static PyObject *py_lz4f_compressFrame(PyObject *self, PyObject *args) {
PyObject *result;
const char* source;
char* dest;
int src_size;
size_t dest_size;
size_t final_size;
size_t ssrc_size;
(void)self;
if (!PyArg_ParseTuple(args, "s#", &source, &src_size)) {
return NULL;
}
ssrc_size = (size_t)src_size;
dest_size = LZ4F_compressFrameBound(ssrc_size, NULL);
dest = (char*)malloc(dest_size);
final_size = LZ4F_compressFrame(dest, dest_size, source, ssrc_size, NULL);
result = PyBytes_FromStringAndSize(dest, final_size);
free(dest);
return result;
}
static int lz4_msendv(struct msock_vfs *mvfs,
const struct iovec *iov, size_t iovlen, int64_t deadline) {
struct lz4_sock *obj = dsock_cont(mvfs, struct lz4_sock, mvfs);
/* Adjust the buffer size as needed. */
size_t len = iov_size(iov, iovlen);
size_t maxlen = LZ4F_compressFrameBound(len, NULL);
if(obj->outlen < maxlen) {
uint8_t *newbuf = realloc(obj->outbuf, maxlen);
if(dsock_slow(!newbuf)) {errno = ENOMEM; return -1;}
obj->outbuf = newbuf;
obj->outlen = maxlen;
}
/* Compress the data. */
/* TODO: Avoid the extra allocations and copies. */
uint8_t *buf = malloc(len);
if(dsock_slow(!buf)) {errno = ENOMEM; return -1;}
iov_copyallfrom(buf, iov, iovlen);
LZ4F_preferences_t prefs = {0};
prefs.frameInfo.contentSize = len;
size_t dstlen = LZ4F_compressFrame(obj->outbuf, obj->outlen,
buf, len, &prefs);
dsock_assert(!LZ4F_isError(dstlen));
dsock_assert(dstlen <= obj->outlen);
free(buf);
/* Send the compressed frame. */
return msend(obj->s, obj->outbuf, dstlen, deadline);
}
static bool writeFile(llvm::StringRef file_name, llvm::StringRef data) {
std::error_code error_code;
llvm::raw_fd_ostream file(file_name, error_code, llvm::sys::fs::F_RW);
if (error_code)
return false;
int uncompressed_size = data.size();
// Write the uncompressed size to the beginning of the file as a simple checksum.
// It looks like each lz4 block has its own data checksum, but we need to also
// make sure that we have all the blocks that we expected.
// In particular, without this, an empty file seems to be a valid lz4 stream.
file.write(reinterpret_cast<const char*>(&uncompressed_size), 4);
LZ4F_preferences_t preferences;
memset(&preferences, 0, sizeof(preferences));
preferences.frameInfo.contentChecksumFlag = contentChecksumEnabled;
preferences.frameInfo.contentSize = data.size();
std::vector<char> compressed;
size_t max_size = LZ4F_compressFrameBound(data.size(), &preferences);
compressed.resize(max_size);
size_t compressed_size = LZ4F_compressFrame(&compressed[0], max_size, data.data(), data.size(), &preferences);
if (LZ4F_isError(compressed_size))
return false;
file.write(compressed.data(), compressed_size);
return true;
}
static size_t
squash_lz4f_stream_get_output_buffer_size (SquashStream* stream) {
/* I'm pretty sure there is a very overly ambitious check in
LZ4F_compressFrame when srcSize == blockSize, but not much we can
do about it here. It just means LZ4F will do some extra
memcpy()ing (for output buffers up to a bit over double the block
size). */
