src/gpu/GrAtlasTextContext.h - platform/external/skqp - Gitiles

 /*
  * Copyright 2015 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #ifndef GrAtlasTextContext_DEFINED
 #define GrAtlasTextContext_DEFINED

 #include "GrTextContext.h"

 #include "GrBatchAtlas.h"
 #include "GrBatchFontCache.h"
 #include "GrGeometryProcessor.h"
 #include "SkDescriptor.h"
 #include "GrMemoryPool.h"
 #include "SkMaskFilter.h"
 #include "SkTextBlob.h"
 #include "SkTInternalLList.h"

 #ifdef GR_TEST_UTILS
 #include "GrBatchTest.h"
 #endif

 class BitmapTextBatch;
 class GrDrawContext;
 class GrDrawTarget;
 class GrPipelineBuilder;
 class GrTextBlobCache;

 /*
  * This class implements GrTextContext using standard bitmap fonts, and can also process textblobs.
  * TODO replace GrBitmapTextContext
  */
 class GrAtlasTextContext : public GrTextContext {
 public:
     static GrAtlasTextContext* Create(GrContext*, GrDrawContext*, const SkSurfaceProps&);

 private:
     GrAtlasTextContext(GrContext*, GrDrawContext*, const SkSurfaceProps&);
     ~GrAtlasTextContext() override {}

     bool canDraw(const GrRenderTarget*, const GrClip&, const GrPaint&,
                  const SkPaint&, const SkMatrix& viewMatrix) override;

     void onDrawText(GrRenderTarget*, const GrClip&, const GrPaint&, const SkPaint&,
                     const SkMatrix& viewMatrix, const char text[], size_t byteLength,
                     SkScalar x, SkScalar y, const SkIRect& regionClipBounds) override;
     void onDrawPosText(GrRenderTarget*, const GrClip&, const GrPaint&,
                        const SkPaint&, const SkMatrix& viewMatrix,
                        const char text[], size_t byteLength,
                        const SkScalar pos[], int scalarsPerPosition,
                        const SkPoint& offset, const SkIRect& regionClipBounds) override;
     void drawTextBlob(GrRenderTarget*, const GrClip&, const SkPaint&,
                       const SkMatrix& viewMatrix, const SkTextBlob*, SkScalar x, SkScalar y,
                       SkDrawFilter*, const SkIRect& clipBounds) override;

     /*
      * A BitmapTextBlob contains a fully processed SkTextBlob, suitable for nearly immediate drawing
      * on the GPU.  These are initially created with valid positions and colors, but invalid
      * texture coordinates.  The BitmapTextBlob itself has a few Blob-wide properties, and also
      * consists of a number of runs.  Runs inside a blob are flushed individually so they can be
      * reordered.
      *
      * The only thing(aside from a memcopy) required to flush a BitmapTextBlob is to ensure that
      * the GrAtlas will not evict anything the Blob needs.
      */
     struct BitmapTextBlob : public SkRefCnt {
         SK_DECLARE_INTERNAL_LLIST_INTERFACE(BitmapTextBlob);

