mirror of
https://gitlab.winehq.org/wine/wine-gecko.git
synced 2024-09-13 09:24:08 -07:00
322 lines
13 KiB
C++
322 lines
13 KiB
C++
/* -*- Mode: C++; tab-width: 20; indent-tabs-mode: nil; c-basic-offset: 2 -*-
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* This Source Code Form is subject to the terms of the Mozilla Public
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* License, v. 2.0. If a copy of the MPL was not distributed with this
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* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
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#define FILTER_PROCESSING_SCALAR
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#include "FilterProcessingSIMD-inl.h"
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namespace mozilla {
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namespace gfx {
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void
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FilterProcessing::ExtractAlpha_Scalar(const IntSize& size, uint8_t* sourceData, int32_t sourceStride, uint8_t* alphaData, int32_t alphaStride)
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{
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for (int32_t y = 0; y < size.height; y++) {
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for (int32_t x = 0; x < size.width; x++) {
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int32_t sourceIndex = y * sourceStride + 4 * x;
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int32_t targetIndex = y * alphaStride + x;
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alphaData[targetIndex] = sourceData[sourceIndex + B8G8R8A8_COMPONENT_BYTEOFFSET_A];
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}
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}
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}
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TemporaryRef<DataSourceSurface>
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FilterProcessing::ConvertToB8G8R8A8_Scalar(SourceSurface* aSurface)
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{
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return ConvertToB8G8R8A8_SIMD<simd::Scalaru8x16_t>(aSurface);
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}
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template<BlendMode aBlendMode>
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static TemporaryRef<DataSourceSurface>
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ApplyBlending_Scalar(DataSourceSurface* aInput1, DataSourceSurface* aInput2)
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{
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IntSize size = aInput1->GetSize();
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RefPtr<DataSourceSurface> target =
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Factory::CreateDataSourceSurface(size, SurfaceFormat::B8G8R8A8);
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if (!target) {
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return nullptr;
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}
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uint8_t* source1Data = aInput1->GetData();
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uint8_t* source2Data = aInput2->GetData();
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uint8_t* targetData = target->GetData();
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uint32_t targetStride = target->Stride();
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uint32_t source1Stride = aInput1->Stride();
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uint32_t source2Stride = aInput2->Stride();
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for (int32_t y = 0; y < size.height; y++) {
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for (int32_t x = 0; x < size.width; x++) {
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uint32_t targetIndex = y * targetStride + 4 * x;
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uint32_t source1Index = y * source1Stride + 4 * x;
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uint32_t source2Index = y * source2Stride + 4 * x;
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uint32_t qa = source1Data[source1Index + B8G8R8A8_COMPONENT_BYTEOFFSET_A];
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uint32_t qb = source2Data[source2Index + B8G8R8A8_COMPONENT_BYTEOFFSET_A];
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for (int32_t i = std::min(B8G8R8A8_COMPONENT_BYTEOFFSET_B, B8G8R8A8_COMPONENT_BYTEOFFSET_R);
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i <= std::max(B8G8R8A8_COMPONENT_BYTEOFFSET_B, B8G8R8A8_COMPONENT_BYTEOFFSET_R); i++) {
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uint32_t ca = source1Data[source1Index + i];
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uint32_t cb = source2Data[source2Index + i];
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uint32_t val;
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switch (aBlendMode) {
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case BLEND_MODE_MULTIPLY:
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val = ((255 - qa) * cb + (255 - qb + cb) * ca);
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break;
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case BLEND_MODE_SCREEN:
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val = 255 * (cb + ca) - ca * cb;
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break;
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case BLEND_MODE_DARKEN:
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val = umin((255 - qa) * cb + 255 * ca,
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(255 - qb) * ca + 255 * cb);
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break;
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case BLEND_MODE_LIGHTEN:
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val = umax((255 - qa) * cb + 255 * ca,
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(255 - qb) * ca + 255 * cb);
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break;
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default:
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MOZ_CRASH();
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}
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val = umin(FilterProcessing::FastDivideBy255<unsigned>(val), 255U);
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targetData[targetIndex + i] = static_cast<uint8_t>(val);
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}
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uint32_t alpha = 255 * 255 - (255 - qa) * (255 - qb);
