scummvm/engines/mohawk/bitmap.cpp
2012-09-09 17:31:45 -04:00

861 lines
25 KiB
C++

/* ScummVM - Graphic Adventure Engine
*
* ScummVM is the legal property of its developers, whose names
* are too numerous to list here. Please refer to the COPYRIGHT
* file distributed with this source distribution.
*
* This program is free software; you can redistribute it and/or
* modify it under the terms of the GNU General Public License
* as published by the Free Software Foundation; either version 2
* of the License, or (at your option) any later version.
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software
* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA.
*
*/
#include "mohawk/bitmap.h"
#include "common/debug.h"
#include "common/util.h"
#include "common/endian.h"
#include "common/memstream.h"
#include "common/substream.h"
#include "common/system.h"
#include "common/textconsole.h"
#include "graphics/decoders/bmp.h"
namespace Mohawk {
#define PACK_COMPRESSION (_header.format & kPackMASK)
#define DRAW_COMPRESSION (_header.format & kDrawMASK)
MohawkBitmap::MohawkBitmap() {
static const PackFunction packTable[] = {
{ kPackNone, "Raw", &MohawkBitmap::unpackRaw },
{ kPackLZ, "LZ", &MohawkBitmap::unpackLZ },
{ kPackRiven, "Riven", &MohawkBitmap::unpackRiven }
};
_packTable = packTable;
_packTableSize = ARRAYSIZE(packTable);
static const DrawFunction drawTable[] = {
{ kDrawRaw, "Raw", &MohawkBitmap::drawRaw },
{ kDrawRLE8, "RLE8", &MohawkBitmap::drawRLE8 }
};
_drawTable = drawTable;
_drawTableSize = ARRAYSIZE(drawTable);
}
MohawkBitmap::~MohawkBitmap() {
}
void MohawkBitmap::decodeImageData(Common::SeekableReadStream *stream) {
_data = stream;
_header.colorTable.palette = NULL;
// NOTE: Only the bottom 12 bits of width/height/bytesPerRow are
// considered valid and bytesPerRow has to be an even number.
_header.width = _data->readUint16BE() & 0x3FFF;
_header.height = _data->readUint16BE() & 0x3FFF;
_header.bytesPerRow = _data->readSint16BE() & 0x3FFE;
_header.format = _data->readUint16BE();
debug (2, "Decoding Mohawk Bitmap (%dx%d, %dbpp, %s Packing + %s Drawing)", _header.width, _header.height, getBitsPerPixel(), getPackName(), getDrawName());
if (getBitsPerPixel() != 8 && getBitsPerPixel() != 24)
error ("Unhandled bpp %d", getBitsPerPixel());
// Read in the palette if it's here.
if (_header.format & kBitmapHasCLUT || (PACK_COMPRESSION == kPackRiven && getBitsPerPixel() == 8)) {
_header.colorTable.tableSize = _data->readUint16BE();
_header.colorTable.rgbBits = _data->readByte();
_header.colorTable.colorCount = _data->readByte();
_header.colorTable.palette = (byte *)malloc(256 * 3);
for (uint16 i = 0; i < 256; i++) {
_header.colorTable.palette[i * 3 + 2] = _data->readByte();
_header.colorTable.palette[i * 3 + 1] = _data->readByte();
_header.colorTable.palette[i * 3 + 0] = _data->readByte();
}
}
unpackImage();
}
MohawkSurface *MohawkBitmap::decodeImage(Common::SeekableReadStream *stream) {
decodeImageData(stream);
Graphics::Surface *surface = createSurface(_header.width, _header.height);
drawImage(surface);
delete _data;
return new MohawkSurface(surface, _header.colorTable.palette);
}
Common::Array<MohawkSurface *> MohawkBitmap::decodeImages(Common::SeekableReadStream *stream) {
decodeImageData(stream);
// Some Mohawk games (CSTime, Zoombinis) store 'compound shapes' by
// packing several sub-images inside the data portion of an image.
// We take a copy of what we need (since it will be overwritten),
// and then decodeImage() all these sub-images.
