Source code of Windows XP (NT5)
You can not select more than 25 topics Topics must start with a letter or number, can include dashes ('-') and can be up to 35 characters long.
 
 
 
 
 
 

839 lines
20 KiB

// Copyright (C) Microsoft Corporation 1990-1997, All Rights reserved.
#include "header.h"
#include "cpaldc.h"
#include "gif.h"
#include "hha_strtable.h"
#include "hhctrl.h"
#define GIF_HDR_SIZE 6
#define MAX_BUFFER_SIZE (2L * MAXSIZE)
#define END_INFO (plzData->ClearCode+1)
#define FIRST_ENTRY (plzData->ClearCode+2)
#define HASH_SIZE 5003
STATIC int GetImagePalette(IFFPTR piff, LPBYTE pal);
STATIC FSERR GetInit(PCSTR pszFileName, IFFPTR piff, UINT GetFlag);
STATIC void GIFFreeMemory(IFFPTR piff);
STATIC void SetUserParams(IFFPTR);
STATIC int IFF_PackLine(PBYTE ToBuff, const BYTE* FromBuff, int Pixels, int Bits);
STATIC LZDATA* LZInitialize(int CharSize);
STATIC void LZCleanUp(LZDATA*);
STATIC int LZExpand(LZDATA*, PBYTE, PBYTE, unsigned, unsigned);
STATIC void BitmapHeaderFromIff(IFFPTR piff, LPBITMAPINFOHEADER pbih);
STATIC IFFPTR GifOpen(PCSTR pszFileName);
STATIC void GifClose(IFFPTR piff);
STATIC int GifGetLine(int NumLines, PBYTE Buffer, IFFPTR piff);
INLINE void InvertLine(LPBYTE Buffer, int DimX);
INLINE int ColorsFromBitDepth(int bitsperpixel);
INLINE int ScanLineWidth(int width, int bitcount);
static const int InterlaceMultiplier[] = { 8, 8, 4, 2 };
static const int InterlaceOffset[] = { 0, 4, 2, 1 };
void BitmapHeaderFromIff(IFFPTR piff, LPBITMAPINFOHEADER pbih)
{
pbih->biSize = sizeof(BITMAPINFOHEADER);
pbih->biWidth = piff->DimX;
pbih->biHeight = piff->DimY;
pbih->biPlanes = 1;
pbih->biCompression = 0;
pbih->biXPelsPerMeter= 0;
pbih->biYPelsPerMeter= 0;
pbih->biClrImportant = 0;
switch (piff->Class) {
case IFFCL_BILEVEL:
pbih->biBitCount = 1;
pbih->biClrUsed = 2;
break;
case IFFCL_PALETTE:
if (piff->Bits <= 4) {
pbih->biBitCount = 4;
pbih->biClrUsed = 16;
}
else {
pbih->biBitCount = 8;
pbih->biClrUsed = 256;
}
break;
case IFFCL_GRAY:
pbih->biBitCount = 8;
pbih->biClrUsed = 256;
break;
}
pbih->biSizeImage = (pbih->biWidth * pbih->biBitCount + 31) / 32;
pbih->biSizeImage *= 4 * pbih->biHeight;
}
BOOL LoadGif(PCSTR pszFile, HBITMAP* phbmp, HPALETTE* phpal, CHtmlHelpControl* phhctrl)
{
IFFPTR piff = GifOpen(pszFile);
if (!piff)
return FALSE;
CMem memBmi(sizeof(BITMAPINFOHEADER) +
sizeof(RGBQUAD) * (piff->Bits > 8 ? 0 : 256));
PBITMAPINFO pbmi = (PBITMAPINFO) memBmi.pb;
PBITMAPINFOHEADER pbih = (PBITMAPINFOHEADER) pbmi;
BitmapHeaderFromIff(piff, pbih);
if (pbih->biBitCount)
pbih->biBitCount = 8; // filter always returns 256-color image
ASSERT(pbih->biBitCount);
// Read in the palette
if (pbih->biBitCount && phpal) {
CMem memPal(768);
int cColors = ColorsFromBitDepth(pbih->biBitCount);
