scummvm/engines/gob/coktelvideo.cpp

/* 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.
 *
 * $URL$
 * $Id$
 *
 */

#include "common/endian.h"
#include "common/system.h"

#include "gob/coktelvideo.h"
#include "gob/indeo3.h"

namespace Gob {

Imd::Imd() {
	clear(false);
}

Imd::~Imd() {
	clear();
}

bool Imd::load(Common::SeekableReadStream &stream) {
	unload();

	_stream = &stream;

	// Version
	uint16 handle = _stream->readUint16LE();
	_version = _stream->readByte();

	// Version checking
	if ((handle != 0) || (_version < 2)) {
		warning("IMD Version incorrect (%d,%X)", handle, _version);
		unload();
		return false;
	}

	// Rest header
	_features = _stream->readByte();
	_framesCount = _stream->readUint16LE();
	_x = _stream->readSint16LE();
	_y = _stream->readSint16LE();
	_width = _stream->readSint16LE();
	_height = _stream->readSint16LE();
	_flags = _stream->readUint16LE();
	_firstFramePos = _stream->readUint16LE();

	// IMDs always have video
	_features |= kFeaturesVideo;
	// IMDs always have palettes
	_features |= kFeaturesPalette;

	// Palette
	_stream->read((byte *) _palette, 768);

	// Standard coordinates
	if (_version >= 3) {
		_stdX = _stream->readUint16LE();
		if (_stdX > 1) {
			warning("IMD: More than one standard coordinate quad found (%d)", _stdX);
			unload();
			return false;
		}
		if (_stdX != 0) {
			_stdX = _stream->readSint16LE();
			_stdY = _stream->readSint16LE();
			_stdWidth = _stream->readSint16LE();
			_stdHeight = _stream->readSint16LE();
			_features |= kFeaturesStdCoords;
		} else
			_stdX = -1;
	} else
		_stdX = -1;

	// Offset to frame positions table
	uint32 framesPosPos = 0;
	if (_version >= 4) {
		framesPosPos = _stream->readUint32LE();
		if (framesPosPos != 0) {
			_framesPos = new uint32[_framesCount];
			assert(_framesPos);
			_features |= kFeaturesFramesPos;
		}
	}

	// Offset to frame coordinates
	uint32 framesCoordsPos = 0;
	if (_features & kFeaturesFrameCoords)
		framesCoordsPos = _stream->readUint32LE();

	// Sound
	if (_features & kFeaturesSound) {
		_soundFreq = _stream->readSint16LE();
		_soundSliceSize = _stream->readSint16LE();
		_soundSlicesCount = _stream->readSint16LE();

		if (_soundFreq < 0)
			_soundFreq = -_soundFreq;

		if (_soundSlicesCount < 0)
			_soundSlicesCount = -_soundSlicesCount - 1;

		if (_soundSlicesCount > 40) {
			warning("IMD: More than 40 sound slices found (%d)", _soundSlicesCount);
			unload();
			return false;
		}

		_soundSliceLength = (uint32) (((double) (1000 << 16)) / 
				((double) _soundFreq / (double) _soundSliceSize));
		_frameLength = _soundSliceLength >> 16;

		_soundStage = 1;
		_hasSound = true;

		_audioStream = Audio::makeAppendableAudioStream(_soundFreq, 0);
	} else
		_frameLength = 1000 / _frameRate;

	// Sizes of the frame data and extra video buffer
	if (_features & kFeaturesDataSize) {
		_frameDataSize = _stream->readUint16LE();
		if (_frameDataSize == 0) {
			_frameDataSize = _stream->readUint32LE();
			_vidBufferSize = _stream->readUint32LE();
		} else
			_vidBufferSize = _stream->readUint16LE();
	} else {
		_frameDataSize = _width * _height + 500;
		if (!(_flags & 0x100) || (_flags & 0x1000))
			_vidBufferSize = _frameDataSize;
	}

	// Frame positions table
	if (_framesPos) {
		_stream->seek(framesPosPos, SEEK_SET);
		for (int i = 0; i < _framesCount; i++)
			_framesPos[i] = _stream->readUint32LE();
	}

	// Frame coordinates table
	if (_features & kFeaturesFrameCoords) {
		_stream->seek(framesCoordsPos, SEEK_SET);
		_frameCoords = new Coord[_framesCount];
		assert(_frameCoords);
		for (int i = 0; i < _framesCount; i++) {
			_frameCoords[i].left = _stream->readSint16LE();
			_frameCoords[i].top = _stream->readSint16LE();
			_frameCoords[i].right = _stream->readSint16LE();
			_frameCoords[i].bottom = _stream->readSint16LE();
		}
	}

	// Seek to the first frame
	_stream->seek(_firstFramePos, SEEK_SET);

	// Allocating working memory
	_frameData = new byte[_frameDataSize + 500];
	assert(_frameData);
	memset(_frameData, 0, _frameDataSize + 500);
	_vidBuffer = new byte[_vidBufferSize + 500];
	assert(_vidBuffer);
	memset(_vidBuffer, 0, _vidBufferSize + 500);

	return true;
}

void Imd::unload() {
	clear();
}

void Imd::setFrameRate(int16 frameRate) {
	if (frameRate == 0)
		frameRate = 1;

	_frameRate = frameRate;
	_frameLength = 1000 / _frameRate;
}

void Imd::setXY(int16 x, int16 y) {
	// Adjusting the standard coordinates
	if (_stdX != -1) {
		if (x >= 0)
			_stdX = _stdX - _x + x;
		if (y >= 0)
			_stdY = _stdY - _y + y;
	}

	// Going through the coordinate table as well
	if (_frameCoords) {
		for (int i = 0; i < _framesCount; i++) {
			if (_frameCoords[i].left != -1) {
				if (x >= 0) {
					_frameCoords[i].left = _frameCoords[i].left - _x + x;
					_frameCoords[i].right = _frameCoords[i].right - _x + x;
				}
				if (y >= 0) {
					_frameCoords[i].top = _frameCoords[i].top - _y + y;
					_frameCoords[i].bottom = _frameCoords[i].bottom - _y + y;
				}
			}
		}
	}

	if (x >= 0)
		_x = x;
	if (y >= 0)
		_y = y;
}

void Imd::setVideoMemory(byte *vidMem, uint16 width, uint16 height) {
	deleteVidMem();

