public void Decode(
Vp9FrameKeys keys,
Vp9FrameHeader header,
Vp9ProbabilityTables probs,
byte[] frameData)
{
bool isKeyFrame = ((header.Flags >> 0) & 1) != 0;
bool lastIsKeyFrame = ((header.Flags >> 1) & 1) != 0;
bool frameSizeChanged = ((header.Flags >> 2) & 1) != 0;
bool errorResilientMode = ((header.Flags >> 3) & 1) != 0;
bool lastShowFrame = ((header.Flags >> 4) & 1) != 0;
bool isFrameIntra = ((header.Flags >> 5) & 1) != 0;
bool showFrame = !isFrameIntra;
//Write compressed header.
byte[] compressedHeaderData;
using (MemoryStream compressedHeader = new MemoryStream())
{
VpxRangeEncoder writer = new VpxRangeEncoder(compressedHeader);
if (!header.Lossless)
{
if ((uint)header.TxMode >= 3)
{
writer.Write(3, 2);
writer.Write(header.TxMode == 4);
}
else
{
writer.Write(header.TxMode, 2);
}
}
if (header.TxMode == 4)
{
WriteProbabilityUpdate(writer, probs.Tx8x8Probs, DefaultTx8x8Probs);
WriteProbabilityUpdate(writer, probs.Tx16x16Probs, DefaultTx16x16Probs);
WriteProbabilityUpdate(writer, probs.Tx32x32Probs, DefaultTx32x32Probs);
}
WriteCoefProbabilityUpdate(writer, header.TxMode, probs.CoefProbs, _defaultCoefProbs);
WriteProbabilityUpdate(writer, probs.SkipProbs, _defaultSkipProbs);
if (!isFrameIntra)
{
WriteProbabilityUpdateAligned4(writer, probs.InterModeProbs, _defaultInterModeProbs);
if (header.RawInterpolationFilter == 4)
{
WriteProbabilityUpdate(writer, probs.InterpFilterProbs, _defaultInterpFilterProbs);
}
WriteProbabilityUpdate(writer, probs.IsInterProbs, _defaultIsInterProbs);
if ((header.RefFrameSignBias[1] & 1) != (header.RefFrameSignBias[2] & 1) ||
(header.RefFrameSignBias[1] & 1) != (header.RefFrameSignBias[3] & 1))
{
if ((uint)header.CompPredMode >= 1)
{
writer.Write(1, 1);
writer.Write(header.CompPredMode == 2);
}
else
{
writer.Write(0, 1);
}
}
if (header.CompPredMode == 2)
{
WriteProbabilityUpdate(writer, probs.CompModeProbs, _defaultCompModeProbs);
}
if (header.CompPredMode != 1)
{
WriteProbabilityUpdate(writer, probs.SingleRefProbs, _defaultSingleRefProbs);
}
if (header.CompPredMode != 0)
{
WriteProbabilityUpdate(writer, probs.CompRefProbs, _defaultCompRefProbs);
}
for (int index = 0; index < 4; index++)
{
int i = index * 8;
int j = index;
WriteProbabilityUpdate(writer, probs.YModeProbs0[i + 0], _defaultYModeProbs0[i + 0]);
WriteProbabilityUpdate(writer, probs.YModeProbs0[i + 1], _defaultYModeProbs0[i + 1]);
WriteProbabilityUpdate(writer, probs.YModeProbs0[i + 2], _defaultYModeProbs0[i + 2]);
WriteProbabilityUpdate(writer, probs.YModeProbs0[i + 3], _defaultYModeProbs0[i + 3]);
WriteProbabilityUpdate(writer, probs.YModeProbs0[i + 4], _defaultYModeProbs0[i + 4]);
WriteProbabilityUpdate(writer, probs.YModeProbs0[i + 5], _defaultYModeProbs0[i + 5]);
WriteProbabilityUpdate(writer, probs.YModeProbs0[i + 6], _defaultYModeProbs0[i + 6]);
WriteProbabilityUpdate(writer, probs.YModeProbs0[i + 7], _defaultYModeProbs0[i + 7]);
WriteProbabilityUpdate(writer, probs.YModeProbs1[j + 0], _defaultYModeProbs1[j + 0]);
}
WriteProbabilityUpdateAligned4(writer, probs.PartitionProbs, _defaultPartitionProbs);
for (int i = 0; i < 3; i++)
{
WriteMvProbabilityUpdate(writer, probs.MvJointProbs[i], _defaultMvJointProbs[i]);
}
for (int i = 0; i < 2; i++)
{
