src/gpu/GrLayerCache.h - platform/external/skia - Gitiles

 /*
  * Copyright 2014 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #ifndef GrLayerCache_DEFINED
 #define GrLayerCache_DEFINED

 #include "GrAtlas.h"
 #include "GrRect.h"

 #include "SkChecksum.h"
 #include "SkImageFilter.h"
 #include "SkMessageBus.h"
 #include "SkPicture.h"
 #include "SkTDynamicHash.h"

 // Set to 0 to disable caching of hoisted layers
 #define GR_CACHE_HOISTED_LAYERS 0

 // GrPictureInfo stores the atlas plots used by a single picture. A single
 // plot may be used to store layers from multiple pictures.
 struct GrPictureInfo {
 public:
     static const int kNumPlots = 4;

     // for SkTDynamicHash - just use the pictureID as the hash key
     static const uint32_t& GetKey(const GrPictureInfo& pictInfo) { return pictInfo.fPictureID; }
     static uint32_t Hash(const uint32_t& key) { return SkChecksum::Mix(key); }

     // GrPictureInfo proper
     GrPictureInfo(uint32_t pictureID) : fPictureID(pictureID) {
 #if !GR_CACHE_HOISTED_LAYERS
         memset(fPlotUses, 0, sizeof(fPlotUses));
 #endif
     }

 #if !GR_CACHE_HOISTED_LAYERS
     void incPlotUsage(int plotID) {
         SkASSERT(plotID < kNumPlots);
         fPlotUses[plotID]++;
     }

     void decPlotUsage(int plotID) {
         SkASSERT(plotID < kNumPlots);
         SkASSERT(fPlotUses[plotID] > 0);
         fPlotUses[plotID]--;
     }

     int plotUsage(int plotID) const {
         SkASSERT(plotID < kNumPlots);
         return fPlotUses[plotID];
     }
 #endif

     const uint32_t fPictureID;
     GrAtlas::ClientPlotUsage  fPlotUsage;

 #if !GR_CACHE_HOISTED_LAYERS
 private:
     int fPlotUses[kNumPlots];
 #endif
 };

 // GrCachedLayer encapsulates the caching information for a single saveLayer.
 //
 // Atlased layers get a ref to the backing GrTexture while non-atlased layers
 // get a ref to the GrTexture in which they reside. In both cases 'fRect'
 // contains the layer's extent in its texture.
 // Atlased layers also get a pointer to the plot in which they reside.
 // For non-atlased layers, the lock field just corresponds to locking in
 // the resource cache. For atlased layers, it implements an additional level
 // of locking to allow atlased layers to be reused multiple times.
 struct GrCachedLayer {
 public:
     // For SkTDynamicHash
     struct Key {
         Key(uint32_t pictureID, const SkMatrix& initialMat,
             const int* key, int keySize, bool copyKey = false)
         : fKeySize(keySize)
         , fFreeKey(copyKey) {
             fIDMatrix.fPictureID = pictureID;
             fIDMatrix.fInitialMat = initialMat;
             fIDMatrix.fInitialMat.getType(); // force initialization of type so hashes match

             if (copyKey) {
                 int* tempKey = new int[keySize];
                 memcpy(tempKey, key, keySize*sizeof(int));
                 fKey = tempKey;
             } else {
                 fKey = key;
             }

             // The pictureID/matrix portion needs to be tightly packed.
             GR_STATIC_ASSERT(sizeof(IDMatrix) == sizeof(uint32_t)+                     // pictureID
                                              9 * sizeof(SkScalar) + sizeof(uint32_t)); // matrix
         }

         ~Key() {
             if (fFreeKey) {
                 delete[] fKey;
             }
         }

         bool operator==(const Key& other) const {
             if (fKeySize != other.fKeySize) {
                 return false;
             }
             return fIDMatrix.fPictureID == other.fIDMatrix.fPictureID &&
                    fIDMatrix.fInitialMat.cheapEqualTo(other.fIDMatrix.fInitialMat) &&
                    !memcmp(fKey, other.fKey, fKeySize * sizeof(int));
         }

         uint32_t pictureID() const { return fIDMatrix.fPictureID; }

         // TODO: remove these when GrCachedLayer & ReplacementInfo fuse
         const int* key() const { SkASSERT(fFreeKey);  return fKey; }
         int keySize() const { SkASSERT(fFreeKey); return fKeySize; }