	_hasOwnVidMem = false;
	_vidMem = vidMem;
	_vidMemWidth = width;
	_vidMemHeight = height;
}

void Imd::setVideoMemory() {
	deleteVidMem();

	if ((_width > 0) && (_height > 0)) {
		setXY(0, 0);
		_hasOwnVidMem = true;
		_vidMem = new byte[_width * _height];
		_vidMemWidth = _width;
		_vidMemHeight = _height;
	}
}

void Imd::enableSound(Audio::Mixer &mixer) {
	// Only possible on the first frame
	if (_curFrame > 0)
		return;

	_mixer = &mixer;
	_soundEnabled = true;
}

void Imd::disableSound() {
	if (_audioStream) {

		if (_soundStage == 2) {
			_audioStream->finish();
			_mixer->stopHandle(_audioHandle);
		} else
			delete _audioStream;

		_audioStream = 0;
		_soundStage = 0;
	}
	_soundEnabled = false;
	_mixer = 0;
}

bool Imd::isSoundPlaying() const {
	if (_audioStream && _mixer->isSoundHandleActive(_audioHandle))
		return true;

	return false;
}

void Imd::seekFrame(int32 frame, int16 whence, bool restart) {
	if (!_stream)
		// Nothing to do
		return;

	// Find the frame to which to seek
	if (whence == SEEK_CUR)
		frame += _curFrame;
	else if (whence == SEEK_END)
		frame = _framesCount - frame - 1;
	else if (whence != SEEK_SET)
		return;

	if ((frame < 0) || (frame >= _framesCount) || (frame == _curFrame))
		// Nothing to do
		return;

	// Try every possible way to find a file offset to that frame
	uint32 framePos = 0;
	if (frame == 0) {
		framePos = _firstFramePos;
	} else if (frame == 1) {
		framePos = _firstFramePos;
		_stream->seek(framePos, SEEK_SET);
		framePos += _stream->readUint16LE() + 4;
	} else if (_framesPos) {
		framePos = _framesPos[frame];
	} else if (restart && (_soundStage == 0)) {
		for (int i = ((frame > _curFrame) ? _curFrame : 0); i <= frame; i++)
			processFrame(i);
	} else
		error("Frame %d is not directly accessible", frame);

	// Seek
	_stream->seek(framePos);
	_curFrame = frame;
}

CoktelVideo::State Imd::nextFrame() {
	return processFrame(_curFrame);
}

void Imd::waitEndFrame() {
	if (_soundEnabled && _hasSound) {
		if (_soundStage != 2)
			return;

		if (_skipFrames == 0) {
			int32 waitTime = (int16) (((_curFrame * _soundSliceLength) -
				(_mixer->getSoundElapsedTime(_audioHandle) << 16)) >> 16);

			if (waitTime < 0) {
				_skipFrames = -waitTime / (_soundSliceLength >> 16);
				warning("Video A/V sync broken, skipping %d frame(s)", _skipFrames + 1);
			} else if (waitTime > 0)
				g_system->delayMillis(waitTime);

		} else
			_skipFrames--;
	} else
		g_system->delayMillis(_frameLength);
}

void Imd::copyCurrentFrame(byte *dest,
		uint16 left, uint16 top, uint16 width, uint16 height,
		uint16 x, uint16 y, uint16 pitch, int16 transp) {

	if (!_vidMem)
		return;

	if (((left + width) > _width) || ((top + height) > _height))
		return;

	dest += pitch * y;
	byte *vidMem = _vidMem + _width * top;

	if (transp < 0) {
		// No transparency
		if ((x > 0) || (left > 0) || (pitch != _width) || (width != _width)) {
			// Copy row-by-row
			for (int i = 0; i < height; i++) {
				byte *d = dest + x;
				byte *s = vidMem + left;

				memcpy(d, s, width);

				dest += pitch;
				vidMem += _width;
			}
		} else
			// Dimensions fit, copy everything at once
			memcpy(dest, vidMem, width * height);

		return;
	}

	for (int i = 0; i < height; i++) {
		byte *d = dest + x;
		byte *s = vidMem + left;

		for (int j = 0; j < width; j++) {
			if (*s != transp)
				*d = *s;

			s++;
			d++;
		}

		dest += pitch;
		vidMem += _width;
	}

}

void Imd::deleteVidMem(bool del) {
	if (del) {
		if (_hasOwnVidMem)
			delete[] _vidMem;
	}

	_hasOwnVidMem = false;
	_vidMem = 0;
	_vidMemWidth = _vidMemHeight = 0;
}

void Imd::clear(bool del) {
	if (del) {
		delete[] _framesPos;
		delete[] _frameCoords;
		delete[] _frameData;
		delete[] _vidBuffer;

		disableSound();
	}

	_stream = 0;

	_version = 0;
	_features = 0;
	_flags = 0;
	_x = _y = _width = _height = 0;
	_stdX = _stdY = _stdWidth = _stdHeight = 0;
	_framesCount = _curFrame = 0;
	_framesPos = 0;
	_firstFramePos = 0;
	_frameCoords = 0;

	_frameDataSize = _vidBufferSize = 0;
	_frameData = _vidBuffer = 0;
	_frameDataLen = 0;

	memset(_palette, 0, 768);

	deleteVidMem(del);

	_hasSound = false;
	_soundEnabled = false;
	_soundStage = 0;
	_skipFrames = 0;

	_soundFlags = 0;
	_soundFreq = 0;
	_soundSliceSize = 0;
	_soundSlicesCount = 0;
	_soundSliceLength = 0;

	_audioStream = 0;

