h"
#include "zstd_static.h" /* ZSTD_compressBound(), ZSTD_maxCLevel() */
#include "zbuff_static.h" /* ZBUFF_createCCtx_advanced */
#include "datagen.h" /* RDG_genBuffer */
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#define XXH_STATIC_LINKING_ONLY
#include "xxhash.h" /* XXH64 */
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/*-************************************
* Constants
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**************************************/
#define KB *(1U<<10)
#define MB *(1U<<20)
#define GB *(1U<<30)
static const U32 nbTestsDefault = 10000;
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#define COMPRESSIBLE_NOISE_LENGTH (10 MB)
#define FUZ_COMPRESSIBILITY_DEFAULT 50
static const U32 prime1 = 2654435761U;
static const U32 prime2 = 2246822519U;
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/*-************************************
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* Display Macros
**************************************/
#define DISPLAY(...) fprintf(stderr, __VA_ARGS__)
#define DISPLAYLEVEL(l, ...) if (g_displayLevel>=l) { DISPLAY(__VA_ARGS__); }
static U32 g_displayLevel = 2;
#define DISPLAYUPDATE(l, ...) if (g_displayLevel>=l) { \
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if ((FUZ_GetMilliSpan(g_displayTime) > g_refreshRate) || (g_displayLevel>=4)) \
{ g_displayTime = FUZ_GetMilliStart(); DISPLAY(__VA_ARGS__); \
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if (g_displayLevel>=4) fflush(stdout); } }
static const U32 g_refreshRate = 150;
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static U32 g_displayTime = 0;
static U32 g_testTime = 0;
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/*-*******************************************************
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* Fuzzer functions
*********************************************************/
#define MAX(a,b) ((a)>(b)?(a):(b))
static U32 FUZ_GetMilliStart(void)
{
struct timeb tb;
U32 nCount;
ftime( &tb );
nCount = (U32) (((tb.time & 0xFFFFF) * 1000) + tb.millitm);
return nCount;
}
static U32 FUZ_GetMilliSpan(U32 nTimeStart)
{
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U32 const nCurrent = FUZ_GetMilliStart();
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U32 nSpan = nCurrent - nTimeStart;
if (nTimeStart > nCurrent)
nSpan += 0x100000 * 1000;
return nSpan;
}
/*! FUZ_rand() :
@return : a 27 bits random value, from a 32-bits `seed`.
`seed` is also modified */
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# define FUZ_rotl32(x,r) ((x << r) | (x >> (32 - r)))
unsigned int FUZ_rand(unsigned int* seedPtr)
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{
U32 rand32 = *seedPtr;
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rand32 *= prime1;
rand32 += prime2;
rand32 = FUZ_rotl32(rand32, 13);
*seedPtr = rand32;
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return rand32 >> 5;
}
/*
static unsigned FUZ_highbit32(U32 v32)
{
unsigned nbBits = 0;
if (v32==0) return 0;
for ( ; v32 ; v32>>=1) nbBits++;
return nbBits;
}
*/
void* ZBUFF_allocFunction(size_t size)
{
void* address = malloc(size);
/* DISPLAYLEVEL(4, "alloc %p, %d \n", address, (int)size); */
return address;
}
void ZBUFF_freeFunction(void* address)
{
/* if (address) DISPLAYLEVEL(4, "free %p \n", address); */
free(address);
}
static int basicUnitTests(U32 seed, double compressibility, ZSTD_customMem customMem)
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{
int testResult = 0;
size_t CNBufferSize = COMPRESSIBLE_NOISE_LENGTH;
void* CNBuffer = malloc(CNBufferSize);
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size_t const skippableFrameSize = 11;
size_t const compressedBufferSize = (8 + skippableFrameSize) + ZSTD_compressBound(COMPRESSIBLE_NOISE_LENGTH);
void* compressedBuffer = malloc(compressedBufferSize);
size_t const decodedBufferSize = CNBufferSize;
void* decodedBuffer = malloc(decodedBufferSize);
size_t cSize, readSize, readSkipSize, genSize;
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U32 testNb=0;
ZBUFF_CCtx* zc = ZBUFF_createCCtx_advanced(customMem);
ZBUFF_DCtx* zd = ZBUFF_createDCtx_advanced(customMem);
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/* Create compressible test buffer */
