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src: clang-format compress_*.cpp; minor cleanup

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Markus F.X.J. Oberhumer 2022-11-14 11:35:13 +01:00
parent 59e3b1f98d
commit eb231b65f3
4 changed files with 329 additions and 359 deletions
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1
src/Makefile
View File

@ -74,6 +74,7 @@ endif
# automatically format some C++ source code files
ifeq ($(shell uname),Linux)
CLANG_FORMAT_FILES += bele.h bele_policy.h
CLANG_FORMAT_FILES += compress_lzma.cpp compress_ucl.cpp compress_zlib.cpp
CLANG_FORMAT_FILES += except.cpp except.h
CLANG_FORMAT_FILES += file.cpp file.h
CLANG_FORMAT_FILES += linker.cpp linker.h packhead.cpp packmast.cpp packmast.h

326
src/compress_lzma.cpp
View File

@ -25,27 +25,24 @@
<markus@oberhumer.com> <ezerotven+github@gmail.com>
*/
#include "conf.h"
#include "compress.h"
#include "util/membuffer.h"
#if (ACC_CC_CLANG)
# pragma clang diagnostic ignored "-Wshadow"
#pragma clang diagnostic ignored "-Wshadow"
#endif
#if (ACC_CC_GNUC >= 0x040200)
# pragma GCC diagnostic ignored "-Wshadow"
#pragma GCC diagnostic ignored "-Wshadow"
#endif
#if (ACC_CC_MSC)
# pragma warning(disable: 4456) // -Wno-shadow
#pragma warning(disable : 4456) // -Wno-shadow
#endif
#if (ACC_CC_MSC && (_MSC_VER < 1900))
# pragma warning(disable: 4127) // warning C4127: conditional expression is constant
#pragma warning(disable : 4127) // warning C4127: conditional expression is constant
#endif
void lzma_compress_config_t::reset()
{
void lzma_compress_config_t::reset() {
pos_bits.reset();
lit_pos_bits.reset();
lit_context_bits.reset();
@ -57,7 +54,6 @@ void lzma_compress_config_t::reset()
max_num_probs = 0;
}
// INFO: the LZMA SDK is covered by a permissive license which allows
// using unmodified LZMA source code in UPX and the UPX stubs.
// See SPECIAL EXCEPTION below.
@ -94,34 +90,31 @@ void lzma_compress_config_t::reset()
// SPECIAL EXCEPTION allows you to use LZMA SDK in applications with closed code,
// while you keep LZMA SDK code unmodified.
/*************************************************************************
// compress defaults
**************************************************************************/
static int prepare(lzma_compress_result_t *res,
unsigned src_len, int method, int level,
const lzma_compress_config_t *lcconf)
{
static bool prepare_result(lzma_compress_result_t *res, unsigned src_len, int method, int level,
const lzma_compress_config_t *lcconf) {
// setup defaults
res->pos_bits = 2; // 0 .. 4
res->lit_pos_bits = 0; // 0 .. 4
res->lit_context_bits = 3; // 0 .. 8
res->dict_size = 4 * 1024 * 1024; // 1 .. 2**30
res->fast_mode = 2;
res->num_fast_bytes = 64; // 5 .. 273
res->pos_bits = 2; // 0 .. 4
res->lit_pos_bits = 0; // 0 .. 4
res->lit_context_bits = 3; // 0 .. 8
res->dict_size = 4 * 1024 * 1024; // 1 .. 2**30
res->fast_mode = 2; // 0 .. 2
res->num_fast_bytes = 64; // 5 .. 273
res->match_finder_cycles = 0;
// UPX overrides
res->pos_bits = lzma_compress_config_t::pos_bits_t::default_value;
res->lit_pos_bits = lzma_compress_config_t::lit_pos_bits_t::default_value;
res->lit_context_bits = lzma_compress_config_t::lit_context_bits_t::default_value;
res->dict_size = lzma_compress_config_t::dict_size_t::default_value;
res->num_fast_bytes = lzma_compress_config_t::num_fast_bytes_t::default_value;
res->pos_bits = lzma_compress_config_t::pos_bits_t::default_value;
res->lit_pos_bits = lzma_compress_config_t::lit_pos_bits_t::default_value;
res->lit_context_bits = lzma_compress_config_t::lit_context_bits_t::default_value;
res->dict_size = lzma_compress_config_t::dict_size_t::default_value;
res->num_fast_bytes = lzma_compress_config_t::num_fast_bytes_t::default_value;
// method overrides
if (method >= 0x100) {
res->pos_bits = (method >> 16) & 15;
res->lit_pos_bits = (method >> 12) & 15;
res->lit_context_bits = (method >> 8) & 15;
res->pos_bits = (method >> 16) & 15;
res->lit_pos_bits = (method >> 12) & 15;
res->lit_context_bits = (method >> 8) & 15;
}
#if 0
// DEBUG - set sizes so that we use a maxmimum amount of stack.