	_frameRate = 12;
	_frameLength = 0;
	_lastFrameTime = 0;
}

CoktelVideo::State Imd::processFrame(uint16 frame) {
	State state;
	uint32 cmd = 0;
	bool hasNextCmd = false;
	bool startSound = false;

	if (!_stream || (frame >= _framesCount)) {
		state.flags = kStateBreak;
		return state;
	}

	if (frame != _curFrame) {
		state.flags |= kStateSeeked;
		seekFrame(frame);
	}

	if (!_vidMem)
		setVideoMemory();

	state.left = _x;
	state.top = _y;
	state.right = _width + state.left - 1;
	state.bottom = _height + state.top - 1;

	do {
		if (frame != 0) {
			if (_stdX != -1) {
				state.left = _stdX;
				state.top = _stdY;
				state.right = _stdWidth + state.left - 1;
				state.bottom = _stdHeight + state.top - 1;
				state.flags |= kStateStdCoords;
			}
			if (_frameCoords &&
					(_frameCoords[frame].left != -1)) {
				state.left = _frameCoords[frame].left;
				state.top = _frameCoords[frame].top;
				state.right = _frameCoords[frame].right;
				state.bottom = _frameCoords[frame].bottom;
				state.flags |= kStateFrameCoords;
			}
		}

		cmd = _stream->readUint16LE();

		if ((cmd & 0xFFF8) == 0xFFF0) {
			if (cmd == 0xFFF0) {
				_stream->seek(2, SEEK_CUR);
				cmd = _stream->readUint16LE();
			}

			if (cmd == 0xFFF1) {
				state.flags = kStateBreak;
				continue;
			} else if (cmd == 0xFFF2) { // Skip (16 bit)
				cmd = _stream->readUint16LE();
				_stream->seek(cmd, SEEK_CUR);
				state.flags = kStateBreak;
				continue;
			} else if (cmd == 0xFFF3) { // Skip (32 bit)
				cmd = _stream->readUint32LE();
				_stream->seek(cmd, SEEK_CUR);
				state.flags = kStateBreak;
				continue;
			}
		}

		if (_soundStage != 0) {
			byte *soundBuf;

			// Next sound slice data
			if (cmd == 0xFF00) {

				if (!hasNextCmd && _soundEnabled) {
					soundBuf = new byte[_soundSliceSize];
					assert(soundBuf);

					_stream->read(soundBuf, _soundSliceSize);
					unsignedToSigned(soundBuf, _soundSliceSize);
					_audioStream->queueBuffer(soundBuf, _soundSliceSize);
				} else
					_stream->seek(_soundSliceSize, SEEK_CUR);

				cmd = _stream->readUint16LE();

			// Initial sound data (all slices)
			} else if (cmd == 0xFF01) {
				int dataLength = _soundSliceSize * _soundSlicesCount;

				if (!hasNextCmd && _soundEnabled) {
					soundBuf = new byte[dataLength];
					assert(soundBuf);

					_stream->read(soundBuf, dataLength);
					unsignedToSigned(soundBuf, dataLength);

					if (_soundStage == 1)
						startSound = true;

					_audioStream->queueBuffer(soundBuf, dataLength);
				} else
					_stream->seek(dataLength, SEEK_CUR);

				cmd = _stream->readUint16LE();

			// Empty sound slice
			} else if (!hasNextCmd && (_soundEnabled)) {
				soundBuf = new byte[_soundSliceSize];
				assert(soundBuf);

				memset(soundBuf, 0, _soundSliceSize);

				_audioStream->queueBuffer(soundBuf, _soundSliceSize);
			}
		}

		// Set palette
		if (cmd == 0xFFF4) {
			_stream->seek(2, SEEK_CUR);
			state.flags |= kStatePalette;

			_stream->read(_palette, 768);
			cmd = _stream->readUint16LE();
		}

		hasNextCmd = false;

		// Jump to frame
		if (cmd == 0xFFFD) {

			frame = _stream->readSint16LE();
			if (_framesPos) {
				_curFrame = frame;
				_stream->seek(_framesPos[frame], SEEK_SET);

				hasNextCmd = true;
				state.flags |= kStateJump;
			}

		} else if (cmd == 0xFFFC) {

			state.flags |= 1;
			cmd = _stream->readUint32LE();
			_stream->read(_frameData, cmd + 2);
			_frameDataLen = cmd + 2;

			if (_vidMemWidth <= state.right) {
				state.left = 0;
				state.right -= state.left;
			}
			if (_vidMemWidth <= state.right)
				state.right = _vidMemWidth - 1;
			if (_vidMemHeight <= state.bottom) {
				state.top = 0;
				state.bottom -= state.top;
			}
			if (_vidMemHeight <= state.bottom)
				state.bottom = _vidMemHeight -1;

			state.flags |= renderFrame(state.left, state.top, state.right, state.bottom);
			state.flags |= _frameData[0];

		// Frame video data
		} else if (cmd != 0) {

			_stream->read(_frameData, cmd + 2);
			_frameDataLen = cmd + 2;

			state.flags |= renderFrame(state.left, state.top, state.right, state.bottom);
			state.flags |= _frameData[0];

		} else
			state.flags |= kStateNoVideoData;

	} while (hasNextCmd);

	if (startSound && _soundEnabled) {
		_mixer->playInputStream(Audio::Mixer::kSFXSoundType, &_audioHandle, _audioStream);
		_skipFrames = 0;
		_soundStage = 2;
	}

	_curFrame++;
	if ((_curFrame == _framesCount) && (_soundStage == 2)) {
		_audioStream->finish();
		_mixer->stopHandle(_audioHandle);
		_audioStream = 0;
		_soundStage = 0;
	}

	_lastFrameTime = g_system->getMillis();
	return state;
}

uint32 Imd::renderFrame(int16 left, int16 top, int16 right, int16 bottom) {
	if (!_frameData || !_vidMem || (_width <= 0) || (_height <= 0))
		return 0;

	uint32 retVal = 0;
	int16 width = right - left + 1;
	int16 height = bottom - top + 1;
	int16 sW = _vidMemWidth;
	byte *dataPtr = _frameData;
	byte *imdVidMem = _vidMem + sW * top + left;
	byte *srcPtr;
	uint8 type = *dataPtr++;

	if (type & 0x10) { // Palette data
		// One byte index
		int index = *dataPtr++;
		// 16 entries with each 3 bytes (RGB)
		memcpy(_palette + index * 3, dataPtr, MIN((255 - index) * 3, 48));

		retVal = kStatePalette;
		dataPtr += 48;
		type ^= 0x10;
	}

	srcPtr = dataPtr;

	if (type & 0x80) { // Frame data is compressed
		srcPtr = _vidBuffer;
		type &= 0x7F;
		if ((type == 2) && (width == sW)) {
			deLZ77(imdVidMem, dataPtr);
			return retVal;
		} else
			deLZ77(srcPtr, dataPtr);
	}

	uint16 pixCount, pixWritten;
	byte *imdVidMemBak;

	if (type == 2) { // Whole block
		for (int i = 0; i < height; i++) {
			memcpy(imdVidMem, srcPtr, width);
			srcPtr += width;
			imdVidMem += sW;
		}
	} else if (type == 1) { // Sparse block
		imdVidMemBak = imdVidMem;
		for (int i = 0; i < height; i++) {
			pixWritten = 0;
			while (pixWritten < width) {
				pixCount = *srcPtr++;
				if (pixCount & 0x80) { // Data
					pixCount = MIN((pixCount & 0x7F) + 1, width - pixWritten);
					memcpy(imdVidMem, srcPtr, pixCount);

