Shipwright/StormLib/src/SCompression.cpp

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/*****************************************************************************/
/* SCompression.cpp Copyright (c) Ladislav Zezula 2003 */
/*---------------------------------------------------------------------------*/
/* This module serves as a bridge between StormLib code and (de)compression */
/* functions. All (de)compression calls go (and should only go) through this */
/* module. No system headers should be included in this module to prevent */
/* compile-time problems. */
/*---------------------------------------------------------------------------*/
/* Date Ver Who Comment */
/* -------- ---- --- ------- */
/* 01.04.03 1.00 Lad The first version of SCompression.cpp */
/* 19.11.03 1.01 Dan Big endian handling */
/*****************************************************************************/
#define __STORMLIB_SELF__
#include "StormLib.h"
#include "StormCommon.h"
//-----------------------------------------------------------------------------
// Local structures
// Information about the input and output buffers for pklib
typedef struct
{
unsigned char * pbInBuff; // Pointer to input data buffer
unsigned char * pbInBuffEnd; // End of the input buffer
unsigned char * pbOutBuff; // Pointer to output data buffer
unsigned char * pbOutBuffEnd; // Pointer to output data buffer
} TDataInfo;
// Prototype of the compression function
// Function doesn't return an error. A success means that the size of compressed buffer
// is lower than size of uncompressed buffer.
typedef void (*COMPRESS)(
void * pvOutBuffer, // [out] Pointer to the buffer where the compressed data will be stored
int * pcbOutBuffer, // [in] Pointer to length of the buffer pointed by pvOutBuffer
void * pvInBuffer, // [in] Pointer to the buffer with data to compress
int cbInBuffer, // [in] Length of the buffer pointer by pvInBuffer
int * pCmpType, // [in] Compression-method specific value. ADPCM Setups this for the following Huffman compression
int nCmpLevel); // [in] Compression specific value. ADPCM uses this. Should be set to zero.
// Prototype of the decompression function
// Returns 1 if success, 0 if failure
typedef int (*DECOMPRESS)(
void * pvOutBuffer, // [out] Pointer to the buffer where to store decompressed data
int * pcbOutBuffer, // [in] Pointer to total size of the buffer pointed by pvOutBuffer
// [out] Contains length of the decompressed data
void * pvInBuffer, // [in] Pointer to data to be decompressed
int cbInBuffer); // [in] Length of the data to be decompressed
// Table of compression functions
typedef struct
{
unsigned long uMask; // Compression mask
COMPRESS Compress; // Compression function
} TCompressTable;
// Table of decompression functions
typedef struct
{
unsigned long uMask; // Decompression bit
DECOMPRESS Decompress; // Decompression function
} TDecompressTable;
/*****************************************************************************/
/* */
/* Support for Huffman compression (0x01) */
/* */
/*****************************************************************************/
void Compress_huff(void * pvOutBuffer, int * pcbOutBuffer, void * pvInBuffer, int cbInBuffer, int * pCmpType, int nCmpLevel)
{
THuffmannTree ht(true);
TOutputStream os(pvOutBuffer, *pcbOutBuffer);
STORMLIB_UNUSED(nCmpLevel);
*pcbOutBuffer = ht.Compress(&os, pvInBuffer, cbInBuffer, *pCmpType);
}
int Decompress_huff(void * pvOutBuffer, int * pcbOutBuffer, void * pvInBuffer, int cbInBuffer)
{
THuffmannTree ht(false);
TInputStream is(pvInBuffer, cbInBuffer);
*pcbOutBuffer = ht.Decompress(pvOutBuffer, *pcbOutBuffer, &is);
return (*pcbOutBuffer == 0) ? 0 : 1;
}
/******************************************************************************/
/* */
/* Support for ZLIB compression (0x02) */
/* */
/******************************************************************************/
void Compress_ZLIB(void * pvOutBuffer, int * pcbOutBuffer, void * pvInBuffer, int cbInBuffer, int * pCmpType, int nCmpLevel)
{
z_stream z; // Stream information for zlib
int windowBits;
int nResult;
// Keep compilers happy
STORMLIB_UNUSED(pCmpType);
STORMLIB_UNUSED(nCmpLevel);
// Fill the stream structure for zlib
z.next_in = (Bytef *)pvInBuffer;
z.avail_in = (uInt)cbInBuffer;
z.total_in = cbInBuffer;
z.next_out = (Bytef *)pvOutBuffer;
z.avail_out = *pcbOutBuffer;
z.total_out = 0;
z.zalloc = NULL;
z.zfree = NULL;
// Determine the proper window bits (WoW.exe build 12694)
if(cbInBuffer <= 0x100)
windowBits = 8;
else if(cbInBuffer <= 0x200)
windowBits = 9;
else if(cbInBuffer <= 0x400)
windowBits = 10;
else if(cbInBuffer <= 0x800)
windowBits = 11;
else if(cbInBuffer <= 0x1000)
windowBits = 12;
else if(cbInBuffer <= 0x2000)
windowBits = 13;
else if(cbInBuffer <= 0x4000)
windowBits = 14;
else
windowBits = 15;
// Initialize the compression.