return LZ4F_compressFrameBound(squash_lz4f_get_input_buffer_size (stream) * 2,
&(((SquashLZ4FStream*) stream)->data.comp.prefs));
}
static ssize_t lz4_mrecvv(struct msock_vfs *mvfs,
const struct iovec *iov, size_t iovlen, int64_t deadline) {
struct lz4_sock *obj = dsock_cont(mvfs, struct lz4_sock, mvfs);
/* Adjust the buffer size as needed. */
size_t len = iov_size(iov, iovlen);
size_t maxlen = LZ4F_compressFrameBound(len, NULL);
if(obj->inlen < maxlen) {
uint8_t *newbuf = realloc(obj->inbuf, maxlen);
if(dsock_slow(!newbuf)) {errno = ENOMEM; return -1;}
obj->inbuf = newbuf;
obj->inlen = maxlen;
}
/* Get the compressed message. */
ssize_t sz = mrecv(obj->s, obj->inbuf, obj->inlen, deadline);
if(dsock_slow(sz < 0)) return -1;
/* Extract size of the uncompressed message from LZ4 frame header. */
LZ4F_frameInfo_t info;
size_t infolen = sz;
size_t ec = LZ4F_getFrameInfo(obj->dctx, &info, obj->inbuf, &infolen);
if(dsock_slow(LZ4F_isError(ec))) {errno = EPROTO; return -1;}
/* Size is a required field. */
if(dsock_slow(info.contentSize == 0)) {errno = EPROTO; return -1;}
/* Decompressed message would exceed the buffer size. */
if(dsock_slow(info.contentSize > len)) {errno = EMSGSIZE; return -1;}
/* Decompress. */
/* TODO: Avoid the extra allocations and copies. */
uint8_t *buf = malloc(len);
if(dsock_slow(!buf)) {errno = ENOMEM; return -1;}
size_t dstlen = len;
size_t srclen = sz - infolen;
ec = LZ4F_decompress(obj->dctx, buf, &dstlen,
obj->inbuf + infolen, &srclen, NULL);
if(dsock_slow(LZ4F_isError(ec))) {errno = EPROTO; return -1;}
if(dsock_slow(ec != 0)) {errno = EPROTO; return -1;}
dsock_assert(srclen == sz - infolen);
iov_copyallto(iov, iovlen, buf);
free(buf);
return dstlen;
}
#include <stdlib.h>
#include "common.h"
#include "lz4/lib/lz4frame.h"
#include <commonlib/compression.h>
static int lz4_compress(char *in, int in_len, char *out, int *out_len)
{
LZ4F_preferences_t prefs = {
.compressionLevel = 20,
.frameInfo = {
.blockSizeID = max4MB,
.blockMode = blockIndependent,
.contentChecksumFlag = noContentChecksum,
},
};
size_t worst_size = LZ4F_compressFrameBound(in_len, &prefs);
void *bounce = malloc(worst_size);
if (!bounce)
return -1;
*out_len = LZ4F_compressFrame(bounce, worst_size, in, in_len, &prefs);
if (LZ4F_isError(*out_len) || *out_len >= in_len)
return -1;
memcpy(out, bounce, *out_len);
return 0;
}
static int lz4_decompress(char *in, int in_len, char *out, int out_len,
size_t *actual_size)
{
size_t result = ulz4fn(in, in_len, out, out_len);
if (result == 0)
int fuzzerTests(U32 seed, unsigned nbTests, unsigned startTest, double compressibility, U32 duration)
{
unsigned testResult = 0;
unsigned testNb = 0;
void* srcBuffer = NULL;
void* compressedBuffer = NULL;
void* decodedBuffer = NULL;
U32 coreRand = seed;
LZ4F_decompressionContext_t dCtx = NULL;
LZ4F_compressionContext_t cCtx = NULL;
size_t result;
const U32 startTime = FUZ_GetMilliStart();
XXH64_state_t xxh64;
# define CHECK(cond, ...) if (cond) { DISPLAY("Error => "); DISPLAY(__VA_ARGS__); \
DISPLAY(" (seed %u, test nb %u) \n", seed, testNb); goto _output_error; }