					pixWritten += pixCount;
					imdVidMem += pixCount;
					srcPtr += pixCount;
				} else { // "Hole"
					pixCount = (pixCount + 1) % 256;
					pixWritten += pixCount;
					imdVidMem += pixCount;
				}
			}
			imdVidMemBak += sW;
			imdVidMem = imdVidMemBak;
		}
	} else if (type == 0x42) { // Whole quarter-wide block
		for (int i = 0; i < height; i++) {
			imdVidMemBak = imdVidMem;

			for (int j = 0; j < width; j += 4, imdVidMem += 4, srcPtr++)
				memset(imdVidMem, *srcPtr, 4);

			imdVidMemBak += sW;
			imdVidMem = imdVidMemBak;
		}
	} else if ((type & 0xF) == 2) { // Whole half-high block
		for (; height > 1; height -= 2, imdVidMem += sW + sW, srcPtr += width) {
			memcpy(imdVidMem, srcPtr, width);
			memcpy(imdVidMem + sW, srcPtr, width);
		}
		if (height == -1)
			memcpy(imdVidMem, srcPtr, width);
	} else { // Sparse half-high block
		imdVidMemBak = imdVidMem;
		for (int i = 0; i < height; i += 2) {
			pixWritten = 0;
			while (pixWritten < width) {
				pixCount = *srcPtr++;
				if (pixCount & 0x80) { // Data
					pixCount = MIN((pixCount & 0x7F) + 1, width - pixWritten);
					memcpy(imdVidMem, srcPtr, pixCount);
					memcpy(imdVidMem + sW, srcPtr, pixCount);

					pixWritten += pixCount;
					imdVidMem += pixCount;
					srcPtr += pixCount;
				} else { // "Hole"
					pixCount = (pixCount + 1) % 256;
					pixWritten += pixCount;
					imdVidMem += pixCount;
				}
			}
			imdVidMemBak += sW + sW;
			imdVidMem = imdVidMemBak;
		}
	}

	return retVal;
}

void Imd::deLZ77(byte *dest, byte *src) {
	int i;
	byte buf[4370];
	uint16 chunkLength;
	uint32 frameLength;
	uint16 bufPos1;
	uint16 bufPos2;
	uint16 tmp;
	uint8 chunkBitField;
	uint8 chunkCount;
	bool mode;

	frameLength = READ_LE_UINT32(src);
	src += 4;

	if ((READ_LE_UINT16(src) == 0x1234) && (READ_LE_UINT16(src + 2) == 0x5678)) {
		src += 4;
		bufPos1 = 273;
		mode = 1; // 123Ch (cmp al, 12h)
	} else {
		bufPos1 = 4078;
		mode = 0; // 275h (jnz +2)
	}

	memset(buf, 32, bufPos1);
	chunkCount = 1;
	chunkBitField = 0;

	while (frameLength > 0) {
		chunkCount--;
		if (chunkCount == 0) {
			tmp = *src++;
			chunkCount = 8;
			chunkBitField = tmp;
		}
		if (chunkBitField % 2) {
			chunkBitField >>= 1;
			buf[bufPos1] = *src;
			*dest++ = *src++;
			bufPos1 = (bufPos1 + 1) % 4096;
			frameLength--;
			continue;
		}
		chunkBitField >>= 1;

		tmp = READ_LE_UINT16(src);
		src += 2;
		chunkLength = ((tmp & 0xF00) >> 8) + 3;

		if ((mode && ((chunkLength & 0xFF) == 0x12)) ||
				(!mode && (chunkLength == 0)))
			chunkLength = *src++ + 0x12;

		bufPos2 = (tmp & 0xFF) + ((tmp >> 4) & 0x0F00);
		if (((tmp + chunkLength) >= 4096) ||
				((chunkLength + bufPos1) >= 4096)) {

			for (i = 0; i < chunkLength; i++, dest++) {
				*dest = buf[bufPos2];
				buf[bufPos1] = buf[bufPos2];
				bufPos1 = (bufPos1 + 1) % 4096;
				bufPos2 = (bufPos2 + 1) % 4096;
			}

		} else if (((tmp + chunkLength) < bufPos1) ||
				((chunkLength + bufPos1) < bufPos2)) {

			memcpy(dest, buf + bufPos2, chunkLength);
			memmove(buf + bufPos1, buf + bufPos2, chunkLength);

			dest += chunkLength;
			bufPos1 += chunkLength;
			bufPos2 += chunkLength;

		} else {

			for (i = 0; i < chunkLength; i++, dest++, bufPos1++, bufPos2++) {
				*dest = buf[bufPos2];
				buf[bufPos1] = buf[bufPos2];
			}

		}
		frameLength -= chunkLength;

	}
}

const uint16 Vmd::_tableADPCM[128] = {
	0x0000, 0x0008, 0x0010, 0x0020, 0x0030, 0x0040, 0x0050, 0x0060, 0x0070, 0x0080,
	0x0090, 0x00A0, 0x00B0, 0x00C0, 0x00D0, 0x00E0, 0x00F0, 0x0100, 0x0110, 0x0120,
	0x0130, 0x0140, 0x0150, 0x0160, 0x0170, 0x0180, 0x0190, 0x01A0, 0x01B0, 0x01C0,
	0x01D0, 0x01E0, 0x01F0, 0x0200, 0x0208, 0x0210, 0x0218, 0x0220, 0x0228, 0x0230,
	0x0238, 0x0240, 0x0248, 0x0250, 0x0258, 0x0260, 0x0268, 0x0270, 0x0278, 0x0280,
	0x0288, 0x0290, 0x0298, 0x02A0, 0x02A8, 0x02B0, 0x02B8, 0x02C0, 0x02C8, 0x02D0,
	0x02D8, 0x02E0, 0x02E8, 0x02F0, 0x02F8, 0x0300, 0x0308, 0x0310, 0x0318, 0x0320,
	0x0328, 0x0330, 0x0338, 0x0340, 0x0348, 0x0350, 0x0358, 0x0360, 0x0368, 0x0370,
	0x0378, 0x0380, 0x0388, 0x0390, 0x0398, 0x03A0, 0x03A8, 0x03B0, 0x03B8, 0x03C0,
	0x03C8, 0x03D0, 0x03D8, 0x03E0, 0x03E8, 0x03F0, 0x03F8, 0x0400, 0x0440, 0x0480,
	0x04C0, 0x0500, 0x0540, 0x0580, 0x05C0, 0x0600, 0x0640, 0x0680, 0x06C0, 0x0700,
	0x0740, 0x0780, 0x07C0, 0x0800, 0x0900, 0x0A00, 0x0B00, 0x0C00, 0x0D00, 0x0E00,
	0x0F00, 0x1000, 0x1400, 0x1800, 0x1C00, 0x2000, 0x3000, 0x4000
};

