src/gpu/ccpr/GrCoverageCountingPathRenderer.cpp - skia - Git at Google

 /*
  * Copyright 2017 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #include "src/gpu/ccpr/GrCoverageCountingPathRenderer.h"

 #include "include/pathops/SkPathOps.h"
 #include "src/core/SkMakeUnique.h"
 #include "src/gpu/GrCaps.h"
 #include "src/gpu/GrClip.h"
 #include "src/gpu/GrProxyProvider.h"
 #include "src/gpu/ccpr/GrCCClipProcessor.h"
 #include "src/gpu/ccpr/GrCCDrawPathsOp.h"
 #include "src/gpu/ccpr/GrCCPathCache.h"

 using PathInstance = GrCCPathProcessor::Instance;

 bool GrCoverageCountingPathRenderer::IsSupported(const GrCaps& caps) {
     const GrShaderCaps& shaderCaps = *caps.shaderCaps();
     if (caps.driverBlacklistCCPR() || !caps.allowCoverageCounting() ||
         !shaderCaps.integerSupport() || !caps.instanceAttribSupport() ||
         !shaderCaps.floatIs32Bits() || GrCaps::kNone_MapFlags == caps.mapBufferFlags() ||
         !caps.isConfigTexturable(kAlpha_half_GrPixelConfig) ||
         !caps.isConfigRenderable(kAlpha_half_GrPixelConfig) ||
         !caps.isConfigTexturable(kAlpha_8_GrPixelConfig) ||
         !caps.isConfigRenderable(kAlpha_8_GrPixelConfig) ||
         !caps.halfFloatVertexAttributeSupport()) {
         return false;
     }
     return true;
 }

 sk_sp<GrCoverageCountingPathRenderer> GrCoverageCountingPathRenderer::CreateIfSupported(
         const GrCaps& caps, AllowCaching allowCaching, uint32_t contextUniqueID) {
     return sk_sp<GrCoverageCountingPathRenderer>((IsSupported(caps))
             ? new GrCoverageCountingPathRenderer(allowCaching, contextUniqueID)
             : nullptr);
 }

 GrCoverageCountingPathRenderer::GrCoverageCountingPathRenderer(AllowCaching allowCaching,
                                                                uint32_t contextUniqueID) {
     if (AllowCaching::kYes == allowCaching) {
         fPathCache = skstd::make_unique<GrCCPathCache>(contextUniqueID);
     }
 }

 GrCCPerOpListPaths* GrCoverageCountingPathRenderer::lookupPendingPaths(uint32_t opListID) {
     auto it = fPendingPaths.find(opListID);
     if (fPendingPaths.end() == it) {
         sk_sp<GrCCPerOpListPaths> paths = sk_make_sp<GrCCPerOpListPaths>();
         it = fPendingPaths.insert(std::make_pair(opListID, std::move(paths))).first;
     }
     return it->second.get();
 }

 GrPathRenderer::CanDrawPath GrCoverageCountingPathRenderer::onCanDrawPath(
         const CanDrawPathArgs& args) const {
     const GrShape& shape = *args.fShape;
     if (GrAAType::kCoverage != args.fAAType || shape.style().hasPathEffect() ||
         args.fViewMatrix->hasPerspective() || shape.inverseFilled()) {
         return CanDrawPath::kNo;
     }

     SkPath path;
     shape.asPath(&path);

     const SkStrokeRec& stroke = shape.style().strokeRec();
     switch (stroke.getStyle()) {
         case SkStrokeRec::kFill_Style: {
             SkRect devBounds;
             args.fViewMatrix->mapRect(&devBounds, path.getBounds());