// Storm.dll uses zlib version 1.1.3
// Wow.exe uses zlib version 1.2.3
nResult = deflateInit2(&z,
6, // Compression level used by WoW MPQs
Z_DEFLATED,
windowBits,
8,
Z_DEFAULT_STRATEGY);
if(nResult == Z_OK)
{
// Call zlib to compress the data
nResult = deflate(&z, Z_FINISH);
if(nResult == Z_OK || nResult == Z_STREAM_END)
*pcbOutBuffer = z.total_out;
deflateEnd(&z);
}
}
int Decompress_ZLIB(void * pvOutBuffer, int * pcbOutBuffer, void * pvInBuffer, int cbInBuffer)
{
z_stream z; // Stream information for zlib
int nResult;
// Fill the stream structure for zlib
z.next_in = (Bytef *)pvInBuffer;
z.avail_in = (uInt)cbInBuffer;
z.total_in = cbInBuffer;
z.next_out = (Bytef *)pvOutBuffer;
z.avail_out = *pcbOutBuffer;
z.total_out = 0;
z.zalloc = NULL;
z.zfree = NULL;
// Initialize the decompression structure. Storm.dll uses zlib version 1.1.3
if((nResult = inflateInit(&z)) == Z_OK)
{
// Call zlib to decompress the data
nResult = inflate(&z, Z_FINISH);
*pcbOutBuffer = z.total_out;
inflateEnd(&z);
}
return (nResult >= Z_OK);
}
/******************************************************************************/
/* */
/* Support functions for PKWARE Data Compression Library compression (0x08) */
/* */
/******************************************************************************/
// Function loads data from the input buffer. Used by Pklib's "implode"
// and "explode" function as user-defined callback
// Returns number of bytes loaded
//
// char * buf - Pointer to a buffer where to store loaded data
// unsigned int * size - Max. number of bytes to read
// void * param - Custom pointer, parameter of implode/explode
static unsigned int ReadInputData(char * buf, unsigned int * size, void * param)
{
TDataInfo * pInfo = (TDataInfo *)param;
unsigned int nMaxAvail = (unsigned int)(pInfo->pbInBuffEnd - pInfo->pbInBuff);
unsigned int nToRead = *size;
// Check the case when not enough data available
if(nToRead > nMaxAvail)
nToRead = nMaxAvail;
// Load data and increment offsets
memcpy(buf, pInfo->pbInBuff, nToRead);
pInfo->pbInBuff += nToRead;
assert(pInfo->pbInBuff <= pInfo->pbInBuffEnd);
return nToRead;
}
// Function for store output data. Used by Pklib's "implode" and "explode"
// as user-defined callback
//
// char * buf - Pointer to data to be written
// unsigned int * size - Number of bytes to write
// void * param - Custom pointer, parameter of implode/explode
static void WriteOutputData(char * buf, unsigned int * size, void * param)
{
TDataInfo * pInfo = (TDataInfo *)param;
unsigned int nMaxWrite = (unsigned int)(pInfo->pbOutBuffEnd - pInfo->pbOutBuff);
unsigned int nToWrite = *size;
// Check the case when not enough space in the output buffer
if(nToWrite > nMaxWrite)
nToWrite = nMaxWrite;
// Write output data and increments offsets
memcpy(pInfo->pbOutBuff, buf, nToWrite);
pInfo->pbOutBuff += nToWrite;
assert(pInfo->pbOutBuff <= pInfo->pbOutBuffEnd);
}
static void Compress_PKLIB(void * pvOutBuffer, int * pcbOutBuffer, void * pvInBuffer, int cbInBuffer, int * pCmpType, int nCmpLevel)
{
TDataInfo Info; // Data information
char * work_buf = STORM_ALLOC(char, CMP_BUFFER_SIZE);// Pklib's work buffer
unsigned int dict_size; // Dictionary size
unsigned int ctype = CMP_BINARY; // Compression type
// Keep compilers happy
STORMLIB_UNUSED(pCmpType);
STORMLIB_UNUSED(nCmpLevel);
// Handle no-memory condition
if(work_buf != NULL)
{
// Fill data information structure
memset(work_buf, 0, CMP_BUFFER_SIZE);
Info.pbInBuff = (unsigned char *)pvInBuffer;
Info.pbInBuffEnd = (unsigned char *)pvInBuffer + cbInBuffer;
Info.pbOutBuff = (unsigned char *)pvOutBuffer;
Info.pbOutBuffEnd = (unsigned char *)pvOutBuffer + *pcbOutBuffer;
//
// Set the dictionary size
//
// Diablo I uses fixed dictionary size of CMP_IMPLODE_DICT_SIZE3
// Starcraft I uses the variable dictionary size based on algorithm below
//
if (cbInBuffer < 0x600)