if (piff->Class == IFFCL_PALETTE || piff->Class == IFFCL_BILEVEL) {
GetImagePalette(piff, memPal.pb);
for (int i = 0; i < cColors; i++) {
pbmi->bmiColors[i].rgbRed = memPal.pb[i * 3];
pbmi->bmiColors[i].rgbGreen = memPal.pb[i * 3 + 1];
pbmi->bmiColors[i].rgbBlue = memPal.pb[i * 3 + 2];
pbmi->bmiColors[i].rgbReserved = 0;
}
}
else {
for (int i = 0; i < cColors; i++) {
pbmi->bmiColors[i].rgbRed =
pbmi->bmiColors[i].rgbGreen =
pbmi->bmiColors[i].rgbBlue = (BYTE) i;
pbmi->bmiColors[i].rgbReserved = 0;
}
}
*phpal = CreateBIPalette(pbih);
}
CPalDC dc;
if (phpal && *phpal)
dc.SelectPal(*phpal);
int cbLineWidth = ScanLineWidth(pbih->biWidth, pbih->biBitCount);
PBYTE pBits;
*phbmp = CreateDIBSection(dc.m_hdc, pbmi, DIB_RGB_COLORS,
(void**) &pBits, NULL, 0);
if (!*phbmp)
goto ErrorReturn;
if (piff->Sequence == IFFSEQ_INTERLACED) {
int InterPass = 0;
int InterLine = InterlaceOffset[InterPass];
for (int i = 0; i < pbih->biHeight; i++) {
int TmpLine = InterlaceMultiplier[InterPass] * InterLine + InterlaceOffset[InterPass];
// Small images will skip one or more passes
while (TmpLine >= pbih->biHeight) {
InterPass++;
InterLine = 0;
TmpLine = InterlaceOffset[InterPass];
if (TmpLine >= pbih->biHeight)
TmpLine = pbih->biHeight - 1;
}
PBYTE pbBits = pBits +
((pbih->biHeight - 1) - TmpLine) * cbLineWidth;
ASSERT(pbBits <= (pBits + ((pbih->biHeight - 1) * cbLineWidth)));
if (GifGetLine(1, pbBits, piff) == IFFERR_NONE) {
InterLine++;
}
else {
goto ErrorReturn;
}
}
}
else {
for (int i = 0; i < pbih->biHeight; i++) {
PBYTE pbBits = pBits +
((pbih->biHeight - 1) - i) * cbLineWidth;
int result = GifGetLine(1, pbBits, piff);
if (result != IFFERR_NONE) {
goto ErrorReturn;
}
}
}
GifClose(piff);
return TRUE;
ErrorReturn:
if (phhctrl)
phhctrl->AuthorMsg(IDSHHA_GIF_CORRUPT, pszFile);
else
doAuthorMsg(IDSHHA_GIF_CORRUPT, pszFile);
GifClose(piff);
if (phpal && *phpal) {
dc.SelectPal(NULL);
DeleteObject(*phpal);
}
return FALSE;
}
STATIC IFFPTR GifOpen(PCSTR pszFileName)
{
IFFPTR piff = (IFFPTR) lcCalloc(sizeof(IFF_FID));
UINT GetFlag = 0;
piff->Error = IFFERR_NONE;
piff->PackMode = IFFPM_NORMALIZED;
piff->linelen = -1;
if ((piff->Error = GetInit(pszFileName, piff, GetFlag)) != FSERR_NONE) {
if (piff->prstream) {
delete piff->prstream;
}
GIFFreeMemory(piff);
lcFree(piff);
return NULL;
}
SetUserParams(piff);
switch (piff->Class) {
case IFFCL_BILEVEL:
piff->LineBytes = (piff->DimX + 7) / 8;
piff->LineOffset = piff->DimX;
break;
case IFFCL_RGB:
piff->LineBytes = piff->DimX * 3;
piff->LineOffset = piff->LineBytes;
break;
default:
piff->LineBytes = piff->DimX;
piff->LineOffset = piff->LineBytes;
break;
}
return piff;
}
STATIC void GifClose(IFFPTR piff)
{
if (piff->prstream)
delete piff->prstream;
GIFFreeMemory(piff);
lcFree(piff);
}