             SkIRect clippedIBounds;
             devBounds.roundOut(&clippedIBounds);
             if (!clippedIBounds.intersect(*args.fClipConservativeBounds)) {
                 // The path is completely clipped away. Our code will eventually notice this before
                 // doing any real work.
                 return CanDrawPath::kYes;
             }

             int64_t numPixels = sk_64_mul(clippedIBounds.height(), clippedIBounds.width());
             if (path.countVerbs() > 1000 && path.countPoints() > numPixels) {
                 // This is a complicated path that has more vertices than pixels! Let's let the SW
                 // renderer have this one: It will probably be faster and a bitmap will require less
                 // total memory on the GPU than CCPR instance buffers would for the raw path data.
                 return CanDrawPath::kNo;
             }

             if (numPixels > 256 * 256) {
                 // Large paths can blow up the atlas fast. And they are not ideal for a two-pass
                 // rendering algorithm. Give the simpler direct renderers a chance before we commit
                 // to drawing it.
                 return CanDrawPath::kAsBackup;
             }

             if (args.fShape->hasUnstyledKey() && path.countVerbs() > 50) {
                 // Complex paths do better cached in an SDF, if the renderer will accept them.
                 return CanDrawPath::kAsBackup;
             }

             return CanDrawPath::kYes;
         }

         case SkStrokeRec::kStroke_Style:
             if (!args.fViewMatrix->isSimilarity()) {
                 // The stroker currently only supports rigid-body transfoms for the stroke lines
                 // themselves. This limitation doesn't affect hairlines since their stroke lines are
                 // defined relative to device space.
                 return CanDrawPath::kNo;
             }
             // fallthru
         case SkStrokeRec::kHairline_Style: {
             float inflationRadius;
             GetStrokeDevWidth(*args.fViewMatrix, stroke, &inflationRadius);
             if (!(inflationRadius <= kMaxBoundsInflationFromStroke)) {
                 // Let extremely wide strokes be converted to fill paths and drawn by the CCPR
                 // filler instead. (Cast the logic negatively in order to also catch r=NaN.)
                 return CanDrawPath::kNo;
             }
             SkASSERT(!SkScalarIsNaN(inflationRadius));
             if (SkPathPriv::ConicWeightCnt(path)) {
                 // The stroker does not support conics yet.
                 return CanDrawPath::kNo;
             }
             return CanDrawPath::kYes;
         }

         case SkStrokeRec::kStrokeAndFill_Style:
             return CanDrawPath::kNo;
     }

     SK_ABORT("Invalid stroke style.");
     return CanDrawPath::kNo;
 }

 bool GrCoverageCountingPathRenderer::onDrawPath(const DrawPathArgs& args) {
     SkASSERT(!fFlushing);

     SkIRect clipIBounds;
     GrRenderTargetContext* rtc = args.fRenderTargetContext;
     args.fClip->getConservativeBounds(rtc->width(), rtc->height(), &clipIBounds, nullptr);

     auto op = GrCCDrawPathsOp::Make(args.fContext, clipIBounds, *args.fViewMatrix, *args.fShape,
                                     std::move(args.fPaint));
     this->recordOp(std::move(op), args);
     return true;
 }

 void GrCoverageCountingPathRenderer::recordOp(std::unique_ptr<GrCCDrawPathsOp> op,
                                               const DrawPathArgs& args) {
     if (op) {
         auto addToOwningPerOpListPaths = [this](GrOp* op, uint32_t opListID) {
             op->cast<GrCCDrawPathsOp>()->addToOwningPerOpListPaths(
                     sk_ref_sp(this->lookupPendingPaths(opListID)));
         };
         args.fRenderTargetContext->addDrawOp(*args.fClip, std::move(op), addToOwningPerOpListPaths);
     }
 }

 std::unique_ptr<GrFragmentProcessor> GrCoverageCountingPathRenderer::makeClipProcessor(
         uint32_t opListID, const SkPath& deviceSpacePath, const SkIRect& accessRect, int rtWidth,
         int rtHeight, const GrCaps& caps) {
     using MustCheckBounds = GrCCClipProcessor::MustCheckBounds;

     SkASSERT(!fFlushing);