         /*
          * Each Run inside of the blob can have its texture coordinates regenerated if required.
          * To determine if regeneration is necessary, fAtlasGeneration is used.  If there have been
          * any evictions inside of the atlas, then we will simply regenerate Runs.  We could track
          * this at a more fine grained level, but its not clear if this is worth it, as evictions
          * should be fairly rare.
          *
          * One additional point, each run can contain glyphs with any of the three mask formats.
          * We call these SubRuns.  Because a subrun must be a contiguous range, we have to create
          * a new subrun each time the mask format changes in a run.  In theory, a run can have as
          * many SubRuns as it has glyphs, ie if a run alternates between color emoji and A8.  In
          * practice, the vast majority of runs have only a single subrun.
          *
          * Finally, for runs where the entire thing is too large for the GrAtlasTextContext to
          * handle, we have a bit to mark the run as flusahable via rendering as paths.  It is worth
          * pointing. It would be a bit expensive to figure out ahead of time whether or not a run
          * can flush in this manner, so we always allocate vertices for the run, regardless of
          * whether or not it is too large.  The benefit of this strategy is that we can always reuse
          * a blob allocation regardless of viewmatrix changes.  We could store positions for these
          * glyphs.  However, its not clear if this is a win because we'd still have to either go the
          * glyph cache to get the path at flush time, or hold onto the path in the cache, which
          * would greatly increase the memory of these cached items.
          */
         struct Run {
             Run()
                 : fColor(GrColor_ILLEGAL)
                 , fInitialized(false)
                 , fDrawAsPaths(false) {
                 fVertexBounds.setLargestInverted();
                 // To ensure we always have one subrun, we push back a fresh run here
                 fSubRunInfo.push_back();
             }
             struct SubRunInfo {
                 SubRunInfo()
                     : fAtlasGeneration(GrBatchAtlas::kInvalidAtlasGeneration)
                     , fVertexStartIndex(0)
                     , fVertexEndIndex(0)
                     , fGlyphStartIndex(0)
                     , fGlyphEndIndex(0)
                     , fDrawAsDistanceFields(false) {}
                 // Distance field text cannot draw coloremoji, and so has to fall back.  However,
                 // though the distance field text and the coloremoji may share the same run, they
                 // will have different descriptors.  If fOverrideDescriptor is non-NULL, then it
                 // will be used in place of the run's descriptor to regen texture coords
                 // TODO we could have a descriptor cache, it would reduce the size of these blobs
                 // significantly, and then the subrun could just have a refed pointer to the
                 // correct descriptor.
                 GrBatchAtlas::BulkUseTokenUpdater fBulkUseToken;
                 uint64_t fAtlasGeneration;
                 size_t fVertexStartIndex;
                 size_t fVertexEndIndex;
                 uint32_t fGlyphStartIndex;
                 uint32_t fGlyphEndIndex;
                 SkScalar fTextRatio; // df property
                 GrMaskFormat fMaskFormat;
                 bool fDrawAsDistanceFields; // df property
                 bool fUseLCDText; // df property
             };

             SubRunInfo& push_back() {
                 // Forward glyph / vertex information to seed the new sub run
                 SubRunInfo& prevSubRun = fSubRunInfo.back();
                 SubRunInfo& newSubRun = fSubRunInfo.push_back();
                 newSubRun.fGlyphStartIndex = prevSubRun.fGlyphEndIndex;
                 newSubRun.fGlyphEndIndex = prevSubRun.fGlyphEndIndex;

                 newSubRun.fVertexStartIndex = prevSubRun.fVertexEndIndex;
                 newSubRun.fVertexEndIndex = prevSubRun.fVertexEndIndex;
                 return newSubRun;
             }
             static const int kMinSubRuns = 1;
             SkAutoTUnref<GrBatchTextStrike> fStrike;
             SkAutoTUnref<SkTypeface> fTypeface;
             SkRect fVertexBounds;
             SkSTArray<kMinSubRuns, SubRunInfo> fSubRunInfo;
             SkAutoDescriptor fDescriptor;
             SkAutoTDelete<SkAutoDescriptor> fOverrideDescriptor; // df properties
             GrColor fColor;
             bool fInitialized;
             bool fDrawAsPaths;
         };

         struct BigGlyph {
             BigGlyph(const SkPath& path, SkScalar vx, SkScalar vy)
                 : fPath(path)
                 , fVx(vx)
                 , fVy(vy) {}
             SkPath fPath;
             SkScalar fVx;
             SkScalar fVy;
         };