@ -132,16 +125,15 @@ static int prepare(lzma_compress_result_t *res,
#endif
// TODO: tune these settings according to level
switch (level)
{
switch (level) {
case 1:
res->dict_size = 256 * 1024;
res->fast_mode = 0;
res->dict_size = 256 * 1024;
res->fast_mode = 0;
res->num_fast_bytes = 8;
break;
case 2:
res->dict_size = 256 * 1024;
res->fast_mode = 0;
res->dict_size = 256 * 1024;
res->fast_mode = 0;
break;
case 3:
break;
@ -156,18 +148,17 @@ static int prepare(lzma_compress_result_t *res,
case 8:
break;
case 9:
res->dict_size = 8 * 1024 * 1024;
res->dict_size = 8 * 1024 * 1024;
break;
case 10:
res->dict_size = src_len;
res->dict_size = src_len;
break;
default:
goto error;
}
// cconf overrides
if (lcconf)
{
if (lcconf) {
oassign(res->pos_bits, lcconf->pos_bits);
oassign(res->lit_pos_bits, lcconf->lit_pos_bits);
oassign(res->lit_context_bits, lcconf->lit_context_bits);
@ -180,21 +171,16 @@ static int prepare(lzma_compress_result_t *res,
res->dict_size = src_len;
// limit num_probs
if (lcconf && lcconf->max_num_probs)
{
for (;;)
{
if (lcconf && lcconf->max_num_probs) {
for (;;) {
unsigned n = 1846 + (768u << (res->lit_context_bits + res->lit_pos_bits));
if (n <= lcconf->max_num_probs)
break;
if (res->lit_pos_bits > res->lit_context_bits)
{
if (res->lit_pos_bits > res->lit_context_bits) {
if (res->lit_pos_bits == 0)
goto error;
res->lit_pos_bits -= 1;
}
else
{
} else {
if (res->lit_context_bits == 0)
goto error;
res->lit_context_bits -= 1;
@ -209,14 +195,14 @@ static int prepare(lzma_compress_result_t *res,
lzma_compress_config_t::num_fast_bytes_t::assertValue(res->num_fast_bytes);
res->num_probs = 1846 + (768u << (res->lit_context_bits + res->lit_pos_bits));
//printf("\nlzma_compress config: %u %u %u %u %u\n", res->pos_bits, res->lit_pos_bits, res->lit_context_bits, res->dict_size, res->num_probs);
return 0;
// printf("\nlzma_compress config: %u %u %u %u %u\n", res->pos_bits, res->lit_pos_bits,
// res->lit_context_bits, res->dict_size, res->num_probs);
return true;
error:
return -1;
return false;
}
/*************************************************************************
// compress - cruft because of pseudo-COM layer
**************************************************************************/
@ -235,69 +221,80 @@ error:
namespace MyLzma {
struct InStream: public ISequentialInStream, public CMyUnknownImp
{
virtual ~InStream() { }
struct InStream : public ISequentialInStream, public CMyUnknownImp {
virtual ~InStream() {}
MY_UNKNOWN_IMP
const Byte *b_buf; size_t b_size; size_t b_pos;
const Byte *b_buf;
size_t b_size;
size_t b_pos;
void Init(const Byte *data, size_t size) {
b_buf = data; b_size = size; b_pos = 0;
b_buf = data;
b_size = size;
b_pos = 0;
}
STDMETHOD(Read)(void *data, UInt32 size, UInt32 *processedSize) override;
};
STDMETHODIMP InStream::Read(void *data, UInt32 size, UInt32 *processedSize)
{
STDMETHODIMP InStream::Read(void *data, UInt32 size, UInt32 *processedSize) {
size_t remain = b_size - b_pos;
if (size > remain) size = (UInt32) remain;
if (size > remain)
size = (UInt32) remain;
memmove(data, b_buf + b_pos, size);
b_pos += size;
if (processedSize != nullptr) *processedSize = size;
if (processedSize != nullptr)
*processedSize = size;
return S_OK;
}
struct OutStream : public ISequentialOutStream, public CMyUnknownImp
{
virtual ~OutStream() { }
struct OutStream : public ISequentialOutStream, public CMyUnknownImp {
virtual ~OutStream() {}
MY_UNKNOWN_IMP
Byte *b_buf; size_t b_size; size_t b_pos; bool overflow;
Byte *b_buf;
size_t b_size;
size_t b_pos;
bool overflow;
void Init(Byte *data, size_t size) {
b_buf = data; b_size = size; b_pos = 0; overflow = false;
b_buf = data;
b_size = size;
b_pos = 0;
overflow = false;
}
HRESULT WriteByte(Byte c) {
if (b_pos >= b_size) { overflow = true; return E_FAIL; }
if (b_pos >= b_size) {
overflow = true;
return E_FAIL;
}
b_buf[b_pos++] = c;
return S_OK;
}
STDMETHOD(Write)(const void *data, UInt32 size, UInt32 *processedSize) override;
};
STDMETHODIMP OutStream::Write(const void *data, UInt32 size, UInt32 *processedSize)
{
STDMETHODIMP OutStream::Write(const void *data, UInt32 size, UInt32 *processedSize) {
size_t remain = b_size - b_pos;
if (size > remain) size = (UInt32) remain, overflow = true;
if (size > remain)
size = (UInt32) remain, overflow = true;
memmove(b_buf + b_pos, data, size);
b_pos += size;
if (processedSize != nullptr) *processedSize = size;
if (processedSize != nullptr)
*processedSize = size;
return overflow ? E_FAIL : S_OK;
}
struct ProgressInfo : public ICompressProgressInfo, public CMyUnknownImp
{
virtual ~ProgressInfo() { }
struct ProgressInfo : public ICompressProgressInfo, public CMyUnknownImp {
virtual ~ProgressInfo() {}
MY_UNKNOWN_IMP
STDMETHOD(SetRatioInfo)(const UInt64 *inSize, const UInt64 *outSize) override;
upx_callback_p cb;
};
STDMETHODIMP ProgressInfo::SetRatioInfo(const UInt64 *inSize, const UInt64 *outSize)
{
STDMETHODIMP ProgressInfo::SetRatioInfo(const UInt64 *inSize, const UInt64 *outSize) {
if (cb && cb->nprogress)
cb->nprogress(cb, (unsigned) *inSize, (unsigned) *outSize);
return S_OK;
}
} // namespace
} // namespace MyLzma
#include <lzma-sdk/C/Common/Alloc.cpp>
#include <lzma-sdk/C/Common/CRC.cpp>
@ -311,50 +308,46 @@ STDMETHODIMP ProgressInfo::SetRatioInfo(const UInt64 *inSize, const UInt64 *outS
#include <lzma-sdk/C/7zip/Compress/RangeCoder/RangeCoderBit.cpp>
#undef RC_NORMALIZE