STATIC int GifGetLine(int NumLines, PBYTE Buffer, IFFPTR piff)
{
int Count, RetCnt;
int UserWidth;
LPBYTE ptr;
if (piff == NULL)
return (IFFERR_PARAMETER);
if (piff->PackMode == IFFPM_PACKED)
UserWidth = piff->BytesPerLine;
else
UserWidth = piff->DimX;
do {
// if there are uncompressed lines in the buffer, just copy them
if (piff->StripLines > 0) {
ptr = piff->DecompBuffer + ((piff->ActualLinesPerStrip - piff->StripLines) * piff->BytesPerLine);
if (piff->PackMode == IFFPM_PACKED) {
IFF_PackLine(Buffer, ptr, piff->DimX, piff->Bits);
if (piff->BlackOnWhite)
InvertLine(Buffer, piff->DimX);
}
else
memcpy(Buffer, ptr, piff->DimX);
piff->StripLines--;
NumLines--;
piff->curline++;
Buffer += UserWidth;
}
else {
// decompress a strip, first get enough compressed data
if (!piff->ReadItAll) {
// copy already read lines to beginning of comp buffer
if (piff->BytesInRWBuffer)
memcpy(piff->RWBuffer, piff->rw_ptr, piff->BytesInRWBuffer);
piff->rw_ptr = piff->RWBuffer + piff->BytesInRWBuffer;
// read compressed blocks until comp buffer is full
while (piff->BytesInRWBuffer < (piff->CompBufferSize - 256)) {
BYTE BlockSize = piff->prstream->cget();
if (piff->prstream->m_fEndOfFile) {
piff->Error = IFFERR_IO_READ;
return piff->Error;
}
if (BlockSize == 0) {
piff->ReadItAll = 1;
break;
}
Count = BlockSize;
if (!piff->prstream->doRead(piff->rw_ptr, BlockSize)) {
piff->Error = IFFERR_IO_READ;
return piff->Error;
}
piff->BytesInRWBuffer += Count;
piff->rw_ptr += Count;
}
piff->rw_ptr = piff->RWBuffer;
}
// copy back already decompressed bytes to beginning of decomp buffer
if (piff->BytesLeft)
memcpy(piff->DecompBuffer, piff->dcmp_ptr, piff->BytesLeft);
piff->dcmp_ptr = piff->DecompBuffer + piff->BytesLeft;
// decompress to fill the decomp buffer
Count = piff->DecompBufferSize;
ASSERT(piff->plzData);
RetCnt = LZExpand(piff->plzData, piff->dcmp_ptr, piff->rw_ptr, Count, piff->BytesInRWBuffer);
if (RetCnt <= 0)
return IFFERR_IMAGE;
piff->BytesInRWBuffer -= RetCnt;
piff->rw_ptr += RetCnt;
piff->StripLines = Count / piff->BytesPerLine;
piff->BytesLeft = Count % piff->BytesPerLine;
piff->ActualLinesPerStrip = piff->StripLines;
piff->dcmp_ptr = piff->DecompBuffer + piff->StripLines * piff->BytesPerLine;
}
} while (NumLines);
return IFFERR_NONE;
}
STATIC void SetUserParams(IFFPTR piff)
{
int i;
BOOL fIsPalette;
piff->BlackOnWhite = FALSE;
fIsPalette = TRUE;
if (piff->Bits == 1) {
if (piff->Palette == NULL)
fIsPalette = FALSE;
else {
if (piff->Palette[0] == piff->Palette[1] &&
piff->Palette[1] == piff->Palette[2] &&
piff->Palette[0] == 0 &&
piff->Palette[3] == piff->Palette[4] &&
piff->Palette[4] == piff->Palette[5] &&
piff->Palette[3] == 255)
fIsPalette = FALSE;
if (piff->Palette[0] == piff->Palette[1] &&
piff->Palette[1] == piff->Palette[2] &&