         uint32_t hash() const {
             uint32_t hash = SkChecksum::Murmur3(reinterpret_cast<const uint32_t*>(fKey),
                                                 fKeySize * sizeof(int));
             return SkChecksum::Murmur3(reinterpret_cast<const uint32_t*>(&fIDMatrix),
                                        sizeof(IDMatrix), hash);
         }

     private:
         struct IDMatrix {
             // ID of the picture of which this layer is a part
             uint32_t fPictureID;
             // The initial matrix passed into drawPicture
             SkMatrix fInitialMat;
         }              fIDMatrix;

         const int* fKey;
         const int  fKeySize;
         bool       fFreeKey;
     };

     static const Key& GetKey(const GrCachedLayer& layer) { return layer.fKey; }
     static uint32_t Hash(const Key& key) { return key.hash(); }

     // GrCachedLayer proper
     GrCachedLayer(uint32_t pictureID,
                   int start,
                   int stop,
                   const SkIRect& srcIR,
                   const SkIRect& dstIR,
                   const SkMatrix& ctm,
                   const int* key,
                   int keySize,
                   const SkPaint* paint)
         : fKey(pictureID, ctm, key, keySize, true)
         , fStart(start)
         , fStop(stop)
         , fSrcIR(srcIR)
         , fDstIR(dstIR)
         , fOffset(SkIPoint::Make(0, 0))
         , fPaint(paint ? new SkPaint(*paint) : nullptr)
         , fFilter(nullptr)
         , fTexture(nullptr)
         , fRect(SkIRect::MakeEmpty())
         , fPlot(nullptr)
         , fUses(0)
         , fLocked(false) {
         SkASSERT(SK_InvalidGenID != pictureID);

         if (fPaint) {
             if (fPaint->getImageFilter()) {
                 fFilter = SkSafeRef(fPaint->getImageFilter());
                 fPaint->setImageFilter(nullptr);
             }
         }
     }

     ~GrCachedLayer() {
         SkSafeUnref(fTexture);
         SkSafeUnref(fFilter);
         delete fPaint;
     }

     uint32_t pictureID() const { return fKey.pictureID(); }
     // TODO: remove these when GrCachedLayer & ReplacementInfo fuse
     const int* key() const { return fKey.key(); }
     int keySize() const { return fKey.keySize(); }

     int start() const { return fStart; }
     // TODO: make bound debug only
     const SkIRect& srcIR() const { return fSrcIR; }
     const SkIRect& dstIR() const { return fDstIR; }
     int stop() const { return fStop; }
     void setTexture(GrTexture* texture, const SkIRect& rect) {
         SkRefCnt_SafeAssign(fTexture, texture);
         fRect = rect;
         if (!fTexture) {
             fLocked = false;
         }
     }
     GrTexture* texture() { return fTexture; }
     const SkPaint* paint() const { return fPaint; }
     const SkImageFilter* filter() const { return fFilter; }
     const SkIRect& rect() const { return fRect; }

     void setOffset(const SkIPoint& offset) { fOffset = offset; }
     const SkIPoint& offset() const { return fOffset; }

     void setPlot(GrPlot* plot) {
         SkASSERT(nullptr == plot || nullptr == fPlot);
         fPlot = plot;
     }
     GrPlot* plot() { return fPlot; }

     bool isAtlased() const { return SkToBool(fPlot); }

     void setLocked(bool locked) { fLocked = locked; }
     bool locked() const { return fLocked; }

     SkDEBUGCODE(const GrPlot* plot() const { return fPlot; })
     SkDEBUGCODE(void validate(const GrTexture* backingTexture) const;)

 private:
     const Key       fKey;

     // The "saveLayer" operation index of the cached layer
     const int  fStart;
     // The final "restore" operation index of the cached layer
     const int  fStop;

     // The layer's src rect (i.e., the portion of the source scene required
     // for filtering).
     const SkIRect   fSrcIR;
     // The layer's dest rect (i.e., where it will land in device space)
     const SkIRect   fDstIR;
     // Offset sometimes required by image filters
     SkIPoint        fOffset;

     // The paint used when dropping the layer down into the owning canvas.
     // Can be nullptr. This class makes a copy for itself.
     SkPaint*  fPaint;

     // The imagefilter that needs to be applied to the layer prior to it being
     // composited with the rest of the scene.
     const SkImageFilter* fFilter;