     GrCCClipPath& clipPath =
             this->lookupPendingPaths(opListID)->fClipPaths[deviceSpacePath.getGenerationID()];
     if (!clipPath.isInitialized()) {
         // This ClipPath was just created during lookup. Initialize it.
         const SkRect& pathDevBounds = deviceSpacePath.getBounds();
         if (SkTMax(pathDevBounds.height(), pathDevBounds.width()) > kPathCropThreshold) {
             // The path is too large. Crop it or analytic AA can run out of fp32 precision.
             SkPath croppedPath;
             int maxRTSize = caps.maxRenderTargetSize();
             CropPath(deviceSpacePath, SkIRect::MakeWH(maxRTSize, maxRTSize), &croppedPath);
             clipPath.init(croppedPath, accessRect, rtWidth, rtHeight, caps);
         } else {
             clipPath.init(deviceSpacePath, accessRect, rtWidth, rtHeight, caps);
         }
     } else {
         clipPath.addAccess(accessRect);
     }

     bool mustCheckBounds = !clipPath.pathDevIBounds().contains(accessRect);
     return skstd::make_unique<GrCCClipProcessor>(&clipPath, MustCheckBounds(mustCheckBounds),
                                                  deviceSpacePath.getFillType());
 }

 void GrCoverageCountingPathRenderer::preFlush(GrOnFlushResourceProvider* onFlushRP,
                                               const uint32_t* opListIDs, int numOpListIDs,
                                               SkTArray<sk_sp<GrRenderTargetContext>>* out) {
     using DoCopiesToA8Coverage = GrCCDrawPathsOp::DoCopiesToA8Coverage;
     SkASSERT(!fFlushing);
     SkASSERT(fFlushingPaths.empty());
     SkDEBUGCODE(fFlushing = true);

     if (fPathCache) {
         fPathCache->doPreFlushProcessing();
     }

     if (fPendingPaths.empty()) {
         return;  // Nothing to draw.
     }

     GrCCPerFlushResourceSpecs specs;
     int maxPreferredRTSize = onFlushRP->caps()->maxPreferredRenderTargetSize();
     specs.fCopyAtlasSpecs.fMaxPreferredTextureSize = SkTMin(2048, maxPreferredRTSize);
     SkASSERT(0 == specs.fCopyAtlasSpecs.fMinTextureSize);
     specs.fRenderedAtlasSpecs.fMaxPreferredTextureSize = maxPreferredRTSize;
     specs.fRenderedAtlasSpecs.fMinTextureSize = SkTMin(512, maxPreferredRTSize);

     // Move the per-opList paths that are about to be flushed from fPendingPaths to fFlushingPaths,
     // and count them up so we can preallocate buffers.
     fFlushingPaths.reserve(numOpListIDs);
     for (int i = 0; i < numOpListIDs; ++i) {
         auto iter = fPendingPaths.find(opListIDs[i]);
         if (fPendingPaths.end() == iter) {
             continue;  // No paths on this opList.
         }

         fFlushingPaths.push_back(std::move(iter->second));
         fPendingPaths.erase(iter);

         for (GrCCDrawPathsOp* op : fFlushingPaths.back()->fDrawOps) {
             op->accountForOwnPaths(fPathCache.get(), onFlushRP, &specs);
         }
         for (const auto& clipsIter : fFlushingPaths.back()->fClipPaths) {
             clipsIter.second.accountForOwnPath(&specs);
         }
     }

     if (specs.isEmpty()) {
         return;  // Nothing to draw.
     }

     // Determine if there are enough reusable paths from last flush for it to be worth our time to
     // copy them to cached atlas(es).
     int numCopies = specs.fNumCopiedPaths[GrCCPerFlushResourceSpecs::kFillIdx] +
                     specs.fNumCopiedPaths[GrCCPerFlushResourceSpecs::kStrokeIdx];
     auto doCopies = DoCopiesToA8Coverage(numCopies > 100 ||
                                          specs.fCopyAtlasSpecs.fApproxNumPixels > 256 * 256);
     if (numCopies && DoCopiesToA8Coverage::kNo == doCopies) {
         specs.cancelCopies();
     }

     auto resources = sk_make_sp<GrCCPerFlushResources>(onFlushRP, specs);
     if (!resources->isMapped()) {
         return;  // Some allocation failed.
     }