// backup all allocated addresses, from which we will later select buffers
const size_t max_buf_size = 131 KB;
size_t num_buf_size_distribution_deviations = 0;
LZ4SG_in_t sg_in_buf_potential [2*MAX_SG_BUFFERS];
LZ4SG_out_t sg_out_buf_potential[2*MAX_SG_BUFFERS];
LZ4SG_in_t sg_cin [MAX_SG_BUFFERS];
LZ4SG_out_t sg_cout[MAX_SG_BUFFERS];
LZ4SG_in_t sg_din [MAX_SG_BUFFERS];
LZ4SG_out_t sg_dout[MAX_SG_BUFFERS];
size_t sg_cin_len, sg_cout_len, sg_din_len, sg_dout_len;
const size_t maxDstSize = LZ4_SG_compressBound(srcDataLength, NELEMS(sg_cin), NELEMS(sg_cout));
unsigned int i;
for (i = 0; i < NELEMS(sg_in_buf_potential); i++) {
sg_in_buf_potential [i].sg_base = malloc(max_buf_size);
sg_in_buf_potential [i].sg_len = max_buf_size;
sg_out_buf_potential[i].sg_base = malloc(max_buf_size);
sg_out_buf_potential[i].sg_len = max_buf_size;
}
/* Init */
duration *= 1000;
/* Create buffers */
result = LZ4F_createDecompressionContext(&dCtx, LZ4F_VERSION);
CHECK(LZ4F_isError(result), "Allocation failed (error %i)", (int)result);
result = LZ4F_createCompressionContext(&cCtx, LZ4F_VERSION);
CHECK(LZ4F_isError(result), "Allocation failed (error %i)", (int)result);
srcBuffer = malloc(srcDataLength);
CHECK(srcBuffer==NULL, "srcBuffer Allocation failed");
const size_t compressedBufferLength = maxDstSize;
compressedBuffer = malloc(compressedBufferLength);
CHECK(compressedBuffer==NULL, "compressedBuffer Allocation failed");
decodedBuffer = calloc(1, srcDataLength); /* calloc avoids decodedBuffer being considered "garbage" by scan-build */
CHECK(decodedBuffer==NULL, "decodedBuffer Allocation failed");
FUZ_fillCompressibleNoiseBuffer(srcBuffer, srcDataLength, compressibility, &coreRand);
/* jump to requested testNb */
for (testNb =0; (testNb < startTest); testNb++) (void)FUZ_rand(&coreRand); // sync randomizer
/* main fuzzer test loop */
for ( ; (testNb < nbTests) || (duration > FUZ_GetMilliSpan(startTime)) ; testNb++)
{
U32 randState = coreRand ^ prime1;
(void)FUZ_rand(&coreRand); /* update seed */
srand48(FUZ_rand(&randState));
DISPLAYUPDATE(2, "\r%5u ", testNb);
const size_t max_src_buf_size = (4 MB > srcDataLength) ? srcDataLength : 4 MB;
unsigned nbBits = (FUZ_rand(&randState) % (FUZ_highbit(max_src_buf_size-1) - 1)) + 1;
const size_t min_src_size = 20;
const size_t min_first_dest_buf_size = 21;
const size_t min_src_buf_size = 1;
const size_t min_dst_buf_size = 10;
size_t srcSize = (FUZ_rand(&randState) & ((1<<nbBits)-1)) + min_src_size;
size_t srcStart = FUZ_rand(&randState) % (srcDataLength - srcSize);
size_t cSize;
size_t dstSize;
size_t dstSizeBound;
U64 crcOrig, crcDecoded;
unsigned int test_selection = FUZ_rand(&randState);
//TODO: enable lz4f_compress_compatibility_test with LZ4_SG_decompress
int lz4f_compress_compatibility_test = 0;//(test_selection % 4) == 0;
if (!lz4f_compress_compatibility_test)
{
// SGL compress
unsigned int buffer_selection = FUZ_rand(&randState);
if ((buffer_selection & 0xF) == 1)
{
// SG compress single source and single target buffers
sg_cin[0].sg_base = (BYTE*)srcBuffer+srcStart;