piff->Palette[0] == 255 &&
piff->Palette[3] == piff->Palette[4] &&
piff->Palette[4] == piff->Palette[5] &&
piff->Palette[3] == 0)
{
piff->BlackOnWhite = TRUE;
fIsPalette = FALSE;
}
}
if (!fIsPalette)
piff->Class = IFFCL_BILEVEL;
}
if (fIsPalette) {
for (i = 0; i < piff->PaletteSize / 3; i++)
if (piff->Palette[i * 3] != piff->Palette[i * 3 + 1] ||
piff->Palette[i * 3 + 1] != piff->Palette[i * 3 + 2] ||
piff->Palette[i * 3] != (BYTE)i)
break;
if (i == piff->PaletteSize / 3) {
for (i = 0; i < piff->PaletteSize / 3; i++)
piff->Palette[i] = piff->Palette[i * 3];
piff->PaletteSize /= 3;
piff->Class = IFFCL_GRAY;
}
else
piff->Class = IFFCL_PALETTE;
}
}
STATIC int GetImagePalette(IFFPTR piff, LPBYTE Pal)
{
if (piff->PaletteSize > 0)
memcpy (Pal, piff->Palette, (unsigned) piff->PaletteSize);
else
return IFFERR_NOTAVAILABLE;
return IFFERR_NONE;
}
STATIC FSERR GetInit(PCSTR pszFileName, IFFPTR piff, UINT GetFlag)
{
BYTE Buffer[13];
piff->prstream = new CStream(pszFileName);
if (!piff->prstream->fInitialized) {
GIFFreeMemory(piff);
return FSERR_CANT_OPEN;
}
if (!piff->prstream->doRead(Buffer, GIF_HDR_SIZE)) {
GIFFreeMemory(piff);
piff->Error = IFFERR_IO_READ;
return FSERR_TRUNCATED;
}
if (((Buffer[0] != 'G') || (Buffer[1] != 'I') || (Buffer[2] != 'F') ||
(Buffer[3] != '8') || (Buffer[5] != 'a')) ||
((Buffer[4] != '7') && (Buffer[4] != '9'))) {
GIFFreeMemory(piff);
piff->Error = IFFERR_HEADER;
return FSERR_INVALID_FORMAT;
}
piff->prstream->read(&piff->lsd, sizeof(LSD));
piff->Bits = (int) (piff->lsd.b.ceGCT + 1);
piff->PaletteSize = 3 * (1 << piff->Bits);
if (piff->lsd.b.fGCT) {
piff->Palette = (PBYTE) lcMalloc(piff->PaletteSize);
if (!piff->prstream->doRead(piff->Palette, piff->PaletteSize)) {
GIFFreeMemory(piff);
piff->Error = IFFERR_IO_READ;
return FSERR_TRUNCATED;
}
}
for (;;) {
if (piff->prstream->m_fEndOfFile) {
piff->Error = IFFERR_IO_READ;
return FSERR_CORRUPTED_FILE;
}
Buffer[0] = piff->prstream->cget();
switch (*Buffer) {
case 0x21: // control extension
if (!piff->prstream->doRead(Buffer, 2)) {
GIFFreeMemory(piff);
piff->Error = IFFERR_IO_READ;
return FSERR_TRUNCATED;
}
switch (*Buffer) {
case 0xFF: // Application Specific Block
case 0xF9: // Graphics Control Extension
case 0x01: // Plain Text Extension
case 0xFE: // Comment Extension
while (Buffer[1] != 0) {
piff->prstream->seek((long) Buffer[1], SK_CUR);
if (piff->prstream->m_fEndOfFile) {
piff->Error = IFFERR_IO_READ;
return FSERR_CORRUPTED_FILE;
}
Buffer[1] = piff->prstream->cget();
}
break;
default:
ASSERT_COMMENT(FALSE, "The following code needs verification");
piff->prstream->seek(Buffer[1] + 1, SK_CUR);
break;
}
break;
case 0x3B: // end of file
return FSERR_NONE;
case 0x2C:
if (!piff->prstream->doRead((Buffer + 1), 9)) {
GIFFreeMemory(piff);
