third_party/skia/src/gpu/ccpr/GrCCAtlas.h - cobalt - 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.
  */

 #ifndef GrCCAtlas_DEFINED
 #define GrCCAtlas_DEFINED

 #include "include/core/SkRefCnt.h"
 #include "include/core/SkSize.h"
 #include "include/gpu/GrTexture.h"
 #include "include/private/GrResourceKey.h"
 #include "src/gpu/GrAllocator.h"
 #include "src/gpu/GrNonAtomicRef.h"
 #include "src/gpu/GrSurfaceProxy.h"

 class GrCCCachedAtlas;
 class GrOnFlushResourceProvider;
 class GrRenderTargetContext;
 class GrResourceProvider;
 class GrTextureProxy;
 struct SkIPoint16;
 struct SkIRect;

 /**
  * This class implements a dynamic size GrRectanizer that grows until it reaches the implementation-
  * dependent max texture size. When finalized, it also creates and stores a GrTextureProxy for the
  * underlying atlas.
  */
 class GrCCAtlas {
 public:
     // As long as GrSurfaceOrigin exists, we just have to decide on one for the atlas texture.
     static constexpr GrSurfaceOrigin kTextureOrigin = kTopLeft_GrSurfaceOrigin;
     static constexpr int kPadding = 1;  // Amount of padding below and to the right of each path.

     // This struct encapsulates the minimum and desired requirements for an atlas, as well as an
     // approximate number of pixels to help select a good initial size.
     struct Specs {
         int fMaxPreferredTextureSize = 0;
         int fMinTextureSize = 0;
         int fMinWidth = 0;  // If there are 100 20x10 paths, this should be 20.
         int fMinHeight = 0;  // If there are 100 20x10 paths, this should be 10.
         int fApproxNumPixels = 0;

         // Add space for a rect in the desired atlas specs.
         void accountForSpace(int width, int height);
     };

     enum class CoverageType {
         kFP16_CoverageCount,
         kA8_Multisample,
         kA8_LiteralCoverage
     };

     static constexpr GrColorType CoverageTypeToColorType(CoverageType coverageType) {
         switch (coverageType) {
             case CoverageType::kFP16_CoverageCount:
                 return GrColorType::kAlpha_F16;
             case CoverageType::kA8_Multisample:
             case CoverageType::kA8_LiteralCoverage:
                 return GrColorType::kAlpha_8;
         }
         SkUNREACHABLE;
     }

     using LazyInstantiateAtlasCallback = std::function<GrSurfaceProxy::LazyCallbackResult(
             GrResourceProvider*, GrPixelConfig, const GrBackendFormat&, int sampleCount)>;

     static sk_sp<GrTextureProxy> MakeLazyAtlasProxy(const LazyInstantiateAtlasCallback&,
                                                     CoverageType,
                                                     const GrCaps&,
                                                     GrSurfaceProxy::UseAllocator);

     GrCCAtlas(CoverageType, const Specs&, const GrCaps&);
     ~GrCCAtlas();

     GrTextureProxy* textureProxy() const { return fTextureProxy.get(); }
     int currentWidth() const { return fWidth; }
     int currentHeight() const { return fHeight; }

     // Attempts to add a rect to the atlas. If successful, returns the integer offset from
     // device-space pixels where the path will be drawn, to atlas pixels where its mask resides.
     bool addRect(const SkIRect& devIBounds, SkIVector* atlasOffset);
     const SkISize& drawBounds() { return fDrawBounds; }

     // This is an optional space for the caller to jot down user-defined instance data to use when
     // rendering atlas content.
     void setFillBatchID(int id);
     int getFillBatchID() const { return fFillBatchID; }
     void setStrokeBatchID(int id);
     int getStrokeBatchID() const { return fStrokeBatchID; }
     void setEndStencilResolveInstance(int idx);
     int getEndStencilResolveInstance() const { return fEndStencilResolveInstance; }

     sk_sp<GrCCCachedAtlas> refOrMakeCachedAtlas(GrOnFlushResourceProvider*);

     // Instantiates our texture proxy for the atlas and returns a pre-cleared GrRenderTargetContext
     // that the caller may use to render the content. After this call, it is no longer valid to call
     // addRect(), setUserBatchID(), or this method again.
     //
     // 'backingTexture', if provided, is a renderable texture with which to instantiate our proxy.
     // If null then we will create a texture using the resource provider. The purpose of this param
     // is to provide a guaranteed way to recycle a stashed atlas texture from a previous flush.
     std::unique_ptr<GrRenderTargetContext> makeRenderTargetContext(
             GrOnFlushResourceProvider*, sk_sp<GrTexture> backingTexture = nullptr);

 private:
     class Node;

     bool internalPlaceRect(int w, int h, SkIPoint16* loc);

     const CoverageType fCoverageType;
     const int fMaxTextureSize;
     int fWidth, fHeight;
     std::unique_ptr<Node> fTopNode;
     SkISize fDrawBounds = {0, 0};

     int fFillBatchID;
     int fStrokeBatchID;
     int fEndStencilResolveInstance;

     sk_sp<GrCCCachedAtlas> fCachedAtlas;
     sk_sp<GrTextureProxy> fTextureProxy;
     sk_sp<GrTexture> fBackingTexture;
 };