sg_cin[0].sg_len = srcSize;
sg_cin_len = 1;
sg_cout[0].sg_base = compressedBuffer;
sg_cout[0].sg_len = compressedBufferLength;
sg_cout_len = 1;
dstSizeBound = dstSize = compressedBufferLength;
}
else
{
// SG compress random number and size source and target buffers
sg_cin_len = 1 + (FUZ_rand(&randState) % MAX_SG_BUFFERS);
sg_cout_len = 1 + (FUZ_rand(&randState) % MAX_SG_BUFFERS);
// single source buffer
if (1 == sg_cin_len) {
sg_cin[0].sg_base = (BYTE*)srcBuffer+srcStart;
sg_cin[0].sg_len = srcSize;
DISPLAYUPDATE(4, "INFO: single source buf size %i\n", (int)srcSize);
}
else {
// multiple source buffers
if (srcSize > sg_cin_len*max_buf_size/2) {
srcSize = sg_cin_len*max_buf_size/2;
num_buf_size_distribution_deviations++;
DISPLAYUPDATE(4, "NOTE: source buffer total size deviation %i\n", (int)num_buf_size_distribution_deviations);
}
size_t exact_src_size = 0;
unsigned int buf_size_mean = srcSize / sg_cin_len;
for (i = 0; i < sg_cin_len; i++) {
size_t buf_size = rnd_exponential(buf_size_mean, min_src_buf_size, max_buf_size);
DISPLAYUPDATE(4, "INFO: source buf %i size %i\n", i, (int)buf_size);
if (srcStart+exact_src_size+buf_size > srcDataLength) {
buf_size = srcDataLength-(srcStart+exact_src_size);
}
sg_cin[i].sg_base = sg_in_buf_potential[i*2+1].sg_base;
sg_cin[i].sg_len = buf_size;
memcpy((void *)sg_cin[i].sg_base, (BYTE*)srcBuffer+srcStart+exact_src_size, buf_size);
exact_src_size += buf_size;
if (srcStart+exact_src_size == srcDataLength) {
num_buf_size_distribution_deviations++;
sg_cin_len = i+1;
DISPLAYUPDATE(4, "NOTE: final source buffer size deviation %i (buffers number limited to %i)\n", (int)num_buf_size_distribution_deviations, (int)sg_cin_len);
}
}
srcSize = exact_src_size;
}
// we can now derive the required limit for output
dstSizeBound = LZ4_SG_compressBound(srcSize, sg_cin_len, sg_cout_len);
// single target buffer
if (1 == sg_cout_len) {
sg_cout[0].sg_base = compressedBuffer;
sg_cout[0].sg_len = compressedBufferLength;
}
else {
// multiple target buffers
int finalBufferTruncated = 0;
dstSize = 0;
unsigned int buf_size_mean = dstSizeBound / sg_cout_len;
for (i = 0; i < sg_cout_len; i++) {
const size_t min_buf_size = (i == 0) ? min_first_dest_buf_size : min_dst_buf_size;
size_t buf_size = rnd_exponential(buf_size_mean, min_buf_size, max_buf_size);
DISPLAYUPDATE(4, "INFO: target buf %i size %i\n", (int)i, (int)buf_size);
if (dstSize+buf_size > dstSizeBound) {
buf_size = dstSizeBound-dstSize;
finalBufferTruncated = 1;
}
dstSize += buf_size;
sg_cout[i].sg_base = sg_out_buf_potential[i*2+1].sg_base;
sg_cout[i].sg_len = buf_size;
if (finalBufferTruncated) {
num_buf_size_distribution_deviations++;
if (buf_size < min_buf_size) {
// merge truncated with previous?
if (i > 0) {
sg_cout[i-1].sg_len += buf_size;
if (sg_cout[i-1].sg_len > max_buf_size) {
// skip, too much hassle
DISPLAYUPDATE(4, "NOTE: unable to truncate final target buffer size (deviations %i), skipping\n", (int)num_buf_size_distribution_deviations);
sg_cout_len = 0; break;
}
}
else {
// can this happen?