WriteMvProbabilityUpdate(writer, probs.MvSignProbs[i], _defaultMvSignProbs[i]);
for (int j = 0; j < 10; j++)
{
int index = i * 10 + j;
WriteMvProbabilityUpdate(writer, probs.MvClassProbs[index], _defaultMvClassProbs[index]);
}
WriteMvProbabilityUpdate(writer, probs.MvClass0BitProbs[i], _defaultMvClass0BitProbs[i]);
for (int j = 0; j < 10; j++)
{
int index = i * 10 + j;
WriteMvProbabilityUpdate(writer, probs.MvBitsProbs[index], _defaultMvBitsProbs[index]);
}
}
for (int i = 0; i < 2; i++)
{
for (int j = 0; j < 2; j++)
{
for (int k = 0; k < 3; k++)
{
int index = i * 2 * 3 + j * 3 + k;
WriteMvProbabilityUpdate(writer, probs.MvClass0FrProbs[index], _defaultMvClass0FrProbs[index]);
}
}
for (int j = 0; j < 3; j++)
{
int index = i * 3 + j;
WriteMvProbabilityUpdate(writer, probs.MvFrProbs[index], _defaultMvFrProbs[index]);
}
}
if (header.AllowHighPrecisionMv)
{
for (int index = 0; index < 2; index++)
{
WriteMvProbabilityUpdate(writer, probs.MvClass0HpProbs[index], _defaultMvClass0HpProbs[index]);
WriteMvProbabilityUpdate(writer, probs.MvHpProbs[index], _defaultMvHpProbs[index]);
}
}
}
writer.End();
compressedHeaderData = compressedHeader.ToArray();
}
//Write uncompressed header.
using (MemoryStream encodedHeader = new MemoryStream())
{
VpxBitStreamWriter writer = new VpxBitStreamWriter(encodedHeader);
writer.WriteU(2, 2); //Frame marker.
writer.WriteU(0, 2); //Profile.
writer.WriteBit(false); //Show existing frame.
writer.WriteBit(!isKeyFrame);
writer.WriteBit(showFrame);
writer.WriteBit(errorResilientMode);
if (isKeyFrame)
{
writer.WriteU(FrameSyncCode, 24);
writer.WriteU(0, 3); //Color space.
writer.WriteU(0, 1); //Color range.
writer.WriteU(header.CurrentFrame.Width - 1, 16);
writer.WriteU(header.CurrentFrame.Height - 1, 16);
writer.WriteBit(false); //Render and frame size different.
_cachedRefFrames.Clear();
//On key frames, all frame slots are set to the current frame,
//so the value of the selected slot doesn't really matter.
GetNewFrameSlot(keys.CurrKey);
}
else
{
if (!showFrame)
{
writer.WriteBit(isFrameIntra);
}
if (!errorResilientMode)
{
writer.WriteU(0, 2); //Reset frame context.
}
int refreshFrameFlags = 1 << GetNewFrameSlot(keys.CurrKey);
if (isFrameIntra)
{
writer.WriteU(FrameSyncCode, 24);
writer.WriteU(refreshFrameFlags, 8);
writer.WriteU(header.CurrentFrame.Width - 1, 16);
writer.WriteU(header.CurrentFrame.Height - 1, 16);
writer.WriteBit(false); //Render and frame size different.
}
else
{
writer.WriteU(refreshFrameFlags, 8);
int[] refFrameIndex = new int[]
{
GetFrameSlot(keys.Ref0Key),
GetFrameSlot(keys.Ref1Key),
GetFrameSlot(keys.Ref2Key)
};
byte[] refFrameSignBias = header.RefFrameSignBias;
for (int index = 1; index < 4; index++)
{
writer.WriteU(refFrameIndex[index - 1], 3);
writer.WriteU(refFrameSignBias[index], 1);
}
writer.WriteBit(true); //Frame size with refs.
writer.WriteBit(false); //Render and frame size different.
writer.WriteBit(header.AllowHighPrecisionMv);
writer.WriteBit(header.RawInterpolationFilter == 4);
if (header.RawInterpolationFilter != 4)
{
writer.WriteU(header.RawInterpolationFilter, 2);
}
}
}
if (!errorResilientMode)
{
writer.WriteBit(false); //Refresh frame context.
writer.WriteBit(true); //Frame parallel decoding mode.