     // Layout the atlas(es) and parse paths.
     for (const auto& flushingPaths : fFlushingPaths) {
         for (GrCCDrawPathsOp* op : flushingPaths->fDrawOps) {
             op->setupResources(fPathCache.get(), onFlushRP, resources.get(), doCopies);
         }
         for (auto& clipsIter : flushingPaths->fClipPaths) {
             clipsIter.second.renderPathInAtlas(resources.get(), onFlushRP);
         }
     }

     if (fPathCache) {
         // Purge invalidated textures from previous atlases *before* calling finalize(). That way,
         // the underlying textures objects can be freed up and reused for the next atlases.
         fPathCache->purgeInvalidatedAtlasTextures(onFlushRP);
     }

     // Allocate resources and then render the atlas(es).
     if (!resources->finalize(onFlushRP, out)) {
         return;
     }

     // Commit flushing paths to the resources once they are successfully completed.
     for (auto& flushingPaths : fFlushingPaths) {
         SkASSERT(!flushingPaths->fFlushResources);
         flushingPaths->fFlushResources = resources;
     }
 }

 void GrCoverageCountingPathRenderer::postFlush(GrDeferredUploadToken, const uint32_t* opListIDs,
                                                int numOpListIDs) {
     SkASSERT(fFlushing);

     if (!fFlushingPaths.empty()) {
         // In DDL mode these aren't guaranteed to be deleted so we must clear out the perFlush
         // resources manually.
         for (auto& flushingPaths : fFlushingPaths) {
             flushingPaths->fFlushResources = nullptr;
         }

         // We wait to erase these until after flush, once Ops and FPs are done accessing their data.
         fFlushingPaths.reset();
     }

     SkDEBUGCODE(fFlushing = false);
 }

 void GrCoverageCountingPathRenderer::purgeCacheEntriesOlderThan(
         GrProxyProvider* proxyProvider, const GrStdSteadyClock::time_point& purgeTime) {
     if (fPathCache) {
         fPathCache->purgeEntriesOlderThan(proxyProvider, purgeTime);
     }
 }

 void GrCoverageCountingPathRenderer::CropPath(const SkPath& path, const SkIRect& cropbox,
                                               SkPath* out) {
     SkPath cropboxPath;
     cropboxPath.addRect(SkRect::Make(cropbox));
     if (!Op(cropboxPath, path, kIntersect_SkPathOp, out)) {
         // This can fail if the PathOps encounter NaN or infinities.
         out->reset();
     }
     out->setIsVolatile(true);
 }

 float GrCoverageCountingPathRenderer::GetStrokeDevWidth(const SkMatrix& m,
                                                         const SkStrokeRec& stroke,
                                                         float* inflationRadius) {
     float strokeDevWidth;
     if (stroke.isHairlineStyle()) {
         strokeDevWidth = 1;
     } else {
         SkASSERT(SkStrokeRec::kStroke_Style == stroke.getStyle());
         SkASSERT(m.isSimilarity());  // Otherwise matrixScaleFactor = m.getMaxScale().
         float matrixScaleFactor = SkVector::Length(m.getScaleX(), m.getSkewY());
         strokeDevWidth = stroke.getWidth() * matrixScaleFactor;
     }
     if (inflationRadius) {
         // Inflate for a minimum stroke width of 1. In some cases when the stroke is less than 1px
         // wide, we may inflate it to 1px and instead reduce the opacity.
         *inflationRadius = SkStrokeRec::GetInflationRadius(
                 stroke.getJoin(), stroke.getMiter(), stroke.getCap(), SkTMax(strokeDevWidth, 1.f));
     }
     return strokeDevWidth;
 }
	/*
	* Copyright 2017 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#include "src/gpu/ccpr/GrCoverageCountingPathRenderer.h"