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if (!CNBuffer || !compressedBuffer || !decodedBuffer || !zc || !zd) {
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DISPLAY("Not enough memory, aborting\n");
goto _output_error;
}
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RDG_genBuffer(CNBuffer, CNBufferSize, compressibility, 0., seed);
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/* generate skippable frame */
MEM_writeLE32(compressedBuffer, ZSTD_MAGIC_SKIPPABLE_START);
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MEM_writeLE32(((char*)compressedBuffer)+4, (U32)skippableFrameSize);
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cSize = skippableFrameSize + 8;
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/* Basic compression test */
DISPLAYLEVEL(4, "test%3i : compress %u bytes : ", testNb++, COMPRESSIBLE_NOISE_LENGTH);
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ZBUFF_compressInitDictionary(zc, CNBuffer, 128 KB, 1);
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readSize = CNBufferSize;
genSize = compressedBufferSize;
{ size_t const r = ZBUFF_compressContinue(zc, ((char*)compressedBuffer)+cSize, &genSize, CNBuffer, &readSize);
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if (ZBUFF_isError(r)) goto _output_error; }
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if (readSize != CNBufferSize) goto _output_error; /* entire input should be consumed */
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cSize += genSize;
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genSize = compressedBufferSize - cSize;
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{ size_t const r = ZBUFF_compressEnd(zc, ((char*)compressedBuffer)+cSize, &genSize);
if (r != 0) goto _output_error; } /*< error, or some data not flushed */
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cSize += genSize;
DISPLAYLEVEL(4, "OK (%u bytes : %.2f%%)\n", (U32)cSize, (double)cSize/COMPRESSIBLE_NOISE_LENGTH*100);
/* Basic decompression test */
DISPLAYLEVEL(4, "test%3i : decompress %u bytes : ", testNb++, COMPRESSIBLE_NOISE_LENGTH);
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ZBUFF_decompressInitDictionary(zd, CNBuffer, 128 KB);
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readSkipSize = cSize;
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genSize = CNBufferSize;
{ size_t const r = ZBUFF_decompressContinue(zd, decodedBuffer, &genSize, compressedBuffer, &readSkipSize);
if (r != 0) goto _output_error; }
if (genSize != 0) goto _output_error; /* skippable frame len is 0 */
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ZBUFF_decompressInitDictionary(zd, CNBuffer, 128 KB);
readSize = cSize - readSkipSize;
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genSize = CNBufferSize;
{ size_t const r = ZBUFF_decompressContinue(zd, decodedBuffer, &genSize, ((char*)compressedBuffer)+readSkipSize, &readSize);
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if (r != 0) goto _output_error; } /* should reach end of frame == 0; otherwise, some data left, or an error */
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if (genSize != CNBufferSize) goto _output_error; /* should regenerate the same amount */
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if (readSize+readSkipSize != cSize) goto _output_error; /* should have read the entire frame */
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DISPLAYLEVEL(4, "OK \n");
/* check regenerated data is byte exact */
{ size_t i;
DISPLAYLEVEL(4, "test%3i : check decompressed result : ", testNb++);
for (i=0; i<CNBufferSize; i++) {
if (((BYTE*)decodedBuffer)[i] != ((BYTE*)CNBuffer)[i]) goto _output_error;;
}
DISPLAYLEVEL(4, "OK \n");
}
/* Byte-by-byte decompression test */
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DISPLAYLEVEL(4, "test%3i : decompress byte-by-byte : ", testNb++);
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{ size_t r, pIn=0, pOut=0;
do
{ ZBUFF_decompressInitDictionary(zd, CNBuffer, 128 KB);
r = 1;
while (r) {
size_t inS = 1;
size_t outS = 1;
r = ZBUFF_decompressContinue(zd, ((BYTE*)decodedBuffer)+pOut, &outS, ((BYTE*)compressedBuffer)+pIn, &inS);
pIn += inS;
pOut += outS;
}
readSize = pIn;