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targetData[targetIndex + B8G8R8A8_COMPONENT_BYTEOFFSET_A] =
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FilterProcessing::FastDivideBy255<uint8_t>(alpha);
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}
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}
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return target.forget();
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}
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TemporaryRef<DataSourceSurface>
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FilterProcessing::ApplyBlending_Scalar(DataSourceSurface* aInput1, DataSourceSurface* aInput2,
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BlendMode aBlendMode)
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{
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switch (aBlendMode) {
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case BLEND_MODE_MULTIPLY:
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return gfx::ApplyBlending_Scalar<BLEND_MODE_MULTIPLY>(aInput1, aInput2);
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case BLEND_MODE_SCREEN:
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return gfx::ApplyBlending_Scalar<BLEND_MODE_SCREEN>(aInput1, aInput2);
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case BLEND_MODE_DARKEN:
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return gfx::ApplyBlending_Scalar<BLEND_MODE_DARKEN>(aInput1, aInput2);
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case BLEND_MODE_LIGHTEN:
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return gfx::ApplyBlending_Scalar<BLEND_MODE_LIGHTEN>(aInput1, aInput2);
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default:
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return nullptr;
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}
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}
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template<MorphologyOperator Operator>
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static void
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ApplyMorphologyHorizontal_Scalar(uint8_t* aSourceData, int32_t aSourceStride,
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uint8_t* aDestData, int32_t aDestStride,
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const IntRect& aDestRect, int32_t aRadius)
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{
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static_assert(Operator == MORPHOLOGY_OPERATOR_ERODE ||
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Operator == MORPHOLOGY_OPERATOR_DILATE,
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"unexpected morphology operator");
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for (int32_t y = aDestRect.y; y < aDestRect.YMost(); y++) {
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int32_t startX = aDestRect.x - aRadius;
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int32_t endX = aDestRect.x + aRadius;
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for (int32_t x = aDestRect.x; x < aDestRect.XMost(); x++, startX++, endX++) {
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int32_t sourceIndex = y * aSourceStride + 4 * startX;
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uint8_t u[4];
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for (size_t i = 0; i < 4; i++) {
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u[i] = aSourceData[sourceIndex + i];
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}
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sourceIndex += 4;
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for (int32_t ix = startX + 1; ix <= endX; ix++, sourceIndex += 4) {
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for (size_t i = 0; i < 4; i++) {
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if (Operator == MORPHOLOGY_OPERATOR_ERODE) {
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u[i] = umin(u[i], aSourceData[sourceIndex + i]);
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} else {
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u[i] = umax(u[i], aSourceData[sourceIndex + i]);
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}
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}
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}
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int32_t destIndex = y * aDestStride + 4 * x;
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for (size_t i = 0; i < 4; i++) {
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aDestData[destIndex+i] = u[i];
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}
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}
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}
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}
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void
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FilterProcessing::ApplyMorphologyHorizontal_Scalar(uint8_t* aSourceData, int32_t aSourceStride,
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uint8_t* aDestData, int32_t aDestStride,
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const IntRect& aDestRect, int32_t aRadius,
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MorphologyOperator aOp)
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{
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if (aOp == MORPHOLOGY_OPERATOR_ERODE) {
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gfx::ApplyMorphologyHorizontal_Scalar<MORPHOLOGY_OPERATOR_ERODE>(
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aSourceData, aSourceStride, aDestData, aDestStride, aDestRect, aRadius);
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} else {
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gfx::ApplyMorphologyHorizontal_Scalar<MORPHOLOGY_OPERATOR_DILATE>(
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aSourceData, aSourceStride, aDestData, aDestStride, aDestRect, aRadius);
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}
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}
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template<MorphologyOperator Operator>
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static void ApplyMorphologyVertical_Scalar(uint8_t* aSourceData, int32_t aSourceStride,
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uint8_t* aDestData, int32_t aDestStride,
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const IntRect& aDestRect, int32_t aRadius)
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{
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static_assert(Operator == MORPHOLOGY_OPERATOR_ERODE ||
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Operator == MORPHOLOGY_OPERATOR_DILATE,
