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Pure Java implementation of video/audio codecs and formats
package org.jcodec.codecs.prores;
import static java.lang.Math.min;
import static java.util.Arrays.fill;
import static org.jcodec.codecs.prores.ProresConsts.dcCodebooks;
import static org.jcodec.codecs.prores.ProresConsts.firstDCCodebook;
import static org.jcodec.codecs.prores.ProresConsts.interlaced_scan;
import static org.jcodec.codecs.prores.ProresConsts.levCodebooks;
import static org.jcodec.codecs.prores.ProresConsts.progressive_scan;
import static org.jcodec.codecs.prores.ProresConsts.runCodebooks;
import static org.jcodec.common.dct.SimpleIDCT10Bit.idct10;
import static org.jcodec.common.tools.MathUtil.log2;
import static org.jcodec.common.tools.MathUtil.toSigned;
import java.io.File;
import java.io.FileNotFoundException;
import java.io.IOException;
import java.nio.ByteBuffer;
import org.jcodec.codecs.prores.ProresConsts.FrameHeader;
import org.jcodec.codecs.prores.ProresConsts.PictureHeader;
import org.jcodec.common.FileChannelWrapper;
import org.jcodec.common.JCodecUtil;
import org.jcodec.common.NIOUtils;
import org.jcodec.common.VideoDecoder;
import org.jcodec.common.io.BitReader;
import org.jcodec.common.model.ColorSpace;
import org.jcodec.common.model.Packet;
import org.jcodec.common.model.Picture;
import org.jcodec.containers.mp4.demuxer.AbstractMP4DemuxerTrack;
import org.jcodec.containers.mp4.demuxer.MP4Demuxer;
import org.jcodec.scale.Yuv422pToRgb;
/**
*
* This class is part of JCodec ( www.jcodec.org ) This software is distributed
* under FreeBSD License
*
* Decoder for Apple ProRes format
*
* As posted at http://git.videolan.org/?p=ffmpeg.git;a=commitdiff;h=5554d
* e13b29b9bb812ee5cfd606349873ddf0945
*
* @author The JCodec project
*
*/
public class ProresDecoder implements VideoDecoder {
public ProresDecoder() {
}
static final int[] table = new int[] { 7, 6, 5, 5, 4, 4, 4, 4, 3, 3, 3, 3, 3, 3, 3, 3, 2, 2, 2, 2, 2, 2, 2, 2, 2,
2, 2, 2, 2, 2, 2, 2, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1,
1, 1, 1, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0 };
static final int[] mask = new int[] { 0, 0, 0, 0, 0, 0, 0, -1 };
public static final int nZeros(int check14Bit) {
int low = table[check14Bit & 0x7f];
check14Bit >>= 7;
int high = table[check14Bit & 0x7f];
return high + (mask[high & 0x7] & low);
}
public static final int readCodeword(BitReader reader, Codebook codebook) {
int q = nZeros(reader.checkNBit(14));
int val;
if (q > codebook.switchBits) {
int bits = codebook.expOrder - codebook.switchBits + (q << 1);
// if (bits + q + 1 > 32) {
// throw new RuntimeException("Codeword damaged");
// }
val = (int) reader.readNBit(bits); // Read value
val -= (1 << codebook.expOrder); // Offset to zero
// Offset to next number after max rice
val += ((codebook.switchBits + 1) << codebook.riceOrder);
} else if (codebook.riceOrder > 0) {
reader.skip(q + 1);
val = (q << codebook.riceOrder) + reader.readNBit(codebook.riceOrder);
} else {
reader.skip(q + 1);
val = q;
}
return val;
}
public static final int golumbToSigned(int val) {
return (val >> 1) ^ golumbSign(val);
}
public static final int golumbSign(int val) {
return -(val & 1);
}
public static final void readDCCoeffs(BitReader bits, int[] qMat, int[] out, int blocksPerSlice, int blkSize) {
int c = readCodeword(bits, firstDCCodebook);
if (c < 0) {
return;
// throw new RuntimeException("DC tex damaged");
}
int prevDc = golumbToSigned(c);
out[0] = 4096 + qScale(qMat, 0, prevDc);
int code = 5, sign = 0, idx = blkSize;
for (int i = 1; i < blocksPerSlice; i++, idx += blkSize) {