Common::SeekableReadStream *data = _data;
int32 startPos = data->pos();
uint16 count = _header.width;
Common::Array<uint32> offsets;
for (uint i = 0; i < count; i++)
offsets.push_back(data->readUint32BE());
Common::Array<MohawkSurface *> surfaces;
for (uint i = 0; i < count; i++) {
uint32 start = startPos + offsets[i] - 8;
uint32 end;
if (i != (uint)count - 1)
end = startPos + offsets[i + 1] - 8;
else
end = data->size();
Common::SeekableSubReadStream *substream = new Common::SeekableSubReadStream(data, start, end);
surfaces.push_back(decodeImage(substream));
}
delete data;
return surfaces;
}
Graphics::Surface *MohawkBitmap::createSurface(uint16 width, uint16 height) {
Graphics::Surface *surface = new Graphics::Surface();
Graphics::PixelFormat format;
if (getBitsPerPixel() <= 8)
format = Graphics::PixelFormat::createFormatCLUT8();
else
format = g_system->getScreenFormat();
surface->create(width, height, format);
return surface;
}
byte MohawkBitmap::getBitsPerPixel() {
switch (_header.format & kBitsPerPixelMask) {
case kBitsPerPixel1:
return 1;
case kBitsPerPixel4:
return 4;
case kBitsPerPixel8:
return 8;
case kBitsPerPixel16:
return 16;
case kBitsPerPixel24:
return 24;
default:
error("Unknown bits per pixel");
}
return 0;
}
const char *MohawkBitmap::getPackName() {
for (int i = 0; i < _packTableSize; i++)
if (PACK_COMPRESSION == _packTable[i].flag)
return _packTable[i].name;
return "Unknown";
}
void MohawkBitmap::unpackImage() {
for (int i = 0; i < _packTableSize; i++)
if (PACK_COMPRESSION == _packTable[i].flag) {
(this->*_packTable[i].func)();
return;
}
error("Unknown Pack Compression");
}
const char *MohawkBitmap::getDrawName() {
for (int i = 0; i < _drawTableSize; i++)
if (DRAW_COMPRESSION == _drawTable[i].flag)
return _drawTable[i].name;
return "Unknown";
}
void MohawkBitmap::drawImage(Graphics::Surface *surface) {
for (int i = 0; i < _drawTableSize; i++)
if (DRAW_COMPRESSION == _drawTable[i].flag) {
(this->*_drawTable[i].func)(surface);
return;
}
error("Unknown Draw Compression");
}
//////////////////////////////////////////
// Raw "Unpacker"
//////////////////////////////////////////
void MohawkBitmap::unpackRaw() {
// Do nothing :D
}
//////////////////////////////////////////
// LZ Unpacker
//////////////////////////////////////////
#define LEN_BITS 6
#define MIN_STRING 3 // lower limit for string length
#define POS_BITS (16 - LEN_BITS)
#define MAX_STRING ((1 << LEN_BITS) + MIN_STRING - 1) // upper limit for string length
#define CBUFFERSIZE (1 << POS_BITS) // size of the circular buffer
#define POS_MASK (CBUFFERSIZE - 1)
Common::SeekableReadStream *MohawkBitmap::decompressLZ(Common::SeekableReadStream *stream, uint32 uncompressedSize) {
uint16 flags = 0;
uint32 bytesOut = 0;
uint16 insertPos = 0;
// Expand the output buffer to at least the ring buffer size
uint32 outBufSize = MAX<int>(uncompressedSize, CBUFFERSIZE);
byte *outputData = (byte *)malloc(outBufSize);
byte *dst = outputData;
byte *buf = dst;
// Clear the buffer to all 0's
memset(outputData, 0, outBufSize);
while (stream->pos() < stream->size()) {
flags >>= 1;
if (!(flags & 0x100))
flags = stream->readByte() | 0xff00;
if (flags & 1) {
if (++bytesOut > uncompressedSize)
break;
*dst++ = stream->readByte();
if (++insertPos > POS_MASK) {
insertPos = 0;
buf += CBUFFERSIZE;
}
} else {
uint16 offLen = stream->readUint16BE();
uint16 stringLen = (offLen >> POS_BITS) + MIN_STRING;
uint16 stringPos = (offLen + MAX_STRING) & POS_MASK;
bytesOut += stringLen;
if (bytesOut > uncompressedSize)
stringLen -= bytesOut - uncompressedSize;