piff->Error = IFFERR_IO_READ;
return FSERR_TRUNCATED;
}
short IntData[2];
memcpy(IntData, Buffer + 5, 2 * sizeof(short));
INTELSWAP16 (IntData[0]);
INTELSWAP16 (IntData[1]);
piff->DimX = IntData[0];
piff->DimY = IntData[1];
if (Buffer[9] & 0x40)
piff->Sequence = IFFSEQ_INTERLACED;
else
piff->Sequence = IFFSEQ_TOPDOWN;
if (Buffer[9] & 0x80) {
piff->Bits = (Buffer[9] & 0x07) + 1;
int Size = (3 * (1 << piff->Bits));
// Ignore local color table for now
piff->prstream->seek(Size, SK_CUR);
}
BYTE CodeSize = piff->prstream->cget();
piff->BytesPerLine = piff->DimX;
piff->CompBufferSize = MAX_BUFFER_SIZE;
piff->DecompBufferSize = (MAX_BUFFER_SIZE >> 1) + (MAX_BUFFER_SIZE >> 2);
// calculate the number of lines in a strip
piff->StripLines = 0;
piff->LinesPerStrip = piff->DecompBufferSize / piff->BytesPerLine;
piff->DecompBufferSize = (piff->LinesPerStrip * piff->BytesPerLine);
piff->BytesInRWBuffer = 0;
piff->BytesLeft = 0;
piff->RWBuffer = (PBYTE) lcMalloc(piff->CompBufferSize);
piff->DecompBuffer = (PBYTE) lcMalloc(piff->DecompBufferSize);
piff->rw_ptr = piff->RWBuffer;
piff->dcmp_ptr = piff->DecompBuffer;
piff->curline = 0;
piff->plzData = LZInitialize(CodeSize);
if (piff->plzData == NULL) {
GIFFreeMemory(piff);
piff->Error = IFFERR_MEMORY;
return FSERR_INSF_MEMORY;
}
return FSERR_NONE;
}
}
return FSERR_NONE;
}
STATIC void GIFFreeMemory(IFFPTR piff)
{
if (piff->plzData != NULL)
LZCleanUp(piff->plzData);
if (piff->Palette)
lcClearFree(&piff->Palette);
if (piff->RWBuffer)
lcClearFree(&piff->RWBuffer);
if (piff->DecompBuffer)
lcClearFree(&piff->DecompBuffer);
piff->plzData = NULL;
return;
}
INLINE void InvertLine(LPBYTE Buffer, int DimX)
{
int il = (DimX + 7) >> 3;
for (int i = 0; i < il; i++)
*Buffer++ = 255 - *Buffer;
}
FSERR SetupForRead(int pos, int iWhichImage, IFF_FID* piff)
{
piff->prstream->seek(pos);
BYTE CodeSize = piff->prstream->cget();
piff->BytesPerLine = piff->DimX;
piff->CompBufferSize = MAX_BUFFER_SIZE;
piff->DecompBufferSize = (MAX_BUFFER_SIZE >> 1) + (MAX_BUFFER_SIZE >> 2);
// calculate the number of lines in a strip
piff->StripLines = 0;
piff->LinesPerStrip = piff->DecompBufferSize / piff->BytesPerLine;
piff->DecompBufferSize = (piff->LinesPerStrip * piff->BytesPerLine);
piff->BytesInRWBuffer = 0;
piff->BytesLeft = 0;
if (piff->RWBuffer)
lcFree(piff->RWBuffer);
piff->RWBuffer = (PBYTE) lcMalloc(piff->CompBufferSize);
if (piff->DecompBuffer)
lcFree(piff->DecompBuffer);
piff->DecompBuffer = (PBYTE) lcMalloc(piff->DecompBufferSize);
piff->rw_ptr = piff->RWBuffer;
piff->dcmp_ptr = piff->DecompBuffer;
piff->curline = 0;
if (piff->plzData)
LZCleanUp(piff->plzData);
piff->plzData = LZInitialize(CodeSize);
if (piff->plzData == NULL) {
GIFFreeMemory(piff);
piff->Error = IFFERR_MEMORY;
return FSERR_UNSUPPORTED_GIF_FORMAT;