}
writer.WriteU(0, 2); //Frame context index.
writer.WriteU(header.LoopFilterLevel, 6);
writer.WriteU(header.LoopFilterSharpness, 3);
writer.WriteBit(header.LoopFilterDeltaEnabled);
if (header.LoopFilterDeltaEnabled)
{
bool[] updateLoopFilterRefDeltas = new bool[4];
bool[] updateLoopFilterModeDeltas = new bool[2];
bool loopFilterDeltaUpdate = false;
for (int index = 0; index < header.LoopFilterRefDeltas.Length; index++)
{
sbyte old = _loopFilterRefDeltas[index];
sbyte New = header.LoopFilterRefDeltas[index];
loopFilterDeltaUpdate |= (updateLoopFilterRefDeltas[index] = old != New);
}
for (int index = 0; index < header.LoopFilterModeDeltas.Length; index++)
{
sbyte old = _loopFilterModeDeltas[index];
sbyte New = header.LoopFilterModeDeltas[index];
loopFilterDeltaUpdate |= (updateLoopFilterModeDeltas[index] = old != New);
}
writer.WriteBit(loopFilterDeltaUpdate);
if (loopFilterDeltaUpdate)
{
for (int index = 0; index < header.LoopFilterRefDeltas.Length; index++)
{
writer.WriteBit(updateLoopFilterRefDeltas[index]);
if (updateLoopFilterRefDeltas[index])
{
writer.WriteS(header.LoopFilterRefDeltas[index], 6);
}
}
for (int index = 0; index < header.LoopFilterModeDeltas.Length; index++)
{
writer.WriteBit(updateLoopFilterModeDeltas[index]);
if (updateLoopFilterModeDeltas[index])
{
writer.WriteS(header.LoopFilterModeDeltas[index], 6);
}
}
}
}
writer.WriteU(header.BaseQIndex, 8);
writer.WriteDeltaQ(header.DeltaQYDc);
writer.WriteDeltaQ(header.DeltaQUvDc);
writer.WriteDeltaQ(header.DeltaQUvAc);
writer.WriteBit(false); //Segmentation enabled (TODO).
int minTileColsLog2 = CalcMinLog2TileCols(header.CurrentFrame.Width);
int maxTileColsLog2 = CalcMaxLog2TileCols(header.CurrentFrame.Width);
int tileColsLog2Diff = header.TileColsLog2 - minTileColsLog2;
int tileColsLog2IncMask = (1 << tileColsLog2Diff) - 1;
//If it's less than the maximum, we need to add an extra 0 on the bitstream
//to indicate that it should stop reading.
if (header.TileColsLog2 < maxTileColsLog2)
{
writer.WriteU(tileColsLog2IncMask << 1, tileColsLog2Diff + 1);
}
else
{
writer.WriteU(tileColsLog2IncMask, tileColsLog2Diff);
}
bool tileRowsLog2IsNonZero = header.TileRowsLog2 != 0;
writer.WriteBit(tileRowsLog2IsNonZero);
if (tileRowsLog2IsNonZero)
{
writer.WriteBit(header.TileRowsLog2 > 1);
}
writer.WriteU(compressedHeaderData.Length, 16);
writer.Flush();
encodedHeader.Write(compressedHeaderData, 0, compressedHeaderData.Length);
if (!FFmpegWrapper.IsInitialized)
{
FFmpegWrapper.Vp9Initialize();
}
FFmpegWrapper.DecodeFrame(DecoderHelper.Combine(encodedHeader.ToArray(), frameData));
}
_loopFilterRefDeltas = header.LoopFilterRefDeltas;
_loopFilterModeDeltas = header.LoopFilterModeDeltas;
}
private void Execute(NvGpuVmm vmm, int[] arguments)
{
if (_currentVideoCodec == VideoCodec.H264)
{
int frameDataSize = vmm.ReadInt32(_decoderContextAddress + 0x48);