     // fTexture is a ref on the atlasing texture for atlased layers and a
     // ref on a GrTexture for non-atlased textures.
     GrTexture*      fTexture;

     // For both atlased and non-atlased layers 'fRect' contains the  bound of
     // the layer in whichever texture it resides. It is empty when 'fTexture'
     // is nullptr.
     SkIRect         fRect;

     // For atlased layers, fPlot stores the atlas plot in which the layer rests.
     // It is always nullptr for non-atlased layers.
     GrPlot*         fPlot;

     // The number of actively hoisted layers using this cached image (e.g.,
     // extant GrHoistedLayers pointing at this object). This object will
     // be unlocked when the use count reaches 0.
     int             fUses;

     // For non-atlased layers 'fLocked' should always match "fTexture".
     // (i.e., if there is a texture it is locked).
     // For atlased layers, 'fLocked' is true if the layer is in a plot and
     // actively required for rendering. If the layer is in a plot but not
     // actively required for rendering, then 'fLocked' is false. If the
     // layer isn't in a plot then is can never be locked.
     bool            fLocked;

     void addUse()     { ++fUses; }
     void removeUse()  { SkASSERT(fUses > 0); --fUses; }
     int uses() const { return fUses; }

     friend class GrLayerCache;  // for access to usage methods
     friend class TestingAccess; // for testing
 };

 // The GrLayerCache caches pre-computed saveLayers for later rendering.
 // Non-atlased layers are stored in their own GrTexture while the atlased
 // layers share a single GrTexture.
 // Unlike the GrFontCache, the GrTexture atlas only has one GrAtlas (for 8888)
 // and one GrPlot (for the entire atlas). As such, the GrLayerCache
 // roughly combines the functionality of the GrFontCache and GrTextStrike
 // classes.
 class GrLayerCache {
 public:
     GrLayerCache(GrContext*);
     ~GrLayerCache();

     // As a cache, the GrLayerCache can be ordered to free up all its cached
     // elements by the GrContext
     void freeAll();

     GrCachedLayer* findLayer(uint32_t pictureID, const SkMatrix& ctm,
                              const int* key, int keySize);
     GrCachedLayer* findLayerOrCreate(uint32_t pictureID,
                                      int start, int stop,
                                      const SkIRect& srcIR,
                                      const SkIRect& dstIR,
                                      const SkMatrix& initialMat,
                                      const int* key, int keySize,
                                      const SkPaint* paint);

     // Attempt to place 'layer' in the atlas. Return true on success; false on failure.
     // When true is returned, 'needsRendering' will indicate if the layer must be (re)drawn.
     // Additionally, the GPU resources will be locked.
     bool tryToAtlas(GrCachedLayer* layer, const GrSurfaceDesc& desc, bool* needsRendering);

     // Attempt to lock the GPU resources required for a layer. Return true on success;
     // false on failure. When true is returned 'needsRendering' will indicate if the
     // layer must be (re)drawn.
     // Note that atlased layers should already have been locked and rendered so only
     // free floating layers will have 'needsRendering' set.
     // Currently, this path always uses a new scratch texture for non-Atlased layers
     // and (thus) doesn't cache anything. This can yield a lot of re-rendering.
     // TODO: allow rediscovery of free-floating layers that are still in the resource cache.
     bool lock(GrCachedLayer* layer, const GrSurfaceDesc& desc, bool* needsRendering);

     // addUse is just here to keep the API symmetric
     void addUse(GrCachedLayer* layer) { layer->addUse(); }
     void removeUse(GrCachedLayer* layer) {
         layer->removeUse();
         if (layer->uses() == 0) {
             // If no one cares about the layer allow it to be recycled.
             this->unlock(layer);
         }
     }

     // Cleanup after any SkPicture deletions
     void processDeletedPictures();

     SkDEBUGCODE(void validate() const;)

 #ifdef SK_DEVELOPER
     void writeLayersToDisk(const SkString& dirName);
 #endif

     static bool PlausiblyAtlasable(int width, int height) {
         return width <= kPlotWidth && height <= kPlotHeight;
     }

 #if !GR_CACHE_HOISTED_LAYERS
     void purgeAll();
 #endif

 private:
     static const int kAtlasTextureWidth = 1024;
     static const int kAtlasTextureHeight = 1024;

     static const int kNumPlotsX = 2;
     static const int kNumPlotsY = 2;

     static const int kPlotWidth = kAtlasTextureWidth / kNumPlotsX;
     static const int kPlotHeight = kAtlasTextureHeight / kNumPlotsY;