byte *strPtr = buf + stringPos;
if (stringPos > insertPos) {
if (bytesOut >= CBUFFERSIZE)
strPtr -= CBUFFERSIZE;
else if (stringPos + stringLen > POS_MASK) {
for (uint16 k = 0; k < stringLen; k++) {
*dst++ = *strPtr++;
if (++stringPos > POS_MASK) {
stringPos = 0;
strPtr = outputData;
}
}
insertPos = (insertPos + stringLen) & POS_MASK;
if (bytesOut >= uncompressedSize)
break;
continue;
}
}
insertPos += stringLen;
if (insertPos > POS_MASK) {
insertPos &= POS_MASK;
buf += CBUFFERSIZE;
}
for (uint16 k = 0; k < stringLen; k++)
*dst++ = *strPtr++;
if (bytesOut >= uncompressedSize)
break;
}
}
return new Common::MemoryReadStream(outputData, uncompressedSize, DisposeAfterUse::YES);
}
void MohawkBitmap::unpackLZ() {
uint32 uncompressedSize = _data->readUint32BE();
/* uint32 compressedSize = */ _data->readUint32BE();
uint16 dictSize = _data->readUint16BE();
// We only support the buffer size of 0x400
if (dictSize != CBUFFERSIZE)
error("Unsupported dictionary size of %04x", dictSize);
// Now go and decompress the data
Common::SeekableReadStream *decompressedData = decompressLZ(_data, uncompressedSize);
delete _data;
_data = decompressedData;
}
//////////////////////////////////////////
// Riven Unpacker
//////////////////////////////////////////
void MohawkBitmap::unpackRiven() {
_data->readUint32BE(); // Unknown, the number is close to bytesPerRow * height. Could be bufSize.
byte *uncompressedData = (byte *)malloc(_header.bytesPerRow * _header.height);
byte *dst = uncompressedData;
while (!_data->eos() && dst < (uncompressedData + _header.bytesPerRow * _header.height)) {
byte cmd = _data->readByte();
debug (8, "Riven Pack Command %02x", cmd);
if (cmd == 0x00) { // End of stream
break;
} else if (cmd >= 0x01 && cmd <= 0x3f) { // Simple Pixel Duplet Output
for (byte i = 0; i < cmd; i++) {
*dst++ = _data->readByte();
*dst++ = _data->readByte();
}
} else if (cmd >= 0x40 && cmd <= 0x7f) { // Simple Repetition of last 2 pixels (cmd - 0x40) times
byte pixel[] = { *(dst - 2), *(dst - 1) };
for (byte i = 0; i < (cmd - 0x40); i++) {
*dst++ = pixel[0];
*dst++ = pixel[1];
}
} else if (cmd >= 0x80 && cmd <= 0xbf) { // Simple Repetition of last 4 pixels (cmd - 0x80) times
byte pixel[] = { *(dst - 4), *(dst - 3), *(dst - 2), *(dst - 1) };
for (byte i = 0; i < (cmd - 0x80); i++) {
*dst++ = pixel[0];
*dst++ = pixel[1];
*dst++ = pixel[2];
*dst++ = pixel[3];
}
} else { // Subcommand Stream of (cmd - 0xc0) subcommands
handleRivenSubcommandStream(cmd - 0xc0, dst);
}
}
delete _data;
_data = new Common::MemoryReadStream(uncompressedData, _header.bytesPerRow * _header.height, DisposeAfterUse::YES);
}
static byte getLastTwoBits(byte c) {
return (c & 0x03);
}
static byte getLastThreeBits(byte c) {
return (c & 0x07);
}
static byte getLastFourBits(byte c) {
return (c & 0x0f);
}
#define B_BYTE() \
*dst = _data->readByte(); \
dst++
#define B_LASTDUPLET() \
*dst = *(dst - 2); \
dst++
#define B_LASTDUPLET_PLUS_M() \
*dst = *(dst - 2) + m; \
dst++
#define B_LASTDUPLET_MINUS_M() \
*dst = *(dst - 2) - m; \
dst++
#define B_LASTDUPLET_PLUS(m) \
*dst = *(dst - 2) + (m); \
dst++
#define B_LASTDUPLET_MINUS(m) \
*dst = *(dst - 2) - (m); \
dst++
#define B_PIXEL_MINUS(m) \
*dst = *(dst - (m)); \
dst++
#define B_NDUPLETS(n) \
uint16 m1 = ((getLastTwoBits(cmd) << 8) + _data->readByte()); \
for (uint16 j = 0; j < (n); j++) { \
*dst = *(dst - m1); \
dst++; \
} \
void dummyFuncToAllowTrailingSemicolon()
void MohawkBitmap::handleRivenSubcommandStream(byte count, byte *&dst) {
for (byte i = 0; i < count; i++) {
byte cmd = _data->readByte();
uint16 m = getLastFourBits(cmd);