int upx_lzma_compress ( const upx_bytep src, unsigned src_len,
upx_bytep dst, unsigned* dst_len,
upx_callback_p cb,
int method, int level,
const upx_compress_config_t *cconf_parm,
upx_compress_result_t *cresult )
{
int upx_lzma_compress(const upx_bytep src, unsigned src_len, upx_bytep dst, unsigned *dst_len,
upx_callback_p cb, int method, int level,
const upx_compress_config_t *cconf_parm, upx_compress_result_t *cresult) {
assert(M_IS_LZMA(method));
assert(level > 0); assert(cresult != nullptr);
assert(level > 0);
assert(cresult != nullptr);
int r = UPX_E_ERROR;
HRESULT rh;
const lzma_compress_config_t *lcconf = cconf_parm ? &cconf_parm->conf_lzma : nullptr;
lzma_compress_result_t *res = &cresult->result_lzma;
const lzma_compress_config_t *const lcconf = cconf_parm ? &cconf_parm->conf_lzma : nullptr;
lzma_compress_result_t *const res = &cresult->result_lzma;
MyLzma::InStream is; is.AddRef();
MyLzma::OutStream os; os.AddRef();
MyLzma::InStream is;
is.AddRef();
MyLzma::OutStream os;
os.AddRef();
is.Init(src, src_len);
os.Init(dst, *dst_len);
MyLzma::ProgressInfo progress; progress.AddRef();
MyLzma::ProgressInfo progress;
progress.AddRef();
progress.cb = cb;
NCompress::NLZMA::CEncoder enc;
const PROPID propIDs[8] = {
NCoderPropID::kPosStateBits, // 0 pb _posStateBits(2)
NCoderPropID::kLitPosBits, // 1 lp _numLiteralPosStateBits(0)
NCoderPropID::kLitContextBits, // 2 lc _numLiteralContextBits(3)
NCoderPropID::kDictionarySize, // 3 ds
NCoderPropID::kAlgorithm, // 4 fm _fastmode
NCoderPropID::kNumFastBytes, // 5 fb
NCoderPropID::kMatchFinderCycles, // 6 mfc _matchFinderCycles, _cutValue
NCoderPropID::kMatchFinder // 7 mf
NCoderPropID::kPosStateBits, // 0 pb _posStateBits(2)
NCoderPropID::kLitPosBits, // 1 lp _numLiteralPosStateBits(0)
NCoderPropID::kLitContextBits, // 2 lc _numLiteralContextBits(3)
NCoderPropID::kDictionarySize, // 3 ds
NCoderPropID::kAlgorithm, // 4 fm _fastmode
NCoderPropID::kNumFastBytes, // 5 fb
NCoderPropID::kMatchFinderCycles, // 6 mfc _matchFinderCycles, _cutValue
NCoderPropID::kMatchFinder // 7 mf
};
PROPVARIANT pr[8];
const unsigned nprops = 8;
static const wchar_t matchfinder[] = L"BT4";
assert(NCompress::NLZMA::FindMatchFinder(matchfinder) >= 0);
pr[7].vt = VT_BSTR; pr[7].bstrVal = ACC_PCAST(BSTR, ACC_UNCONST_CAST(wchar_t *, matchfinder));
pr[0].vt = pr[1].vt = pr[2].vt = pr[3].vt = VT_UI4;
pr[4].vt = pr[5].vt = pr[6].vt = VT_UI4;
if (prepare(res, src_len, method, level, lcconf) != 0)
if (!prepare_result(res, src_len, method, level, lcconf))
goto error;
pr[0].vt = pr[1].vt = pr[2].vt = pr[3].vt = pr[4].vt = pr[5].vt = pr[6].vt = VT_UI4;
pr[7].vt = VT_BSTR;
pr[0].uintVal = res->pos_bits;
pr[1].uintVal = res->lit_pos_bits;
pr[2].uintVal = res->lit_context_bits;
@ -362,55 +355,59 @@ int upx_lzma_compress ( const upx_bytep src, unsigned src_len,
pr[4].uintVal = res->fast_mode;
pr[5].uintVal = res->num_fast_bytes;
pr[6].uintVal = res->match_finder_cycles;
static const wchar_t matchfinder[] = L"BT4";
assert(NCompress::NLZMA::FindMatchFinder(matchfinder) >= 0);
pr[7].bstrVal = ACC_PCAST(BSTR, ACC_UNCONST_CAST(wchar_t *, matchfinder));
try {
if (enc.SetCoderProperties(propIDs, pr, nprops) != S_OK)
goto error;
// encode properties in LZMA-style (5 bytes)
if (enc.WriteCoderProperties(&os) != S_OK)
goto error;
if (os.overflow) {
// r = UPX_E_OUTPUT_OVERRUN;
r = UPX_E_NOT_COMPRESSIBLE;
goto error;
}
assert(os.b_pos == 5);
if (enc.SetCoderProperties(propIDs, pr, nprops) != S_OK)
goto error;
if (enc.WriteCoderProperties(&os) != S_OK)
goto error;
if (os.overflow) {
//r = UPX_E_OUTPUT_OVERRUN;
r = UPX_E_NOT_COMPRESSIBLE;
goto error;
}
assert(os.b_pos == 5);
os.b_pos = 0;
// extra stuff in first byte: 5 high bits convenience for stub decompressor
unsigned t = res->lit_context_bits + res->lit_pos_bits;
os.WriteByte(Byte((t << 3) | res->pos_bits));
os.WriteByte(Byte((res->lit_pos_bits << 4) | (res->lit_context_bits)));
// reset and encode properties in UPX-style (2 bytes)
os.b_pos = 0;
// UPX extra stuff in first byte: 5 high bits convenience for stub decompressor
unsigned t = res->lit_context_bits + res->lit_pos_bits;
os.WriteByte(Byte((t << 3) | res->pos_bits));
os.WriteByte(Byte((res->lit_pos_bits << 4) | (res->lit_context_bits)));
rh = enc.Code(&is, &os, nullptr, nullptr, &progress);
// compress
rh = enc.Code(&is, &os, nullptr, nullptr, &progress);
} catch (...) {
rh = E_OUTOFMEMORY;
}
assert(is.b_pos <= src_len);
assert(is.b_pos <= src_len);
assert(os.b_pos <= *dst_len);
if (rh == E_OUTOFMEMORY)
r = UPX_E_OUT_OF_MEMORY;
else if (os.overflow)
{
else if (os.overflow) {
assert(os.b_pos == *dst_len);
//r = UPX_E_OUTPUT_OVERRUN;
// r = UPX_E_OUTPUT_OVERRUN;
r = UPX_E_NOT_COMPRESSIBLE;
}
else if (rh == S_OK)
{
} else if (rh == S_OK) {
assert(is.b_pos == src_len);
r = UPX_E_OK;
}
error:
*dst_len = (unsigned) os.b_pos;
//printf("\nlzma_compress: %d: %u %u %u %u %u, %u - > %u\n", r, res->pos_bits, res->lit_pos_bits, res->lit_context_bits, res->dict_size, res->num_probs, src_len, *dst_len);
//printf("%u %u %u\n", is.__m_RefCount, os.__m_RefCount, progress.__m_RefCount);
// printf("\nlzma_compress: %d: %u %u %u %u %u, %u - > %u\n", r, res->pos_bits,
// res->lit_pos_bits,
// res->lit_context_bits, res->dict_size, res->num_probs, src_len, *dst_len);
// printf("%u %u %u\n", is.__m_RefCount, os.__m_RefCount, progress.__m_RefCount);
return r;
}
/*************************************************************************
// decompress