dict_size = CMP_IMPLODE_DICT_SIZE1;
else if(0x600 <= cbInBuffer && cbInBuffer < 0xC00)
dict_size = CMP_IMPLODE_DICT_SIZE2;
else
dict_size = CMP_IMPLODE_DICT_SIZE3;
// Do the compression
if(implode(ReadInputData, WriteOutputData, work_buf, &Info, &ctype, &dict_size) == CMP_NO_ERROR)
*pcbOutBuffer = (int)(Info.pbOutBuff - (unsigned char *)pvOutBuffer);
STORM_FREE(work_buf);
}
}
static int Decompress_PKLIB(void * pvOutBuffer, int * pcbOutBuffer, void * pvInBuffer, int cbInBuffer)
{
TDataInfo Info; // Data information
char * work_buf;
int nResult = 0;
// Allocate Pklib's work buffer
if((work_buf = STORM_ALLOC(char, EXP_BUFFER_SIZE)) != NULL)
{
// Fill data information structure
memset(work_buf, 0, EXP_BUFFER_SIZE);
Info.pbInBuff = (unsigned char *)pvInBuffer;
Info.pbInBuffEnd = (unsigned char *)pvInBuffer + cbInBuffer;
Info.pbOutBuff = (unsigned char *)pvOutBuffer;
Info.pbOutBuffEnd = (unsigned char *)pvOutBuffer + *pcbOutBuffer;
// Do the decompression
if(explode(ReadInputData, WriteOutputData, work_buf, &Info) == CMP_NO_ERROR)
nResult = 1;
// Give away the number of decompressed bytes
*pcbOutBuffer = (int)(Info.pbOutBuff - (unsigned char *)pvOutBuffer);
STORM_FREE(work_buf);
}
return nResult;
}
/******************************************************************************/
/* */
/* Support for Bzip2 compression (0x10) */
/* */
/******************************************************************************/
static void Compress_BZIP2(void * pvOutBuffer, int * pcbOutBuffer, void * pvInBuffer, int cbInBuffer, int * pCmpType, int nCmpLevel)
{
bz_stream strm;
int blockSize100k = 9;
int workFactor = 30;
int bzError;
// Keep compilers happy
STORMLIB_UNUSED(pCmpType);
STORMLIB_UNUSED(nCmpLevel);
// Initialize the BZIP2 compression
strm.bzalloc = NULL;
strm.bzfree = NULL;
strm.opaque = NULL;
// Blizzard uses 9 as blockSize100k, (0x30 as workFactor)
// Last checked on Starcraft II
if(BZ2_bzCompressInit(&strm, blockSize100k, 0, workFactor) == BZ_OK)
{
strm.next_in = (char *)pvInBuffer;
strm.avail_in = cbInBuffer;
strm.next_out = (char *)pvOutBuffer;
strm.avail_out = *pcbOutBuffer;
// Perform the compression
for(;;)
{
bzError = BZ2_bzCompress(&strm, (strm.avail_in != 0) ? BZ_RUN : BZ_FINISH);
if(bzError == BZ_STREAM_END || bzError < 0)
break;
}
// Put the stream into idle state
BZ2_bzCompressEnd(&strm);
if(bzError > 0)
*pcbOutBuffer = strm.total_out_lo32;
}
}
static int Decompress_BZIP2(void * pvOutBuffer, int * pcbOutBuffer, void * pvInBuffer, int cbInBuffer)
{
bz_stream strm;
int nResult;
// Initialize the BZIP2 decompression
strm.next_in = (char *)pvInBuffer;
strm.avail_in = cbInBuffer;
strm.next_out = (char *)pvOutBuffer;
strm.avail_out = *pcbOutBuffer;
strm.bzalloc = NULL;
strm.bzfree = NULL;
strm.opaque = NULL;
// Initialize decompression
if((nResult = BZ2_bzDecompressInit(&strm, 0, 0)) == BZ_OK)
{
// Perform the decompression
nResult = BZ2_bzDecompress(&strm);
*pcbOutBuffer = strm.total_out_lo32;
BZ2_bzDecompressEnd(&strm);
}
return (nResult >= BZ_OK);
}
/******************************************************************************/
/* */
/* Support functions for LZMA compression (0x12) */
/* */
/******************************************************************************/
#define LZMA_HEADER_SIZE (1 + LZMA_PROPS_SIZE + 8)
static SRes LZMA_Callback_Progress(void * /* p */, UInt64 /* inSize */, UInt64 /* outSize */)
{
return SZ_OK;
}
static void * LZMA_Callback_Alloc(void *p, size_t size)
{
p = p;
return STORM_ALLOC(BYTE, size);
}
/* address can be 0 */
static void LZMA_Callback_Free(void *p, void *address)
{
p = p;
if(address != NULL)
STORM_FREE(address);
}
//
// Note: So far, I haven't seen any files compressed by LZMA.
// This code haven't been verified against code ripped from Starcraft II Beta,
// but we know that Starcraft LZMA decompression code is able to decompress
// the data compressed by StormLib.
