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/* 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 "common/scummsys.h"
#include "zvision/video/rlf_decoder.h"
#include "common/str.h"
#include "common/file.h"
#include "common/textconsole.h"
#include "common/debug.h"
#include "common/endian.h"
#include "graphics/colormasks.h"
namespace ZVision {
RLFDecoder::~RLFDecoder() {
close();
}
bool RLFDecoder::loadStream(Common::SeekableReadStream *stream) {
close();
addTrack(new RLFVideoTrack(stream));
return true;
}
RLFDecoder::RLFVideoTrack::RLFVideoTrack(Common::SeekableReadStream *stream)
: _readStream(stream),
_lastFrameRead(0),
_frameCount(0),
_width(0),
_height(0),
_frameTime(0),
_frames(0),
_curFrame(0),
_frameBufferByteSize(0) {
if (!readHeader()) {
warning("Not a RLF animation file. Wrong magic number");
return;
}
_currentFrameBuffer.create(_width, _height, Graphics::createPixelFormat<565>());
_frameBufferByteSize = _width * _height * sizeof(uint16);
_frames = new Frame[_frameCount];
// Read in each frame
for (uint i = 0; i < _frameCount; ++i) {
_frames[i] = readNextFrame();
}
}
RLFDecoder::RLFVideoTrack::~RLFVideoTrack() {
for (uint i = 0; i < _frameCount; ++i) {
delete[] _frames[i].encodedData;
}
delete[] _frames;
delete _readStream;
_currentFrameBuffer.free();
}
bool RLFDecoder::RLFVideoTrack::readHeader() {
if (_readStream->readUint32BE() != MKTAG('F', 'E', 'L', 'R')) {
return false;
}
// Read the header
_readStream->readUint32LE(); // Size1
_readStream->readUint32LE(); // Unknown1
_readStream->readUint32LE(); // Unknown2
_frameCount = _readStream->readUint32LE(); // Frame count
// Since we don't need any of the data, we can just seek right to the
// entries we need rather than read in all the individual entries.
_readStream->seek(136, SEEK_CUR);
//// Read CIN header
//_readStream->readUint32BE(); // Magic number FNIC
//_readStream->readUint32LE(); // Size2
//_readStream->readUint32LE(); // Unknown3
//_readStream->readUint32LE(); // Unknown4
//_readStream->readUint32LE(); // Unknown5
//_readStream->seek(0x18, SEEK_CUR); // VRLE
//_readStream->readUint32LE(); // LRVD
//_readStream->readUint32LE(); // Unknown6
//_readStream->seek(0x18, SEEK_CUR); // HRLE
//_readStream->readUint32LE(); // ELHD
//_readStream->readUint32LE(); // Unknown7
//_readStream->seek(0x18, SEEK_CUR); // HKEY
//_readStream->readUint32LE(); // ELRH
//// Read MIN info header
//_readStream->readUint32BE(); // Magic number FNIM
//_readStream->readUint32LE(); // Size3
//_readStream->readUint32LE(); // OEDV
//_readStream->readUint32LE(); // Unknown8
//_readStream->readUint32LE(); // Unknown9
//_readStream->readUint32LE(); // Unknown10
_width = _readStream->readUint32LE(); // Width
_height = _readStream->readUint32LE(); // Height
// Read time header
_readStream->readUint32BE(); // Magic number EMIT
_readStream->readUint32LE(); // Size4
_readStream->readUint32LE(); // Unknown11
_frameTime = _readStream->readUint32LE() / 10; // Frame time in microseconds
return true;
}
RLFDecoder::RLFVideoTrack::Frame RLFDecoder::RLFVideoTrack::readNextFrame() {
RLFDecoder::RLFVideoTrack::Frame frame;
_readStream->readUint32BE(); // Magic number MARF
uint32 size = _readStream->readUint32LE(); // Size
_readStream->readUint32LE(); // Unknown1
_readStream->readUint32LE(); // Unknown2
uint32 type = _readStream->readUint32BE(); // Either ELHD or ELRH
uint32 headerSize = _readStream->readUint32LE(); // Offset from the beginning of this frame to the frame data. Should always be 28
_readStream->readUint32LE(); // Unknown3
frame.encodedSize = size - headerSize;
frame.encodedData = new int8[frame.encodedSize];
_readStream->read(frame.encodedData, frame.encodedSize);
if (type == MKTAG('E', 'L', 'H', 'D')) {
frame.type = Masked;
} else if (type == MKTAG('E', 'L', 'R', 'H')) {
frame.type = Simple;
_completeFrames.push_back(_lastFrameRead);
} else {
warning("Frame %u doesn't have type that can be decoded", _lastFrameRead);
}
_lastFrameRead++;
return frame;
}
bool RLFDecoder::RLFVideoTrack::seek(const Audio::Timestamp &time) {
uint frame = getFrameAtTime(time);
assert(frame < (int)_frameCount);
if ((uint)_curFrame == frame)
return true;
if (frame < 0) {
_curFrame = 0;
return false;
}
int closestFrame = _curFrame;
int distance = (int)frame - _curFrame;
if (distance < 0) {
for (uint i = 0; i < _completeFrames.size(); ++i) {
if ((int)_completeFrames[i] > frame)
break;
closestFrame = _completeFrames[i];
}
} else {