	#include "include/pathops/SkPathOps.h"
	#include "src/core/SkMakeUnique.h"
	#include "src/gpu/GrCaps.h"
	#include "src/gpu/GrClip.h"
	#include "src/gpu/GrProxyProvider.h"
	#include "src/gpu/ccpr/GrCCClipProcessor.h"
	#include "src/gpu/ccpr/GrCCDrawPathsOp.h"
	#include "src/gpu/ccpr/GrCCPathCache.h"

	using PathInstance = GrCCPathProcessor::Instance;

	bool GrCoverageCountingPathRenderer::IsSupported(const GrCaps& caps) {
	const GrShaderCaps& shaderCaps = *caps.shaderCaps();
	if (caps.driverBlacklistCCPR() \|\| !caps.allowCoverageCounting() \|\|
	!shaderCaps.integerSupport() \|\| !caps.instanceAttribSupport() \|\|
	!shaderCaps.floatIs32Bits() \|\| GrCaps::kNone_MapFlags == caps.mapBufferFlags() \|\|
	!caps.isConfigTexturable(kAlpha_half_GrPixelConfig) \|\|
	!caps.isConfigRenderable(kAlpha_half_GrPixelConfig) \|\|
	!caps.isConfigTexturable(kAlpha_8_GrPixelConfig) \|\|
	!caps.isConfigRenderable(kAlpha_8_GrPixelConfig) \|\|
	!caps.halfFloatVertexAttributeSupport()) {
	return false;
	}
	return true;
	}

	sk_sp<GrCoverageCountingPathRenderer> GrCoverageCountingPathRenderer::CreateIfSupported(
	const GrCaps& caps, AllowCaching allowCaching, uint32_t contextUniqueID) {
	return sk_sp<GrCoverageCountingPathRenderer>((IsSupported(caps))
	? new GrCoverageCountingPathRenderer(allowCaching, contextUniqueID)
	: nullptr);
	}

	GrCoverageCountingPathRenderer::GrCoverageCountingPathRenderer(AllowCaching allowCaching,
	uint32_t contextUniqueID) {
	if (AllowCaching::kYes == allowCaching) {
	fPathCache = skstd::make_unique<GrCCPathCache>(contextUniqueID);
	}
	}

	GrCCPerOpListPaths* GrCoverageCountingPathRenderer::lookupPendingPaths(uint32_t opListID) {
	auto it = fPendingPaths.find(opListID);
	if (fPendingPaths.end() == it) {
	sk_sp<GrCCPerOpListPaths> paths = sk_make_sp<GrCCPerOpListPaths>();
	it = fPendingPaths.insert(std::make_pair(opListID, std::move(paths))).first;
	}
	return it->second.get();
	}

	GrPathRenderer::CanDrawPath GrCoverageCountingPathRenderer::onCanDrawPath(
	const CanDrawPathArgs& args) const {
	const GrShape& shape = *args.fShape;
	if (GrAAType::kCoverage != args.fAAType \|\| shape.style().hasPathEffect() \|\|
	args.fViewMatrix->hasPerspective() \|\| shape.inverseFilled()) {
	return CanDrawPath::kNo;
	}

	SkPath path;
	shape.asPath(&path);

	const SkStrokeRec& stroke = shape.style().strokeRec();
	switch (stroke.getStyle()) {
	case SkStrokeRec::kFill_Style: {
	SkRect devBounds;
	args.fViewMatrix->mapRect(&devBounds, path.getBounds());