}
// piff->Sequence = pGifImage->fInterlaced ? IFFSEQ_INTERLACED : IFFSEQ_TOPDOWN;
return FSERR_NONE;
}
int IFF_PackLine(PBYTE ToBuff, const BYTE* FromBuff, int Pixels, int Bits)
{
int Mask;
int PMask;
int Pix;
int Shift;
int i;
switch (Bits) {
case 1:
case 4:
Mask = ((8 / Bits) - 1);
Pix = 0;
Shift = (WORD) (8 - Bits);
PMask = (WORD) (0xFF >> Shift);
for (i = 0; i < Pixels; i++)
{
Pix |= *FromBuff++ & PMask;
if ((i & Mask) == Mask)
{
*ToBuff++ = (BYTE) Pix;
Pix = 0;
}
else
Pix <<= Bits;
}
if ((i & Mask) != 0)
{
while ((++i & Mask) != 0)
Pix <<= Bits;
*ToBuff = (BYTE) Pix;
}
return (Pixels + Mask) / (Mask + 1);
break;
case 8: // degenerate case
memcpy(ToBuff, FromBuff, Pixels);
return Pixels;
default:
IASSERT_COMMENT(FALSE, "Invalid bit depth");
break;
}
return 0;
}
INLINE void ExpandReset(LZDATA* plzData)
{
plzData->BitPos = 0;
plzData->CurBits = plzData->CharSize + 1;
plzData->OutString = 0;
plzData->CodeJump = (1 << plzData->CurBits) - 1;
plzData->CodeJump++;
}
INLINE unsigned GetNextCode(LZDATA* plzData)
{
unsigned short code;
int newbitpos;
code = (unsigned short) (*plzData->CodeInput | (plzData->CodeInput[1] << 8));
code >>= plzData->BitPos; // ditch previous bits
code &= 0xFFFF >> (16 - plzData->CurBits); // ditch next bits
newbitpos = plzData->BitPos + plzData->CurBits;
if (newbitpos > 7)
++plzData->CodeInput; // used up at least one * byte
if (newbitpos >= 16)
++plzData->CodeInput; // used up two bytes
if (newbitpos > 16) { // need more bits
code |= (*plzData->CodeInput << (32 - newbitpos)) >> (16 - plzData->CurBits);
code &= 0xFFFF >> (16 - plzData->CurBits); // ditch next bits
}
plzData->BitPos = newbitpos & 7;
return code; // need mask in 32 bit
}
STATIC int LZExpand(LZDATA* plzData, LPBYTE ToBuff, LPBYTE FromBuff, unsigned ToCnt, unsigned FromCnt)
{
unsigned cnt;
LPBYTE outbuff = ToBuff;
int code, incode;
ASSERT(plzData);
plzData->CodeInput = FromBuff;
cnt = ToCnt;
while (plzData->OutString > 0 && cnt > 0) {
*outbuff++ = plzData->Stack[--plzData->OutString];
cnt--;
}
while (cnt > 0) {
if ((code = GetNextCode(plzData)) == END_INFO)
break;
if (code == plzData->ClearCode) {
ZeroMemory(plzData->CodeTable, sizeof(int*) * HASH_SIZE);
for (int i = 0; i < HASH_SIZE; i++) {
// plzData->CodeTable[i] = 0;
plzData->StringTable[i] = (unsigned char) i;
}
plzData->CurBits = plzData->CharSize + 1; // start beginning
plzData->TableEntry = FIRST_ENTRY;
plzData->OutString = 0;
plzData->CodeJump = (1 << plzData->CurBits) - 1;
plzData->CodeJump++;
plzData->LastChar = plzData->OldCode = GetNextCode(plzData);
if (plzData->OldCode == END_INFO)
break;
*outbuff++ = (unsigned char) plzData->LastChar; // output a code
cnt--;
}
else {
if ((incode = code) >= plzData->TableEntry) { // is_in_code_table ?