     GrContext*                fContext;  // pointer back to owning context
     SkAutoTDelete<GrAtlas>    fAtlas;    // TODO: could lazily allocate

     // We cache this information here (rather then, say, on the owning picture)
     // because we want to be able to clean it up as needed (e.g., if a picture
     // is leaked and never cleans itself up we still want to be able to
     // remove the GrPictureInfo once its layers are purged from all the atlas
     // plots).
     SkTDynamicHash<GrPictureInfo, uint32_t> fPictureHash;

     SkTDynamicHash<GrCachedLayer, GrCachedLayer::Key> fLayerHash;

     SkMessageBus<SkPicture::DeletionMessage>::Inbox fPictDeletionInbox;

     // This implements a plot-centric locking mechanism (since the atlas
     // backing texture is always locked). Each layer that is locked (i.e.,
     // needed for the current rendering) in a plot increments the plot lock
     // count for that plot. Similarly, once a rendering is complete all the
     // layers used in it decrement the lock count for the used plots.
     // Plots with a 0 lock count are open for recycling/purging.
     int fPlotLocks[kNumPlotsX * kNumPlotsY];

     // Inform the cache that layer's cached image is not currently required
     void unlock(GrCachedLayer* layer);

     void initAtlas();
     GrCachedLayer* createLayer(uint32_t pictureID, int start, int stop,
                                const SkIRect& srcIR, const SkIRect& dstIR,
                                const SkMatrix& initialMat,
                                const int* key, int keySize,
                                const SkPaint* paint);

     // Remove all the layers (and unlock any resources) associated with 'pictureID'
     void purge(uint32_t pictureID);

     void purgePlot(GrPlot* plot);

     // Try to find a purgeable plot and clear it out. Return true if a plot
     // was purged; false otherwise.
     bool purgePlot();

     void incPlotLock(int plotIdx) { ++fPlotLocks[plotIdx]; }
     void decPlotLock(int plotIdx) {
         SkASSERT(fPlotLocks[plotIdx] > 0);
         --fPlotLocks[plotIdx];
     }

     // for testing
     friend class TestingAccess;
     int numLayers() const { return fLayerHash.count(); }
 };

 #endif
	/*
	* Copyright 2014 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#ifndef GrLayerCache_DEFINED
	#define GrLayerCache_DEFINED

	#include "GrAtlas.h"
	#include "GrRect.h"

	#include "SkChecksum.h"
	#include "SkImageFilter.h"
	#include "SkMessageBus.h"
	#include "SkPicture.h"
	#include "SkTDynamicHash.h"

	// Set to 0 to disable caching of hoisted layers
	#define GR_CACHE_HOISTED_LAYERS 0

	// GrPictureInfo stores the atlas plots used by a single picture. A single
	// plot may be used to store layers from multiple pictures.
	struct GrPictureInfo {
	public:
	static const int kNumPlots = 4;

	// for SkTDynamicHash - just use the pictureID as the hash key
	static const uint32_t& GetKey(const GrPictureInfo& pictInfo) { return pictInfo.fPictureID; }
	static uint32_t Hash(const uint32_t& key) { return SkChecksum::Mix(key); }

	// GrPictureInfo proper
	GrPictureInfo(uint32_t pictureID) : fPictureID(pictureID) {
	#if !GR_CACHE_HOISTED_LAYERS
	memset(fPlotUses, 0, sizeof(fPlotUses));
	#endif
	}

	#if !GR_CACHE_HOISTED_LAYERS
	void incPlotUsage(int plotID) {
	SkASSERT(plotID < kNumPlots);
	fPlotUses[plotID]++;
	}

	void decPlotUsage(int plotID) {
	SkASSERT(plotID < kNumPlots);
	SkASSERT(fPlotUses[plotID] > 0);
	fPlotUses[plotID]--;
	}

	int plotUsage(int plotID) const {
	SkASSERT(plotID < kNumPlots);
	return fPlotUses[plotID];
	}
	#endif

	const uint32_t fPictureID;
	GrAtlas::ClientPlotUsage fPlotUsage;

	#if !GR_CACHE_HOISTED_LAYERS
	private:
	int fPlotUses[kNumPlots];
	#endif
	};