//
static void Compress_LZMA(void * pvOutBuffer, int * pcbOutBuffer, void * pvInBuffer, int cbInBuffer, int * pCmpType, int nCmpLevel)
{
ICompressProgress Progress;
CLzmaEncProps props;
ISzAlloc SzAlloc;
Byte * pbOutBuffer = (Byte *)pvOutBuffer;
Byte * destBuffer;
SizeT destLen = *pcbOutBuffer;
SizeT srcLen = cbInBuffer;
Byte encodedProps[LZMA_PROPS_SIZE];
size_t encodedPropsSize = LZMA_PROPS_SIZE;
SRes nResult;
// Keep compilers happy
STORMLIB_UNUSED(pCmpType);
STORMLIB_UNUSED(nCmpLevel);
// Fill the callbacks in structures
Progress.Progress = LZMA_Callback_Progress;
SzAlloc.Alloc = LZMA_Callback_Alloc;
SzAlloc.Free = LZMA_Callback_Free;
// Initialize properties
LzmaEncProps_Init(&props);
// Perform compression
destBuffer = (Byte *)pvOutBuffer + LZMA_HEADER_SIZE;
destLen = *pcbOutBuffer - LZMA_HEADER_SIZE;
nResult = LzmaEncode(destBuffer,
&destLen,
(Byte *)pvInBuffer,
srcLen,
&props,
encodedProps,
&encodedPropsSize,
0,
&Progress,
&SzAlloc,
&SzAlloc);
if(nResult != SZ_OK)
return;
// If we failed to compress the data
if(destLen >= (SizeT)(*pcbOutBuffer - LZMA_HEADER_SIZE))
return;
// Write "useFilter" variable. Blizzard MPQ must not use filter.
*pbOutBuffer++ = 0;
// Copy the encoded properties to the output buffer
memcpy(pvOutBuffer, encodedProps, encodedPropsSize);
pbOutBuffer += encodedPropsSize;
// Copy the size of the data
*pbOutBuffer++ = (unsigned char)(srcLen >> 0x00);
*pbOutBuffer++ = (unsigned char)(srcLen >> 0x08);
*pbOutBuffer++ = (unsigned char)(srcLen >> 0x10);
*pbOutBuffer++ = (unsigned char)(srcLen >> 0x18);
*pbOutBuffer++ = 0;
*pbOutBuffer++ = 0;
*pbOutBuffer++ = 0;
*pbOutBuffer++ = 0;
// Give the size of the data to the caller
*pcbOutBuffer = (unsigned int)(destLen + LZMA_HEADER_SIZE);
}
static int Decompress_LZMA(void * pvOutBuffer, int * pcbOutBuffer, void * pvInBuffer, int cbInBuffer)
{
ELzmaStatus LzmaStatus;
ISzAlloc SzAlloc;
Byte * destBuffer = (Byte *)pvOutBuffer;
Byte * srcBuffer = (Byte *)pvInBuffer;
SizeT destLen = *pcbOutBuffer;
SizeT srcLen = cbInBuffer;
SRes nResult;
// There must be at least 0x0E bytes in the buffer
if(srcLen <= LZMA_HEADER_SIZE)
return 0;
// We only accept blocks that have no filter used
if(*srcBuffer != 0)
return 0;
// Fill the callbacks in structures
SzAlloc.Alloc = LZMA_Callback_Alloc;
SzAlloc.Free = LZMA_Callback_Free;
// Perform compression
srcLen = cbInBuffer - LZMA_HEADER_SIZE;
nResult = LzmaDecode(destBuffer,
&destLen,
srcBuffer + LZMA_HEADER_SIZE,
&srcLen,
srcBuffer + 1,
LZMA_PROPS_SIZE,
LZMA_FINISH_END,
&LzmaStatus,
&SzAlloc);
if(nResult != SZ_OK)
return 0;
*pcbOutBuffer = (unsigned int)destLen;
return 1;
}
static int Decompress_LZMA_MPK(void * pvOutBuffer, int * pcbOutBuffer, void * pvInBuffer, int cbInBuffer)
{
ELzmaStatus LzmaStatus;
ISzAlloc SzAlloc;
Byte * destBuffer = (Byte *)pvOutBuffer;
Byte * srcBuffer = (Byte *)pvInBuffer;
SizeT destLen = *pcbOutBuffer;
SizeT srcLen = cbInBuffer;
SRes nResult;
BYTE LZMA_Props[] = {0x5D, 0x00, 0x00, 0x00, 0x01};
// There must be at least 0x0E bytes in the buffer
if(srcLen <= sizeof(LZMA_Props))
return 0;
// Verify the props header
if(memcmp(pvInBuffer, LZMA_Props, sizeof(LZMA_Props)))
return 0;
// Fill the callbacks in structures
SzAlloc.Alloc = LZMA_Callback_Alloc;
SzAlloc.Free = LZMA_Callback_Free;
// Perform compression
srcLen = cbInBuffer - sizeof(LZMA_Props);
nResult = LzmaDecode(destBuffer,
&destLen,
srcBuffer + sizeof(LZMA_Props),
&srcLen,
srcBuffer,
sizeof(LZMA_Props),
LZMA_FINISH_END,
&LzmaStatus,
&SzAlloc);
if(nResult != SZ_OK)
return 0;
*pcbOutBuffer = (unsigned int)destLen;
return 1;
}
/******************************************************************************/
/* */
/* Support functions for SPARSE compression (0x20) */
/* */
/******************************************************************************/
void Compress_SPARSE(void * pvOutBuffer, int * pcbOutBuffer, void * pvInBuffer, int cbInBuffer, int * pCmpType, int nCmpLevel)
{
// Keep compilers happy
STORMLIB_UNUSED(pCmpType);
STORMLIB_UNUSED(nCmpLevel);
CompressSparse(pvOutBuffer, pcbOutBuffer, pvInBuffer, cbInBuffer);
}