genSize = pOut;
} while (genSize==0);
}
if (genSize != CNBufferSize) goto _output_error; /* should regenerate the same amount */
if (readSize != cSize) goto _output_error; /* should have read the entire frame */
DISPLAYLEVEL(4, "OK \n");
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/* check regenerated data is byte exact */
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{ size_t i;
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DISPLAYLEVEL(4, "test%3i : check decompressed result : ", testNb++);
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for (i=0; i<CNBufferSize; i++) {
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if (((BYTE*)decodedBuffer)[i] != ((BYTE*)CNBuffer)[i]) goto _output_error;;
}
DISPLAYLEVEL(4, "OK \n");
}
_end:
ZBUFF_freeCCtx(zc);
ZBUFF_freeDCtx(zd);
free(CNBuffer);
free(compressedBuffer);
free(decodedBuffer);
return testResult;
_output_error:
testResult = 1;
DISPLAY("Error detected in Unit tests ! \n");
goto _end;
}
static size_t findDiff(const void* buf1, const void* buf2, size_t max)
{
const BYTE* b1 = (const BYTE*)buf1;
const BYTE* b2 = (const BYTE*)buf2;
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size_t u;
for (u=0; u<max; u++) {
if (b1[u] != b2[u]) break;
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}
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return u;
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}
static size_t FUZ_rLogLength(U32* seed, U32 logLength)
{
size_t const lengthMask = ((size_t)1 << logLength) - 1;
return (lengthMask+1) + (FUZ_rand(seed) & lengthMask);
}
static size_t FUZ_randomLength(U32* seed, U32 maxLog)
{
U32 const logLength = FUZ_rand(seed) % maxLog;
return FUZ_rLogLength(seed, logLength);
}
#define MIN(a,b) ( (a) < (b) ? (a) : (b) )
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#define CHECK(cond, ...) if (cond) { DISPLAY("Error => "); DISPLAY(__VA_ARGS__); \
DISPLAY(" (seed %u, test nb %u) \n", seed, testNb); goto _output_error; }
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static int fuzzerTests(U32 seed, U32 nbTests, unsigned startTest, double compressibility)
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{
static const U32 maxSrcLog = 24;
static const U32 maxSampleLog = 19;
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BYTE* cNoiseBuffer[5];
size_t srcBufferSize = (size_t)1<<maxSrcLog;
BYTE* copyBuffer;
size_t copyBufferSize= srcBufferSize + (1<<maxSampleLog);
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BYTE* cBuffer;
size_t cBufferSize = ZSTD_compressBound(srcBufferSize);
BYTE* dstBuffer;
size_t dstBufferSize = srcBufferSize;
U32 result = 0;
U32 testNb = 0;
U32 coreSeed = seed;
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ZBUFF_CCtx* zc;
ZBUFF_DCtx* zd;
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U32 startTime = FUZ_GetMilliStart();
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/* allocations */
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zc = ZBUFF_createCCtx();
zd = ZBUFF_createDCtx();
cNoiseBuffer[0] = (BYTE*)malloc (srcBufferSize);
cNoiseBuffer[1] = (BYTE*)malloc (srcBufferSize);
cNoiseBuffer[2] = (BYTE*)malloc (srcBufferSize);
cNoiseBuffer[3] = (BYTE*)malloc (srcBufferSize);
cNoiseBuffer[4] = (BYTE*)malloc (srcBufferSize);
copyBuffer= (BYTE*)malloc (copyBufferSize);
dstBuffer = (BYTE*)malloc (dstBufferSize);
cBuffer = (BYTE*)malloc (cBufferSize);
CHECK (!cNoiseBuffer[0] || !cNoiseBuffer[1] || !cNoiseBuffer[2] || !cNoiseBuffer[3] || !cNoiseBuffer[4] ||
!copyBuffer || !dstBuffer || !cBuffer || !zc || !zd,
"Not enough memory, fuzzer tests cancelled");
/* Create initial samples */
RDG_genBuffer(cNoiseBuffer[0], srcBufferSize, 0.00, 0., coreSeed); /* pure noise */
RDG_genBuffer(cNoiseBuffer[1], srcBufferSize, 0.05, 0., coreSeed); /* barely compressible */
RDG_genBuffer(cNoiseBuffer[2], srcBufferSize, compressibility, 0., coreSeed);
RDG_genBuffer(cNoiseBuffer[3], srcBufferSize, 0.95, 0., coreSeed); /* highly compressible */
RDG_genBuffer(cNoiseBuffer[4], srcBufferSize, 1.00, 0., coreSeed); /* sparse content */
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memset(copyBuffer, 0x65, copyBufferSize); /* make copyBuffer considered initialized */
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/* catch up testNb */