 /**
  * This class implements an unbounded stack of atlases. When the current atlas reaches the
  * implementation-dependent max texture size, a new one is pushed to the back and we continue on.
  */
 class GrCCAtlasStack {
 public:
     using CoverageType = GrCCAtlas::CoverageType;

     GrCCAtlasStack(CoverageType coverageType, const GrCCAtlas::Specs& specs, const GrCaps* caps)
             : fCoverageType(coverageType), fSpecs(specs), fCaps(caps) {}

     CoverageType coverageType() const { return fCoverageType; }
     bool empty() const { return fAtlases.empty(); }
     const GrCCAtlas& front() const { SkASSERT(!this->empty()); return fAtlases.front(); }
     GrCCAtlas& front() { SkASSERT(!this->empty()); return fAtlases.front(); }
     GrCCAtlas& current() { SkASSERT(!this->empty()); return fAtlases.back(); }

     class Iter {
     public:
         Iter(GrCCAtlasStack& stack) : fImpl(&stack.fAtlases) {}
         bool next() { return fImpl.next(); }
         GrCCAtlas* operator->() const { return fImpl.get(); }
     private:
         typename GrTAllocator<GrCCAtlas>::Iter fImpl;
     };

     // Adds a rect to the current atlas and returns the offset from device space to atlas space.
     // Call current() to get the atlas it was added to.
     //
     // If the return value is non-null, it means the given rect did not fit in the then-current
     // atlas, so it was retired and a new one was added to the stack. The return value is the
     // newly-retired atlas. The caller should call setUserBatchID() on the retired atlas before
     // moving on.
     GrCCAtlas* addRect(const SkIRect& devIBounds, SkIVector* devToAtlasOffset);

 private:
     const CoverageType fCoverageType;
     const GrCCAtlas::Specs fSpecs;
     const GrCaps* const fCaps;
     GrSTAllocator<4, GrCCAtlas> fAtlases;
 };

 inline void GrCCAtlas::Specs::accountForSpace(int width, int height) {
     fMinWidth = SkTMax(width, fMinWidth);
     fMinHeight = SkTMax(height, fMinHeight);
     fApproxNumPixels += (width + kPadding) * (height + kPadding);
 }

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

	#ifndef GrCCAtlas_DEFINED
	#define GrCCAtlas_DEFINED

	#include "include/core/SkRefCnt.h"
	#include "include/core/SkSize.h"
	#include "include/gpu/GrTexture.h"
	#include "include/private/GrResourceKey.h"
	#include "src/gpu/GrAllocator.h"
	#include "src/gpu/GrNonAtomicRef.h"
	#include "src/gpu/GrSurfaceProxy.h"

	class GrCCCachedAtlas;
	class GrOnFlushResourceProvider;
	class GrRenderTargetContext;
	class GrResourceProvider;
	class GrTextureProxy;
	struct SkIPoint16;
	struct SkIRect;

	/**
	* This class implements a dynamic size GrRectanizer that grows until it reaches the implementation-
	* dependent max texture size. When finalized, it also creates and stores a GrTextureProxy for the
	* underlying atlas.
	*/
	class GrCCAtlas {
	public:
	// As long as GrSurfaceOrigin exists, we just have to decide on one for the atlas texture.
	static constexpr GrSurfaceOrigin kTextureOrigin = kTopLeft_GrSurfaceOrigin;
	static constexpr int kPadding = 1; // Amount of padding below and to the right of each path.

	// This struct encapsulates the minimum and desired requirements for an atlas, as well as an
	// approximate number of pixels to help select a good initial size.
	struct Specs {
	int fMaxPreferredTextureSize = 0;
	int fMinTextureSize = 0;
	int fMinWidth = 0; // If there are 100 20x10 paths, this should be 20.
	int fMinHeight = 0; // If there are 100 20x10 paths, this should be 10.
	int fApproxNumPixels = 0;

	// Add space for a rect in the desired atlas specs.
	void accountForSpace(int width, int height);
	};

	enum class CoverageType {
	kFP16_CoverageCount,
	kA8_Multisample,
	kA8_LiteralCoverage
	};

	static constexpr GrColorType CoverageTypeToColorType(CoverageType coverageType) {
	switch (coverageType) {
	case CoverageType::kFP16_CoverageCount:
	return GrColorType::kAlpha_F16;
	case CoverageType::kA8_Multisample:
	case CoverageType::kA8_LiteralCoverage:
	return GrColorType::kAlpha_8;
	}
	SkUNREACHABLE;
	}

	using LazyInstantiateAtlasCallback = std::function<GrSurfaceProxy::LazyCallbackResult(
	GrResourceProvider*, GrPixelConfig, const GrBackendFormat&, int sampleCount)>;

	static sk_sp<GrTextureProxy> MakeLazyAtlasProxy(const LazyInstantiateAtlasCallback&,
	CoverageType,
	const GrCaps&,
	GrSurfaceProxy::UseAllocator);