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"unexpected morphology operator");
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int32_t startY = aDestRect.y - aRadius;
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int32_t endY = aDestRect.y + aRadius;
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for (int32_t y = aDestRect.y; y < aDestRect.YMost(); y++, startY++, endY++) {
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for (int32_t x = aDestRect.x; x < aDestRect.XMost(); x++) {
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int32_t sourceIndex = startY * aSourceStride + 4 * x;
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uint8_t u[4];
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for (size_t i = 0; i < 4; i++) {
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u[i] = aSourceData[sourceIndex + i];
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}
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sourceIndex += aSourceStride;
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for (int32_t iy = startY + 1; iy <= endY; iy++, sourceIndex += aSourceStride) {
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for (size_t i = 0; i < 4; i++) {
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if (Operator == MORPHOLOGY_OPERATOR_ERODE) {
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u[i] = umin(u[i], aSourceData[sourceIndex + i]);
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} else {
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u[i] = umax(u[i], aSourceData[sourceIndex + i]);
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}
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}
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}
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int32_t destIndex = y * aDestStride + 4 * x;
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for (size_t i = 0; i < 4; i++) {
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aDestData[destIndex+i] = u[i];
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}
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}
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}
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}
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void
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FilterProcessing::ApplyMorphologyVertical_Scalar(uint8_t* aSourceData, int32_t aSourceStride,
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uint8_t* aDestData, int32_t aDestStride,
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const IntRect& aDestRect, int32_t aRadius,
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MorphologyOperator aOp)
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{
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if (aOp == MORPHOLOGY_OPERATOR_ERODE) {
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gfx::ApplyMorphologyVertical_Scalar<MORPHOLOGY_OPERATOR_ERODE>(
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aSourceData, aSourceStride, aDestData, aDestStride, aDestRect, aRadius);
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} else {
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gfx::ApplyMorphologyVertical_Scalar<MORPHOLOGY_OPERATOR_DILATE>(
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aSourceData, aSourceStride, aDestData, aDestStride, aDestRect, aRadius);
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}
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}
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TemporaryRef<DataSourceSurface>
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FilterProcessing::ApplyColorMatrix_Scalar(DataSourceSurface* aInput, const Matrix5x4 &aMatrix)
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{
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return ApplyColorMatrix_SIMD<simd::Scalari32x4_t,simd::Scalari16x8_t,simd::Scalaru8x16_t>(aInput, aMatrix);
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}
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void
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FilterProcessing::ApplyComposition_Scalar(DataSourceSurface* aSource, DataSourceSurface* aDest,
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CompositeOperator aOperator)
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{
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return ApplyComposition_SIMD<simd::Scalari32x4_t,simd::Scalaru16x8_t,simd::Scalaru8x16_t>(aSource, aDest, aOperator);
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}
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void
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FilterProcessing::SeparateColorChannels_Scalar(const IntSize &size, uint8_t* sourceData, int32_t sourceStride, uint8_t* channel0Data, uint8_t* channel1Data, uint8_t* channel2Data, uint8_t* channel3Data, int32_t channelStride)
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{
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for (int32_t y = 0; y < size.height; y++) {
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for (int32_t x = 0; x < size.width; x++) {
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int32_t sourceIndex = y * sourceStride + 4 * x;
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int32_t targetIndex = y * channelStride + x;
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channel0Data[targetIndex] = sourceData[sourceIndex];
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channel1Data[targetIndex] = sourceData[sourceIndex+1];
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channel2Data[targetIndex] = sourceData[sourceIndex+2];
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channel3Data[targetIndex] = sourceData[sourceIndex+3];
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}
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}
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}
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void
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FilterProcessing::CombineColorChannels_Scalar(const IntSize &size, int32_t resultStride, uint8_t* resultData, int32_t channelStride, uint8_t* channel0Data, uint8_t* channel1Data, uint8_t* channel2Data, uint8_t* channel3Data)
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{
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for (int32_t y = 0; y < size.height; y++) {
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for (int32_t x = 0; x < size.width; x++) {
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int32_t resultIndex = y * resultStride + 4 * x;
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int32_t channelIndex = y * channelStride + x;
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resultData[resultIndex] = channel0Data[channelIndex];