DISPLAYUPDATE(4, "NOTE: unable to truncate first and final target buffer size (deviations %i), skipping\n", (int)num_buf_size_distribution_deviations);
sg_cout_len = 0; break;
}
sg_cout_len = i;
}
else {
sg_cout_len = i+1;
}
DISPLAYUPDATE(4, "NOTE: final target buffer size truncated (%i), buffers number limited to %i, final's size is now %i (deviations %i)\n",
(int)buf_size, (int)sg_cout_len, (int)sg_cout[sg_cout_len-1].sg_len, (int)num_buf_size_distribution_deviations);
}
}
// skip/abort condition
if (0 == sg_cout_len) continue;
}
if ((buffer_selection & 0xF) == 0) {
//TODO: select a random input and output buffer and split it in two,
// feeding consecutive addresses as consecutive entries in SGL
}
}
crcOrig = XXH64((BYTE*)srcBuffer+srcStart, srcSize, 1);
size_t sourceSizeOut = srcSize;
result = LZ4_SG_compress(&sg_cin[0], sg_cin_len, &sg_cout[0], sg_cout_len, &sourceSizeOut, maxDstSize, DEFAULT_ACCEL);
if (((result == 0) || (sourceSizeOut != srcSize)) && (dstSize < dstSizeBound)) {
// forgive compression failure when output total size is lower than bound
num_buf_size_distribution_deviations++;
DISPLAYUPDATE(4, "NOTE: dstSize %i < %i dstSizeBound, compression attempt failed, not totally unexpected (deviations %i), skipping\n",
(int)dstSize, (int)dstSizeBound, (int)num_buf_size_distribution_deviations);
continue;
}
CHECK(result <= 0, "Compression failed (error %i)", (int)result);
CHECK(sourceSizeOut != srcSize, "Compression stopped at %i out of %i", (int)sourceSizeOut, (int)srcSize);
cSize = result;
}
else
{
// LZ4F compression - use it in order to verify SGL decompress compatibility with it
DISPLAYUPDATE(4, "INFO: LZ4F compression\n");
// alternative
// size_t dstMaxSize = LZ4F_compressFrameBound(srcSize, prefsPtr);
// DISPLAYLEVEL(3, "compressFrame srcSize %zu dstMaxSize %zu\n",
// srcSize, dstMaxSize);
// cSize = LZ4F_compressFrame(compressedBuffer, dstMaxSize, (char*)srcBuffer + srcStart, srcSize, prefsPtr);
// CHECK(LZ4F_isError(cSize), "LZ4F_compressFrame failed : error %i (%s)", (int)cSize, LZ4F_getErrorName(cSize));
crcOrig = XXH64((BYTE*)srcBuffer+srcStart, srcSize, 1);
unsigned BSId = 4 + (FUZ_rand(&randState) & 3);
unsigned BMId = FUZ_rand(&randState) & 1;
unsigned CCflag = FUZ_rand(&randState) & 1;
unsigned autoflush = (FUZ_rand(&randState) & 7) == 2;
U64 frameContentSize = ((FUZ_rand(&randState) & 0xF) == 1) ? srcSize : 0;
LZ4F_preferences_t prefs;
LZ4F_compressOptions_t cOptions;
LZ4F_preferences_t* prefsPtr = &prefs;
memset(&prefs, 0, sizeof(prefs));
memset(&cOptions, 0, sizeof(cOptions));
prefs.frameInfo.blockMode = (LZ4F_blockMode_t)BMId;
prefs.frameInfo.blockSizeID = (LZ4F_blockSizeID_t)BSId;
prefs.frameInfo.contentChecksumFlag = (LZ4F_contentChecksum_t)CCflag;
prefs.frameInfo.contentSize = frameContentSize;
prefs.autoFlush = autoflush;
prefs.compressionLevel = FUZ_rand(&randState) % 5;
if ((FUZ_rand(&randState) & 0xF) == 1) prefsPtr = NULL;
const BYTE* ip = (const BYTE*)srcBuffer + srcStart;
const BYTE* const iend = ip + srcSize;
BYTE* op = (BYTE*)compressedBuffer;
BYTE* const oend = op + LZ4F_compressFrameBound(srcDataLength, NULL);
unsigned maxBits = FUZ_highbit((U32)srcSize);
result = LZ4F_compressBegin(cCtx, op, oend-op, prefsPtr);
