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/*
* Copyright 2014 Google Inc.
*
* Use of this source code is governed by a BSD-style license that can be
* found in the LICENSE file.
*/
#include "GrOptDrawState.h"
#include "GrDrawState.h"
#include "GrDrawTargetCaps.h"
#include "GrGpu.h"
#include "GrProcOptInfo.h"
#include "GrXferProcessor.h"
GrOptDrawState::GrOptDrawState(const GrDrawState& drawState,
GrColor color,
uint8_t coverage,
const GrDrawTargetCaps& caps,
const ScissorState& scissorState,
const GrDeviceCoordTexture* dstCopy,
GrGpu::DrawType drawType)
: fFinalized(false) {
GrColor coverageColor = GrColorPackRGBA(coverage, coverage, coverage, coverage);
fDrawType = drawType;
const GrProcOptInfo& colorPOI = drawState.colorProcInfo(color);
const GrProcOptInfo& coveragePOI = drawState.coverageProcInfo(coverageColor);
fColor = colorPOI.inputColorToEffectiveStage();
fCoverage = coverage;
// Create XferProcessor from DS's XPFactory
SkAutoTUnref<GrXferProcessor> xferProcessor(
drawState.getXPFactory()->createXferProcessor(colorPOI, coveragePOI));
GrXferProcessor::OptFlags optFlags;
if (xferProcessor) {
fXferProcessor.reset(xferProcessor.get());
optFlags = xferProcessor->getOptimizations(colorPOI,
coveragePOI,
drawState.isCoverageDrawing(),
drawState.isColorWriteDisabled(),
drawState.getStencil().doesWrite(),
&fColor,
&fCoverage);
}
// When path rendering the stencil settings are not always set on the draw state
// so we must check the draw type. In cases where we will skip drawing we simply return a
// null GrOptDrawState.
if (!xferProcessor || ((GrXferProcessor::kSkipDraw_OptFlag & optFlags) &&
GrGpu::kStencilPath_DrawType != drawType)) {
// Set the fields that don't default init and return. The lack of a render target will
// indicate that this can be skipped.
fFlags = 0;
fDrawFace = GrDrawState::kInvalid_DrawFace;
fSrcBlend = kZero_GrBlendCoeff;
fDstBlend = kZero_GrBlendCoeff;
fBlendConstant = 0x0;
fViewMatrix.reset();
return;
}
fRenderTarget.reset(drawState.fRenderTarget.get());
SkASSERT(fRenderTarget);
fScissorState = scissorState;
fViewMatrix = drawState.getViewMatrix();
fStencilSettings = drawState.getStencil();
fDrawFace = drawState.getDrawFace();
// TODO move this out of optDrawState
if (dstCopy) {
fDstCopy = *dstCopy;
}
fFlags = 0;
if (drawState.isHWAntialias()) {
fFlags |= kHWAA_Flag;
}
if (drawState.isColorWriteDisabled()) {
fFlags |= kDisableColorWrite_Flag;
}
if (drawState.isDither()) {
fFlags |= kDither_Flag;
}
fDescInfo.fHasVertexColor = drawState.hasGeometryProcessor() &&
drawState.getGeometryProcessor()->hasVertexColor();
fDescInfo.fHasVertexCoverage = drawState.hasGeometryProcessor() &&
drawState.getGeometryProcessor()->hasVertexCoverage();
bool hasLocalCoords = drawState.hasGeometryProcessor() &&
drawState.getGeometryProcessor()->hasLocalCoords();
int firstColorStageIdx = colorPOI.firstEffectiveStageIndex();
fDescInfo.fInputColorIsUsed = colorPOI.inputColorIsUsed();
if (colorPOI.removeVertexAttrib()) {
fDescInfo.fHasVertexColor = false;
}
// TODO: Once we can handle single or four channel input into coverage stages then we can use
// drawState's coverageProcInfo (like color above) to set this initial information.
int firstCoverageStageIdx = 0;
fDescInfo.fInputCoverageIsUsed = true;
GrXferProcessor::BlendInfo blendInfo;
fXferProcessor->getBlendInfo(&blendInfo);
fSrcBlend = blendInfo.fSrcBlend;
fDstBlend = blendInfo.fDstBlend;
fBlendConstant = blendInfo.fBlendConstant;
this->adjustProgramFromOptimizations(drawState, optFlags, colorPOI, coveragePOI,
&firstColorStageIdx, &firstCoverageStageIdx);
fDescInfo.fRequiresLocalCoordAttrib = hasLocalCoords;
// Copy GeometryProcesssor from DS or ODS
SkASSERT(GrGpu::IsPathRenderingDrawType(drawType) ||
GrGpu::kStencilPath_DrawType ||
drawState.hasGeometryProcessor());
fGeometryProcessor.reset(drawState.getGeometryProcessor());
// Copy Stages from DS to ODS
for (int i = firstColorStageIdx; i < drawState.numColorStages(); ++i) {
SkNEW_APPEND_TO_TARRAY(&fFragmentStages,
GrPendingFragmentStage,
(drawState.fColorStages[i], hasLocalCoords));
}
fNumColorStages = fFragmentStages.count();
for (int i = firstCoverageStageIdx; i < drawState.numCoverageStages(); ++i) {
SkNEW_APPEND_TO_TARRAY(&fFragmentStages,
GrPendingFragmentStage,
(drawState.fCoverageStages[i], hasLocalCoords));
}
// let the GP init the batch tracker
if (drawState.hasGeometryProcessor()) {
GrGeometryProcessor::InitBT init;
init.fOutputColor = fDescInfo.fInputColorIsUsed;
init.fOutputCoverage = fDescInfo.fInputCoverageIsUsed;
init.fColor = this->getColor();
init.fCoverage = this->getCoverage();
fGeometryProcessor->initBatchTracker(&fBatchTracker, init);
}
this->setOutputStateInfo(drawState, coverageColor, optFlags, caps);
}
void GrOptDrawState::setOutputStateInfo(const GrDrawState& ds,
GrColor coverage,
GrXferProcessor::OptFlags optFlags,
const GrDrawTargetCaps& caps) {
// Set this default and then possibly change our mind if there is coverage.