	SkIRect clippedIBounds;
	devBounds.roundOut(&clippedIBounds);
	if (!clippedIBounds.intersect(*args.fClipConservativeBounds)) {
	// The path is completely clipped away. Our code will eventually notice this before
	// doing any real work.
	return CanDrawPath::kYes;
	}

	int64_t numPixels = sk_64_mul(clippedIBounds.height(), clippedIBounds.width());
	if (path.countVerbs() > 1000 && path.countPoints() > numPixels) {
	// This is a complicated path that has more vertices than pixels! Let's let the SW
	// renderer have this one: It will probably be faster and a bitmap will require less
	// total memory on the GPU than CCPR instance buffers would for the raw path data.
	return CanDrawPath::kNo;
	}

	if (numPixels > 256 * 256) {
	// Large paths can blow up the atlas fast. And they are not ideal for a two-pass
	// rendering algorithm. Give the simpler direct renderers a chance before we commit
	// to drawing it.
	return CanDrawPath::kAsBackup;
	}

	if (args.fShape->hasUnstyledKey() && path.countVerbs() > 50) {
	// Complex paths do better cached in an SDF, if the renderer will accept them.
	return CanDrawPath::kAsBackup;
	}

	return CanDrawPath::kYes;
	}

	case SkStrokeRec::kStroke_Style:
	if (!args.fViewMatrix->isSimilarity()) {
	// The stroker currently only supports rigid-body transfoms for the stroke lines
	// themselves. This limitation doesn't affect hairlines since their stroke lines are
	// defined relative to device space.
	return CanDrawPath::kNo;
	}
	// fallthru
	case SkStrokeRec::kHairline_Style: {
	float inflationRadius;
	GetStrokeDevWidth(*args.fViewMatrix, stroke, &inflationRadius);
	if (!(inflationRadius <= kMaxBoundsInflationFromStroke)) {
	// Let extremely wide strokes be converted to fill paths and drawn by the CCPR
	// filler instead. (Cast the logic negatively in order to also catch r=NaN.)
	return CanDrawPath::kNo;
	}
	SkASSERT(!SkScalarIsNaN(inflationRadius));
	if (SkPathPriv::ConicWeightCnt(path)) {
	// The stroker does not support conics yet.
	return CanDrawPath::kNo;
	}
	return CanDrawPath::kYes;
	}

	case SkStrokeRec::kStrokeAndFill_Style:
	return CanDrawPath::kNo;
	}

	SK_ABORT("Invalid stroke style.");
	return CanDrawPath::kNo;
	}

	bool GrCoverageCountingPathRenderer::onDrawPath(const DrawPathArgs& args) {
	SkASSERT(!fFlushing);

	SkIRect clipIBounds;
	GrRenderTargetContext* rtc = args.fRenderTargetContext;
	args.fClip->getConservativeBounds(rtc->width(), rtc->height(), &clipIBounds, nullptr);

	auto op = GrCCDrawPathsOp::Make(args.fContext, clipIBounds, args.fViewMatrix, args.fShape,
	std::move(args.fPaint));
	this->recordOp(std::move(op), args);
	return true;
	}

	void GrCoverageCountingPathRenderer::recordOp(std::unique_ptr<GrCCDrawPathsOp> op,
	const DrawPathArgs& args) {
	if (op) {
	auto addToOwningPerOpListPaths = [this](GrOp* op, uint32_t opListID) {
	op->cast<GrCCDrawPathsOp>()->addToOwningPerOpListPaths(
	sk_ref_sp(this->lookupPendingPaths(opListID)));
	};
	args.fRenderTargetContext->addDrawOp(*args.fClip, std::move(op), addToOwningPerOpListPaths);
	}
	}

	std::unique_ptr<GrFragmentProcessor> GrCoverageCountingPathRenderer::makeClipProcessor(
	uint32_t opListID, const SkPath& deviceSpacePath, const SkIRect& accessRect, int rtWidth,
	int rtHeight, const GrCaps& caps) {
	using MustCheckBounds = GrCCClipProcessor::MustCheckBounds;

	SkASSERT(!fFlushing);

