private long OneStatPass(int width, int height, int yStride, int uvStride, Vp8RdLevel rdOpt, int nbMbs, PassStats stats)
{
Span <byte> y = this.Y.GetSpan();
Span <byte> u = this.U.GetSpan();
Span <byte> v = this.V.GetSpan();
var it = new Vp8EncIterator(this.YTop, this.UvTop, this.Nz, this.MbInfo, this.Preds, this.TopDerr, this.Mbw, this.Mbh);
long size = 0;
long sizeP0 = 0;
long distortion = 0;
long pixelCount = nbMbs * 384;
it.Init();
this.SetLoopParams(stats.Q);
var info = new Vp8ModeScore();
do
{
info.Clear();
it.Import(y, u, v, yStride, uvStride, width, height, false);
if (this.Decimate(it, ref info, rdOpt))
{
// Just record the number of skips and act like skipProba is not used.
++this.Proba.NbSkip;
}
this.RecordResiduals(it, info);
size += info.R + info.H;
sizeP0 += info.H;
distortion += info.D;
it.SaveBoundary();
}while (it.Next() && --nbMbs > 0);
sizeP0 += this.SegmentHeader.Size;
if (stats.DoSizeSearch)
{
size += this.Proba.FinalizeSkipProba(this.Mbw, this.Mbh);
size += this.Proba.FinalizeTokenProbas();
size = ((size + sizeP0 + 1024) >> 11) + HeaderSizeEstimate;
stats.Value = size;
}
else
{
stats.Value = GetPsnr(distortion, pixelCount);
}
return(sizeP0);
}
public static void PickBestUv(Vp8EncIterator it, ref Vp8ModeScore rd, Vp8SegmentInfo[] segmentInfos, Vp8EncProba proba)
{
const int numBlocks = 8;
Vp8SegmentInfo dqm = segmentInfos[it.CurrentMacroBlockInfo.Segment];
int lambda = dqm.LambdaUv;
Span <byte> src = it.YuvIn.AsSpan(Vp8EncIterator.UOffEnc);
Span <byte> tmpDst = it.YuvOut2.AsSpan(Vp8EncIterator.UOffEnc);
Span <byte> dst0 = it.YuvOut.AsSpan(Vp8EncIterator.UOffEnc);
Span <byte> dst = dst0;
var rdBest = new Vp8ModeScore();
var rdUv = new Vp8ModeScore();
var res = new Vp8Residual();
int mode;
rd.ModeUv = -1;
rdBest.InitScore();
for (mode = 0; mode < WebpConstants.NumPredModes; ++mode)
{
rdUv.Clear();
// Reconstruct
rdUv.Nz = (uint)ReconstructUv(it, dqm, rdUv, tmpDst, mode);
// Compute RD-score
rdUv.D = LossyUtils.Vp8_Sse16X8(src, tmpDst);
rdUv.SD = 0; // not calling TDisto here: it tends to flatten areas.
rdUv.H = WebpConstants.Vp8FixedCostsUv[mode];
rdUv.R = it.GetCostUv(rdUv, proba, res);
if (mode > 0 && IsFlat(rdUv.UvLevels, numBlocks, WebpConstants.FlatnessLimitIUv))
{
rdUv.R += WebpConstants.FlatnessPenality * numBlocks;
}
rdUv.SetRdScore(lambda);
if (mode == 0 || rdUv.Score < rdBest.Score)
{
rdBest.CopyScore(rdUv);
rd.ModeUv = mode;
rdUv.UvLevels.CopyTo(rd.UvLevels.AsSpan());
for (int i = 0; i < 2; i++)
{
rd.Derr[i, 0] = rdUv.Derr[i, 0];
rd.Derr[i, 1] = rdUv.Derr[i, 1];
rd.Derr[i, 2] = rdUv.Derr[i, 2];
}
Span <byte> tmp = dst;
dst = tmpDst;
tmpDst = tmp;
}
}
it.SetIntraUvMode(rd.ModeUv);
rd.AddScore(rdBest);
if (dst != dst0)
{
// copy 16x8 block if needed.