code = readCodeword(bits, dcCodebooks[min(code, 6)]);
if (code < 0) {
return;
// throw new RuntimeException("DC tex damaged");
}
if (code != 0)
sign ^= golumbSign(code);
else
sign = 0;
prevDc += toSigned((code + 1) >> 1, sign);
out[idx] = 4096 + qScale(qMat, 0, prevDc);
}
}
protected static final void readACCoeffs(BitReader bits, int[] qMat, int[] out, int blocksPerSlice, int[] scan,
int max, int log2blkSize) {
int run = 4;
int level = 2;
int blockMask = blocksPerSlice - 1; // since blocksPerSlice is 1 << n
int log2BlocksPerSlice = log2(blocksPerSlice);
int maxCoeffs = 64 << log2BlocksPerSlice;
int pos = blockMask;
while (bits.moreData()) {
run = readCodeword(bits, runCodebooks[min(run, 15)]);
if (run < 0 || run >= maxCoeffs - pos - 1) {
return;
// throw new RuntimeException("AC tex damaged, RUN");
}
pos += run + 1;
level = readCodeword(bits, levCodebooks[min(level, 9)]) + 1;
if (level < 0 || level > 65535) {
return;
// throw new RuntimeException("DC tex damaged, LEV");
}
int sign = -bits.read1Bit();
int ind = pos >> log2BlocksPerSlice;
if (ind >= max)
break;
out[((pos & blockMask) << log2blkSize) + scan[ind]] = qScale(qMat, ind, toSigned(level, sign));
}
}
private static final int qScale(int[] qMat, int ind, int val) {
return ((val * qMat[ind]) >> 2);
}
protected int[] decodeOnePlane(BitReader bits, int blocksPerSlice, int[] qMat, int[] scan, int mbX, int mbY,
int plane) {
int[] out = new int[blocksPerSlice << 6];
try {
readDCCoeffs(bits, qMat, out, blocksPerSlice, 64);
readACCoeffs(bits, qMat, out, blocksPerSlice, scan, 64, 6);
} catch (RuntimeException e) {
System.err.println("Suppressing slice error at [" + mbX + ", " + mbY + "].");
}
for (int i = 0; i < blocksPerSlice; i++) {
idct10(out, i << 6);
}
return out;
}
public Picture decodeFrame(ByteBuffer data, int[][] target) {
FrameHeader fh = readFrameHeader(data);
int codedWidth = (fh.width + 15) & ~0xf;
int codedHeight = (fh.height + 15) & ~0xf;
int lumaSize = codedWidth * codedHeight;
int chromaSize = lumaSize >> (3 - fh.chromaType);
if (target == null || target[0].length < lumaSize || target[1].length < chromaSize
|| target[2].length < chromaSize) {
throw new RuntimeException("Provided output picture won't fit into provided buffer");
}
if (fh.frameType == 0) {
decodePicture(data, target, fh.width, fh.height, codedWidth >> 4, fh.qMatLuma, fh.qMatChroma, fh.scan, 0,
fh.chromaType);
} else {
decodePicture(data, target, fh.width, fh.height >> 1, codedWidth >> 4, fh.qMatLuma, fh.qMatChroma, fh.scan,
fh.topFieldFirst ? 1 : 2, fh.chromaType);
decodePicture(data, target, fh.width, fh.height >> 1, codedWidth >> 4, fh.qMatLuma, fh.qMatChroma, fh.scan,
fh.topFieldFirst ? 2 : 1, fh.chromaType);
}
return new Picture(codedWidth, codedHeight, target, fh.chromaType == 2 ? ColorSpace.YUV422_10
: ColorSpace.YUV444_10);
}
public Picture[] decodeFields(ByteBuffer data, int[][][] target) {
FrameHeader fh = readFrameHeader(data);
int codedWidth = (fh.width + 15) & ~0xf;
int codedHeight = (fh.height + 15) & ~0xf;
int lumaSize = codedWidth * codedHeight;
int chromaSize = lumaSize >> 1;
if (fh.frameType == 0) {
if (target == null || target[0][0].length < lumaSize || target[0][1].length < chromaSize
|| target[0][2].length < chromaSize) {
throw new RuntimeException("Provided output picture won't fit into provided buffer");
}
decodePicture(data, target[0], fh.width, fh.height, codedWidth >> 4, fh.qMatLuma, fh.qMatChroma, fh.scan,
0, fh.chromaType);
return new Picture[] { new Picture(codedWidth, codedHeight, target[0], ColorSpace.YUV422_10) };
} else {
lumaSize >>= 1;
chromaSize >>= 1;