**************************************************************************/
@ -422,22 +419,21 @@ error:
#include <lzma-sdk/C/7zip/Compress/LZMA_C/LzmaDecode.h>
#include <lzma-sdk/C/7zip/Compress/LZMA_C/LzmaDecode.c>
int upx_lzma_decompress ( const upx_bytep src, unsigned src_len,
upx_bytep dst, unsigned* dst_len,
int method,
const upx_compress_result_t *cresult )
{
int upx_lzma_decompress(const upx_bytep src, unsigned src_len, upx_bytep dst, unsigned *dst_len,
int method, const upx_compress_result_t *cresult) {
assert(M_IS_LZMA(method));
// see res->num_probs above
COMPILE_TIME_ASSERT(sizeof(CProb) == 2)
COMPILE_TIME_ASSERT(LZMA_BASE_SIZE == 1846)
COMPILE_TIME_ASSERT(LZMA_LIT_SIZE == 768)
CLzmaDecoderState s; memset(&s, 0, sizeof(s));
CLzmaDecoderState s;
memset(&s, 0, sizeof(s));
SizeT src_out = 0, dst_out = 0;
int r = UPX_E_ERROR;
int rh;
// decode UPX-style properties (2 bytes)
if (src_len < 3) {
r = UPX_E_INPUT_OVERRUN;
goto error;
@ -445,39 +441,42 @@ int upx_lzma_decompress ( const upx_bytep src, unsigned src_len,
s.Properties.pb = src[0] & 7;
s.Properties.lp = (src[1] >> 4);
s.Properties.lc = src[1] & 15;
if (s.Properties.pb >= 5) goto error;
if (s.Properties.lp >= 5) goto error;
if (s.Properties.lc >= 9) goto error;
// extra
if ((src[0] >> 3) != s.Properties.lc + s.Properties.lp) goto error;
src += 2; src_len -= 2;
if (s.Properties.pb >= 5)
goto error;
if (s.Properties.lp >= 5)
goto error;
if (s.Properties.lc >= 9)
goto error;
// UPX extra stuff in first byte: 5 high bits convenience for stub decompressor
if ((src[0] >> 3) != s.Properties.lc + s.Properties.lp)
goto error;
src += 2;
src_len -= 2;
if (cresult)
{
if (cresult) {
assert(cresult->method == method);
assert(cresult->result_lzma.pos_bits == (unsigned) s.Properties.pb);
assert(cresult->result_lzma.lit_pos_bits == (unsigned) s.Properties.lp);
assert(cresult->result_lzma.lit_context_bits == (unsigned) s.Properties.lc);
assert(cresult->result_lzma.num_probs == (unsigned) LzmaGetNumProbs(&s.Properties));
const lzma_compress_result_t *res = &cresult->result_lzma;
// printf("\nlzma_decompress config: %u %u %u %u %u\n", res->pos_bits, res->lit_pos_bits,
// res->lit_context_bits, res->dict_size, res->num_probs);
UNUSED(res);
//printf("\nlzma_decompress config: %u %u %u %u %u\n", res->pos_bits, res->lit_pos_bits, res->lit_context_bits, res->dict_size, res->num_probs);
}
s.Probs = (CProb *) malloc(sizeof(CProb) * LzmaGetNumProbs(&s.Properties));
if (!s.Probs)
{
if (!s.Probs) {
r = UPX_E_OUT_OF_MEMORY;
goto error;
}
rh = LzmaDecode(&s, src, src_len, &src_out, dst, *dst_len, &dst_out);
assert(src_out <= src_len);
assert(src_out <= src_len);
assert(dst_out <= *dst_len);
if (rh == 0) {
r = UPX_E_OK;
if (src_out != src_len)
r = UPX_E_INPUT_NOT_CONSUMED;
}
else if (rh == LZMA_RESULT_INPUT_OVERRUN)
} else if (rh == LZMA_RESULT_INPUT_OVERRUN)
r = UPX_E_INPUT_OVERRUN;
else if (rh == LZMA_RESULT_OUTPUT_OVERRUN)
r = UPX_E_OUTPUT_OVERRUN;
@ -488,24 +487,20 @@ error:
return r;
}
/*************************************************************************
// test_overlap - see <ucl/ucl.h> for semantics
**************************************************************************/
int upx_lzma_test_overlap ( const upx_bytep buf,
const upx_bytep tbuf,
unsigned src_off, unsigned src_len,
unsigned* dst_len,
int method,
const upx_compress_result_t *cresult )
{
int upx_lzma_test_overlap(const upx_bytep buf, const upx_bytep tbuf, unsigned src_off,
unsigned src_len, unsigned *dst_len, int method,
const upx_compress_result_t *cresult) {
assert(M_IS_LZMA(method));
MemBuffer b(src_off + src_len);
memcpy(b + src_off, buf + src_off, src_len);
unsigned saved_dst_len = *dst_len;
int r = upx_lzma_decompress(raw_index_bytes(b, src_off, src_len), src_len, raw_bytes(b, *dst_len), dst_len, method, cresult);
int r = upx_lzma_decompress(raw_index_bytes(b, src_off, src_len), src_len,
raw_bytes(b, *dst_len), dst_len, method, cresult);
if (r != UPX_E_OK)
return r;
if (*dst_len != saved_dst_len)
@ -518,22 +513,17 @@ int upx_lzma_test_overlap ( const upx_bytep buf,
return UPX_E_OK;
}
/*************************************************************************
// misc
**************************************************************************/
int upx_lzma_init(void)
{
return 0;
}
int upx_lzma_init(void) { return 0; }
const char *upx_lzma_version_string(void)
{
const char *upx_lzma_version_string(void) {
#if (WITH_LZMA == 0x443)
return "4.43";
#else
# error "unknown WITH_LZMA version"
#error "unknown WITH_LZMA version"
return nullptr;
#endif
}
@ -549,7 +539,7 @@ TEST_CASE("upx_lzma_decompress") {
unsigned d_len;
int r;
c_data = (C*) "\x1a\x03\x00\x7f\xed\x3c\x00\x00\x00";
c_data = (C *) "\x1a\x03\x00\x7f\xed\x3c\x00\x00\x00";
d_len = 16;
r = upx_lzma_decompress(c_data, 9, d_buf, &d_len, M_LZMA, nullptr);
CHECK((r == 0 && d_len == 16));

223
src/compress_ucl.cpp
View File

@ -25,60 +25,62 @@
<markus@oberhumer.com> <ezerotven+github@gmail.com>
*/
#include "conf.h"
#include "compress.h"
/*************************************************************************
//
**************************************************************************/
static int convert_errno_from_ucl(int r)
{
switch (r)
{
case UCL_E_OK: return UPX_E_OK;
case UCL_E_ERROR: return UPX_E_ERROR;
case UCL_E_OUT_OF_MEMORY: return UPX_E_OUT_OF_MEMORY;
case UCL_E_NOT_COMPRESSIBLE: return UPX_E_NOT_COMPRESSIBLE;