int Decompress_SPARSE(void * pvOutBuffer, int * pcbOutBuffer, void * pvInBuffer, int cbInBuffer)
{
return DecompressSparse(pvOutBuffer, pcbOutBuffer, pvInBuffer, cbInBuffer);
}
/******************************************************************************/
/* */
/* Support for ADPCM mono compression (0x40) */
/* */
/******************************************************************************/
static void Compress_ADPCM_mono(void * pvOutBuffer, int * pcbOutBuffer, void * pvInBuffer, int cbInBuffer, int * pCmpType, int nCmpLevel)
{
// Prepare the compression level for Huffmann compression,
// which will be called as next step
if(0 < nCmpLevel && nCmpLevel <= 2)
{
nCmpLevel = 4;
*pCmpType = 6;
}
else if(nCmpLevel == 3)
{
nCmpLevel = 6;
*pCmpType = 8;
}
else
{
nCmpLevel = 5;
*pCmpType = 7;
}
*pcbOutBuffer = CompressADPCM(pvOutBuffer, *pcbOutBuffer, pvInBuffer, cbInBuffer, 1, nCmpLevel);
}
static int Decompress_ADPCM_mono(void * pvOutBuffer, int * pcbOutBuffer, void * pvInBuffer, int cbInBuffer)
{
*pcbOutBuffer = DecompressADPCM(pvOutBuffer, *pcbOutBuffer, pvInBuffer, cbInBuffer, 1);
return 1;
}
/******************************************************************************/
/* */
/* Support for ADPCM stereo compression (0x80) */
/* */
/******************************************************************************/
static void Compress_ADPCM_stereo(void * pvOutBuffer, int * pcbOutBuffer, void * pvInBuffer, int cbInBuffer, int * pCmpType, int nCmpLevel)
{
// Prepare the compression level for Huffmann compression,
// which will be called as next step
if(0 < nCmpLevel && nCmpLevel <= 2)
{
nCmpLevel = 4;
*pCmpType = 6;
}
else if(nCmpLevel == 3)
{
nCmpLevel = 6;
*pCmpType = 8;
}
else
{
nCmpLevel = 5;
*pCmpType = 7;
}
*pcbOutBuffer = CompressADPCM(pvOutBuffer, *pcbOutBuffer, pvInBuffer, cbInBuffer, 2, nCmpLevel);
}
static int Decompress_ADPCM_stereo(void * pvOutBuffer, int * pcbOutBuffer, void * pvInBuffer, int cbInBuffer)
{
*pcbOutBuffer = DecompressADPCM(pvOutBuffer, *pcbOutBuffer, pvInBuffer, cbInBuffer, 2);
return 1;
}
/*****************************************************************************/
/* */
/* SCompImplode */
/* */
/*****************************************************************************/
int WINAPI SCompImplode(void * pvOutBuffer, int * pcbOutBuffer, void * pvInBuffer, int cbInBuffer)
{
int cbOutBuffer;
// Check for valid parameters
if(!pcbOutBuffer || *pcbOutBuffer < cbInBuffer || !pvOutBuffer || !pvInBuffer)
{
SetLastError(ERROR_INVALID_PARAMETER);
return 0;
}
// Perform the compression
cbOutBuffer = *pcbOutBuffer;
Compress_PKLIB(pvOutBuffer, &cbOutBuffer, pvInBuffer, cbInBuffer, NULL, 0);
// If the compression was unsuccessful, copy the data as-is
if(cbOutBuffer >= *pcbOutBuffer)
{
memcpy(pvOutBuffer, pvInBuffer, cbInBuffer);
cbOutBuffer = *pcbOutBuffer;
}
*pcbOutBuffer = cbOutBuffer;
return 1;
}
/*****************************************************************************/
/* */
/* SCompExplode */
/* */
/*****************************************************************************/
int WINAPI SCompExplode(void * pvOutBuffer, int * pcbOutBuffer, void * pvInBuffer, int cbInBuffer)
{
int cbOutBuffer;
// Check for valid parameters
if(!pcbOutBuffer || *pcbOutBuffer < cbInBuffer || !pvOutBuffer || !pvInBuffer)
{
SetLastError(ERROR_INVALID_PARAMETER);
return 0;
}
// If the input length is the same as output length, do nothing.
cbOutBuffer = *pcbOutBuffer;
if(cbInBuffer == cbOutBuffer)
{
// If the buffers are equal, don't copy anything.
if(pvInBuffer == pvOutBuffer)
return 1;
memcpy(pvOutBuffer, pvInBuffer, cbInBuffer);
return 1;
}
// Perform decompression
if(!Decompress_PKLIB(pvOutBuffer, &cbOutBuffer, pvInBuffer, cbInBuffer))
{
SetLastError(ERROR_FILE_CORRUPT);
return 0;
}
*pcbOutBuffer = cbOutBuffer;
return 1;
}
/*****************************************************************************/
/* */
/* SCompCompress */
/* */
/*****************************************************************************/
// This table contains compress functions which can be applied to
// uncompressed data. Each bit means the corresponding
// compression method/function must be applied.