if (target == null || target[0][0].length < lumaSize || target[0][1].length < chromaSize
|| target[0][2].length < chromaSize || target[1][0].length < lumaSize
|| target[1][1].length < chromaSize || target[1][2].length < chromaSize) {
throw new RuntimeException("Provided output picture won't fit into provided buffer");
}
decodePicture(data, target[fh.topFieldFirst ? 0 : 1], fh.width, fh.height >> 1, codedWidth >> 4,
fh.qMatLuma, fh.qMatChroma, fh.scan, 0, fh.chromaType);
decodePicture(data, target[fh.topFieldFirst ? 1 : 0], fh.width, fh.height >> 1, codedWidth >> 4,
fh.qMatLuma, fh.qMatChroma, fh.scan, 0, fh.chromaType);
return new Picture[] { new Picture(codedWidth, codedHeight >> 1, target[0], ColorSpace.YUV422_10),
new Picture(codedWidth, codedHeight >> 1, target[1], ColorSpace.YUV422_10) };
}
}
public static FrameHeader readFrameHeader(ByteBuffer inp) {
int frameSize = inp.getInt();
String sig = readSig(inp);
if (!"icpf".equals(sig))
throw new RuntimeException("Not a prores frame");
short hdrSize = inp.getShort();
short version = inp.getShort();
int res1 = inp.getInt();
short width = inp.getShort();
short height = inp.getShort();
int flags1 = inp.get();
int frameType = (flags1 >> 2) & 3;
int chromaType = (flags1 >> 6) & 3;
int[] scan;
boolean topFieldFirst = false;
if (frameType == 0) {
scan = progressive_scan;
} else {
scan = interlaced_scan;
if (frameType == 1)
topFieldFirst = true;
}
byte res2 = inp.get();
byte prim = inp.get();
byte transFunc = inp.get();
byte matrix = inp.get();
byte pixFmt = inp.get();
byte res3 = inp.get();
int flags2 = inp.get() & 0xff;
int[] qMatLuma = new int[64];
int[] qMatChroma = new int[64];
if (hasQMatLuma(flags2)) {
readQMat(inp, qMatLuma, scan);
} else {
fill(qMatLuma, 4);
}
if (hasQMatChroma(flags2)) {
readQMat(inp, qMatChroma, scan);
} else {
fill(qMatChroma, 4);
}
inp.position(inp.position() + hdrSize
- (20 + (hasQMatLuma(flags2) ? 64 : 0) + (hasQMatChroma(flags2) ? 64 : 0)));
return new FrameHeader(frameSize - hdrSize - 8, width, height, frameType, topFieldFirst, scan, qMatLuma,
qMatChroma, chromaType);
}
static final String readSig(ByteBuffer inp) {
byte[] sig = new byte[4];
inp.get(sig);
return new String(sig);
}
protected void decodePicture(ByteBuffer data, int[][] result, int width, int height, int mbWidth, int[] qMatLuma,
int[] qMatChroma, int[] scan, int pictureType, int chromaType) {
ProresConsts.PictureHeader ph = readPictureHeader(data);
// int mbWidth = (width + 15) >> 4;
// int mbHeight = (height + 15) >> 4;
int mbX = 0, mbY = 0;
int sliceMbCount = 1 << ph.log2SliceMbWidth;
for (int i = 0; i < ph.sliceSizes.length; i++) {
while (mbWidth - mbX < sliceMbCount)
sliceMbCount >>= 1;
decodeSlice(NIOUtils.read(data, ph.sliceSizes[i]), qMatLuma, qMatChroma, scan, sliceMbCount, mbX, mbY,
ph.sliceSizes[i], result, width, pictureType, chromaType);
mbX += sliceMbCount;
if (mbX == mbWidth) {
sliceMbCount = 1 << ph.log2SliceMbWidth;
mbX = 0;
mbY++;
}
}
}
public static PictureHeader readPictureHeader(ByteBuffer inp) {
int hdrSize = (inp.get() & 0xff) >> 3;
inp.getInt();
int sliceCount = inp.getShort();
int a = inp.get() & 0xff;
int log2SliceMbWidth = a >> 4;
short[] sliceSizes = new short[sliceCount];
for (int i = 0; i < sliceCount; i++) {
sliceSizes[i] = inp.getShort();
}
return new PictureHeader(log2SliceMbWidth, sliceSizes);
}
private void decodeSlice(ByteBuffer data, int[] qMatLuma, int[] qMatChroma, int[] scan, int sliceMbCount, int mbX,
int mbY, short sliceSize, int[][] result, int lumaStride, int pictureType, int chromaType) {
int hdrSize = (data.get() & 0xff) >> 3;