CHECK(LZ4F_isError(result), "Compression header failed (error %i)", (int)result);
op += result;
while (ip < iend)
{
unsigned nbBitsSeg = FUZ_rand(&randState) % maxBits;
size_t iSize = (FUZ_rand(&randState) & ((1<<nbBitsSeg)-1)) + 1;
size_t oSize = LZ4F_compressBound(iSize, prefsPtr);
unsigned forceFlush = ((FUZ_rand(&randState) & 3) == 1);
if (iSize > (size_t)(iend-ip)) iSize = iend-ip;
cOptions.stableSrc = ((FUZ_rand(&randState) & 3) == 1);
DISPLAYLEVEL(3, "compressUpdate ip %d iSize %zu oSize %zu forceFlush %d\n",
(int)(ip-((const BYTE*)srcBuffer + srcStart)), iSize, oSize, forceFlush);
result = LZ4F_compressUpdate(cCtx, op, oSize, ip, iSize, &cOptions);
CHECK(LZ4F_isError(result), "Compression failed (error %i)", (int)result);
op += result;
ip += iSize;
if (forceFlush)
{
result = LZ4F_flush(cCtx, op, oend-op, &cOptions);
CHECK(LZ4F_isError(result), "Compression failed (error %i)", (int)result);
op += result;
}
}
result = LZ4F_compressEnd(cCtx, op, oend-op, &cOptions);
CHECK(LZ4F_isError(result), "Compression completion failed (error %i)", (int)result);
op += result;
cSize = op-(BYTE*)compressedBuffer;
}
//DECOMPRESS
test_selection = FUZ_rand(&randState);
if (lz4f_compress_compatibility_test || ((test_selection % 2) == 0))
{
//TODO: SGL decompress with random buffer sizes
// SGL decompress with same buffer sizes used for compression
// prepare din with cout's data
sg_din_len = sg_cout_len;
for (i = 0; i < sg_din_len; i++) {
sg_din[i].sg_len = sg_cout[i].sg_len;
if (sg_cout[i].sg_len <= max_buf_size) {
// enough room to copy - do it
sg_din[i].sg_base = sg_in_buf_potential[i*2+0].sg_base;
if (sg_din[i].sg_base != sg_cout[i].sg_base) {
memcpy((void *)sg_din[i].sg_base, sg_cout[i].sg_base, sg_cout[i].sg_len);
}
}
else {
// this is probably single output buffer - skip copy, use directly
sg_din[i].sg_base = sg_cout[i].sg_base;
}
}
// prepare dout to receive decompressed data
sg_dout_len = sg_cin_len;
for (i = 0; i < sg_dout_len; i++) {
sg_dout[i].sg_len = sg_cin[i].sg_len;
if (sg_cin[i].sg_len <= max_buf_size) {
// enough room to decompress into independent buffer
sg_dout[i].sg_base = sg_out_buf_potential[i*2+0].sg_base;
}
else {
// this is probably single input buffer, use an external output buffer
sg_dout[i].sg_base = decodedBuffer;
}
}
size_t sourceSizeOut = cSize;
size_t maxOutputSize = srcSize;
int decomp_result = LZ4_SG_decompress(&sg_din[0], sg_din_len, &sg_dout[0], sg_dout_len, &sourceSizeOut, maxOutputSize);
CHECK(decomp_result <= 0, "SG decompression failed (error %i)", (int)decomp_result);
CHECK(decomp_result != (int)srcSize, "SG decompression stopped at %i", (int)decomp_result);
// verify result checksum
size_t total_checked = 0;
XXH64_reset(&xxh64, 1);
for (i = 0; (i < sg_dout_len) && ((int)total_checked < decomp_result); i++) {
size_t cur_size = sg_dout[i].sg_len;
size_t rem = decomp_result - total_checked;
if (rem < cur_size) cur_size = rem;
total_checked += cur_size;
XXH64_update(&xxh64, sg_dout[i].sg_base, cur_size);
}
crcDecoded = XXH64_digest(&xxh64);
if (crcDecoded != crcOrig) {
DISPLAYLEVEL(1, "checked %i out of %i (crcDecoded %08x, crcOrig %08x)\n",
(int)total_checked, decomp_result, (unsigned)crcDecoded, (unsigned)crcOrig);
// locate error if any