case UCL_E_INPUT_OVERRUN: return UPX_E_INPUT_OVERRUN;
case UCL_E_OUTPUT_OVERRUN: return UPX_E_OUTPUT_OVERRUN;
case UCL_E_LOOKBEHIND_OVERRUN: return UPX_E_LOOKBEHIND_OVERRUN;
case UCL_E_EOF_NOT_FOUND: return UPX_E_EOF_NOT_FOUND;
case UCL_E_INPUT_NOT_CONSUMED: return UPX_E_INPUT_NOT_CONSUMED;
// case UCL_E_NOT_YET_IMPLEMENTED: return UPX_E_NOT_YET_IMPLEMENTED;
case UCL_E_INVALID_ARGUMENT: return UPX_E_INVALID_ARGUMENT;
static int convert_errno_from_ucl(int r) {
switch (r) {
case UCL_E_OK:
return UPX_E_OK;
case UCL_E_ERROR:
return UPX_E_ERROR;
case UCL_E_OUT_OF_MEMORY:
return UPX_E_OUT_OF_MEMORY;
case UCL_E_NOT_COMPRESSIBLE:
return UPX_E_NOT_COMPRESSIBLE;
case UCL_E_INPUT_OVERRUN:
return UPX_E_INPUT_OVERRUN;
case UCL_E_OUTPUT_OVERRUN:
return UPX_E_OUTPUT_OVERRUN;
case UCL_E_LOOKBEHIND_OVERRUN:
return UPX_E_LOOKBEHIND_OVERRUN;
case UCL_E_EOF_NOT_FOUND:
return UPX_E_EOF_NOT_FOUND;
case UCL_E_INPUT_NOT_CONSUMED:
return UPX_E_INPUT_NOT_CONSUMED;
case UCL_E_INVALID_ARGUMENT:
return UPX_E_INVALID_ARGUMENT;
// UCL extra:
case UCL_E_OVERLAP_OVERRUN: return UPX_E_ERROR;
case UCL_E_OVERLAP_OVERRUN:
return UPX_E_ERROR;
}
return UPX_E_ERROR;
}
extern "C" {
static void __UCL_CDECL wrap_nprogress_ucl(ucl_uint a, ucl_uint b, int state, ucl_voidp user)
{
if (state != -1 && state != 3) return;
static void __UCL_CDECL wrap_nprogress_ucl(ucl_uint a, ucl_uint b, int state, ucl_voidp user) {
if (state != -1 && state != 3)
return;
upx_callback_p cb = (upx_callback_p) user;
if (cb && cb->nprogress)
cb->nprogress(cb, a, b);
}}
}
}
/*************************************************************************
//
**************************************************************************/
int upx_ucl_compress ( const upx_bytep src, unsigned src_len,
upx_bytep dst, unsigned* dst_len,
upx_callback_p cb_parm,
int method, int level,
const upx_compress_config_t *cconf_parm,
upx_compress_result_t *cresult )
{
int upx_ucl_compress(const upx_bytep src, unsigned src_len, upx_bytep dst, unsigned *dst_len,
upx_callback_p cb_parm, int method, int level,
const upx_compress_config_t *cconf_parm, upx_compress_result_t *cresult) {
int r;
assert(level > 0); assert(cresult != nullptr);
assert(level > 0);
assert(cresult != nullptr);
COMPILE_TIME_ASSERT(sizeof(ucl_compress_config_t) == sizeof(REAL_ucl_compress_config_t))
@ -90,49 +92,47 @@ int upx_ucl_compress ( const upx_bytep src, unsigned src_len,
cb.user = cb_parm;
}
ucl_compress_config_t cconf; cconf.reset();
if (cconf_parm)
memcpy(&cconf, &cconf_parm->conf_ucl, sizeof(cconf)); // cconf = cconf_parm->conf_ucl; // struct copy
ucl_compress_config_t cconf;
cconf.reset();
if (cconf_parm) {
// cconf = cconf_parm->conf_ucl; // struct copy
memcpy(&cconf, &cconf_parm->conf_ucl, sizeof(cconf));
}
ucl_uint *res = cresult->result_ucl.result;
ucl_uint *const res = cresult->result_ucl.result;
// assume no info available - fill in worst case results
//res[0] = 1; // min_offset_found - NOT USED
res[1] = src_len - 1; // max_offset_found
//res[2] = 2; // min_match_found - NOT USED
res[3] = src_len - 1; // max_match_found
//res[4] = 1; // min_run_found - NOT USED
res[5] = src_len; // max_run_found
res[6] = 1; // first_offset_found
//res[7] = 999999; // same_match_offsets_found - NOT USED
// res[0] = 1; // min_offset_found - NOT USED
res[1] = src_len - 1; // max_offset_found
// res[2] = 2; // min_match_found - NOT USED
res[3] = src_len - 1; // max_match_found
// res[4] = 1; // min_run_found - NOT USED
res[5] = src_len; // max_run_found
res[6] = 1; // first_offset_found
// res[7] = 999999; // same_match_offsets_found - NOT USED
// prepare bit-buffer settings
cconf.bb_endian = 0;
cconf.bb_size = 0;
if (method >= M_NRV2B_LE32 && method <= M_NRV2E_LE16)
{
if (method >= M_NRV2B_LE32 && method <= M_NRV2E_LE16) {
static const unsigned char sizes[3] = {32, 8, 16};
cconf.bb_size = sizes[(method - M_NRV2B_LE32) % 3];
}
else {
} else {
throwInternalError("unknown compression method");
return UPX_E_ERROR;
}
// optimize compression parms
if (level <= 3 && cconf.max_offset == UCL_UINT_MAX)
cconf.max_offset = 8*1024-1;
cconf.max_offset = 8 * 1024 - 1;
else if (level == 4 && cconf.max_offset == UCL_UINT_MAX)
cconf.max_offset = 32*1024-1;
cconf.max_offset = 32 * 1024 - 1;
if M_IS_NRV2B(method)
r = ucl_nrv2b_99_compress(src, src_len, dst, dst_len,
&cb, level, &cconf, res);
else if M_IS_NRV2D(method)
r = ucl_nrv2d_99_compress(src, src_len, dst, dst_len,
&cb, level, &cconf, res);
else if M_IS_NRV2E(method)
r = ucl_nrv2e_99_compress(src, src_len, dst, dst_len,
&cb, level, &cconf, res);
if M_IS_NRV2B (method)
r = ucl_nrv2b_99_compress(src, src_len, dst, dst_len, &cb, level, &cconf, res);
else if M_IS_NRV2D (method)
r = ucl_nrv2d_99_compress(src, src_len, dst, dst_len, &cb, level, &cconf, res);
else if M_IS_NRV2E (method)
r = ucl_nrv2e_99_compress(src, src_len, dst, dst_len, &cb, level, &cconf, res);
else {
throwInternalError("unknown compression method");
return UPX_E_ERROR;
@ -145,46 +145,41 @@ int upx_ucl_compress ( const upx_bytep src, unsigned src_len,
return convert_errno_from_ucl(r);
}
/*************************************************************************
//
**************************************************************************/
int upx_ucl_decompress ( const upx_bytep src, unsigned src_len,
upx_bytep dst, unsigned* dst_len,
int method,
const upx_compress_result_t *cresult )
{
int upx_ucl_decompress(const upx_bytep src, unsigned src_len, upx_bytep dst, unsigned *dst_len,