//
// WAVes compression Data compression
// ------------------ -------------------
// 1st sector - 0x08 0x08 (D, HF, W2, SC, D2)
// Next sectors - 0x81 0x02 (W3)
static TCompressTable cmp_table[] =
{
{MPQ_COMPRESSION_SPARSE, Compress_SPARSE}, // Sparse compression
{MPQ_COMPRESSION_ADPCM_MONO, Compress_ADPCM_mono}, // IMA ADPCM mono compression
{MPQ_COMPRESSION_ADPCM_STEREO, Compress_ADPCM_stereo}, // IMA ADPCM stereo compression
{MPQ_COMPRESSION_HUFFMANN, Compress_huff}, // Huffmann compression
{MPQ_COMPRESSION_ZLIB, Compress_ZLIB}, // Compression with the "zlib" library
{MPQ_COMPRESSION_PKWARE, Compress_PKLIB}, // Compression with Pkware DCL
{MPQ_COMPRESSION_BZIP2, Compress_BZIP2} // Compression Bzip2 library
};
int WINAPI SCompCompress(void * pvOutBuffer, int * pcbOutBuffer, void * pvInBuffer, int cbInBuffer, unsigned uCompressionMask, int nCmpType, int nCmpLevel)
{
COMPRESS CompressFuncArray[0x10]; // Array of compression functions, applied sequentially
unsigned char CompressByte[0x10]; // CompressByte for each method in the CompressFuncArray array
unsigned char * pbWorkBuffer = NULL; // Temporary storage for decompressed data
unsigned char * pbOutBuffer = (unsigned char *)pvOutBuffer;
unsigned char * pbOutput = (unsigned char *)pvOutBuffer;// Current output buffer
unsigned char * pbInput = (unsigned char *)pvInBuffer; // Current input buffer
int nCompressCount = 0;
int nCompressIndex = 0;
int nAtLeastOneCompressionDone = 0;
int cbOutBuffer = 0;
int cbInLength = cbInBuffer;
int nResult = 1;
// Check for valid parameters
if(!pcbOutBuffer || *pcbOutBuffer < cbInBuffer || !pvOutBuffer || !pvInBuffer)
{
SetLastError(ERROR_INVALID_PARAMETER);
return 0;
}
// Zero input length brings zero output length
if(cbInBuffer == 0)
{
*pcbOutBuffer = 0;
return true;
}
// Setup the compression function array
if(uCompressionMask == MPQ_COMPRESSION_LZMA)
{
CompressFuncArray[0] = Compress_LZMA;
CompressByte[0] = (char)uCompressionMask;
nCompressCount = 1;
}
else
{
// Fill the compressions array
for(size_t i = 0; i < (sizeof(cmp_table) / sizeof(TCompressTable)); i++)
{
// If the mask agrees, insert the compression function to the array
if(uCompressionMask & cmp_table[i].uMask)
{
CompressFuncArray[nCompressCount] = cmp_table[i].Compress;
CompressByte[nCompressCount] = (unsigned char)cmp_table[i].uMask;
uCompressionMask &= ~cmp_table[i].uMask;
nCompressCount++;
}
}
// If at least one of the compressions remaing unknown, return an error
if(uCompressionMask != 0)
{
SetLastError(ERROR_NOT_SUPPORTED);
return 0;
}
}
// If there is at least one compression, do it
if(nCompressCount > 0)
{
// If we need to do more than 1 compression, allocate intermediate buffer
if(nCompressCount > 1)
{
pbWorkBuffer = STORM_ALLOC(unsigned char, *pcbOutBuffer);
if(pbWorkBuffer == NULL)
{
SetLastError(ERROR_NOT_ENOUGH_MEMORY);
return 0;
}
}
// Get the current compression index
nCompressIndex = nCompressCount - 1;
// Perform all compressions in the array
for(int i = 0; i < nCompressCount; i++)
{
// Choose the proper output buffer
pbOutput = (nCompressIndex & 1) ? pbWorkBuffer : pbOutBuffer;
nCompressIndex--;
// Perform the (next) compression
// Note that if the compression method is unable to compress the input data block
// by at least 2 bytes, we consider it as failure and will use source data instead
cbOutBuffer = *pcbOutBuffer - 1;
CompressFuncArray[i](pbOutput + 1, &cbOutBuffer, pbInput, cbInLength, &nCmpType, nCmpLevel);
// If the compression failed, we copy the input buffer as-is.