LossyUtils.Vp8Copy16X8(dst, dst0);
}
// Store diffusion errors for next block.
it.StoreDiffusionErrors(rd);
}
/// <summary>
/// Encodes the image to the specified stream from the <see cref="Image{TPixel}"/>.
/// </summary>
/// <typeparam name="TPixel">The pixel format.</typeparam>
/// <param name="image">The <see cref="Image{TPixel}"/> to encode from.</param>
/// <param name="stream">The <see cref="Stream"/> to encode the image data to.</param>
public void Encode <TPixel>(Image <TPixel> image, Stream stream)
where TPixel : unmanaged, IPixel <TPixel>
{
int width = image.Width;
int height = image.Height;
Span <byte> y = this.Y.GetSpan();
Span <byte> u = this.U.GetSpan();
Span <byte> v = this.V.GetSpan();
YuvConversion.ConvertRgbToYuv(image, this.configuration, this.memoryAllocator, y, u, v);
int yStride = width;
int uvStride = (yStride + 1) >> 1;
var it = new Vp8EncIterator(this.YTop, this.UvTop, this.Nz, this.MbInfo, this.Preds, this.TopDerr, this.Mbw, this.Mbh);
int[] alphas = new int[WebpConstants.MaxAlpha + 1];
this.alpha = this.MacroBlockAnalysis(width, height, it, y, u, v, yStride, uvStride, alphas, out this.uvAlpha);
int totalMb = this.Mbw * this.Mbw;
this.alpha /= totalMb;
this.uvAlpha /= totalMb;
// Analysis is done, proceed to actual encoding.
this.SegmentHeader = new Vp8EncSegmentHeader(4);
this.AssignSegments(alphas);
this.SetLoopParams(this.quality);
// Initialize the bitwriter.
int averageBytesPerMacroBlock = this.averageBytesPerMb[this.BaseQuant >> 4];
int expectedSize = this.Mbw * this.Mbh * averageBytesPerMacroBlock;
this.bitWriter = new Vp8BitWriter(expectedSize, this);
// TODO: EncodeAlpha();
bool hasAlpha = false;
// Stats-collection loop.
this.StatLoop(width, height, yStride, uvStride);
it.Init();
it.InitFilter();
var info = new Vp8ModeScore();
var residual = new Vp8Residual();
do
{
bool dontUseSkip = !this.Proba.UseSkipProba;
info.Clear();
it.Import(y, u, v, yStride, uvStride, width, height, false);
// Warning! order is important: first call VP8Decimate() and
// *then* decide how to code the skip decision if there's one.
if (!this.Decimate(it, ref info, this.rdOptLevel) || dontUseSkip)
{
this.CodeResiduals(it, info, residual);
}
else
{
it.ResetAfterSkip();
}
it.SaveBoundary();
}while (it.Next());
// Store filter stats.
this.AdjustFilterStrength();
// Write bytes from the bitwriter buffer to the stream.