H264ParameterSets Params = MemoryHelper.Read <H264ParameterSets>(vmm.Memory, vmm.GetPhysicalAddress(_decoderContextAddress + 0x58));
H264Matrices matrices = new H264Matrices()
{
ScalingMatrix4 = vmm.ReadBytes(_decoderContextAddress + 0x1c0, 6 * 16),
ScalingMatrix8 = vmm.ReadBytes(_decoderContextAddress + 0x220, 2 * 64)
};
byte[] frameData = vmm.ReadBytes(_frameDataAddress, frameDataSize);
_h264Decoder.Decode(Params, matrices, frameData);
}
else if (_currentVideoCodec == VideoCodec.Vp9)
{
int frameDataSize = vmm.ReadInt32(_decoderContextAddress + 0x30);
Vp9FrameKeys keys = new Vp9FrameKeys()
{
CurrKey = vmm.GetPhysicalAddress(_vpxCurrLumaAddress),
Ref0Key = vmm.GetPhysicalAddress(_vpxRef0LumaAddress),
Ref1Key = vmm.GetPhysicalAddress(_vpxRef1LumaAddress),
Ref2Key = vmm.GetPhysicalAddress(_vpxRef2LumaAddress)
};
Vp9FrameHeader header = MemoryHelper.Read <Vp9FrameHeader>(vmm.Memory, vmm.GetPhysicalAddress(_decoderContextAddress + 0x48));
Vp9ProbabilityTables probs = new Vp9ProbabilityTables()
{
SegmentationTreeProbs = vmm.ReadBytes(_vpxProbTablesAddress + 0x387, 0x7),
SegmentationPredProbs = vmm.ReadBytes(_vpxProbTablesAddress + 0x38e, 0x3),
Tx8x8Probs = vmm.ReadBytes(_vpxProbTablesAddress + 0x470, 0x2),
Tx16x16Probs = vmm.ReadBytes(_vpxProbTablesAddress + 0x472, 0x4),
Tx32x32Probs = vmm.ReadBytes(_vpxProbTablesAddress + 0x476, 0x6),
CoefProbs = vmm.ReadBytes(_vpxProbTablesAddress + 0x5a0, 0x900),
SkipProbs = vmm.ReadBytes(_vpxProbTablesAddress + 0x537, 0x3),
InterModeProbs = vmm.ReadBytes(_vpxProbTablesAddress + 0x400, 0x1c),
InterpFilterProbs = vmm.ReadBytes(_vpxProbTablesAddress + 0x52a, 0x8),
IsInterProbs = vmm.ReadBytes(_vpxProbTablesAddress + 0x41c, 0x4),
CompModeProbs = vmm.ReadBytes(_vpxProbTablesAddress + 0x532, 0x5),
SingleRefProbs = vmm.ReadBytes(_vpxProbTablesAddress + 0x580, 0xa),
CompRefProbs = vmm.ReadBytes(_vpxProbTablesAddress + 0x58a, 0x5),
YModeProbs0 = vmm.ReadBytes(_vpxProbTablesAddress + 0x480, 0x20),
YModeProbs1 = vmm.ReadBytes(_vpxProbTablesAddress + 0x47c, 0x4),
PartitionProbs = vmm.ReadBytes(_vpxProbTablesAddress + 0x4e0, 0x40),
MvJointProbs = vmm.ReadBytes(_vpxProbTablesAddress + 0x53b, 0x3),
MvSignProbs = vmm.ReadBytes(_vpxProbTablesAddress + 0x53e, 0x3),
MvClassProbs = vmm.ReadBytes(_vpxProbTablesAddress + 0x54c, 0x14),
MvClass0BitProbs = vmm.ReadBytes(_vpxProbTablesAddress + 0x540, 0x3),
MvBitsProbs = vmm.ReadBytes(_vpxProbTablesAddress + 0x56c, 0x14),
MvClass0FrProbs = vmm.ReadBytes(_vpxProbTablesAddress + 0x560, 0xc),
MvFrProbs = vmm.ReadBytes(_vpxProbTablesAddress + 0x542, 0x6),
MvClass0HpProbs = vmm.ReadBytes(_vpxProbTablesAddress + 0x548, 0x2),
MvHpProbs = vmm.ReadBytes(_vpxProbTablesAddress + 0x54a, 0x2)
};
byte[] frameData = vmm.ReadBytes(_frameDataAddress, frameDataSize);
_vp9Decoder.Decode(keys, header, probs, frameData);
}
else
{
ThrowUnimplementedCodec();
}
}