int method, const upx_compress_result_t *cresult) {
int r;
switch (method)
{
switch (method) {
case M_NRV2B_8:
r = ucl_nrv2b_decompress_safe_8(src,src_len,dst,dst_len,nullptr);
r = ucl_nrv2b_decompress_safe_8(src, src_len, dst, dst_len, nullptr);
break;
case M_NRV2B_LE16:
r = ucl_nrv2b_decompress_safe_le16(src,src_len,dst,dst_len,nullptr);
r = ucl_nrv2b_decompress_safe_le16(src, src_len, dst, dst_len, nullptr);
break;
case M_NRV2B_LE32:
r = ucl_nrv2b_decompress_safe_le32(src,src_len,dst,dst_len,nullptr);
r = ucl_nrv2b_decompress_safe_le32(src, src_len, dst, dst_len, nullptr);
break;
case M_NRV2D_8:
r = ucl_nrv2d_decompress_safe_8(src,src_len,dst,dst_len,nullptr);
r = ucl_nrv2d_decompress_safe_8(src, src_len, dst, dst_len, nullptr);
break;
case M_NRV2D_LE16:
r = ucl_nrv2d_decompress_safe_le16(src,src_len,dst,dst_len,nullptr);
r = ucl_nrv2d_decompress_safe_le16(src, src_len, dst, dst_len, nullptr);
break;
case M_NRV2D_LE32:
r = ucl_nrv2d_decompress_safe_le32(src,src_len,dst,dst_len,nullptr);
r = ucl_nrv2d_decompress_safe_le32(src, src_len, dst, dst_len, nullptr);
break;
case M_NRV2E_8:
r = ucl_nrv2e_decompress_safe_8(src,src_len,dst,dst_len,nullptr);
r = ucl_nrv2e_decompress_safe_8(src, src_len, dst, dst_len, nullptr);
break;
case M_NRV2E_LE16:
r = ucl_nrv2e_decompress_safe_le16(src,src_len,dst,dst_len,nullptr);
r = ucl_nrv2e_decompress_safe_le16(src, src_len, dst, dst_len, nullptr);
break;
case M_NRV2E_LE32:
r = ucl_nrv2e_decompress_safe_le32(src,src_len,dst,dst_len,nullptr);
r = ucl_nrv2e_decompress_safe_le32(src, src_len, dst, dst_len, nullptr);
break;
default:
throwInternalError("unknown decompression method");
@ -195,49 +190,43 @@ int upx_ucl_decompress ( const upx_bytep src, unsigned src_len,
return convert_errno_from_ucl(r);
}
/*************************************************************************
//
**************************************************************************/
int upx_ucl_test_overlap ( const upx_bytep buf,
const upx_bytep tbuf,
unsigned src_off, unsigned src_len,
unsigned* dst_len,
int method,
const upx_compress_result_t *cresult )
{
int upx_ucl_test_overlap(const upx_bytep buf, const upx_bytep tbuf, unsigned src_off,
unsigned src_len, unsigned *dst_len, int method,
const upx_compress_result_t *cresult) {
int r;
UNUSED(tbuf); // not needed for UCL
switch (method)
{
switch (method) {
case M_NRV2B_8:
r = ucl_nrv2b_test_overlap_8(buf,src_off,src_len,dst_len,nullptr);
r = ucl_nrv2b_test_overlap_8(buf, src_off, src_len, dst_len, nullptr);
break;
case M_NRV2B_LE16:
r = ucl_nrv2b_test_overlap_le16(buf,src_off,src_len,dst_len,nullptr);
r = ucl_nrv2b_test_overlap_le16(buf, src_off, src_len, dst_len, nullptr);
break;
case M_NRV2B_LE32:
r = ucl_nrv2b_test_overlap_le32(buf,src_off,src_len,dst_len,nullptr);
r = ucl_nrv2b_test_overlap_le32(buf, src_off, src_len, dst_len, nullptr);
break;
case M_NRV2D_8:
r = ucl_nrv2d_test_overlap_8(buf,src_off,src_len,dst_len,nullptr);
r = ucl_nrv2d_test_overlap_8(buf, src_off, src_len, dst_len, nullptr);
break;
case M_NRV2D_LE16:
r = ucl_nrv2d_test_overlap_le16(buf,src_off,src_len,dst_len,nullptr);
r = ucl_nrv2d_test_overlap_le16(buf, src_off, src_len, dst_len, nullptr);
break;
case M_NRV2D_LE32:
r = ucl_nrv2d_test_overlap_le32(buf,src_off,src_len,dst_len,nullptr);
r = ucl_nrv2d_test_overlap_le32(buf, src_off, src_len, dst_len, nullptr);
break;
case M_NRV2E_8:
r = ucl_nrv2e_test_overlap_8(buf,src_off,src_len,dst_len,nullptr);
r = ucl_nrv2e_test_overlap_8(buf, src_off, src_len, dst_len, nullptr);
break;
case M_NRV2E_LE16:
r = ucl_nrv2e_test_overlap_le16(buf,src_off,src_len,dst_len,nullptr);
r = ucl_nrv2e_test_overlap_le16(buf, src_off, src_len, dst_len, nullptr);
break;
case M_NRV2E_LE32:
r = ucl_nrv2e_test_overlap_le32(buf,src_off,src_len,dst_len,nullptr);
r = ucl_nrv2e_test_overlap_le32(buf, src_off, src_len, dst_len, nullptr);
break;
default:
throwInternalError("unknown decompression method");
@ -248,7 +237,6 @@ int upx_ucl_test_overlap ( const upx_bytep buf,
return convert_errno_from_ucl(r);
}
/*************************************************************************
// misc
**************************************************************************/
@ -258,8 +246,7 @@ static ucl_voidp __UCL_CDECL my_malloc(ucl_uint n) { return calloc(1, n); }
static void __UCL_CDECL my_free(ucl_voidp p) { free(p); }
}
int upx_ucl_init(void)
{
int upx_ucl_init(void) {
if (ucl_init() != UCL_E_OK)
return -1;
if (UCL_VERSION != ucl_version() || strcmp(UCL_VERSION_STRING, ucl_version_string()) != 0)
@ -268,19 +255,14 @@ int upx_ucl_init(void)
return 0;
}
const char *upx_ucl_version_string(void)
{
return ucl_version_string();
}
const char *upx_ucl_version_string(void) { return ucl_version_string(); }
unsigned upx_ucl_adler32(const void *buf, unsigned len, unsigned adler)
{
unsigned upx_ucl_adler32(const void *buf, unsigned len, unsigned adler) {
return ucl_adler32(adler, (const ucl_bytep) buf, len);
}
#if 0 /* UNUSED */
unsigned upx_ucl_crc32(const void *buf, unsigned len, unsigned crc)
{
unsigned upx_ucl_crc32(const void *buf, unsigned len, unsigned crc) {
return ucl_crc32(crc, (const ucl_bytep) buf, len);
}
#endif
@ -308,21 +290,26 @@ static bool check_ucl(const int method, const unsigned expected_c_len) {
d_buf.allocForDecompression(u_len);
c_len = c_buf.getSize() - c_extra;