         struct Key {
             Key() {
                 sk_bzero(this, sizeof(Key));
             }
             uint32_t fUniqueID;
             // Color may affect the gamma of the mask we generate, but in a fairly limited way.
             // Each color is assigned to on of a fixed number of buckets based on its
             // luminance. For each luminance bucket there is a "canonical color" that
             // represents the bucket.  This functionality is currently only supported for A8
             SkColor fCanonicalColor;
             SkPaint::Style fStyle;
             SkPixelGeometry fPixelGeometry;
             bool fHasBlur;

             bool operator==(const Key& other) const {
                 return 0 == memcmp(this, &other, sizeof(Key));
             }
         };

         struct StrokeInfo {
             SkScalar fFrameWidth;
             SkScalar fMiterLimit;
             SkPaint::Join fJoin;
         };

         enum TextType {
             kHasDistanceField_TextType = 0x1,
             kHasBitmap_TextType = 0x2,
         };

         // all glyph / vertex offsets are into these pools.
         unsigned char* fVertices;
         GrGlyph** fGlyphs;
         Run* fRuns;
         GrMemoryPool* fPool;
         SkMaskFilter::BlurRec fBlurRec;
         StrokeInfo fStrokeInfo;
         SkTArray<BigGlyph> fBigGlyphs;
         Key fKey;
         SkMatrix fViewMatrix;
         SkColor fPaintColor;
         SkScalar fX;
         SkScalar fY;

         // We can reuse distance field text, but only if the new viewmatrix would not result in
         // a mip change.  Because there can be multiple runs in a blob, we track the overall
         // maximum minimum scale, and minimum maximum scale, we can support before we need to regen
         SkScalar fMaxMinScale;
         SkScalar fMinMaxScale;
         int fRunCount;
         uint8_t fTextType;

         BitmapTextBlob()
             : fMaxMinScale(-SK_ScalarMax)
             , fMinMaxScale(SK_ScalarMax)
             , fTextType(0) {}

         ~BitmapTextBlob() override {
             for (int i = 0; i < fRunCount; i++) {
                 fRuns[i].~Run();
             }
         }

         static const Key& GetKey(const BitmapTextBlob& blob) {
             return blob.fKey;
         }

         static uint32_t Hash(const Key& key) {
             return SkChecksum::Murmur3(&key, sizeof(Key));
         }

         void operator delete(void* p) {
             BitmapTextBlob* blob = reinterpret_cast<BitmapTextBlob*>(p);
             blob->fPool->release(p);
         }
         void* operator new(size_t) {
             SkFAIL("All blobs are created by placement new.");
             return sk_malloc_throw(0);
         }

         void* operator new(size_t, void* p) { return p; }
         void operator delete(void* target, void* placement) {
             ::operator delete(target, placement);
         }

         bool hasDistanceField() const { return SkToBool(fTextType & kHasDistanceField_TextType); }
         bool hasBitmap() const { return SkToBool(fTextType & kHasBitmap_TextType); }
         void setHasDistanceField() { fTextType |= kHasDistanceField_TextType; }
         void setHasBitmap() { fTextType |= kHasBitmap_TextType; }
     };

     typedef BitmapTextBlob::Run Run;
     typedef Run::SubRunInfo PerSubRunInfo;

     inline bool canDrawAsDistanceFields(const SkPaint&, const SkMatrix& viewMatrix);
     BitmapTextBlob* setupDFBlob(int glyphCount, const SkPaint& origPaint,
                                 const SkMatrix& viewMatrix, SkGlyphCache** cache,
                                 SkPaint* dfPaint, SkScalar* textRatio);
     void bmpAppendGlyph(BitmapTextBlob*, int runIndex, GrGlyph::PackedID, int left, int top,
                         GrColor color, GrFontScaler*, const SkIRect& clipRect);
     bool dfAppendGlyph(BitmapTextBlob*, int runIndex, GrGlyph::PackedID, SkScalar sx, SkScalar sy,
                        GrColor color, GrFontScaler*, const SkIRect& clipRect, SkScalar textRatio,
                        const SkMatrix& viewMatrix);
     inline void appendGlyphPath(BitmapTextBlob* blob, GrGlyph* glyph,
                                 GrFontScaler* scaler, SkScalar x, SkScalar y);
     inline void appendGlyphCommon(BitmapTextBlob*, Run*, Run::SubRunInfo*,
                                   const SkRect& positions, GrColor color,
                                   size_t vertexStride, bool useVertexColor,
                                   GrGlyph*);