debug (9, "Riven Pack Subcommand %02x", cmd);
// Notes: p = value of the next byte, m = last four bits of the command
// Arithmetic operations
if (cmd >= 0x01 && cmd <= 0x0f) {
// Repeat duplet at relative position of -m duplets
B_PIXEL_MINUS(m * 2);
B_PIXEL_MINUS(m * 2);
} else if (cmd == 0x10) {
// Repeat last duplet, but set the value of the second pixel to p
B_LASTDUPLET();
B_BYTE();
} else if (cmd >= 0x11 && cmd <= 0x1f) {
// Repeat last duplet, but set the value of the second pixel to the value of the -m pixel
B_LASTDUPLET();
B_PIXEL_MINUS(m);
} else if (cmd >= 0x20 && cmd <= 0x2f) {
// Repeat last duplet, but add x to second pixel
B_LASTDUPLET();
B_LASTDUPLET_PLUS_M();
} else if (cmd >= 0x30 && cmd <= 0x3f) {
// Repeat last duplet, but subtract x from second pixel
B_LASTDUPLET();
B_LASTDUPLET_MINUS_M();
} else if (cmd == 0x40) {
// Repeat last duplet, but set the value of the first pixel to p
B_BYTE();
B_LASTDUPLET();
} else if (cmd >= 0x41 && cmd <= 0x4f) {
// Output pixel at relative position -m, then second pixel of last duplet
B_PIXEL_MINUS(m);
B_LASTDUPLET();
} else if (cmd == 0x50) {
// Output two absolute pixel values, p1 and p2
B_BYTE();
B_BYTE();
} else if (cmd >= 0x51 && cmd <= 0x57) {
// Output pixel at relative position -m, then absolute pixel value p
// m is the last 3 bits of cmd here, not last 4
B_PIXEL_MINUS(getLastThreeBits(cmd));
B_BYTE();
} else if (cmd >= 0x59 && cmd <= 0x5f) {
// Output absolute pixel value p, then pixel at relative position -m
// m is the last 3 bits of cmd here, not last 4
B_BYTE();
B_PIXEL_MINUS(getLastThreeBits(cmd));
} else if (cmd >= 0x60 && cmd <= 0x6f) {
// Output absolute pixel value p, then (second pixel of last duplet) + x
B_BYTE();
B_LASTDUPLET_PLUS_M();
} else if (cmd >= 0x70 && cmd <= 0x7f) {
// Output absolute pixel value p, then (second pixel of last duplet) - x
B_BYTE();
B_LASTDUPLET_MINUS_M();
} else if (cmd >= 0x80 && cmd <= 0x8f) {
// Repeat last duplet adding x to the first pixel
B_LASTDUPLET_PLUS_M();
B_LASTDUPLET();
} else if (cmd >= 0x90 && cmd <= 0x9f) {
// Output (first pixel of last duplet) + x, then absolute pixel value p
B_LASTDUPLET_PLUS_M();
B_BYTE();
} else if (cmd == 0xa0) {
// Repeat last duplet, adding first 4 bits of the next byte
// to first pixel and last 4 bits to second
byte pattern = _data->readByte();
B_LASTDUPLET_PLUS(pattern >> 4);
B_LASTDUPLET_PLUS(getLastFourBits(pattern));
} else if (cmd == 0xb0) {
// Repeat last duplet, adding first 4 bits of the next byte
// to first pixel and subtracting last 4 bits from second
byte pattern = _data->readByte();
B_LASTDUPLET_PLUS(pattern >> 4);
B_LASTDUPLET_MINUS(getLastFourBits(pattern));
} else if (cmd >= 0xc0 && cmd <= 0xcf) {
// Repeat last duplet subtracting x from first pixel
B_LASTDUPLET_MINUS_M();
B_LASTDUPLET();
} else if (cmd >= 0xd0 && cmd <= 0xdf) {
// Output (first pixel of last duplet) - x, then absolute pixel value p
B_LASTDUPLET_MINUS_M();
B_BYTE();
} else if (cmd == 0xe0) {
// Repeat last duplet, subtracting first 4 bits of the next byte
// to first pixel and adding last 4 bits to second
byte pattern = _data->readByte();
B_LASTDUPLET_MINUS(pattern >> 4);
B_LASTDUPLET_PLUS(getLastFourBits(pattern));
} else if (cmd == 0xf0 || cmd == 0xff) {
// Repeat last duplet, subtracting first 4 bits from the next byte
// to first pixel and last 4 bits from second
byte pattern = _data->readByte();
B_LASTDUPLET_MINUS(pattern >> 4);
B_LASTDUPLET_MINUS(getLastFourBits(pattern));
// Repeat operations
// Repeat n duplets from relative position -m (given in pixels, not duplets).