	GrCCClipPath& clipPath =
	this->lookupPendingPaths(opListID)->fClipPaths[deviceSpacePath.getGenerationID()];
	if (!clipPath.isInitialized()) {
	// This ClipPath was just created during lookup. Initialize it.
	const SkRect& pathDevBounds = deviceSpacePath.getBounds();
	if (SkTMax(pathDevBounds.height(), pathDevBounds.width()) > kPathCropThreshold) {
	// The path is too large. Crop it or analytic AA can run out of fp32 precision.
	SkPath croppedPath;
	int maxRTSize = caps.maxRenderTargetSize();
	CropPath(deviceSpacePath, SkIRect::MakeWH(maxRTSize, maxRTSize), &croppedPath);
	clipPath.init(croppedPath, accessRect, rtWidth, rtHeight, caps);
	} else {
	clipPath.init(deviceSpacePath, accessRect, rtWidth, rtHeight, caps);
	}
	} else {
	clipPath.addAccess(accessRect);
	}

	bool mustCheckBounds = !clipPath.pathDevIBounds().contains(accessRect);
	return skstd::make_unique<GrCCClipProcessor>(&clipPath, MustCheckBounds(mustCheckBounds),
	deviceSpacePath.getFillType());
	}

	void GrCoverageCountingPathRenderer::preFlush(GrOnFlushResourceProvider* onFlushRP,
	const uint32_t* opListIDs, int numOpListIDs,
	SkTArray<sk_sp<GrRenderTargetContext>>* out) {
	using DoCopiesToA8Coverage = GrCCDrawPathsOp::DoCopiesToA8Coverage;
	SkASSERT(!fFlushing);
	SkASSERT(fFlushingPaths.empty());
	SkDEBUGCODE(fFlushing = true);

	if (fPathCache) {
	fPathCache->doPreFlushProcessing();
	}

	if (fPendingPaths.empty()) {
	return; // Nothing to draw.
	}

	GrCCPerFlushResourceSpecs specs;
	int maxPreferredRTSize = onFlushRP->caps()->maxPreferredRenderTargetSize();
	specs.fCopyAtlasSpecs.fMaxPreferredTextureSize = SkTMin(2048, maxPreferredRTSize);
	SkASSERT(0 == specs.fCopyAtlasSpecs.fMinTextureSize);
	specs.fRenderedAtlasSpecs.fMaxPreferredTextureSize = maxPreferredRTSize;
	specs.fRenderedAtlasSpecs.fMinTextureSize = SkTMin(512, maxPreferredRTSize);

	// Move the per-opList paths that are about to be flushed from fPendingPaths to fFlushingPaths,
	// and count them up so we can preallocate buffers.
	fFlushingPaths.reserve(numOpListIDs);
	for (int i = 0; i < numOpListIDs; ++i) {
	auto iter = fPendingPaths.find(opListIDs[i]);
	if (fPendingPaths.end() == iter) {
	continue; // No paths on this opList.
	}

	fFlushingPaths.push_back(std::move(iter->second));
	fPendingPaths.erase(iter);

	for (GrCCDrawPathsOp* op : fFlushingPaths.back()->fDrawOps) {
	op->accountForOwnPaths(fPathCache.get(), onFlushRP, &specs);
	}
	for (const auto& clipsIter : fFlushingPaths.back()->fClipPaths) {
	clipsIter.second.accountForOwnPath(&specs);
	}
	}

	if (specs.isEmpty()) {
	return; // Nothing to draw.
	}

	// Determine if there are enough reusable paths from last flush for it to be worth our time to
	// copy them to cached atlas(es).
	int numCopies = specs.fNumCopiedPaths[GrCCPerFlushResourceSpecs::kFillIdx] +
	specs.fNumCopiedPaths[GrCCPerFlushResourceSpecs::kStrokeIdx];
	auto doCopies = DoCopiesToA8Coverage(numCopies > 100 \|\|
	specs.fCopyAtlasSpecs.fApproxNumPixels > 256 * 256);
	if (numCopies && DoCopiesToA8Coverage::kNo == doCopies) {
	specs.cancelCopies();
	}

	auto resources = sk_make_sp<GrCCPerFlushResources>(onFlushRP, specs);
	if (!resources->isMapped()) {
	return; // Some allocation failed.
	}