Vmd::Vmd(PaletteLUT *palLUT) : _palLUT(palLUT) {
	clear(false);
}

Vmd::~Vmd() {
	clear();
}

bool Vmd::load(Common::SeekableReadStream &stream) {
	unload();

	_stream = &stream;

	uint16 headerLength = _stream->readUint16LE();
	uint16 handle = _stream->readUint16LE();
	_version = _stream->readUint16LE();

	if (!(_version & 2))
		_features |= kFeaturesPalette;
	else
		_features |= kFeaturesFullColor;

	// 0x4 (4)

	// Version checking
	if (headerLength != 814) {
		warning("VMD Version incorrect (%d, %d, %d)", headerLength, handle, _version);
		unload();
		return false;
	}

	_framesCount = _stream->readUint16LE();

	// 0x6 (6)

	_x = _stream->readSint16LE();
	_y = _stream->readSint16LE();
	_width = _stream->readSint16LE();
	_height = _stream->readSint16LE();

	// 0xE (14)

	if ((_width != 0) && (_height != 0)) {
		_hasVideo = true;
		_features |= kFeaturesVideo;
		if (_features & kFeaturesFullColor)
			_codecIndeo3 = new Indeo3(_width, _height, _palLUT);
	} else
		_hasVideo = false;

	if (_width > 320) {
		if (!(_version & 4)) {
			_version |= 4;
			handle = 0;
		}
	}

	if (handle > 2) {
		warning("VMD Version incorrect (%d, %d, %d)", headerLength, handle, _version);
		unload();
		return false;
	}

	_bytesPerPixel = handle + 1;

	if (_bytesPerPixel > 1) {
		_features |= kFeaturesFullColor;
		_features &= ~kFeaturesPalette;
	}

	_flags = _stream->readUint16LE();
	_partsPerFrame = _stream->readUint16LE();
	_firstFramePos = _stream->readUint32LE();
	_stream->skip(4); // Unknown

	// 0x1A (26)

	_stream->read((byte *) _palette, 768);

	// 0x31A (794)

	_frameDataSize = _stream->readUint32LE();
	_vidBufferSize = _stream->readUint32LE();

	if ((_version & 2) && !(_version & 8)) {
		_externalCodec = true;
		_frameDataSize = _vidBufferSize = 0;
	} else
		_externalCodec = false;

	// 0x322 (802)

	if (_hasVideo) {
		if ((_frameDataSize == 0) || (_frameDataSize > 1048576))
			_frameDataSize = _width * _height + 1000;
		if ((_vidBufferSize == 0) || (_vidBufferSize > 1048576))
			_vidBufferSize = _frameDataSize;

		_frameData = new byte[_frameDataSize];
		assert(_frameData);
		memset(_frameData, 0, _frameDataSize);

		_vidBuffer = new byte[_vidBufferSize];
		assert(_vidBuffer);
		memset(_vidBuffer, 0, _vidBufferSize);

		if ((_bytesPerPixel > 1) && !_externalCodec) {
			_vidMemBuffer = new byte[_bytesPerPixel * (_width * _height + 1000)];
			memset(_vidMemBuffer, 0, _bytesPerPixel * (_width * _height + 1000));
		}
	}

	_soundFreq = _stream->readSint16LE();
	_soundSliceSize = _stream->readSint16LE();
	_soundSlicesCount = _stream->readSint16LE();
	_soundFlags = _stream->readUint16LE();
	_hasSound = (_soundFreq != 0);

	// 0x32A (810)

	if (_hasSound) {
		_features |= kFeaturesSound;

		_soundStereo = (_soundFlags & 0x8000) ? 1 : ((_soundFlags & 0x200) ? 2 : 0);
		if (_soundStereo > 0) {
			warning("TODO: VMD stereo");
			unload();
			return false;
		}

		if (_soundSliceSize < 0) {
			_soundBytesPerSample = 2;
			_soundSliceSize = -_soundSliceSize;
		}

		_soundSliceLength = (uint32) (((double) (1000 << 16)) / 
				((double) _soundFreq / (double) _soundSliceSize));
		_frameLength = _soundSliceLength >> 16;

		_soundStage = 1;
		_audioStream = Audio::makeAppendableAudioStream(_soundFreq,
				(_soundBytesPerSample == 2) ? Audio::Mixer::FLAG_16BITS : 0);
	} else
		_frameLength = 1000 / _frameRate;

	_frameInfoOffset = _stream->readUint32LE();

	int numExtraData = 0;

	_stream->seek(_frameInfoOffset);
	_frames = new Frame[_framesCount];
	for (uint16 i = 0; i < _framesCount; i++) {
		_frames[i].parts = new Part[_partsPerFrame];
		_stream->skip(2); // Unknown
		_frames[i].offset = _stream->readUint32LE();
	}
	for (uint16 i = 0; i < _framesCount; i++) {
		bool separator = false;

		for (uint16 j = 0; j < _partsPerFrame; j++) {

			_frames[i].parts[j].type = (PartType) _stream->readByte();
			_frames[i].parts[j].field_1 = _stream->readByte();
			_frames[i].parts[j].size = _stream->readUint32LE();

			if (_frames[i].parts[j].type == kPartTypeAudio) {

				_frames[i].parts[j].flags = _stream->readByte();
				_stream->skip(9); // Unknown

			} else if (_frames[i].parts[j].type == kPartTypeVideo) {

				_frames[i].parts[j].left = _stream->readUint16LE();
				_frames[i].parts[j].top = _stream->readUint16LE();
				_frames[i].parts[j].right = _stream->readUint16LE();
				_frames[i].parts[j].bottom = _stream->readUint16LE();
				_frames[i].parts[j].field_E = _stream->readByte();
				_frames[i].parts[j].flags = _stream->readByte();