// If r is 0, another byte follows and the last pixel is set to that value
} else if (cmd >= 0xa4 && cmd <= 0xa7) {
B_NDUPLETS(3);
B_BYTE();
} else if (cmd >= 0xa8 && cmd <= 0xab) {
B_NDUPLETS(4);
} else if (cmd >= 0xac && cmd <= 0xaf) {
B_NDUPLETS(5);
B_BYTE();
} else if (cmd >= 0xb4 && cmd <= 0xb7) {
B_NDUPLETS(6);
} else if (cmd >= 0xb8 && cmd <= 0xbb) {
B_NDUPLETS(7);
B_BYTE();
} else if (cmd >= 0xbc && cmd <= 0xbf) {
B_NDUPLETS(8);
} else if (cmd >= 0xe4 && cmd <= 0xe7) {
B_NDUPLETS(9);
B_BYTE();
} else if (cmd >= 0xe8 && cmd <= 0xeb) {
B_NDUPLETS(10); // 5 duplets
} else if (cmd >= 0xec && cmd <= 0xef) {
B_NDUPLETS(11);
B_BYTE();
} else if (cmd >= 0xf4 && cmd <= 0xf7) {
B_NDUPLETS(12);
} else if (cmd >= 0xf8 && cmd <= 0xfb) {
B_NDUPLETS(13);
B_BYTE();
} else if (cmd == 0xfc) {
byte b1 = _data->readByte();
byte b2 = _data->readByte();
uint16 m1 = ((getLastTwoBits(b1) << 8) + b2);
for (uint16 j = 0; j < ((b1 >> 3) + 1); j++) { // one less iteration
B_PIXEL_MINUS(m1);
B_PIXEL_MINUS(m1);
}
// last iteration
B_PIXEL_MINUS(m1);
if ((b1 & (1 << 2)) == 0) {
B_BYTE();
} else {
B_PIXEL_MINUS(m1);
}
} else
warning("Unknown Riven Pack Subcommand 0x%02x", cmd);
}
}
//////////////////////////////////////////
// Raw Drawer
//////////////////////////////////////////
void MohawkBitmap::drawRaw(Graphics::Surface *surface) {
assert(surface);
for (uint16 y = 0; y < _header.height; y++) {
if (getBitsPerPixel() == 24) {
Graphics::PixelFormat pixelFormat = g_system->getScreenFormat();
for (uint16 x = 0; x < _header.width; x++) {
byte b = _data->readByte();
byte g = _data->readByte();
byte r = _data->readByte();
if (surface->format.bytesPerPixel == 2)
*((uint16 *)surface->getBasePtr(x, y)) = pixelFormat.RGBToColor(r, g, b);
else
*((uint32 *)surface->getBasePtr(x, y)) = pixelFormat.RGBToColor(r, g, b);
}
_data->skip(_header.bytesPerRow - _header.width * 3);
} else {
_data->read((byte *)surface->pixels + y * _header.width, _header.width);
_data->skip(_header.bytesPerRow - _header.width);
}
}
}
//////////////////////////////////////////
// RLE8 Drawer
//////////////////////////////////////////
void MohawkBitmap::drawRLE8(Graphics::Surface *surface, bool isLE) {
// A very simple RLE8 scheme is used as a secondary compression on
// most images in non-Riven tBMP's.