	// GrCachedLayer encapsulates the caching information for a single saveLayer.
	//
	// Atlased layers get a ref to the backing GrTexture while non-atlased layers
	// get a ref to the GrTexture in which they reside. In both cases 'fRect'
	// contains the layer's extent in its texture.
	// Atlased layers also get a pointer to the plot in which they reside.
	// For non-atlased layers, the lock field just corresponds to locking in
	// the resource cache. For atlased layers, it implements an additional level
	// of locking to allow atlased layers to be reused multiple times.
	struct GrCachedLayer {
	public:
	// For SkTDynamicHash
	struct Key {
	Key(uint32_t pictureID, const SkMatrix& initialMat,
	const int* key, int keySize, bool copyKey = false)
	: fKeySize(keySize)
	, fFreeKey(copyKey) {
	fIDMatrix.fPictureID = pictureID;
	fIDMatrix.fInitialMat = initialMat;
	fIDMatrix.fInitialMat.getType(); // force initialization of type so hashes match

	if (copyKey) {
	int* tempKey = new int[keySize];
	memcpy(tempKey, key, keySize*sizeof(int));
	fKey = tempKey;
	} else {
	fKey = key;
	}

	// The pictureID/matrix portion needs to be tightly packed.
	GR_STATIC_ASSERT(sizeof(IDMatrix) == sizeof(uint32_t)+ // pictureID
	9 * sizeof(SkScalar) + sizeof(uint32_t)); // matrix
	}

	~Key() {
	if (fFreeKey) {
	delete[] fKey;
	}
	}

	bool operator==(const Key& other) const {
	if (fKeySize != other.fKeySize) {
	return false;
	}
	return fIDMatrix.fPictureID == other.fIDMatrix.fPictureID &&
	fIDMatrix.fInitialMat.cheapEqualTo(other.fIDMatrix.fInitialMat) &&
	!memcmp(fKey, other.fKey, fKeySize * sizeof(int));
	}

	uint32_t pictureID() const { return fIDMatrix.fPictureID; }

	// TODO: remove these when GrCachedLayer & ReplacementInfo fuse
	const int* key() const { SkASSERT(fFreeKey); return fKey; }
	int keySize() const { SkASSERT(fFreeKey); return fKeySize; }

	uint32_t hash() const {
	uint32_t hash = SkChecksum::Murmur3(reinterpret_cast<const uint32_t*>(fKey),
	fKeySize * sizeof(int));
	return SkChecksum::Murmur3(reinterpret_cast<const uint32_t*>(&fIDMatrix),
	sizeof(IDMatrix), hash);
	}

	private:
	struct IDMatrix {
	// ID of the picture of which this layer is a part
	uint32_t fPictureID;
	// The initial matrix passed into drawPicture
	SkMatrix fInitialMat;
	} fIDMatrix;

	const int* fKey;
	const int fKeySize;
	bool fFreeKey;
	};

	static const Key& GetKey(const GrCachedLayer& layer) { return layer.fKey; }
	static uint32_t Hash(const Key& key) { return key.hash(); }

	// GrCachedLayer proper
	GrCachedLayer(uint32_t pictureID,
	int start,
	int stop,
	const SkIRect& srcIR,
	const SkIRect& dstIR,
	const SkMatrix& ctm,
	const int* key,
	int keySize,
	const SkPaint* paint)
	: fKey(pictureID, ctm, key, keySize, true)
	, fStart(start)
	, fStop(stop)
	, fSrcIR(srcIR)
	, fDstIR(dstIR)
	, fOffset(SkIPoint::Make(0, 0))
	, fPaint(paint ? new SkPaint(*paint) : nullptr)
	, fFilter(nullptr)
	, fTexture(nullptr)
	, fRect(SkIRect::MakeEmpty())
	, fPlot(nullptr)
	, fUses(0)
	, fLocked(false) {
	SkASSERT(SK_InvalidGenID != pictureID);

	if (fPaint) {
	if (fPaint->getImageFilter()) {
	fFilter = SkSafeRef(fPaint->getImageFilter());
	fPaint->setImageFilter(nullptr);
	}
	}
	}