			} else if (_frames[i].parts[j].type == kPartTypeExtraData) {
				if (!separator)
					numExtraData++;
				_stream->skip(10);
			} else if (_frames[i].parts[j].type == kPartTypeSeparator) {
				separator = true;
				_stream->skip(10);
			} else {
				// Unknow type
				_stream->skip(10);
			}

		}
	}

	_stream->seek(_firstFramePos);

	if (numExtraData == 0)
		return true;

	_extraData.reserve(numExtraData);

	numExtraData = 0;

	uint32 ssize = _stream->size();
	for (uint16 i = 0; i < _framesCount; i++) {
		_stream->seek(_frames[i].offset);

		for (uint16 j = 0; j < _partsPerFrame; j++) {
			if (_frames[i].parts[j].type == kPartTypeSeparator)
				break;

			if (_frames[i].parts[j].type == kPartTypeExtraData) {
				ExtraData data;

				data.offset = _stream->pos() + 20;
				data.size = _frames[i].parts[j].size;
				data.realSize = _stream->readUint32LE();
				_stream->read(data.name, 16);
				data.name[15] = '\0';

				_stream->skip(_frames[i].parts[j].size - 20);

				if ((((uint32) data.realSize) >= ssize) || (data.name[0] == 0))
					continue;
					
				_extraData.push_back(data);

			} else
				_stream->skip(_frames[i].parts[j].size);
		}
	}

	_stream->seek(_firstFramePos);
	return true;
}

void Vmd::unload() {
	clear();
}

int16 Vmd::getWidth() const {
	if (_bytesPerPixel == 2)
		return _width >> 1;

	return _width;
}

void Vmd::setXY(int16 x, int16 y) {

	for (int i = 0; i < _framesCount; i++) {
		for (int j = 0; j < _partsPerFrame; j++) {

			if (_frames[i].parts[j].type == kPartTypeVideo) {
				if (x >= 0) {
					_frames[i].parts[j].left = _frames[i].parts[j].left - _x + x;
					_frames[i].parts[j].right = _frames[i].parts[j].right - _x + x;
				}
				if (y >= 0) {
					_frames[i].parts[j].top = _frames[i].parts[j].top - _y + y;
					_frames[i].parts[j].bottom = _frames[i].parts[j].bottom - _y + y;
				}
			}

		}
	}

	if (x >= 0)
		_x = x;
	if (y >= 0)
		_y = y;
}

void Vmd::seekFrame(int32 frame, int16 whence, bool restart) {
	if (!_stream)
		// Nothing to do
		return;

	// Find the frame to which to seek
	if (whence == SEEK_CUR)
		frame += _curFrame;
	else if (whence == SEEK_END)
		frame = _framesCount - frame - 1;
	else if (whence != SEEK_SET)
		return;

	if ((frame < 0) || (frame >= _framesCount))
		// Nothing to do
		return;

	// Restart sound
	if (_hasSound && (frame == 0) && (_soundStage == 0) && !_audioStream) {
		_soundStage = 1;
		_audioStream = Audio::makeAppendableAudioStream(_soundFreq,
				(_soundBytesPerSample == 2) ? Audio::Mixer::FLAG_16BITS : 0);
	}

	// Seek
	_stream->seek(_frames[frame].offset);
	_curFrame = frame;
}

CoktelVideo::State Vmd::nextFrame() {
	State state;

	state = processFrame(_curFrame);
	_curFrame++;
	return state;
}

void Vmd::clear(bool del) {
	Imd::clear(del);

	if (del) {
		delete _codecIndeo3;
		delete[] _frames;
		delete[] _vidMemBuffer;
	}

	_hasVideo = true;

	_codecIndeo3 = 0;

	_partsPerFrame = 0;
	_frames = 0;

	_extraData.clear();

	_soundBytesPerSample = 1;
	_soundStereo = 0;

	_externalCodec = false;
	_bytesPerPixel = 1;
	_vidMemBuffer = 0;
}

CoktelVideo::State Vmd::processFrame(uint16 frame) {
	State state;
	bool startSound = false;

	seekFrame(frame);

	state.flags |= kStateNoVideoData;
	state.left = 0x7FFF;
	state.top = 0x7FFF;
	state.right = 0;
	state.bottom = 0;

	if (!_vidMem)
		setVideoMemory();

	for (uint16 i = 0; (i < _partsPerFrame) && (frame < _framesCount); i++) {
		Part &part = _frames[frame].parts[i];

		if (part.type == kPartTypeAudio) {
			// Next sound slice data
			if (part.flags == 1) {

				if (_soundEnabled) {
					filledSoundSlice(part.size);

					if (_soundStage == 1)
						startSound = true;

				} else
					_stream->skip(part.size);

			// Initial sound data (all slices)
			} else if (part.flags == 2) {

				if (_soundEnabled) {
					uint32 mask = _stream->readUint32LE();
					filledSoundSlices(part.size - 4, mask);

					if (_soundStage == 1)
						startSound = true;

				} else
					_stream->skip(part.size);

			// Empty sound slice
			} else if (part.flags == 3) {

				if (_soundEnabled) {
					emptySoundSlice(_soundSliceSize * _soundBytesPerSample);

					if (_soundStage == 1)
						startSound = true;
				}

				_stream->skip(part.size);
			} else {
				warning("Unknown sound part type %d", part.flags);
				_stream->skip(part.size);
			}

		} else if (part.type == kPartTypeVideo) {
			state.flags &= ~kStateNoVideoData;

			uint32 size = part.size;

			// New palette
			if (part.flags & 2) {
				uint8 index = _stream->readByte();
				uint8 count = _stream->readByte();

				_stream->read(_palette + index * 3, (count + 1) * 3);
				_stream->skip((255 - count) * 3);

				state.flags |= kStatePalette;

				size -= (768 + 2);
			}

			_stream->read(_frameData, size);
			_frameDataLen = size;

			int16 l = part.left, t = part.top, r = part.right, b = part.bottom;
			if (renderFrame(l, t, r, b)) {
				if (!_externalCodec) {
					l /= _bytesPerPixel;
					r /= _bytesPerPixel;
				}
				// Rendering succeeded, merging areas
				state.left   = MIN(state.left,   l);
				state.top    = MIN(state.top,    t);
				state.right  = MAX(state.right,  r);
				state.bottom = MAX(state.bottom, b);
			}