r = upx_ucl_compress(raw_bytes(u_buf, u_len), u_len, raw_index_bytes(c_buf, c_extra, c_len), &c_len, nullptr, method, level, NULL_cconf, &cresult);
if (r != 0 || c_len != expected_c_len) return false;
r = upx_ucl_compress(raw_bytes(u_buf, u_len), u_len, raw_index_bytes(c_buf, c_extra, c_len),
&c_len, nullptr, method, level, NULL_cconf, &cresult);
if (r != 0 || c_len != expected_c_len)
return false;
d_len = d_buf.getSize();
r = upx_ucl_decompress(raw_index_bytes(c_buf, c_extra, c_len), c_len, raw_bytes(d_buf, d_len), &d_len, method, nullptr);
if (r != 0 || d_len != u_len) return false;
if (memcmp(u_buf, d_buf, u_len) != 0) return false;
r = upx_ucl_decompress(raw_index_bytes(c_buf, c_extra, c_len), c_len, raw_bytes(d_buf, d_len),
&d_len, method, nullptr);
if (r != 0 || d_len != u_len || memcmp(u_buf, d_buf, u_len) != 0)
return false;
d_len = u_len - 1;
r = upx_ucl_decompress(raw_index_bytes(c_buf, c_extra, c_len), c_len, raw_bytes(d_buf, d_len), &d_len, method, nullptr);
if (r == 0) return false;
r = upx_ucl_decompress(raw_index_bytes(c_buf, c_extra, c_len), c_len, raw_bytes(d_buf, d_len),
&d_len, method, nullptr);
if (r == 0)
return false;
// TODO: rewrite Packer::findOverlapOverhead() so that we can test it here
//unsigned x_len = d_len;
//r = upx_ucl_test_overlap(c_buf, u_buf, c_extra, c_len, &x_len, method, nullptr);
// unsigned x_len = d_len;
// r = upx_ucl_test_overlap(c_buf, u_buf, c_extra, c_len, &x_len, method, nullptr);
return true;
}
@ -347,7 +334,7 @@ TEST_CASE("upx_ucl_decompress") {
unsigned d_len;
int r;
c_data = (C*) "\x92\xff\x10\x00\x00\x00\x00\x00\x48\xff";
c_data = (C *) "\x92\xff\x10\x00\x00\x00\x00\x00\x48\xff";
d_len = 16;
r = upx_ucl_decompress(c_data, 10, d_buf, &d_len, M_NRV2B_8, nullptr);
CHECK((r == 0 && d_len == 16));
@ -357,7 +344,7 @@ TEST_CASE("upx_ucl_decompress") {
r = upx_ucl_decompress(c_data, 10, d_buf, &d_len, M_NRV2B_8, nullptr);
CHECK(r == UPX_E_OUTPUT_OVERRUN);
c_data = (C*) "\x92\xff\x10\x92\x49\x24\x92\xa0\xff";
c_data = (C *) "\x92\xff\x10\x92\x49\x24\x92\xa0\xff";
d_len = 16;
r = upx_ucl_decompress(c_data, 9, d_buf, &d_len, M_NRV2D_8, nullptr);
CHECK((r == 0 && d_len == 16));
@ -367,7 +354,7 @@ TEST_CASE("upx_ucl_decompress") {
r = upx_ucl_decompress(c_data, 9, d_buf, &d_len, M_NRV2D_8, nullptr);
CHECK(r == UPX_E_OUTPUT_OVERRUN);
c_data = (C*) "\x90\xff\xb0\x92\x49\x24\x92\xa0\xff";
c_data = (C *) "\x90\xff\xb0\x92\x49\x24\x92\xa0\xff";
d_len = 16;
r = upx_ucl_decompress(c_data, 9, d_buf, &d_len, M_NRV2E_8, nullptr);
CHECK((r == 0 && d_len == 16));

138
src/compress_zlib.cpp
View File

@ -25,16 +25,13 @@
<markus@oberhumer.com> <ezerotven+github@gmail.com>
*/
#include "conf.h"
#include "compress.h"
#include "util/membuffer.h"
#include <zlib/zlib.h>
#include <zlib/deflate.h>
void zlib_compress_config_t::reset()
{
void zlib_compress_config_t::reset() {
mem_clear(this, sizeof(*this));
mem_level.reset();
@ -42,40 +39,49 @@ void zlib_compress_config_t::reset()
strategy.reset();
}
static int convert_errno_from_zlib(int zr)
{
switch (zr)
{
case Z_OK: return UPX_E_OK;
case Z_NEED_DICT: return UPX_E_ERROR;
case Z_DATA_ERROR: return UPX_E_ERROR;
case Z_MEM_ERROR: return UPX_E_OUT_OF_MEMORY;
case Z_BUF_ERROR: return UPX_E_OUTPUT_OVERRUN;
case -7: return UPX_E_INPUT_OVERRUN;
static int convert_errno_from_zlib(int zr) {
switch (zr) {
case Z_OK:
return UPX_E_OK;
// positive values
case Z_STREAM_END:
return UPX_E_ERROR;
case Z_NEED_DICT:
return UPX_E_ERROR;
// negative values
case Z_ERRNO:
return UPX_E_ERROR;
case Z_STREAM_ERROR:
return UPX_E_ERROR;
case Z_DATA_ERROR:
return UPX_E_ERROR;
case Z_MEM_ERROR:
return UPX_E_OUT_OF_MEMORY;
case Z_BUF_ERROR:
return UPX_E_OUTPUT_OVERRUN;
case Z_VERSION_ERROR:
return UPX_E_ERROR;
case -7: // UPX extra
return UPX_E_INPUT_OVERRUN;
}
return UPX_E_ERROR;
}
/*************************************************************************
//
**************************************************************************/
int upx_zlib_compress ( const upx_bytep src, unsigned src_len,
upx_bytep dst, unsigned* dst_len,
upx_callback_p cb_parm,
int method, int level,
const upx_compress_config_t *cconf_parm,
upx_compress_result_t *cresult )
{
int upx_zlib_compress(const upx_bytep src, unsigned src_len, upx_bytep dst, unsigned *dst_len,
upx_callback_p cb_parm, int method, int level,
const upx_compress_config_t *cconf_parm, upx_compress_result_t *cresult) {
assert(method == M_DEFLATE);
assert(level > 0); assert(cresult != nullptr);
assert(level > 0);
assert(cresult != nullptr);
UNUSED(cb_parm);
int r = UPX_E_ERROR;
int zr;
const zlib_compress_config_t *lcconf = cconf_parm ? &cconf_parm->conf_zlib : nullptr;
zlib_compress_result_t *res = &cresult->result_zlib;
const zlib_compress_config_t *const lcconf = cconf_parm ? &cconf_parm->conf_zlib : nullptr;
zlib_compress_result_t *const res = &cresult->result_zlib;
if (level == 10)
level = 9;
@ -84,8 +90,7 @@ int upx_zlib_compress ( const upx_bytep src, unsigned src_len,
zlib_compress_config_t::window_bits_t window_bits;
zlib_compress_config_t::strategy_t strategy;
// cconf overrides
if (lcconf)
{
if (lcconf) {
oassign(mem_level, lcconf->mem_level);
oassign(window_bits, lcconf->window_bits);
oassign(strategy, lcconf->strategy);
@ -102,8 +107,7 @@ int upx_zlib_compress ( const upx_bytep src, unsigned src_len,
s.avail_out = *dst_len;
s.total_in = s.total_out = 0;
zr = (int)deflateInit2(&s, level, Z_DEFLATED, 0 - (int)window_bits,
mem_level, strategy);