assert(surface);
for (uint16 i = 0; i < _header.height; i++) {
uint16 rowByteCount = isLE ? _data->readUint16LE() : _data->readUint16BE();
int32 startPos = _data->pos();
byte *dst = (byte *)surface->pixels + i * _header.width;
int16 remaining = _header.width;
while (remaining > 0) {
byte code = _data->readByte();
uint16 runLen = (code & 0x7F) + 1;
if (runLen > remaining)
runLen = remaining;
if (code & 0x80) {
byte val = _data->readByte();
memset(dst, val, runLen);
} else {
_data->read(dst, runLen);
}
dst += runLen;
remaining -= runLen;
}
_data->seek(startPos + rowByteCount);
}
}
#ifdef ENABLE_MYST
//////////////////////////////////////////
// Myst Bitmap Decoder
//////////////////////////////////////////
MohawkSurface *MystBitmap::decodeImage(Common::SeekableReadStream *stream) {
uint32 uncompressedSize = stream->readUint32LE();
Common::SeekableReadStream *bmpStream = decompressLZ(stream, uncompressedSize);
delete stream;
Graphics::BitmapDecoder bitmapDecoder;
if (!bitmapDecoder.loadStream(*bmpStream))
error("Could not decode Myst bitmap");
const Graphics::Surface *bmpSurface = bitmapDecoder.getSurface();
Graphics::Surface *newSurface = 0;
if (bmpSurface->format.bytesPerPixel == 1) {
_bitsPerPixel = 8;
newSurface = new Graphics::Surface();
newSurface->copyFrom(*bmpSurface);
} else {
_bitsPerPixel = 24;
newSurface = bmpSurface->convertTo(g_system->getScreenFormat());
}
// Copy the palette to one of our own
byte *newPal = 0;
if (bitmapDecoder.hasPalette()) {
const byte *palette = bitmapDecoder.getPalette();
newPal = (byte *)malloc(256 * 3);
memcpy(newPal, palette, 256 * 3);
}
delete bmpStream;
return new MohawkSurface(newSurface, newPal);
}
#endif
MohawkSurface *LivingBooksBitmap_v1::decodeImage(Common::SeekableReadStream *stream) {
Common::SeekableSubReadStreamEndian *endianStream = (Common::SeekableSubReadStreamEndian *)stream;
// 12 bytes header for the image
_header.format = endianStream->readUint16();
_header.bytesPerRow = endianStream->readUint16();
_header.width = endianStream->readUint16();
_header.height = endianStream->readUint16();
int offsetX = endianStream->readSint16();
int offsetY = endianStream->readSint16();
debug(7, "Decoding Old Mohawk Bitmap (%dx%d, %d bytesPerRow, %04x Format)", _header.width, _header.height, _header.bytesPerRow, _header.format);
debug(7, "Offset X = %d, Y = %d", offsetX, offsetY);
bool leRLE8 = false;
if ((_header.format & 0xf0) == kOldPackLZ) {
// 12 bytes header for the compressed data
uint32 uncompressedSize = endianStream->readUint32();
uint32 compressedSize = endianStream->readUint32();
uint16 posBits = endianStream->readUint16();
uint16 lengthBits = endianStream->readUint16();
if (compressedSize != (uint32)endianStream->size() - 24)
error("More bytes (%d) remaining in stream than header says there should be (%d)", endianStream->size() - 24, compressedSize);
// These two errors are really just sanity checks and should never go off
if (posBits != POS_BITS)
error("Position bits modified to %d", posBits);
if (lengthBits != LEN_BITS)
error("Length bits modified to %d", lengthBits);
_data = decompressLZ(stream, uncompressedSize);
if (endianStream->pos() != endianStream->size())
error("LivingBooksBitmap_v1 decompression failed");
} else {
if ((_header.format & 0xf0) != 0)
error("Tried to use unknown LivingBooksBitmap_v1 compression (format %02x)", _header.format & 0xf0);
// This is so nasty on so many levels. The original Windows LZ decompressor for the
// Living Books v1 games had knowledge of the underlying RLE8 data. While going
// through the LZ data, it would byte swap the RLE8 length fields to make them LE.