plzData->Stack[plzData->OutString++] = (unsigned char) plzData->LastChar; /* not in table */
code = plzData->OldCode;
}
while (code >= plzData->ClearCode) { // need decoding
if ((plzData->OutString >= (1L << 12)) || (code > HASH_SIZE))
return -1;
plzData->Stack[plzData->OutString++] = plzData->StringTable[code];
code = plzData->CodeTable[code];
}
if (code < 0 || code > HASH_SIZE || plzData->TableEntry >= HASH_SIZE) {
// pretend that we decoded all data.
return min((int) (plzData->CodeInput - FromBuff), (int) FromCnt);
}
plzData->Stack[plzData->OutString++] =
(BYTE) (plzData->LastChar =
plzData->StringTable[code]);
// output string
while (plzData->OutString > 0 && cnt > 0) {
*outbuff++ = plzData->Stack[--plzData->OutString];
cnt--;
}
plzData->CodeTable[plzData->TableEntry] = plzData->OldCode; // Add string to table
plzData->StringTable[plzData->TableEntry++] = (unsigned char) plzData->LastChar;
if (plzData->TableEntry == plzData->CodeJump && plzData->CurBits < 12) {
plzData->CodeJump += 1 << plzData->CurBits;
plzData->CurBits++;
}
plzData->OldCode = incode;
}
} // End while
cnt = (UINT)(plzData->CodeInput - FromBuff);
return (cnt);
}
STATIC LZDATA* LZInitialize(int CharSize)
{
if (CharSize < 2)
CharSize = 2;
LZDATA* plzData = (LZDATA*) lcCalloc(sizeof(LZDATA));
plzData->CharSize = CharSize;
plzData->CodeSize = 12;
plzData->ClearCode = (1 << CharSize);
plzData->CodeTable = (int*) lcCalloc(sizeof(int) * HASH_SIZE);
plzData->StringTable = (PBYTE) lcCalloc(HASH_SIZE);
plzData->Stack = (PBYTE) lcCalloc(1 << 12);
ExpandReset(plzData);
return plzData;
}
STATIC void LZCleanUp(LZDATA* plzData)
{
if (plzData == NULL)
return;
if (plzData->CodeTable)
lcFree(plzData->CodeTable);
if (plzData->StringTable)
lcFree(plzData->StringTable);
if (plzData->HashTable)
lcFree(plzData->HashTable);
if (plzData->Stack)
lcFree(plzData->Stack);
lcFree(plzData);
}
INLINE int ColorsFromBitDepth(int bitsperpixel)
{
switch (bitsperpixel) {
case 1:
return 2;
case 4:
return 16;
case 8:
return 256;
break;
default:
return 0;
}
}
INLINE int ScanLineWidth(int width, int bitcount)
{
switch (bitcount) {
case 1: // REVIEW: is this true?
return ((width + 31) & ~31) * bitcount / 8;
case 4:
return ((width * 4 + 31) / 32 * 4);
case 8:
break;
default:
IASSERT(!"Invalid bitcount value in ScanLineWidth");
break;
}
if (width & 0x03)
width += (4 - width % 4);
return width;
}