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resultData[resultIndex+1] = channel1Data[channelIndex];
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resultData[resultIndex+2] = channel2Data[channelIndex];
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resultData[resultIndex+3] = channel3Data[channelIndex];
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}
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}
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}
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void
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FilterProcessing::DoPremultiplicationCalculation_Scalar(const IntSize& aSize,
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uint8_t* aTargetData, int32_t aTargetStride,
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uint8_t* aSourceData, int32_t aSourceStride)
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{
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for (int32_t y = 0; y < aSize.height; y++) {
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for (int32_t x = 0; x < aSize.width; x++) {
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int32_t inputIndex = y * aSourceStride + 4 * x;
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int32_t targetIndex = y * aTargetStride + 4 * x;
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uint8_t alpha = aSourceData[inputIndex + B8G8R8A8_COMPONENT_BYTEOFFSET_A];
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aTargetData[targetIndex + B8G8R8A8_COMPONENT_BYTEOFFSET_R] =
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FastDivideBy255<uint8_t>(aSourceData[inputIndex + B8G8R8A8_COMPONENT_BYTEOFFSET_R] * alpha);
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aTargetData[targetIndex + B8G8R8A8_COMPONENT_BYTEOFFSET_G] =
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FastDivideBy255<uint8_t>(aSourceData[inputIndex + B8G8R8A8_COMPONENT_BYTEOFFSET_G] * alpha);
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aTargetData[targetIndex + B8G8R8A8_COMPONENT_BYTEOFFSET_B] =
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FastDivideBy255<uint8_t>(aSourceData[inputIndex + B8G8R8A8_COMPONENT_BYTEOFFSET_B] * alpha);
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aTargetData[targetIndex + B8G8R8A8_COMPONENT_BYTEOFFSET_A] = alpha;
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}
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}
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}
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void
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FilterProcessing::DoUnpremultiplicationCalculation_Scalar(
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const IntSize& aSize,
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uint8_t* aTargetData, int32_t aTargetStride,
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uint8_t* aSourceData, int32_t aSourceStride)
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{
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for (int32_t y = 0; y < aSize.height; y++) {
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for (int32_t x = 0; x < aSize.width; x++) {
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int32_t inputIndex = y * aSourceStride + 4 * x;
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int32_t targetIndex = y * aTargetStride + 4 * x;
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uint8_t alpha = aSourceData[inputIndex + B8G8R8A8_COMPONENT_BYTEOFFSET_A];
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uint16_t alphaFactor = sAlphaFactors[alpha];
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// inputColor * alphaFactor + 128 is guaranteed to fit into uint16_t
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// because the input is premultiplied and thus inputColor <= inputAlpha.
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// The maximum value this can attain is 65520 (which is less than 65535)
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// for color == alpha == 244:
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// 244 * sAlphaFactors[244] + 128 == 244 * 268 + 128 == 65520
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aTargetData[targetIndex + B8G8R8A8_COMPONENT_BYTEOFFSET_R] =
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(aSourceData[inputIndex + B8G8R8A8_COMPONENT_BYTEOFFSET_R] * alphaFactor + 128) >> 8;
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aTargetData[targetIndex + B8G8R8A8_COMPONENT_BYTEOFFSET_G] =
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(aSourceData[inputIndex + B8G8R8A8_COMPONENT_BYTEOFFSET_G] * alphaFactor + 128) >> 8;
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aTargetData[targetIndex + B8G8R8A8_COMPONENT_BYTEOFFSET_B] =
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(aSourceData[inputIndex + B8G8R8A8_COMPONENT_BYTEOFFSET_B] * alphaFactor + 128) >> 8;
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aTargetData[targetIndex + B8G8R8A8_COMPONENT_BYTEOFFSET_A] = alpha;
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}
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}
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}
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TemporaryRef<DataSourceSurface>
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FilterProcessing::RenderTurbulence_Scalar(const IntSize &aSize, const Point &aOffset, const Size &aBaseFrequency,
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int32_t aSeed, int aNumOctaves, TurbulenceType aType, bool aStitch, const Rect &aTileRect)
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{
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return RenderTurbulence_SIMD<simd::Scalarf32x4_t,simd::Scalari32x4_t,simd::Scalaru8x16_t>(
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aSize, aOffset, aBaseFrequency, aSeed, aNumOctaves, aType, aStitch, aTileRect);
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}
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TemporaryRef<DataSourceSurface>
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FilterProcessing::ApplyArithmeticCombine_Scalar(DataSourceSurface* aInput1, DataSourceSurface* aInput2, Float aK1, Float aK2, Float aK3, Float aK4)
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{
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return ApplyArithmeticCombine_SIMD<simd::Scalari32x4_t,simd::Scalari16x8_t,simd::Scalaru8x16_t>(aInput1, aInput2, aK1, aK2, aK3, aK4);
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}
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} // namespace mozilla
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} // namespace gfx
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