		} else if (part.type == 4) {
			// Unknown
			_stream->skip(part.size);
		} else {
			// Unknow type
//			warning("Unknown frame part type %d, size %d (%d of %d)", part.type, part.size, i + 1, _partsPerFrame);
		}
	}

	if (startSound && _soundEnabled) {
		_mixer->playInputStream(Audio::Mixer::kSFXSoundType, &_audioHandle, _audioStream);
		_skipFrames = 0;
		_soundStage = 2;
	}

	if ((_curFrame == (_framesCount - 1)) && (_soundStage == 2)) {
		_audioStream->finish();
		_mixer->stopHandle(_audioHandle);
		_audioStream = 0;
		_soundStage = 0;
	}

	// If these are still 0x7FFF, no video data has been processed
	if ((state.left == 0x7FFF) || (state.top == 0x7FFF))
		state.left = state.top = state.right = state.bottom = 0;

	_lastFrameTime = g_system->getMillis();
	return state;
}

void Vmd::deRLE(byte *&srcPtr, byte *&destPtr, int16 len) {
	srcPtr++;

	if (len & 1)
		*destPtr += *srcPtr++;

	len >>= 1;

	while (len > 0) {
		uint8 tmp = *srcPtr++;
		if (tmp & 0x80) { // Verbatim copy
			tmp &= 0x7F;

			memcpy(destPtr, srcPtr, tmp * 2);
			destPtr += tmp * 2;
			srcPtr += tmp * 2;
		} else { // 2 bytes tmp times
			for (int i = 0; i < tmp; i++) {
				*destPtr++ = srcPtr[0];
				*destPtr++ = srcPtr[1];
			}
			srcPtr += 2;
		}
		len -= tmp;
	}
}

uint32 Vmd::renderFrame(int16 &left, int16 &top, int16 &right, int16 &bottom) {
	if (!_frameData || !_vidMem || (_width <= 0) || (_height <= 0))
		return 0;

	int16 width = right - left + 1;
	int16 height = bottom - top + 1;
	int16 sW = _vidMemWidth;
	uint32 dataLen = _frameDataLen;
	byte *dataPtr = _frameData;
	byte *imdVidMem = _vidMem + sW * top + left;
	byte *srcPtr;
	uint8 type;

	if ((width < 0) || (height < 0))
		return 1;

	byte *dest = imdVidMem;

	if (Indeo3::isIndeo3(dataPtr, dataLen)) {
		if (!_codecIndeo3)
			return 0;

		if (!_codecIndeo3->decompressFrame(dataPtr, dataLen, _vidBuffer, width, height))
			return 0;

		type = 2;
		srcPtr = _vidBuffer;
		width = _width;
		height = _height;
		right = left + width - 1;
		bottom = top + height - 1;

	} else {

		if (_externalCodec) {
			warning("Unknown external codec");
			return 0;
		}

		type = *dataPtr++;
		srcPtr = dataPtr;

		if (_bytesPerPixel > 1) {
			dest = _vidMemBuffer + _width * (top - _y) + (left - _x);
			imdVidMem = _vidMem + _vidMemWidth * top + (left / _bytesPerPixel);
			sW = _width;
		}

		if (type & 0x80) { // Frame data is compressed
			srcPtr = _vidBuffer;
			type &= 0x7F;
			if ((type == 2) && (width == sW)) {
				deLZ77(dest, dataPtr);
				blit(imdVidMem, dest, width, height);
				return 1;
			} else
				deLZ77(srcPtr, dataPtr);
		}

	}

	uint16 pixCount, pixWritten;
	byte *destBak;

	if (type == 1) { // Sparse block
		destBak = dest;
		for (int i = 0; i < height; i++) {
			pixWritten = 0;
			while (pixWritten < width) {
				pixCount = *srcPtr++;
				if (pixCount & 0x80) { // Data
					pixCount = MIN((pixCount & 0x7F) + 1, width - pixWritten);
					memcpy(dest, srcPtr, pixCount);

					pixWritten += pixCount;
					dest += pixCount;
					srcPtr += pixCount;
				} else { // "Hole"
					pixCount = (pixCount + 1) % 256;
					pixWritten += pixCount;
					dest += pixCount;
				}
			}
			destBak += sW;
			dest = destBak;
		}
	} else if (type == 2) { // Whole block
		for (int i = 0; i < height; i++) {
			memcpy(dest, srcPtr, width);
			srcPtr += width;
			dest += sW;
		}
	} else if (type == 3) { // RLE block
		for (int i = 0; i < height; i++) {
			destBak = dest;

			pixWritten = 0;
			while (pixWritten < width) {
				pixCount = *srcPtr++;
				if (pixCount & 0x80) {
					pixCount = (pixCount & 0x7F) + 1;

					if (*srcPtr != 0xFF) { // Normal copy
						memcpy(dest, srcPtr, pixCount);
						dest += pixCount;
						srcPtr += pixCount;
					} else
						deRLE(srcPtr, dest, pixCount);

					pixWritten += pixCount;
				} else { // "Hole"
					dest += pixCount + 1;
					pixWritten += pixCount + 1;
				}

			}
			destBak += sW;
			dest = destBak;
		}
	} else if (type == 0x42) { // Whole quarter-wide block
		for (int i = 0; i < height; i++) {
			destBak = dest;

			for (int j = 0; j < width; j += 4, dest += 4, srcPtr++)
				memset(dest, *srcPtr, 4);

			destBak += sW;
			dest = destBak;
		}
	} else if ((type & 0xF) == 2) { // Whole half-high block
		for (; height > 1; height -= 2, dest += sW + sW, srcPtr += width) {
			memcpy(dest, srcPtr, width);
			memcpy(dest + sW, srcPtr, width);
		}
		if (height == -1)
			memcpy(dest, srcPtr, width);
	} else { // Sparse half-high block
		destBak = dest;
		for (int i = 0; i < height; i += 2) {
			pixWritten = 0;
			while (pixWritten < width) {
				pixCount = *srcPtr++;
				if (pixCount & 0x80) { // Data
					pixCount = MIN((pixCount & 0x7F) + 1, width - pixWritten);
					memcpy(dest, srcPtr, pixCount);
					memcpy(dest + sW, srcPtr, pixCount);

					pixWritten += pixCount;
					dest += pixCount;
					srcPtr += pixCount;
				} else { // "Hole"
					pixCount = (pixCount + 1) % 256;
					pixWritten += pixCount;
					dest += pixCount;
				}
			}
			destBak += sW + sW;
			dest = destBak;
		}
	}

	dest = _vidMemBuffer + _width * (top - _y) + (left - _x);
	blit(imdVidMem, dest, width, height);

	return 1;
}

void Vmd::blit(byte *dest, byte *src, int16 width, int16 height) {
	if ((_bytesPerPixel == 1) || _externalCodec)
		return;

	if (_bytesPerPixel == 2)
		blit16(dest, (uint16 *) src, width, height);
	else if (_bytesPerPixel == 3)
		blit24(dest, src, width, height);
}

void Vmd::blit16(byte *dest, uint16 *src, int16 width, int16 height) {
	int16 vWidth = _width >> 1;
	width >>= 1;

	assert(_palLUT);