     inline void flushRunAsPaths(GrRenderTarget*,
                                 const SkTextBlob::RunIterator&, const GrClip& clip,
                                 const SkPaint&, SkDrawFilter*,
                                 const SkMatrix& viewMatrix, const SkIRect& clipBounds, SkScalar x,
                                 SkScalar y);
     inline BitmapTextBatch* createBatch(BitmapTextBlob*, const PerSubRunInfo&,
                                         int glyphCount, int run, int subRun,
                                         GrColor, SkScalar transX, SkScalar transY,
                                         const SkPaint&);
     inline void flushRun(GrPipelineBuilder*, BitmapTextBlob*, int run, GrColor,
                          SkScalar transX, SkScalar transY, const SkPaint&);
     inline void flushBigGlyphs(BitmapTextBlob* cacheBlob, GrRenderTarget*,
                                const GrClip& clip, const SkPaint& skPaint,
                                SkScalar transX, SkScalar transY, const SkIRect& clipBounds);

     // We have to flush SkTextBlobs differently from drawText / drawPosText
     void flush(const SkTextBlob*, BitmapTextBlob*, GrRenderTarget*,
                const SkPaint&, const GrPaint&, SkDrawFilter*, const GrClip&,
                const SkMatrix& viewMatrix, const SkIRect& clipBounds, SkScalar x, SkScalar y,
                SkScalar transX, SkScalar transY);
     void flush(BitmapTextBlob*, GrRenderTarget*, const SkPaint&,
                const GrPaint&, const GrClip&, const SkIRect& clipBounds);

     // A helper for drawing BitmapText in a run of distance fields
     inline void fallbackDrawPosText(BitmapTextBlob*, int runIndex,
                                     GrRenderTarget*, const GrClip&,
                                     const GrPaint&,
                                     const SkPaint&, const SkMatrix& viewMatrix,
                                     const SkTDArray<char>& fallbackTxt,
                                     const SkTDArray<SkScalar>& fallbackPos,
                                     int scalarsPerPosition,
                                     const SkPoint& offset,
                                     const SkIRect& clipRect);

     void internalDrawBMPText(BitmapTextBlob*, int runIndex, SkGlyphCache*, const SkPaint&,
                              GrColor color, const SkMatrix& viewMatrix,
                              const char text[], size_t byteLength,
                              SkScalar x, SkScalar y, const SkIRect& clipRect);
     void internalDrawBMPPosText(BitmapTextBlob*, int runIndex, SkGlyphCache*, const SkPaint&,
                                 GrColor color, const SkMatrix& viewMatrix,
                                 const char text[], size_t byteLength,
                                 const SkScalar pos[], int scalarsPerPosition,
                                 const SkPoint& offset, const SkIRect& clipRect);

     void internalDrawDFText(BitmapTextBlob*, int runIndex, SkGlyphCache*, const SkPaint&,
                             GrColor color, const SkMatrix& viewMatrix,
                             const char text[], size_t byteLength,
                             SkScalar x, SkScalar y, const SkIRect& clipRect,
                             SkScalar textRatio,
                             SkTDArray<char>* fallbackTxt,
                             SkTDArray<SkScalar>* fallbackPos,
                             SkPoint* offset, const SkPaint& origPaint);
     void internalDrawDFPosText(BitmapTextBlob*, int runIndex, SkGlyphCache*, const SkPaint&,
                                GrColor color, const SkMatrix& viewMatrix,
                                const char text[], size_t byteLength,
                                const SkScalar pos[], int scalarsPerPosition,
                                const SkPoint& offset, const SkIRect& clipRect,
                                SkScalar textRatio,
                                SkTDArray<char>* fallbackTxt,
                                SkTDArray<SkScalar>* fallbackPos);