// Note that there is one extra byte at the end of the intermediate buffer, so it should be OK
if(cbOutBuffer > (cbInLength - 2))
{
memcpy(pbOutput + nAtLeastOneCompressionDone, pbInput, cbInLength);
cbOutBuffer = cbInLength;
}
else
{
// Remember that we have done at least one compression
nAtLeastOneCompressionDone = 1;
uCompressionMask |= CompressByte[i];
}
// Now point input buffer to the output buffer
pbInput = pbOutput + nAtLeastOneCompressionDone;
cbInLength = cbOutBuffer;
}
// If at least one compression succeeded, put the compression
// mask to the begin of the output buffer
if(nAtLeastOneCompressionDone)
*pbOutBuffer = (unsigned char)uCompressionMask;
*pcbOutBuffer = cbOutBuffer + nAtLeastOneCompressionDone;
}
else
{
memcpy(pvOutBuffer, pvInBuffer, cbInBuffer);
*pcbOutBuffer = cbInBuffer;
}
// Cleanup and return
if(pbWorkBuffer != NULL)
STORM_FREE(pbWorkBuffer);
return nResult;
}
/*****************************************************************************/
/* */
/* SCompDecompress */
/* */
/*****************************************************************************/
// This table contains decompress functions which can be applied to
// uncompressed data. The compression mask is stored in the first byte
// of compressed data
static TDecompressTable dcmp_table[] =
{
{MPQ_COMPRESSION_BZIP2, Decompress_BZIP2}, // Decompression with Bzip2 library
{MPQ_COMPRESSION_PKWARE, Decompress_PKLIB}, // Decompression with Pkware Data Compression Library
{MPQ_COMPRESSION_ZLIB, Decompress_ZLIB}, // Decompression with the "zlib" library
{MPQ_COMPRESSION_HUFFMANN, Decompress_huff}, // Huffmann decompression
{MPQ_COMPRESSION_ADPCM_STEREO, Decompress_ADPCM_stereo}, // IMA ADPCM stereo decompression
{MPQ_COMPRESSION_ADPCM_MONO, Decompress_ADPCM_mono}, // IMA ADPCM mono decompression
{MPQ_COMPRESSION_SPARSE, Decompress_SPARSE} // Sparse decompression
};
int WINAPI SCompDecompress(void * pvOutBuffer, int * pcbOutBuffer, void * pvInBuffer, int cbInBuffer)
{
unsigned char * pbWorkBuffer = NULL;
unsigned char * pbOutBuffer = (unsigned char *)pvOutBuffer;
unsigned char * pbInBuffer = (unsigned char *)pvInBuffer;
unsigned char * pbOutput = (unsigned char *)pvOutBuffer;
unsigned char * pbInput;
unsigned uCompressionMask; // Decompressions applied to the data
unsigned uCompressionCopy; // Decompressions applied to the data
int cbOutBuffer = *pcbOutBuffer; // Current size of the output buffer
int cbInLength; // Current size of the input buffer
int nCompressCount = 0; // Number of compressions to be applied
int nCompressIndex = 0;
int nResult = 1;
// Verify buffer sizes
if(cbOutBuffer < cbInBuffer || cbInBuffer < 1)
return 0;
// If the input length is the same as output length, do nothing.
if(cbOutBuffer == cbInBuffer)
{
// If the buffers are equal, don't copy anything.
if(pvInBuffer != pvOutBuffer)
memcpy(pvOutBuffer, pvInBuffer, cbInBuffer);
return 1;
}
// Get applied compression types and decrement data length
uCompressionMask = uCompressionCopy = (unsigned char)*pbInBuffer++;
cbInBuffer--;
// Get current compressed data and length of it
pbInput = pbInBuffer;
cbInLength = cbInBuffer;
// This compression function doesn't support LZMA
assert(uCompressionMask != MPQ_COMPRESSION_LZMA);
// Parse the compression mask
for(size_t i = 0; i < (sizeof(dcmp_table) / sizeof(TDecompressTable)); i++)
{
// If the mask agrees, insert the compression function to the array
if(uCompressionMask & dcmp_table[i].uMask)
{
uCompressionCopy &= ~dcmp_table[i].uMask;
nCompressCount++;
}
}
// If at least one of the compressions remaing unknown, return an error
if(nCompressCount == 0 || uCompressionCopy != 0)
{
SetLastError(ERROR_NOT_SUPPORTED);
return 0;
}
// If there is more than one compression, we have to allocate extra buffer
if(nCompressCount > 1)
{
pbWorkBuffer = STORM_ALLOC(unsigned char, cbOutBuffer);
if(pbWorkBuffer == NULL)
{
SetLastError(ERROR_NOT_ENOUGH_MEMORY);
return 0;
}
}
// Get the current compression index