fDescInfo.fPrimaryOutputType = GrProgramDesc::kModulate_PrimaryOutputType;
fDescInfo.fSecondaryOutputType = GrProgramDesc::kNone_SecondaryOutputType;
// Determine whether we should use dual source blending or shader code to keep coverage
// separate from color.
bool keepCoverageSeparate = !(optFlags & GrXferProcessor::kSetCoverageDrawing_OptFlag);
if (keepCoverageSeparate && !ds.hasSolidCoverage(coverage)) {
if (caps.dualSourceBlendingSupport()) {
if (kZero_GrBlendCoeff == fDstBlend) {
// write the coverage value to second color
fDescInfo.fSecondaryOutputType = GrProgramDesc::kCoverage_SecondaryOutputType;
fDstBlend = (GrBlendCoeff)GrGpu::kIS2C_GrBlendCoeff;
} else if (kSA_GrBlendCoeff == fDstBlend) {
// SA dst coeff becomes 1-(1-SA)*coverage when dst is partially covered.
fDescInfo.fSecondaryOutputType = GrProgramDesc::kCoverageISA_SecondaryOutputType;
fDstBlend = (GrBlendCoeff)GrGpu::kIS2C_GrBlendCoeff;
} else if (kSC_GrBlendCoeff == fDstBlend) {
// SA dst coeff becomes 1-(1-SA)*coverage when dst is partially covered.
fDescInfo.fSecondaryOutputType = GrProgramDesc::kCoverageISC_SecondaryOutputType;
fDstBlend = (GrBlendCoeff)GrGpu::kIS2C_GrBlendCoeff;
}
} else if (fDescInfo.fReadsDst &&
kOne_GrBlendCoeff == fSrcBlend &&
kZero_GrBlendCoeff == fDstBlend) {
fDescInfo.fPrimaryOutputType = GrProgramDesc::kCombineWithDst_PrimaryOutputType;
}
}
}
void GrOptDrawState::adjustProgramFromOptimizations(const GrDrawState& ds,
GrXferProcessor::OptFlags flags,
const GrProcOptInfo& colorPOI,
const GrProcOptInfo& coveragePOI,
int* firstColorStageIdx,
int* firstCoverageStageIdx) {
fDescInfo.fReadsDst = false;
fDescInfo.fReadsFragPosition = false;
if (flags & GrXferProcessor::kClearColorStages_OptFlag) {
fDescInfo.fInputColorIsUsed = true;
*firstColorStageIdx = ds.numColorStages();
fDescInfo.fHasVertexColor = false;
} else {
fDescInfo.fReadsDst = colorPOI.readsDst();
fDescInfo.fReadsFragPosition = colorPOI.readsFragPosition();
}
if (flags & GrXferProcessor::kClearCoverageStages_OptFlag) {
fDescInfo.fInputCoverageIsUsed = true;
*firstCoverageStageIdx = ds.numCoverageStages();
fDescInfo.fHasVertexCoverage = false;
} else {
if (coveragePOI.readsDst()) {
fDescInfo.fReadsDst = true;
}
if (coveragePOI.readsFragPosition()) {
fDescInfo.fReadsFragPosition = true;
}
}
}
void GrOptDrawState::finalize(GrGpu* gpu) {
gpu->buildProgramDesc(*this, fDescInfo, fDrawType, &fDesc);
fFinalized = true;
}
////////////////////////////////////////////////////////////////////////////////
bool GrOptDrawState::operator== (const GrOptDrawState& that) const {
if (fDescInfo != that.fDescInfo) {
return false;
}
if (!fDescInfo.fHasVertexColor && this->fColor != that.fColor) {
return false;
}
if (this->getRenderTarget() != that.getRenderTarget() ||
this->fFragmentStages.count() != that.fFragmentStages.count() ||
this->fNumColorStages != that.fNumColorStages ||
this->fScissorState != that.fScissorState ||
!this->fViewMatrix.cheapEqualTo(that.fViewMatrix) ||
this->fSrcBlend != that.fSrcBlend ||
this->fDstBlend != that.fDstBlend ||
this->fDrawType != that.fDrawType ||
this->fBlendConstant != that.fBlendConstant ||
this->fFlags != that.fFlags ||
this->fStencilSettings != that.fStencilSettings ||
this->fDrawFace != that.fDrawFace ||
this->fDstCopy.texture() != that.fDstCopy.texture()) {
return false;
}
if (!fDescInfo.fHasVertexCoverage && this->fCoverage != that.fCoverage) {
return false;
}
if (this->hasGeometryProcessor()) {
if (!that.hasGeometryProcessor()) {
return false;
} else if (!this->getGeometryProcessor()->isEqual(*that.getGeometryProcessor())) {
return false;
}
} else if (that.hasGeometryProcessor()) {
return false;
}
// The program desc comparison should have already assured that the stage counts match.
SkASSERT(this->numFragmentStages() == that.numFragmentStages());
for (int i = 0; i < this->numFragmentStages(); i++) {
if (this->getFragmentStage(i) != that.getFragmentStage(i)) {
return false;
}
}
return true;
}
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