// This is an extremely vile thing and there's no way in hell that I'm doing
// anything similar. When no LZ compression is used, the underlying RLE8 fields
// are LE, so we need to set a swap in this condition for LE vs. BE in the RLE8
// decoder. *sigh*
if (!endianStream->isBE())
leRLE8 = true;
_data = stream;
stream = NULL;
}
Graphics::Surface *surface = createSurface(_header.width, _header.height);
if ((_header.format & 0xf00) == kOldDrawRLE8)
drawRLE8(surface, leRLE8);
else
drawRaw(surface);
delete _data;
delete stream;
MohawkSurface *mhkSurface = new MohawkSurface(surface);
mhkSurface->setOffsetX(offsetX);
mhkSurface->setOffsetY(offsetY);
return mhkSurface;
}
// Partially based on the Prince of Persia Format Specifications
// See http://sdfg.com.ar/git/?p=fp-git.git;a=blob;f=FP/doc/FormatSpecifications
MohawkSurface *DOSBitmap::decodeImage(Common::SeekableReadStream *stream) {
_header.height = stream->readUint16LE();
_header.width = stream->readUint16LE();
stream->readByte(); // Always 0
_header.format = stream->readByte();
debug(2, "Decoding DOS Bitmap (%dx%d, %dbpp, Compression %d)", _header.width, _header.height, getBitsPerPixel(), _header.format & 0xf);
// All the PoP games seem to have this flag, but at least CSWorld Deluxe doesn't...
// Perhaps this differentiates between normal bitmap mode and planar mode?
if (_header.format & 0x80)
error("Unknown EGA flag?");
// Calculate the bytes per row
byte pixelsPerByte = 8 / getBitsPerPixel();
_header.bytesPerRow = (_header.width + pixelsPerByte - 1) / pixelsPerByte;
// Only Raw and LZ L/R are supported currently
// Notice how Broderbund used their same LZ compression for every PC game possibly ever?
switch (_header.format & 0xf) {
case 0: // Raw
_data = stream;
break;
case 3: // LZ Left/Right
_data = decompressLZ(stream, _header.bytesPerRow * _header.height);
delete stream;
break;
case 1: // RLE Left/Right (Used by PoP, haven't seen in a CS game)
case 2: // RLE Up/Down (Used by PoP, haven't seen in a CS game)
case 4: // LZ Up/Down (Used by CS America's Past and CS Space)
error("Unhandled DOS bitmap compression %d", _header.format & 0xf);
break;
default:
error("Unknown DOS bitmap compression %d", _header.format & 0xf);
}
Graphics::Surface *surface = createSurface(_header.width, _header.height);
memset(surface->pixels, 0, _header.width * _header.height);
// Expand the <8bpp data to one byte per pixel
switch (getBitsPerPixel()) {
case 1:
expandMonochromePlane(surface, _data);
break;
case 4:
expandEGAPlanes(surface, _data);
break;
default:
error("Unhandled %dbpp", getBitsPerPixel());
}
delete _data;
return new MohawkSurface(surface);
}
void DOSBitmap::expandMonochromePlane(Graphics::Surface *surface, Common::SeekableReadStream *rawStream) {
assert(surface->format.bytesPerPixel == 1);
byte *dst = (byte *)surface->pixels;
// Expand the 8 pixels in a byte into a full byte per pixel
for (uint32 i = 0; i < surface->h; i++) {
for (uint x = 0; x < surface->w;) {
byte temp = rawStream->readByte();
for (int j = 7; j >= 0 && x < surface->w; j--) {
if (temp & (1 << j))
*dst++ = 0xf;
else
*dst++ = 0;
x++;
}
}
}
}
#define ADD_BIT(dstPixel, srcBit) \
*(dst + j * 4 + dstPixel) = (*(dst + j * 4 + dstPixel) >> 1) | (((temp >> srcBit) & 1) << 3)
void DOSBitmap::expandEGAPlanes(Graphics::Surface *surface, Common::SeekableReadStream *rawStream) {
assert(surface->format.bytesPerPixel == 1);
// Note that the image is in EGA planar form and not just standard 4bpp
// This seems to contradict the PoP specs which seem to do something else
byte *dst = (byte *)surface->pixels;
for (uint32 i = 0; i < surface->h; i++) {
uint x = 0;
for (int32 j = 0; j < surface->w / 4; j++) {
byte temp = rawStream->readByte();
ADD_BIT(3, 4);
ADD_BIT(2, 5);
ADD_BIT(1, 6);
ADD_BIT(0, 7);
j++;
ADD_BIT(3, 0);
ADD_BIT(2, 1);
ADD_BIT(1, 2);
ADD_BIT(0, 3);
if (x < 3 && j + 1 >= surface->w / 4) {
j = -1;
x++;
}
}
dst += surface->w;
}
}
} // End of namespace Mohawk