int qScale = clip(data.get() & 0xff, 1, 224);
qScale = qScale > 128 ? qScale - 96 << 2 : qScale;
int yDataSize = data.getShort();
int uDataSize = data.getShort();
int vDataSize = hdrSize > 7 ? data.getShort() : sliceSize - uDataSize - yDataSize - hdrSize;
int[] y = decodeOnePlane(bitstream(data, yDataSize), sliceMbCount << 2, scaleMat(qMatLuma, qScale), scan, mbX,
mbY, 0);
int chromaBlkCount = (sliceMbCount << chromaType) >> 1;
int[] u = decodeOnePlane(bitstream(data, uDataSize), chromaBlkCount, scaleMat(qMatChroma, qScale), scan, mbX,
mbY, 1);
int[] v = decodeOnePlane(bitstream(data, vDataSize), chromaBlkCount, scaleMat(qMatChroma, qScale), scan, mbX,
mbY, 2);
putSlice(result, lumaStride, mbX, mbY, y, u, v, pictureType == 0 ? 0 : 1, pictureType == 2 ? 1 : 0, chromaType);
}
public static final int[] scaleMat(int[] qMatLuma, int qScale) {
int[] res = new int[qMatLuma.length];
for (int i = 0; i < qMatLuma.length; i++)
res[i] = qMatLuma[i] * qScale;
return res;
}
static final BitReader bitstream(ByteBuffer data, int dataSize) {
return new BitReader(NIOUtils.read(data, dataSize));
}
static final int clip(int val, int min, int max) {
return val < min ? min : (val > max ? max : val);
}
protected void putSlice(int[][] result, int lumaStride, int mbX, int mbY, int[] y, int[] u, int[] v, int dist,
int shift, int chromaType) {
int mbPerSlice = y.length >> 8;
int chromaStride = lumaStride >> 1;
putLuma(result[0], shift * lumaStride, lumaStride << dist, mbX, mbY, y, mbPerSlice, dist, shift);
if (chromaType == 2) {
putChroma(result[1], shift * chromaStride, chromaStride << dist, mbX, mbY, u, mbPerSlice, dist, shift);
putChroma(result[2], shift * chromaStride, chromaStride << dist, mbX, mbY, v, mbPerSlice, dist, shift);
} else {
putLuma(result[1], shift * lumaStride, lumaStride << dist, mbX, mbY, u, mbPerSlice, dist, shift);
putLuma(result[2], shift * lumaStride, lumaStride << dist, mbX, mbY, v, mbPerSlice, dist, shift);
}
}
private void putLuma(int[] y, int off, int stride, int mbX, int mbY, int[] luma, int mbPerSlice, int dist, int shift) {
off += (mbX << 4) + (mbY << 4) * stride;
for (int k = 0; k < mbPerSlice; k++) {
putBlock(y, off, stride, luma, k << 8, dist, shift);
putBlock(y, off + 8, stride, luma, (k << 8) + 64, dist, shift);
putBlock(y, off + 8 * stride, stride, luma, (k << 8) + 128, dist, shift);
putBlock(y, off + 8 * stride + 8, stride, luma, (k << 8) + 192, dist, shift);
off += 16;
}
}
private void putChroma(int[] y, int off, int stride, int mbX, int mbY, int[] chroma, int mbPerSlice, int dist,
int shift) {
off += (mbX << 3) + (mbY << 4) * stride;
for (int k = 0; k < mbPerSlice; k++) {
putBlock(y, off, stride, chroma, k << 7, dist, shift);
putBlock(y, off + 8 * stride, stride, chroma, (k << 7) + 64, dist, shift);
off += 8;
}
}
private void putBlock(int[] square, int sqOff, int sqStride, int[] flat, int flOff, int dist, int shift) {
for (int i = 0; i < 8; i++) {
for (int j = 0; j < 8; j++)
square[j + sqOff] = clip(flat[j + flOff], 4, 1019);
sqOff += sqStride;
flOff += 8;
}
}
static final boolean hasQMatChroma(int flags2) {
return (flags2 & 1) != 0;
}
static final void readQMat(ByteBuffer inp, int[] qMatLuma, int[] scan) {
byte[] b = new byte[64];
inp.get(b);
for (int i = 0; i < 64; i++) {
qMatLuma[i] = b[scan[i]] & 0xff;
}
}
static final boolean hasQMatLuma(int flags2) {
return (flags2 & 2) != 0;
}
public boolean isProgressive(ByteBuffer data) {
return (((data.get(20) & 0xff) >> 2) & 3) == 0;
}
public int probe(ByteBuffer data) {
if (data.get(4) == 'i' && data.get(5) == 'c' && data.get(6) == 'p' && data.get(7) == 'f')
return 100;
return 0;
}
}