	GrCCAtlas(CoverageType, const Specs&, const GrCaps&);
	~GrCCAtlas();

	GrTextureProxy* textureProxy() const { return fTextureProxy.get(); }
	int currentWidth() const { return fWidth; }
	int currentHeight() const { return fHeight; }

	// Attempts to add a rect to the atlas. If successful, returns the integer offset from
	// device-space pixels where the path will be drawn, to atlas pixels where its mask resides.
	bool addRect(const SkIRect& devIBounds, SkIVector* atlasOffset);
	const SkISize& drawBounds() { return fDrawBounds; }

	// This is an optional space for the caller to jot down user-defined instance data to use when
	// rendering atlas content.
	void setFillBatchID(int id);
	int getFillBatchID() const { return fFillBatchID; }
	void setStrokeBatchID(int id);
	int getStrokeBatchID() const { return fStrokeBatchID; }
	void setEndStencilResolveInstance(int idx);
	int getEndStencilResolveInstance() const { return fEndStencilResolveInstance; }

	sk_sp<GrCCCachedAtlas> refOrMakeCachedAtlas(GrOnFlushResourceProvider*);

	// Instantiates our texture proxy for the atlas and returns a pre-cleared GrRenderTargetContext
	// that the caller may use to render the content. After this call, it is no longer valid to call
	// addRect(), setUserBatchID(), or this method again.
	//
	// 'backingTexture', if provided, is a renderable texture with which to instantiate our proxy.
	// If null then we will create a texture using the resource provider. The purpose of this param
	// is to provide a guaranteed way to recycle a stashed atlas texture from a previous flush.
	std::unique_ptr<GrRenderTargetContext> makeRenderTargetContext(
	GrOnFlushResourceProvider*, sk_sp<GrTexture> backingTexture = nullptr);

	private:
	class Node;

	bool internalPlaceRect(int w, int h, SkIPoint16* loc);

	const CoverageType fCoverageType;
	const int fMaxTextureSize;
	int fWidth, fHeight;
	std::unique_ptr<Node> fTopNode;
	SkISize fDrawBounds = {0, 0};

	int fFillBatchID;
	int fStrokeBatchID;
	int fEndStencilResolveInstance;

	sk_sp<GrCCCachedAtlas> fCachedAtlas;
	sk_sp<GrTextureProxy> fTextureProxy;
	sk_sp<GrTexture> fBackingTexture;
	};

	/**
	* This class implements an unbounded stack of atlases. When the current atlas reaches the
	* implementation-dependent max texture size, a new one is pushed to the back and we continue on.
	*/
	class GrCCAtlasStack {
	public:
	using CoverageType = GrCCAtlas::CoverageType;

	GrCCAtlasStack(CoverageType coverageType, const GrCCAtlas::Specs& specs, const GrCaps* caps)
	: fCoverageType(coverageType), fSpecs(specs), fCaps(caps) {}

	CoverageType coverageType() const { return fCoverageType; }
	bool empty() const { return fAtlases.empty(); }
	const GrCCAtlas& front() const { SkASSERT(!this->empty()); return fAtlases.front(); }
	GrCCAtlas& front() { SkASSERT(!this->empty()); return fAtlases.front(); }
	GrCCAtlas& current() { SkASSERT(!this->empty()); return fAtlases.back(); }

	class Iter {
	public:
	Iter(GrCCAtlasStack& stack) : fImpl(&stack.fAtlases) {}
	bool next() { return fImpl.next(); }
	GrCCAtlas* operator->() const { return fImpl.get(); }
	private:
	typename GrTAllocator<GrCCAtlas>::Iter fImpl;
	};

	// Adds a rect to the current atlas and returns the offset from device space to atlas space.
	// Call current() to get the atlas it was added to.
	//
	// If the return value is non-null, it means the given rect did not fit in the then-current
	// atlas, so it was retired and a new one was added to the stack. The return value is the
	// newly-retired atlas. The caller should call setUserBatchID() on the retired atlas before
	// moving on.
	GrCCAtlas* addRect(const SkIRect& devIBounds, SkIVector* devToAtlasOffset);

	private:
	const CoverageType fCoverageType;
	const GrCCAtlas::Specs fSpecs;
	const GrCaps* const fCaps;
	GrSTAllocator<4, GrCCAtlas> fAtlases;
	};

	inline void GrCCAtlas::Specs::accountForSpace(int width, int height) {
	fMinWidth = SkTMax(width, fMinWidth);
	fMinHeight = SkTMax(height, fMinHeight);
	fApproxNumPixels += (width + kPadding) * (height + kPadding);
	}

	#endif