for (testNb=1; testNb < startTest; testNb++)
FUZ_rand(&coreSeed);
/* test loop */
for ( ; (testNb <= nbTests) || (FUZ_GetMilliSpan(startTime) < g_testTime) ; testNb++ ) {
U32 lseed;
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const BYTE* srcBuffer;
const BYTE* dict;
size_t maxTestSize, dictSize;
size_t cSize, totalTestSize, totalCSize, totalGenSize;
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size_t errorCode;
U32 n, nbChunks;
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XXH64_state_t xxhState;
U64 crcOrig;
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/* init */
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DISPLAYUPDATE(2, "\r%6u", testNb);
if (nbTests >= testNb) DISPLAYUPDATE(2, "/%6u ", nbTests);
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FUZ_rand(&coreSeed);
lseed = coreSeed ^ prime1;
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/* state total reset */
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/* some problems only happen when states are re-used in a specific order */
if ((FUZ_rand(&lseed) & 0xFF) == 131) { ZBUFF_freeCCtx(zc); zc = ZBUFF_createCCtx(); }
if ((FUZ_rand(&lseed) & 0xFF) == 132) { ZBUFF_freeDCtx(zd); zd = ZBUFF_createDCtx(); }
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/* srcBuffer selection [0-4] */
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{ U32 buffNb = FUZ_rand(&lseed) & 0x7F;
if (buffNb & 7) buffNb=2; /* most common : compressible (P) */
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else {
buffNb >>= 3;
if (buffNb & 7) {
const U32 tnb[2] = { 1, 3 }; /* barely/highly compressible */
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buffNb = tnb[buffNb >> 3];
} else {
const U32 tnb[2] = { 0, 4 }; /* not compressible / sparse */
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buffNb = tnb[buffNb >> 3];
} }
srcBuffer = cNoiseBuffer[buffNb];
}
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/* compression init */
{ U32 const testLog = FUZ_rand(&lseed) % maxSrcLog;
U32 const cLevel = (FUZ_rand(&lseed) % (ZSTD_maxCLevel() - (testLog/3))) + 1;
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maxTestSize = FUZ_rLogLength(&lseed, testLog);
/* random dictionary selection */
{ size_t dictStart;
dictSize = (FUZ_rand(&lseed)==1) ? FUZ_randomLength(&lseed, maxSampleLog) : 0;
dictStart = FUZ_rand(&lseed) % (srcBufferSize - dictSize);
dict = srcBuffer + dictStart;
}
{ size_t const initError = ZBUFF_compressInitDictionary(zc, dict, dictSize, cLevel);
CHECK (ZBUFF_isError(initError),"init error : %s", ZBUFF_getErrorName(initError));
} }
/* multi-segments compression test */
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XXH64_reset(&xxhState, 0);
nbChunks = (FUZ_rand(&lseed) & 127) + 2;
for (n=0, cSize=0, totalTestSize=0 ; (n<nbChunks) && (totalTestSize < maxTestSize) ; n++) {
/* compress random chunk into random size dst buffer */
{ size_t readChunkSize = FUZ_randomLength(&lseed, maxSampleLog);
size_t const randomDstSize = FUZ_randomLength(&lseed, maxSampleLog);
size_t dstBuffSize = MIN(cBufferSize - cSize, randomDstSize);
size_t const srcStart = FUZ_rand(&lseed) % (srcBufferSize - readChunkSize);
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size_t const compressionError = ZBUFF_compressContinue(zc, cBuffer+cSize, &dstBuffSize, srcBuffer+srcStart, &readChunkSize);
CHECK (ZBUFF_isError(compressionError), "compression error : %s", ZBUFF_getErrorName(compressionError));
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XXH64_update(&xxhState, srcBuffer+srcStart, readChunkSize);
memcpy(copyBuffer+totalTestSize, srcBuffer+srcStart, readChunkSize);
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cSize += dstBuffSize;
totalTestSize += readChunkSize;
}
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/* random flush operation, to mess around */
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if ((FUZ_rand(&lseed) & 15) == 0) {
size_t const randomDstSize = FUZ_randomLength(&lseed, maxSampleLog);
size_t dstBuffSize = MIN(cBufferSize - cSize, randomDstSize);
size_t const flushError = ZBUFF_compressFlush(zc, cBuffer+cSize, &dstBuffSize);
CHECK (ZBUFF_isError(flushError), "flush error : %s", ZBUFF_getErrorName(flushError));