nCompressIndex = nCompressCount - 1;
// Apply all decompressions
for(size_t i = 0; i < (sizeof(dcmp_table) / sizeof(TDecompressTable)); i++)
{
// Perform the (next) decompression
if(uCompressionMask & dcmp_table[i].uMask)
{
// Get the correct output buffer
pbOutput = (nCompressIndex & 1) ? pbWorkBuffer : pbOutBuffer;
nCompressIndex--;
// Perform the decompression
cbOutBuffer = *pcbOutBuffer;
nResult = dcmp_table[i].Decompress(pbOutput, &cbOutBuffer, pbInput, cbInLength);
if(nResult == 0 || cbOutBuffer == 0)
{
SetLastError(ERROR_FILE_CORRUPT);
nResult = 0;
break;
}
// Switch buffers
cbInLength = cbOutBuffer;
pbInput = pbOutput;
}
}
// Put the length of the decompressed data to the output buffer
*pcbOutBuffer = cbOutBuffer;
// Cleanup and return
if(pbWorkBuffer != NULL)
STORM_FREE(pbWorkBuffer);
return nResult;
}
int WINAPI SCompDecompress2(void * pvOutBuffer, int * pcbOutBuffer, void * pvInBuffer, int cbInBuffer)
{
DECOMPRESS pfnDecompress1 = NULL;
DECOMPRESS pfnDecompress2 = NULL;
unsigned char * pbWorkBuffer = (unsigned char *)pvOutBuffer;
unsigned char * pbInBuffer = (unsigned char *)pvInBuffer;
int cbWorkBuffer = *pcbOutBuffer;
int nResult;
char CompressionMethod;
// Verify buffer sizes
if(*pcbOutBuffer < cbInBuffer || cbInBuffer < 1)
return 0;
// If the outputbuffer is as big as input buffer, just copy the block
if(*pcbOutBuffer == cbInBuffer)
{
if(pvOutBuffer != pvInBuffer)
memcpy(pvOutBuffer, pvInBuffer, cbInBuffer);
return 1;
}
// Get the compression methods
CompressionMethod = *pbInBuffer++;
cbInBuffer--;
// We only recognize a fixed set of compression methods
switch((unsigned char)CompressionMethod)
{
case MPQ_COMPRESSION_ZLIB:
pfnDecompress1 = Decompress_ZLIB;
break;
case MPQ_COMPRESSION_PKWARE:
pfnDecompress1 = Decompress_PKLIB;
break;
case MPQ_COMPRESSION_BZIP2:
pfnDecompress1 = Decompress_BZIP2;
break;
case MPQ_COMPRESSION_LZMA:
pfnDecompress1 = Decompress_LZMA;
break;
case MPQ_COMPRESSION_SPARSE:
pfnDecompress1 = Decompress_SPARSE;
break;
case (MPQ_COMPRESSION_SPARSE | MPQ_COMPRESSION_ZLIB):
pfnDecompress1 = Decompress_ZLIB;
pfnDecompress2 = Decompress_SPARSE;
break;
case (MPQ_COMPRESSION_SPARSE | MPQ_COMPRESSION_BZIP2):
pfnDecompress1 = Decompress_BZIP2;
pfnDecompress2 = Decompress_SPARSE;
break;
//
// Note: Any combination including MPQ_COMPRESSION_ADPCM_MONO,
// MPQ_COMPRESSION_ADPCM_STEREO or MPQ_COMPRESSION_HUFFMANN
// is not supported by newer MPQs.
//
case (MPQ_COMPRESSION_ADPCM_MONO | MPQ_COMPRESSION_HUFFMANN):
pfnDecompress1 = Decompress_huff;
pfnDecompress2 = Decompress_ADPCM_mono;
break;
case (MPQ_COMPRESSION_ADPCM_STEREO | MPQ_COMPRESSION_HUFFMANN):
pfnDecompress1 = Decompress_huff;
pfnDecompress2 = Decompress_ADPCM_stereo;
break;
default:
SetLastError(ERROR_FILE_CORRUPT);
return 0;
}
// If we have to use two decompressions, allocate temporary buffer
if(pfnDecompress2 != NULL)
{
pbWorkBuffer = STORM_ALLOC(unsigned char, *pcbOutBuffer);
if(pbWorkBuffer == NULL)
{
SetLastError(ERROR_NOT_ENOUGH_MEMORY);
return 0;
}
}
// Apply the first decompression method
nResult = pfnDecompress1(pbWorkBuffer, &cbWorkBuffer, pbInBuffer, cbInBuffer);
// Apply the second decompression method, if any
if(pfnDecompress2 != NULL && nResult != 0)
{
cbInBuffer = cbWorkBuffer;
cbWorkBuffer = *pcbOutBuffer;
nResult = pfnDecompress2(pvOutBuffer, &cbWorkBuffer, pbWorkBuffer, cbInBuffer);
}
// Supply the output buffer size
*pcbOutBuffer = cbWorkBuffer;
// Free temporary buffer
if(pbWorkBuffer != pvOutBuffer)
STORM_FREE(pbWorkBuffer);
if(nResult == 0)
SetLastError(ERROR_FILE_CORRUPT);
return nResult;
}
/*****************************************************************************/
/* */
/* File decompression for MPK archives */
/* */
/*****************************************************************************/
int SCompDecompressMpk(void * pvOutBuffer, int * pcbOutBuffer, void * pvInBuffer, int cbInBuffer)
{
return Decompress_LZMA_MPK(pvOutBuffer, pcbOutBuffer, pvInBuffer, cbInBuffer);
}