image.Metadata.SyncProfiles();
this.bitWriter.WriteEncodedImageToStream(stream, image.Metadata.ExifProfile, (uint)width, (uint)height, hasAlpha);
}
public static bool PickBestIntra4(Vp8EncIterator it, ref Vp8ModeScore rd, Vp8SegmentInfo[] segmentInfos, Vp8EncProba proba, int maxI4HeaderBits)
{
Vp8SegmentInfo dqm = segmentInfos[it.CurrentMacroBlockInfo.Segment];
int lambda = dqm.LambdaI4;
int tlambda = dqm.TLambda;
Span <byte> src0 = it.YuvIn.AsSpan(Vp8EncIterator.YOffEnc);
Span <byte> bestBlocks = it.YuvOut2.AsSpan(Vp8EncIterator.YOffEnc);
Span <int> scratch = it.Scratch3;
int totalHeaderBits = 0;
var rdBest = new Vp8ModeScore();
if (maxI4HeaderBits == 0)
{
return(false);
}
rdBest.InitScore();
rdBest.H = 211; // '211' is the value of VP8BitCost(0, 145)
rdBest.SetRdScore(dqm.LambdaMode);
it.StartI4();
var rdi4 = new Vp8ModeScore();
var rdTmp = new Vp8ModeScore();
var res = new Vp8Residual();
Span <short> tmpLevels = new short[16];
do
{
int numBlocks = 1;
rdi4.Clear();
int mode;
int bestMode = -1;
Span <byte> src = src0.Slice(WebpLookupTables.Vp8Scan[it.I4]);
short[] modeCosts = it.GetCostModeI4(rd.ModesI4);
Span <byte> bestBlock = bestBlocks.Slice(WebpLookupTables.Vp8Scan[it.I4]);
Span <byte> tmpDst = it.Scratch.AsSpan();
tmpDst.Clear();
rdi4.InitScore();
it.MakeIntra4Preds();
for (mode = 0; mode < WebpConstants.NumBModes; ++mode)
{
rdTmp.Clear();
tmpLevels.Clear();
// Reconstruct.
rdTmp.Nz = (uint)ReconstructIntra4(it, dqm, tmpLevels, src, tmpDst, mode);
// Compute RD-score.
rdTmp.D = LossyUtils.Vp8_Sse4X4(src, tmpDst);
rdTmp.SD = tlambda != 0 ? Mult8B(tlambda, LossyUtils.Vp8Disto4X4(src, tmpDst, WeightY, scratch)) : 0;
rdTmp.H = modeCosts[mode];
// Add flatness penalty, to avoid flat area to be mispredicted by a complex mode.
if (mode > 0 && IsFlat(tmpLevels, numBlocks, WebpConstants.FlatnessLimitI4))
{
rdTmp.R = WebpConstants.FlatnessPenality * numBlocks;
}
else
{
rdTmp.R = 0;
}
// Early-out check.
rdTmp.SetRdScore(lambda);
if (bestMode >= 0 && rdTmp.Score >= rdi4.Score)
{
continue;
}
// Finish computing score.
rdTmp.R += it.GetCostLuma4(tmpLevels, proba, res);
rdTmp.SetRdScore(lambda);
if (bestMode < 0 || rdTmp.Score < rdi4.Score)
{
rdi4.CopyScore(rdTmp);
bestMode = mode;
Span <byte> tmp = tmpDst;
tmpDst = bestBlock;
bestBlock = tmp;
tmpLevels.CopyTo(rdBest.YAcLevels.AsSpan(it.I4 * 16, 16));
}
}
rdi4.SetRdScore(dqm.LambdaMode);
rdBest.AddScore(rdi4);
if (rdBest.Score >= rd.Score)
{
return(false);
}
totalHeaderBits += (int)rdi4.H; // <- equal to modeCosts[bestMode];
if (totalHeaderBits > maxI4HeaderBits)
{
return(false);
}
// Copy selected samples to the right place.
LossyUtils.Vp8Copy4X4(bestBlock, bestBlocks.Slice(WebpLookupTables.Vp8Scan[it.I4]));
rd.ModesI4[it.I4] = (byte)bestMode;
it.TopNz[it.I4 & 3] = it.LeftNz[it.I4 >> 2] = rdi4.Nz != 0 ? 1 : 0;
}while (it.RotateI4(bestBlocks));
// Finalize state.
rd.CopyScore(rdBest);
it.SetIntra4Mode(rd.ModesI4);
it.SwapOut();
rdBest.YAcLevels.AsSpan().CopyTo(rd.YAcLevels);
// Select intra4x4 over intra16x16.
return(true);
}