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cSize += dstBuffSize;
} }
/* final frame epilogue */
{ size_t dstBuffSize = cBufferSize - cSize;
size_t const flushError = ZBUFF_compressEnd(zc, cBuffer+cSize, &dstBuffSize);
CHECK (ZBUFF_isError(flushError), "flush error : %s", ZBUFF_getErrorName(flushError));
cSize += dstBuffSize;
}
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crcOrig = XXH64_digest(&xxhState);
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/* multi - fragments decompression test */
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ZBUFF_decompressInitDictionary(zd, dict, dictSize);
for (totalCSize = 0, totalGenSize = 0 ; totalCSize < cSize ; ) {
size_t readCSrcSize = FUZ_randomLength(&lseed, maxSampleLog);
size_t const randomDstSize = FUZ_randomLength(&lseed, maxSampleLog);
size_t dstBuffSize = MIN(dstBufferSize - totalGenSize, randomDstSize);
size_t const decompressError = ZBUFF_decompressContinue(zd, dstBuffer+totalGenSize, &dstBuffSize, cBuffer+totalCSize, &readCSrcSize);
CHECK (ZBUFF_isError(decompressError), "decompression error : %s", ZBUFF_getErrorName(decompressError));
totalGenSize += dstBuffSize;
totalCSize += readCSrcSize;
errorCode = decompressError; /* needed for != 0 last test */
}
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CHECK (errorCode != 0, "frame not fully decoded");
CHECK (totalGenSize != totalTestSize, "decompressed data : wrong size")
CHECK (totalCSize != cSize, "compressed data should be fully read")
{ U64 const crcDest = XXH64(dstBuffer, totalTestSize, 0);
if (crcDest!=crcOrig) findDiff(copyBuffer, dstBuffer, totalTestSize);
CHECK (crcDest!=crcOrig, "decompressed data corrupted"); }
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/*===== noisy/erroneous src decompression test =====*/
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/* add some noise */
{ U32 const nbNoiseChunks = (FUZ_rand(&lseed) & 7) + 2;
U32 nn; for (nn=0; nn<nbNoiseChunks; nn++) {
size_t const randomNoiseSize = FUZ_randomLength(&lseed, maxSampleLog);
size_t const noiseSize = MIN((cSize/3) , randomNoiseSize);
size_t const noiseStart = FUZ_rand(&lseed) % (srcBufferSize - noiseSize);
size_t const cStart = FUZ_rand(&lseed) % (cSize - noiseSize);
memcpy(cBuffer+cStart, srcBuffer+noiseStart, noiseSize);
} }
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/* try decompression on noisy data */
ZBUFF_decompressInit(zd);
totalCSize = 0;
totalGenSize = 0;
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while ( (totalCSize < cSize) && (totalGenSize < dstBufferSize) ) {
size_t readCSrcSize = FUZ_randomLength(&lseed, maxSampleLog);
size_t const randomDstSize = FUZ_randomLength(&lseed, maxSampleLog);
size_t dstBuffSize = MIN(dstBufferSize - totalGenSize, randomDstSize);
size_t const decompressError = ZBUFF_decompressContinue(zd, dstBuffer+totalGenSize, &dstBuffSize, cBuffer+totalCSize, &readCSrcSize);
if (ZBUFF_isError(decompressError)) break; /* error correctly detected */
totalGenSize += dstBuffSize;
totalCSize += readCSrcSize;
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} }
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DISPLAY("\r%u fuzzer tests completed \n", testNb);
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_cleanup:
ZBUFF_freeCCtx(zc);
ZBUFF_freeDCtx(zd);
free(cNoiseBuffer[0]);
free(cNoiseBuffer[1]);
free(cNoiseBuffer[2]);
free(cNoiseBuffer[3]);
free(cNoiseBuffer[4]);
free(copyBuffer);
free(cBuffer);
free(dstBuffer);
return result;
_output_error:
result = 1;
goto _cleanup;
}
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/*-*******************************************************
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* Command line
*********************************************************/
int FUZ_usage(const char* programName)
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{
DISPLAY( "Usage :\n");
DISPLAY( " %s [args]\n", programName);
DISPLAY( "\n");
DISPLAY( "Arguments :\n");
DISPLAY( " -i# : Nb of tests (default:%u) \n", nbTestsDefault);
DISPLAY( " -s# : Select seed (default:prompt user)\n");
DISPLAY( " -t# : Select starting test number (default:0)\n");
DISPLAY( " -P# : Select compressibility in %% (default:%i%%)\n", FUZ_COMPRESSIBILITY_DEFAULT);