	SierraLight *dither = new SierraLight(width, height, _palLUT);

	for (int i = 0; i < height; i++) {
		byte *d = dest;
		uint16 *s = src;

		for (int j = 0; j < width; j++, s++) {
			byte r = ((*s & 0x7C00) >> 10) << 1;
			byte g = ((*s & 0x03E0) >>  5) << 1;
			byte b = ((*s & 0x001F) >>  0) << 1;
			byte dY, dU, dV;

			PaletteLUT::RGB2YUV(r << 2, g << 2, b << 2, dY, dU, dV);

			byte p = dither->dither(dY, dU, dV, j);

			if ((dY == 0) || ((r == 0) && (g == 0) && (b == 0)))
				*d++ = 0;
			else
				*d++ = p;
		}

		dither->nextLine();
		dest += _vidMemWidth;
		src += vWidth;
	}

	delete dither;
}

void Vmd::blit24(byte *dest, byte *sc, int16 width, int16 height) {
	warning("TODO: blit24");
}

void Vmd::emptySoundSlice(uint32 size) {
	if (!_audioStream)
		return;

	byte *soundBuf = new byte[size];
	assert(soundBuf);

	memset(soundBuf, 0, size);

	_audioStream->queueBuffer(soundBuf, size);
}

void Vmd::soundSlice8bit(uint32 size) {
	if (!_audioStream)
		return;

	byte *soundBuf = new byte[size];
	assert(soundBuf);

	_stream->read(soundBuf, size);
	unsignedToSigned(soundBuf, size);

	_audioStream->queueBuffer(soundBuf, size);
}

void Vmd::soundSlice16bit(uint32 size, int16 &init) {
	if (!_audioStream)
		return;

	byte *dataBuf = new byte[size];
	byte *soundBuf = new byte[size * 2];

	_stream->read(dataBuf, size);
	deADPCM(soundBuf, dataBuf, init, size);
	_audioStream->queueBuffer(soundBuf, size * 2);

	delete[] dataBuf;
}

void Vmd::filledSoundSlice(uint32 size) {
	if (_soundBytesPerSample == 1) {
		soundSlice8bit(size);
	} else if (_soundBytesPerSample == 2) {
		int16 init = _stream->readSint16LE();
		soundSlice16bit(size - 2, init);
	}
}

void Vmd::filledSoundSlices(uint32 size, uint32 mask) {
	int n = MIN<int>(_soundSlicesCount - 1, 31);
	for (int i = 0; i < n; i++) {

		if (mask & 1)
			emptySoundSlice(_soundSliceSize * _soundBytesPerSample);
		else
			filledSoundSlice(_soundSliceSize + 1);

		mask >>= 1;
	}
	if (_soundSlicesCount > 32)
		filledSoundSlice((_soundSlicesCount - 32) * _soundSliceSize);
}

void Vmd::deADPCM(byte *soundBuf, byte *dataBuf, int16 &init, uint32 n) {
	int16 *out = (int16 *) soundBuf;

	int32 s = init;
	for (uint32 i = 0; i < n; i++) {
		if (dataBuf[i] & 0x80)
			s -= _tableADPCM[dataBuf[i] & 0x7F];
		else
			s += _tableADPCM[dataBuf[i]];

		s = CLIP<int32>(s, -32768, 32767);
		*out++ = TO_BE_16(s);
	}
}

bool Vmd::getAnchor(int16 frame, uint16 partType,
		int16 &x, int16 &y, int16 &width, int16 &height) {

	uint32 pos = _stream->pos();

	_stream->seek(_frameInfoOffset);
	// Offsets to frames
	_stream->skip(_framesCount * 6);
	// Jump to the specified frame
	_stream->skip(_partsPerFrame * frame * 16);

	// Find the anchor part
	uint16 i;
	for (i = 0; i < _partsPerFrame; i++) {
		byte type = _stream->readByte();

		if ((type == kPartTypeSeparator) || (type == partType))
			break;

		_stream->skip(15);
	}

	if (i == _partsPerFrame) {
		// No anchor

		_stream->seek(pos);
		return false;
	}

	_stream->skip(5);
	x = _stream->readSint16LE();
	y = _stream->readSint16LE();
	width = _stream->readSint16LE() - x + 1;
	height = _stream->readSint16LE() - y + 1;

	_stream->seek(pos);
	return true;
}

bool Vmd::hasExtraData(const char *fileName) const {
	for (uint i = 0; i < _extraData.size(); i++)
		if (!scumm_stricmp(_extraData[i].name, fileName))
			return true;

	return false;
}

Common::MemoryReadStream *Vmd::getExtraData(const char *fileName) {
	uint i = 0;

	for (i = 0; i < _extraData.size(); i++)
		if (!scumm_stricmp(_extraData[i].name, fileName))
			break;

	if (i >= _extraData.size())
		return 0;

	if ((_extraData[i].size - 20) != _extraData[i].realSize) {
		warning("Vmd::getExtraData(): Sizes for \"%s\" differ! (%d, %d)",
				fileName, (_extraData[i].size - 20), _extraData[i].realSize);
		return 0;
	}

	byte *data = (byte *) malloc(_extraData[i].realSize);

	_stream->seek(_extraData[i].offset);
	if (_stream->ioFailed() || (((uint32) _stream->pos()) != _extraData[i].offset)) {
		warning("Vmd::getExtraData(): Can't seek to offset %d to get extra data file \"%s\"",
				_extraData[i].offset, fileName);
		return 0;
	}

	_stream->read(data, _extraData[i].realSize);

	Common::MemoryReadStream *stream =
		new Common::MemoryReadStream(data, _extraData[i].realSize, true);

	return stream;
}

} // End of namespace Gob