     // sets up the descriptor on the blob and returns a detached cache.  Client must attach
     inline static GrColor ComputeCanonicalColor(const SkPaint&, bool lcd);
     inline SkGlyphCache* setupCache(Run*, const SkPaint&, const SkMatrix* viewMatrix, bool noGamma);
     static inline bool MustRegenerateBlob(SkScalar* outTransX, SkScalar* outTransY,
                                           const BitmapTextBlob&, const SkPaint&,
                                           const SkMaskFilter::BlurRec&,
                                           const SkMatrix& viewMatrix, SkScalar x, SkScalar y);
     void regenerateTextBlob(BitmapTextBlob* bmp, const SkPaint& skPaint, GrColor,
                             const SkMatrix& viewMatrix,
                             const SkTextBlob* blob, SkScalar x, SkScalar y,
                             SkDrawFilter* drawFilter, const SkIRect& clipRect, GrRenderTarget*,
                             const GrClip&, const GrPaint&);
     inline static bool HasLCD(const SkTextBlob*);
     inline void initDistanceFieldPaint(BitmapTextBlob*, SkPaint*, SkScalar* textRatio,
                                        const SkMatrix&);

     // Test methods
     // TODO this is really ugly.  It'd be much nicer if positioning could be moved to batch
     inline BitmapTextBlob* createDrawTextBlob(GrRenderTarget*, const GrClip&, const GrPaint&,
                                               const SkPaint&, const SkMatrix& viewMatrix,
                                               const char text[], size_t byteLength,
                                               SkScalar x, SkScalar y,
                                               const SkIRect& regionClipBounds);
     inline BitmapTextBlob* createDrawPosTextBlob(GrRenderTarget*, const GrClip&, const GrPaint&,
                                                  const SkPaint&, const SkMatrix& viewMatrix,
                                                  const char text[], size_t byteLength,
                                                  const SkScalar pos[], int scalarsPerPosition,
                                                  const SkPoint& offset,
                                                  const SkIRect& regionClipBounds);

     // Distance field text needs this table to compute a value for use in the fragment shader.
     // Because the GrAtlasTextContext can go out of scope before the final flush, this needs to be
     // refcnted and malloced
     struct DistanceAdjustTable : public SkNVRefCnt<DistanceAdjustTable> {
         DistanceAdjustTable() { this->buildDistanceAdjustTable(); }
         ~DistanceAdjustTable() { SkDELETE_ARRAY(fTable); }

         const SkScalar& operator[] (int i) const {
             return fTable[i];
         }

     private:
         void buildDistanceAdjustTable();

         SkScalar* fTable;
     };

     GrBatchTextStrike* fCurrStrike;
     GrTextBlobCache* fCache;
     SkAutoTUnref<DistanceAdjustTable> fDistanceAdjustTable;

     friend class GrTextBlobCache;
     friend class BitmapTextBatch;

 #ifdef GR_TEST_UTILS
     BATCH_TEST_FRIEND(TextBlobBatch);
 #endif

     typedef GrTextContext INHERITED;
 };

 #endif
	/*
	* Copyright 2015 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#ifndef GrAtlasTextContext_DEFINED
	#define GrAtlasTextContext_DEFINED

	#include "GrTextContext.h"

	#include "GrBatchAtlas.h"
	#include "GrBatchFontCache.h"
	#include "GrGeometryProcessor.h"
	#include "SkDescriptor.h"
	#include "GrMemoryPool.h"
	#include "SkMaskFilter.h"
	#include "SkTextBlob.h"
	#include "SkTInternalLList.h"