	~GrCachedLayer() {
	SkSafeUnref(fTexture);
	SkSafeUnref(fFilter);
	delete fPaint;
	}

	uint32_t pictureID() const { return fKey.pictureID(); }
	// TODO: remove these when GrCachedLayer & ReplacementInfo fuse
	const int* key() const { return fKey.key(); }
	int keySize() const { return fKey.keySize(); }

	int start() const { return fStart; }
	// TODO: make bound debug only
	const SkIRect& srcIR() const { return fSrcIR; }
	const SkIRect& dstIR() const { return fDstIR; }
	int stop() const { return fStop; }
	void setTexture(GrTexture* texture, const SkIRect& rect) {
	SkRefCnt_SafeAssign(fTexture, texture);
	fRect = rect;
	if (!fTexture) {
	fLocked = false;
	}
	}
	GrTexture* texture() { return fTexture; }
	const SkPaint* paint() const { return fPaint; }
	const SkImageFilter* filter() const { return fFilter; }
	const SkIRect& rect() const { return fRect; }

	void setOffset(const SkIPoint& offset) { fOffset = offset; }
	const SkIPoint& offset() const { return fOffset; }

	void setPlot(GrPlot* plot) {
	SkASSERT(nullptr == plot \|\| nullptr == fPlot);
	fPlot = plot;
	}
	GrPlot* plot() { return fPlot; }

	bool isAtlased() const { return SkToBool(fPlot); }

	void setLocked(bool locked) { fLocked = locked; }
	bool locked() const { return fLocked; }

	SkDEBUGCODE(const GrPlot* plot() const { return fPlot; })
	SkDEBUGCODE(void validate(const GrTexture* backingTexture) const;)

	private:
	const Key fKey;

	// The "saveLayer" operation index of the cached layer
	const int fStart;
	// The final "restore" operation index of the cached layer
	const int fStop;

	// The layer's src rect (i.e., the portion of the source scene required
	// for filtering).
	const SkIRect fSrcIR;
	// The layer's dest rect (i.e., where it will land in device space)
	const SkIRect fDstIR;
	// Offset sometimes required by image filters
	SkIPoint fOffset;

	// The paint used when dropping the layer down into the owning canvas.
	// Can be nullptr. This class makes a copy for itself.
	SkPaint* fPaint;

	// The imagefilter that needs to be applied to the layer prior to it being
	// composited with the rest of the scene.
	const SkImageFilter* fFilter;

	// fTexture is a ref on the atlasing texture for atlased layers and a
	// ref on a GrTexture for non-atlased textures.
	GrTexture* fTexture;

	// For both atlased and non-atlased layers 'fRect' contains the bound of
	// the layer in whichever texture it resides. It is empty when 'fTexture'
	// is nullptr.
	SkIRect fRect;

	// For atlased layers, fPlot stores the atlas plot in which the layer rests.
	// It is always nullptr for non-atlased layers.
	GrPlot* fPlot;

	// The number of actively hoisted layers using this cached image (e.g.,
	// extant GrHoistedLayers pointing at this object). This object will
	// be unlocked when the use count reaches 0.
	int fUses;

	// For non-atlased layers 'fLocked' should always match "fTexture".
	// (i.e., if there is a texture it is locked).
	// For atlased layers, 'fLocked' is true if the layer is in a plot and
	// actively required for rendering. If the layer is in a plot but not
	// actively required for rendering, then 'fLocked' is false. If the
	// layer isn't in a plot then is can never be locked.
	bool fLocked;

	void addUse() { ++fUses; }
	void removeUse() { SkASSERT(fUses > 0); --fUses; }
	int uses() const { return fUses; }

	friend class GrLayerCache; // for access to usage methods
	friend class TestingAccess; // for testing
	};

	// The GrLayerCache caches pre-computed saveLayers for later rendering.
	// Non-atlased layers are stored in their own GrTexture while the atlased
	// layers share a single GrTexture.
	// Unlike the GrFontCache, the GrTexture atlas only has one GrAtlas (for 8888)
	// and one GrPlot (for the entire atlas). As such, the GrLayerCache
	// roughly combines the functionality of the GrFontCache and GrTextStrike
	// classes.
	class GrLayerCache {
	public:
	GrLayerCache(GrContext*);
	~GrLayerCache();

	// As a cache, the GrLayerCache can be ordered to free up all its cached
	// elements by the GrContext
	void freeAll();

	GrCachedLayer* findLayer(uint32_t pictureID, const SkMatrix& ctm,
	const int* key, int keySize);
	GrCachedLayer* findLayerOrCreate(uint32_t pictureID,
	int start, int stop,
	const SkIRect& srcIR,
	const SkIRect& dstIR,
	const SkMatrix& initialMat,
	const int* key, int keySize,
	const SkPaint* paint);