zr = (int) deflateInit2(&s, level, Z_DEFLATED, 0 - (int) window_bits, mem_level, strategy);
if (zr != Z_OK)
goto error;
assert(s.state->level == level);
@ -121,27 +125,22 @@ error:
if (r == UPX_E_OK)
r = UPX_E_ERROR;
done:
if (r == UPX_E_OK)
{
if (r == UPX_E_OK) {
if (s.avail_in != 0 || s.total_in != src_len)
r = UPX_E_ERROR;
}
assert(s.total_in <= src_len);
assert(s.total_in <= src_len);
assert(s.total_out <= *dst_len);
*dst_len = s.total_out;
return r;
}
/*************************************************************************
//
**************************************************************************/
int upx_zlib_decompress ( const upx_bytep src, unsigned src_len,
upx_bytep dst, unsigned* dst_len,
int method,
const upx_compress_result_t *cresult )
{
int upx_zlib_decompress(const upx_bytep src, unsigned src_len, upx_bytep dst, unsigned *dst_len,
int method, const upx_compress_result_t *cresult) {
assert(method == M_DEFLATE);
UNUSED(method);
UNUSED(cresult);
@ -163,7 +162,7 @@ int upx_zlib_decompress ( const upx_bytep src, unsigned src_len,
zr = inflate(&s, Z_FINISH);
if (zr != Z_STREAM_END) {
if (zr == Z_BUF_ERROR && s.avail_in == 0)
zr = -7;
zr = -7; // UPX extra
goto error;
}
zr = inflateEnd(&s);
@ -177,35 +176,30 @@ error:
if (r == UPX_E_OK)
r = UPX_E_ERROR;
done:
if (r == UPX_E_OK)
{
if (r == UPX_E_OK) {
if (s.avail_in != 0 || s.total_in != src_len)
r = UPX_E_INPUT_NOT_CONSUMED;
}
assert(s.total_in <= src_len);
assert(s.total_in <= src_len);
assert(s.total_out <= *dst_len);
*dst_len = s.total_out;
return r;
}
/*************************************************************************
// test_overlap - see <ucl/ucl.h> for semantics
**************************************************************************/
int upx_zlib_test_overlap ( const upx_bytep buf,
const upx_bytep tbuf,
unsigned src_off, unsigned src_len,
unsigned* dst_len,
int method,
const upx_compress_result_t *cresult )
{
int upx_zlib_test_overlap(const upx_bytep buf, const upx_bytep tbuf, unsigned src_off,
unsigned src_len, unsigned *dst_len, int method,
const upx_compress_result_t *cresult) {
assert(method == M_DEFLATE);
MemBuffer b(src_off + src_len);
memcpy(b + src_off, buf + src_off, src_len);
unsigned saved_dst_len = *dst_len;
int r = upx_zlib_decompress(raw_index_bytes(b, src_off, src_len), src_len, raw_bytes(b, *dst_len), dst_len, method, cresult);
int r = upx_zlib_decompress(raw_index_bytes(b, src_off, src_len), src_len,
raw_bytes(b, *dst_len), dst_len, method, cresult);
if (r != UPX_E_OK)
return r;
if (*dst_len != saved_dst_len)
@ -218,33 +212,26 @@ int upx_zlib_test_overlap ( const upx_bytep buf,
return UPX_E_OK;
}
/*************************************************************************
// misc
**************************************************************************/
int upx_zlib_init(void)
{
int upx_zlib_init(void) {
if (strcmp(ZLIB_VERSION, zlibVersion()) != 0)
return -2;
return 0;
}
const char *upx_zlib_version_string(void)
{
return zlibVersion();
}
const char *upx_zlib_version_string(void) { return zlibVersion(); }
#if 0 /* UNUSED */
unsigned upx_zlib_adler32(const void *buf, unsigned len, unsigned adler)
{
unsigned upx_zlib_adler32(const void *buf, unsigned len, unsigned adler) {
return adler32(adler, (const Bytef *) buf, len);
}
#endif
#if 0 /* UNUSED */
unsigned upx_zlib_crc32(const void *buf, unsigned len, unsigned crc)
{
unsigned upx_zlib_crc32(const void *buf, unsigned len, unsigned crc) {
return crc32(crc, (const Bytef *) buf, len);
}
#endif
@ -271,21 +258,26 @@ static bool check_zlib(const int method, const int level, const unsigned expecte
d_buf.allocForDecompression(u_len);
c_len = c_buf.getSize() - c_extra;
r = upx_zlib_compress(raw_bytes(u_buf, u_len), u_len, raw_index_bytes(c_buf, c_extra, c_len), &c_len, nullptr, method, level, NULL_cconf, &cresult);
if (r != 0 || c_len != expected_c_len) return false;
r = upx_zlib_compress(raw_bytes(u_buf, u_len), u_len, raw_index_bytes(c_buf, c_extra, c_len),
&c_len, nullptr, method, level, NULL_cconf, &cresult);
if (r != 0 || c_len != expected_c_len)
return false;
d_len = d_buf.getSize();
r = upx_zlib_decompress(raw_index_bytes(c_buf, c_extra, c_len), c_len, raw_bytes(d_buf, d_len), &d_len, method, nullptr);
if (r != 0 || d_len != u_len) return false;
if (memcmp(u_buf, d_buf, u_len) != 0) return false;
r = upx_zlib_decompress(raw_index_bytes(c_buf, c_extra, c_len), c_len, raw_bytes(d_buf, d_len),
&d_len, method, nullptr);
if (r != 0 || d_len != u_len || memcmp(u_buf, d_buf, u_len) != 0)
return false;
d_len = u_len - 1;
r = upx_zlib_decompress(raw_index_bytes(c_buf, c_extra, c_len), c_len, raw_bytes(d_buf, d_len), &d_len, method, nullptr);
if (r == 0) return false;
r = upx_zlib_decompress(raw_index_bytes(c_buf, c_extra, c_len), c_len, raw_bytes(d_buf, d_len),
&d_len, method, nullptr);
if (r == 0)
return false;
// TODO: rewrite Packer::findOverlapOverhead() so that we can test it here
//unsigned x_len = d_len;
//r = upx_zlib_test_overlap(c_buf, u_buf, c_extra, c_len, &x_len, method, nullptr);
// unsigned x_len = d_len;
// r = upx_zlib_test_overlap(c_buf, u_buf, c_extra, c_len, &x_len, method, nullptr);
return true;
}
@ -304,7 +296,7 @@ TEST_CASE("upx_zlib_decompress") {
unsigned d_len;
int r;
c_data = (C*) "\xfb\xff\x1f\x15\x00\x00";
c_data = (C *) "\xfb\xff\x1f\x15\x00\x00";
d_len = 16;
r = upx_zlib_decompress(c_data, 6, d_buf, &d_len, M_DEFLATE, nullptr);
CHECK((r == 0 && d_len == 16));