DISPLAY( " -v : verbose\n");
DISPLAY( " -p : pause at the end\n");
DISPLAY( " -h : display help and exit\n");
return 0;
}
int main(int argc, const char** argv)
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{
U32 seed=0;
int seedset=0;
int argNb;
int nbTests = nbTestsDefault;
int testNb = 0;
int proba = FUZ_COMPRESSIBILITY_DEFAULT;
int result=0;
U32 mainPause = 0;
const char* programName = argv[0];
ZSTD_customMem customMem = { ZBUFF_allocFunction, ZBUFF_freeFunction };
ZSTD_customMem customNULL = { NULL, NULL };
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/* Check command line */
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for(argNb=1; argNb<argc; argNb++) {
const char* argument = argv[argNb];
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if(!argument) continue; /* Protection if argument empty */
/* Parsing commands. Aggregated commands are allowed */
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if (argument[0]=='-') {
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argument++;
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while (*argument!=0) {
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switch(*argument)
{
case 'h':
return FUZ_usage(programName);
case 'v':
argument++;
g_displayLevel=4;
break;
case 'q':
argument++;
g_displayLevel--;
break;
case 'p': /* pause at the end */
argument++;
mainPause = 1;
break;
case 'i':
argument++;
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nbTests=0; g_testTime=0;
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while ((*argument>='0') && (*argument<='9')) {
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nbTests *= 10;
nbTests += *argument - '0';
argument++;
}
break;
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case 'T':
argument++;
nbTests=0; g_testTime=0;
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while ((*argument>='0') && (*argument<='9')) {
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g_testTime *= 10;
g_testTime += *argument - '0';
argument++;
}
if (*argument=='m') g_testTime *=60, argument++;
if (*argument=='n') argument++;
g_testTime *= 1000;
break;
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case 's':
argument++;
seed=0;
seedset=1;
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while ((*argument>='0') && (*argument<='9')) {
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seed *= 10;
seed += *argument - '0';
argument++;
}
break;
case 't':
argument++;
testNb=0;
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while ((*argument>='0') && (*argument<='9')) {
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testNb *= 10;
testNb += *argument - '0';
argument++;
}
break;
case 'P': /* compressibility % */
argument++;
proba=0;
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while ((*argument>='0') && (*argument<='9')) {
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proba *= 10;
proba += *argument - '0';
argument++;
}
if (proba<0) proba=0;
if (proba>100) proba=100;
break;
default:
return FUZ_usage(programName);
}
} } } /* for(argNb=1; argNb<argc; argNb++) */
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/* Get Seed */
DISPLAY("Starting zstd_buffered tester (%i-bits, %s)\n", (int)(sizeof(size_t)*8), ZSTD_VERSION_STRING);
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if (!seedset) seed = FUZ_GetMilliStart() % 10000;
DISPLAY("Seed = %u\n", seed);
if (proba!=FUZ_COMPRESSIBILITY_DEFAULT) DISPLAY("Compressibility : %i%%\n", proba);
if (nbTests<=0) nbTests=1;
if (testNb==0) {
result = basicUnitTests(0, ((double)proba) / 100, customNULL); /* constant seed for predictability */
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if (!result) {
DISPLAYLEVEL(4, "Unit tests using customMem :\n")
result = basicUnitTests(0, ((double)proba) / 100, customMem); /* use custom memory allocation functions */
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} }
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if (!result)
result = fuzzerTests(seed, nbTests, testNb, ((double)proba) / 100);
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if (mainPause) {
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int unused;
DISPLAY("Press Enter \n");
unused = getchar();
(void)unused;
}
return result;
}