for (uint i = 0; i < _completeFrames.size(); ++i) {
int newDistance = (int)frame - (int)(_completeFrames[i]);
if (newDistance < 0)
break;
if (newDistance < distance) {
closestFrame = _completeFrames[i];
distance = newDistance;
}
}
}
for (uint i = closestFrame; i < frame; ++i) {
applyFrameToCurrent(i);
}
_curFrame = frame;
return true;
}
const Graphics::Surface *RLFDecoder::RLFVideoTrack::decodeNextFrame() {
// When an animation ends, rewind
if (_curFrame == (int)_frameCount)
seek(Audio::Timestamp(0, getFrameRate().toInt()));
applyFrameToCurrent(_curFrame);
_curFrame++;
return &_currentFrameBuffer;
}
void RLFDecoder::RLFVideoTrack::applyFrameToCurrent(uint frameNumber) {
if (_frames[frameNumber].type == Masked) {
decodeMaskedRunLengthEncoding(_frames[frameNumber].encodedData, (int8 *)_currentFrameBuffer.getPixels(), _frames[frameNumber].encodedSize, _frameBufferByteSize);
} else if (_frames[frameNumber].type == Simple) {
decodeSimpleRunLengthEncoding(_frames[frameNumber].encodedData, (int8 *)_currentFrameBuffer.getPixels(), _frames[frameNumber].encodedSize, _frameBufferByteSize);
}
}
void RLFDecoder::RLFVideoTrack::decodeMaskedRunLengthEncoding(int8 *source, int8 *dest, uint32 sourceSize, uint32 destSize) const {
uint32 sourceOffset = 0;
uint32 destOffset = 0;
int16 numberOfCopy = 0;
while (sourceOffset < sourceSize) {
int8 numberOfSamples = source[sourceOffset];
sourceOffset++;
// If numberOfSamples is negative, the next abs(numberOfSamples) samples should
// be copied directly from source to dest
if (numberOfSamples < 0) {
numberOfCopy = -numberOfSamples;
while (numberOfCopy > 0) {
if (sourceOffset + 1 >= sourceSize) {
return;
} else if (destOffset + 1 >= destSize) {
debug(2, "Frame decoding overflow\n\tsourceOffset=%u\tsourceSize=%u\n\tdestOffset=%u\tdestSize=%u", sourceOffset, sourceSize, destOffset, destSize);
return;
}
byte r, g, b;
Graphics::colorToRGB<Graphics::ColorMasks<555> >(READ_LE_UINT16(source + sourceOffset), r, g, b);
uint16 destColor = Graphics::RGBToColor<Graphics::ColorMasks<565> >(r, g, b);
WRITE_UINT16(dest + destOffset, destColor);
sourceOffset += 2;
destOffset += 2;
numberOfCopy--;
}
// If numberOfSamples is >= 0, move destOffset forward ((numberOfSamples * 2) + 2)
// This function assumes the dest buffer has been memset with 0's.
} else {
if (sourceOffset + 1 >= sourceSize) {
return;
} else if (destOffset + 1 >= destSize) {
debug(2, "Frame decoding overflow\n\tsourceOffset=%u\tsourceSize=%u\n\tdestOffset=%u\tdestSize=%u", sourceOffset, sourceSize, destOffset, destSize);
return;
}
destOffset += (numberOfSamples * 2) + 2;
}
}
}
void RLFDecoder::RLFVideoTrack::decodeSimpleRunLengthEncoding(int8 *source, int8 *dest, uint32 sourceSize, uint32 destSize) const {
uint32 sourceOffset = 0;
uint32 destOffset = 0;
int16 numberOfCopy = 0;
while (sourceOffset < sourceSize) {
int8 numberOfSamples = source[sourceOffset];
sourceOffset++;
// If numberOfSamples is negative, the next abs(numberOfSamples) samples should
// be copied directly from source to dest
if (numberOfSamples < 0) {
numberOfCopy = -numberOfSamples;
while (numberOfCopy > 0) {
if (sourceOffset + 1 >= sourceSize) {
return;
} else if (destOffset + 1 >= destSize) {
debug(2, "Frame decoding overflow\n\tsourceOffset=%u\tsourceSize=%u\n\tdestOffset=%u\tdestSize=%u", sourceOffset, sourceSize, destOffset, destSize);
return;
}
byte r, g, b;
Graphics::colorToRGB<Graphics::ColorMasks<555> >(READ_LE_UINT16(source + sourceOffset), r, g, b);
uint16 destColor = Graphics::RGBToColor<Graphics::ColorMasks<565> >(r, g, b);
WRITE_UINT16(dest + destOffset, destColor);
sourceOffset += 2;
destOffset += 2;
numberOfCopy--;
}
// If numberOfSamples is >= 0, copy one sample from source to the
// next (numberOfSamples + 2) dest spots
} else {
if (sourceOffset + 1 >= sourceSize) {
return;
}
byte r, g, b;
Graphics::colorToRGB<Graphics::ColorMasks<555> >(READ_LE_UINT16(source + sourceOffset), r, g, b);
uint16 sampleColor = Graphics::RGBToColor<Graphics::ColorMasks<565> >(r, g, b);
sourceOffset += 2;
numberOfCopy = numberOfSamples + 2;
while (numberOfCopy > 0) {
if (destOffset + 1 >= destSize) {
debug(2, "Frame decoding overflow\n\tsourceOffset=%u\tsourceSize=%u\n\tdestOffset=%u\tdestSize=%u", sourceOffset, sourceSize, destOffset, destSize);
return;
}
WRITE_UINT16(dest + destOffset, sampleColor);
destOffset += 2;
numberOfCopy--;
}
}
}
}
} // End of namespace ZVision
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