	// Attempt to place 'layer' in the atlas. Return true on success; false on failure.
	// When true is returned, 'needsRendering' will indicate if the layer must be (re)drawn.
	// Additionally, the GPU resources will be locked.
	bool tryToAtlas(GrCachedLayer* layer, const GrSurfaceDesc& desc, bool* needsRendering);

	// Attempt to lock the GPU resources required for a layer. Return true on success;
	// false on failure. When true is returned 'needsRendering' will indicate if the
	// layer must be (re)drawn.
	// Note that atlased layers should already have been locked and rendered so only
	// free floating layers will have 'needsRendering' set.
	// Currently, this path always uses a new scratch texture for non-Atlased layers
	// and (thus) doesn't cache anything. This can yield a lot of re-rendering.
	// TODO: allow rediscovery of free-floating layers that are still in the resource cache.
	bool lock(GrCachedLayer* layer, const GrSurfaceDesc& desc, bool* needsRendering);

	// addUse is just here to keep the API symmetric
	void addUse(GrCachedLayer* layer) { layer->addUse(); }
	void removeUse(GrCachedLayer* layer) {
	layer->removeUse();
	if (layer->uses() == 0) {
	// If no one cares about the layer allow it to be recycled.
	this->unlock(layer);
	}
	}

	// Cleanup after any SkPicture deletions
	void processDeletedPictures();

	SkDEBUGCODE(void validate() const;)

	#ifdef SK_DEVELOPER
	void writeLayersToDisk(const SkString& dirName);
	#endif

	static bool PlausiblyAtlasable(int width, int height) {
	return width <= kPlotWidth && height <= kPlotHeight;
	}

	#if !GR_CACHE_HOISTED_LAYERS
	void purgeAll();
	#endif

	private:
	static const int kAtlasTextureWidth = 1024;
	static const int kAtlasTextureHeight = 1024;

	static const int kNumPlotsX = 2;
	static const int kNumPlotsY = 2;

	static const int kPlotWidth = kAtlasTextureWidth / kNumPlotsX;
	static const int kPlotHeight = kAtlasTextureHeight / kNumPlotsY;

	GrContext* fContext; // pointer back to owning context
	SkAutoTDelete<GrAtlas> fAtlas; // TODO: could lazily allocate

	// We cache this information here (rather then, say, on the owning picture)
	// because we want to be able to clean it up as needed (e.g., if a picture
	// is leaked and never cleans itself up we still want to be able to
	// remove the GrPictureInfo once its layers are purged from all the atlas
	// plots).
	SkTDynamicHash<GrPictureInfo, uint32_t> fPictureHash;

	SkTDynamicHash<GrCachedLayer, GrCachedLayer::Key> fLayerHash;

	SkMessageBus<SkPicture::DeletionMessage>::Inbox fPictDeletionInbox;

	// This implements a plot-centric locking mechanism (since the atlas
	// backing texture is always locked). Each layer that is locked (i.e.,
	// needed for the current rendering) in a plot increments the plot lock
	// count for that plot. Similarly, once a rendering is complete all the
	// layers used in it decrement the lock count for the used plots.
	// Plots with a 0 lock count are open for recycling/purging.
	int fPlotLocks[kNumPlotsX * kNumPlotsY];

	// Inform the cache that layer's cached image is not currently required
	void unlock(GrCachedLayer* layer);

	void initAtlas();
	GrCachedLayer* createLayer(uint32_t pictureID, int start, int stop,
	const SkIRect& srcIR, const SkIRect& dstIR,
	const SkMatrix& initialMat,
	const int* key, int keySize,
	const SkPaint* paint);

	// Remove all the layers (and unlock any resources) associated with 'pictureID'
	void purge(uint32_t pictureID);

	void purgePlot(GrPlot* plot);

	// Try to find a purgeable plot and clear it out. Return true if a plot
	// was purged; false otherwise.
	bool purgePlot();

	void incPlotLock(int plotIdx) { ++fPlotLocks[plotIdx]; }
	void decPlotLock(int plotIdx) {
	SkASSERT(fPlotLocks[plotIdx] > 0);
	--fPlotLocks[plotIdx];
	}

	// for testing
	friend class TestingAccess;
	int numLayers() const { return fLayerHash.count(); }
	};

	#endif