total_checked = 0;
for (i = 0; (i < sg_dout_len) && ((int)total_checked < decomp_result); i++) {
size_t cur_size = sg_dout[i].sg_len;
size_t rem = decomp_result - total_checked;
if (rem < cur_size) cur_size = rem;
total_checked += cur_size;
U64 crc_in = XXH64(sg_cin [i].sg_base, cur_size, 1);
U64 crc_out = XXH64(sg_dout[i].sg_base, cur_size, 1);
if (crc_in != crc_out) {
locateBuffDiff(sg_cin[i].sg_base, sg_dout[i].sg_base, cur_size);
break;
}
}
DISPLAYLEVEL(1, "checked %i out of %i\n",
(int)total_checked, decomp_result);
}
CHECK(crcDecoded != crcOrig, "Decompression corruption");
}
else
{
// prepare compressedBuffer from SGL
size_t total_copied = 0;
for (i = 0; i < sg_cout_len; i++) {
size_t buf_size_bytes = cSize - total_copied;
if (buf_size_bytes == 0) break;
if (buf_size_bytes > sg_cout[i].sg_len) buf_size_bytes = sg_cout[i].sg_len;
if (((char *)compressedBuffer)+total_copied != sg_cout[i].sg_base) {
memcpy(((char *)compressedBuffer)+total_copied, sg_cout[i].sg_base, buf_size_bytes);
}
total_copied += buf_size_bytes;
}
LZ4F_decompressOptions_t dOptions;
memset(&dOptions, 0, sizeof(dOptions));
const BYTE* ip = (const BYTE*)compressedBuffer;
const BYTE* const iend = ip + cSize;
BYTE* op = (BYTE*)decodedBuffer;
BYTE* const oend = op + srcDataLength;
size_t totalOut = 0;
unsigned maxBits = FUZ_highbit((U32)cSize);
XXH64_reset(&xxh64, 1);
if (maxBits < 3) maxBits = 3;
while (ip < iend)
{
unsigned nbBitsI = (FUZ_rand(&randState) % (maxBits-1)) + 1;
unsigned nbBitsO = (FUZ_rand(&randState) % (maxBits)) + 1;
size_t iSize = (FUZ_rand(&randState) & ((1<<nbBitsI)-1)) + 1;
size_t oSize = (FUZ_rand(&randState) & ((1<<nbBitsO)-1)) + 2;
if (iSize > (size_t)(iend-ip)) iSize = iend-ip;
if (oSize > (size_t)(oend-op)) oSize = oend-op;
dOptions.stableDst = FUZ_rand(&randState) & 1;
result = LZ4F_decompress(dCtx, op, &oSize, ip, &iSize, &dOptions);
if (result == (size_t)-LZ4F_ERROR_contentChecksum_invalid)
locateBuffDiff((BYTE*)srcBuffer+srcStart, decodedBuffer, srcSize);
CHECK(LZ4F_isError(result), "Decompression failed (error %i:%s ip %d)",
(int)result, LZ4F_getErrorName((LZ4F_errorCode_t)result), (int)(ip-(const BYTE*)compressedBuffer));
XXH64_update(&xxh64, op, (U32)oSize);
totalOut += oSize;
op += oSize;
ip += iSize;
}
CHECK(result != 0, "Frame decompression failed (error %i)", (int)result);
if (totalOut) /* otherwise, it's a skippable frame */
{
crcDecoded = XXH64_digest(&xxh64);
if (crcDecoded != crcOrig) locateBuffDiff((BYTE*)srcBuffer+srcStart, decodedBuffer, srcSize);
CHECK(crcDecoded != crcOrig, "Decompression corruption");
}
}
}
DISPLAYLEVEL(2, "\rAll tests completed \n");
_end:
LZ4F_freeDecompressionContext(dCtx);
LZ4F_freeCompressionContext(cCtx);
free(srcBuffer);
free(compressedBuffer);
free(decodedBuffer);
for (i = 0; i < NELEMS(sg_in_buf_potential); i++) {
free((void *)(sg_in_buf_potential [i].sg_base));
free( sg_out_buf_potential[i].sg_base);
}
if (num_buf_size_distribution_deviations > 0) {
DISPLAYLEVEL(2, "NOTE: %i buffer size deviations \n", (int)num_buf_size_distribution_deviations);
}
if (pause)
{
DISPLAY("press enter to finish \n");
(void)getchar();
}
return testResult;
_output_error:
testResult = 1;
goto _end;
// unreachable
return -1;
#undef CHECK
}