	// Layout the atlas(es) and parse paths.
	for (const auto& flushingPaths : fFlushingPaths) {
	for (GrCCDrawPathsOp* op : flushingPaths->fDrawOps) {
	op->setupResources(fPathCache.get(), onFlushRP, resources.get(), doCopies);
	}
	for (auto& clipsIter : flushingPaths->fClipPaths) {
	clipsIter.second.renderPathInAtlas(resources.get(), onFlushRP);
	}
	}

	if (fPathCache) {
	// Purge invalidated textures from previous atlases before calling finalize(). That way,
	// the underlying textures objects can be freed up and reused for the next atlases.
	fPathCache->purgeInvalidatedAtlasTextures(onFlushRP);
	}

	// Allocate resources and then render the atlas(es).
	if (!resources->finalize(onFlushRP, out)) {
	return;
	}

	// Commit flushing paths to the resources once they are successfully completed.
	for (auto& flushingPaths : fFlushingPaths) {
	SkASSERT(!flushingPaths->fFlushResources);
	flushingPaths->fFlushResources = resources;
	}
	}

	void GrCoverageCountingPathRenderer::postFlush(GrDeferredUploadToken, const uint32_t* opListIDs,
	int numOpListIDs) {
	SkASSERT(fFlushing);

	if (!fFlushingPaths.empty()) {
	// In DDL mode these aren't guaranteed to be deleted so we must clear out the perFlush
	// resources manually.
	for (auto& flushingPaths : fFlushingPaths) {
	flushingPaths->fFlushResources = nullptr;
	}

	// We wait to erase these until after flush, once Ops and FPs are done accessing their data.
	fFlushingPaths.reset();
	}

	SkDEBUGCODE(fFlushing = false);
	}

	void GrCoverageCountingPathRenderer::purgeCacheEntriesOlderThan(
	GrProxyProvider* proxyProvider, const GrStdSteadyClock::time_point& purgeTime) {
	if (fPathCache) {
	fPathCache->purgeEntriesOlderThan(proxyProvider, purgeTime);
	}
	}

	void GrCoverageCountingPathRenderer::CropPath(const SkPath& path, const SkIRect& cropbox,
	SkPath* out) {
	SkPath cropboxPath;
	cropboxPath.addRect(SkRect::Make(cropbox));
	if (!Op(cropboxPath, path, kIntersect_SkPathOp, out)) {
	// This can fail if the PathOps encounter NaN or infinities.
	out->reset();
	}
	out->setIsVolatile(true);
	}

	float GrCoverageCountingPathRenderer::GetStrokeDevWidth(const SkMatrix& m,
	const SkStrokeRec& stroke,
	float* inflationRadius) {
	float strokeDevWidth;
	if (stroke.isHairlineStyle()) {
	strokeDevWidth = 1;
	} else {
	SkASSERT(SkStrokeRec::kStroke_Style == stroke.getStyle());
	SkASSERT(m.isSimilarity()); // Otherwise matrixScaleFactor = m.getMaxScale().
	float matrixScaleFactor = SkVector::Length(m.getScaleX(), m.getSkewY());
	strokeDevWidth = stroke.getWidth() * matrixScaleFactor;
	}
	if (inflationRadius) {
	// Inflate for a minimum stroke width of 1. In some cases when the stroke is less than 1px
	// wide, we may inflate it to 1px and instead reduce the opacity.
	*inflationRadius = SkStrokeRec::GetInflationRadius(
	stroke.getJoin(), stroke.getMiter(), stroke.getCap(), SkTMax(strokeDevWidth, 1.f));
	}
	return strokeDevWidth;
	}