	#ifdef GR_TEST_UTILS
	#include "GrBatchTest.h"
	#endif

	class BitmapTextBatch;
	class GrDrawContext;
	class GrDrawTarget;
	class GrPipelineBuilder;
	class GrTextBlobCache;

	/*
	* This class implements GrTextContext using standard bitmap fonts, and can also process textblobs.
	* TODO replace GrBitmapTextContext
	*/
	class GrAtlasTextContext : public GrTextContext {
	public:
	static GrAtlasTextContext* Create(GrContext, GrDrawContext, const SkSurfaceProps&);

	private:
	GrAtlasTextContext(GrContext, GrDrawContext, const SkSurfaceProps&);
	~GrAtlasTextContext() override {}

	bool canDraw(const GrRenderTarget*, const GrClip&, const GrPaint&,
	const SkPaint&, const SkMatrix& viewMatrix) override;

	void onDrawText(GrRenderTarget*, const GrClip&, const GrPaint&, const SkPaint&,
	const SkMatrix& viewMatrix, const char text[], size_t byteLength,
	SkScalar x, SkScalar y, const SkIRect& regionClipBounds) override;
	void onDrawPosText(GrRenderTarget*, const GrClip&, const GrPaint&,
	const SkPaint&, const SkMatrix& viewMatrix,
	const char text[], size_t byteLength,
	const SkScalar pos[], int scalarsPerPosition,
	const SkPoint& offset, const SkIRect& regionClipBounds) override;
	void drawTextBlob(GrRenderTarget*, const GrClip&, const SkPaint&,
	const SkMatrix& viewMatrix, const SkTextBlob*, SkScalar x, SkScalar y,
	SkDrawFilter*, const SkIRect& clipBounds) override;

	/*
	* A BitmapTextBlob contains a fully processed SkTextBlob, suitable for nearly immediate drawing
	* on the GPU. These are initially created with valid positions and colors, but invalid
	* texture coordinates. The BitmapTextBlob itself has a few Blob-wide properties, and also
	* consists of a number of runs. Runs inside a blob are flushed individually so they can be
	* reordered.
	*
	* The only thing(aside from a memcopy) required to flush a BitmapTextBlob is to ensure that
	* the GrAtlas will not evict anything the Blob needs.
	*/
	struct BitmapTextBlob : public SkRefCnt {
	SK_DECLARE_INTERNAL_LLIST_INTERFACE(BitmapTextBlob);

	/*
	* Each Run inside of the blob can have its texture coordinates regenerated if required.
	* To determine if regeneration is necessary, fAtlasGeneration is used. If there have been
	* any evictions inside of the atlas, then we will simply regenerate Runs. We could track
	* this at a more fine grained level, but its not clear if this is worth it, as evictions
	* should be fairly rare.
	*
	* One additional point, each run can contain glyphs with any of the three mask formats.
	* We call these SubRuns. Because a subrun must be a contiguous range, we have to create
	* a new subrun each time the mask format changes in a run. In theory, a run can have as
	* many SubRuns as it has glyphs, ie if a run alternates between color emoji and A8. In
	* practice, the vast majority of runs have only a single subrun.
	*
	* Finally, for runs where the entire thing is too large for the GrAtlasTextContext to
	* handle, we have a bit to mark the run as flusahable via rendering as paths. It is worth
	* pointing. It would be a bit expensive to figure out ahead of time whether or not a run
	* can flush in this manner, so we always allocate vertices for the run, regardless of
	* whether or not it is too large. The benefit of this strategy is that we can always reuse
	* a blob allocation regardless of viewmatrix changes. We could store positions for these
	* glyphs. However, its not clear if this is a win because we'd still have to either go the
	* glyph cache to get the path at flush time, or hold onto the path in the cache, which
	* would greatly increase the memory of these cached items.
	*/
	struct Run {
	Run()
	: fColor(GrColor_ILLEGAL)
	, fInitialized(false)
	, fDrawAsPaths(false) {
	fVertexBounds.setLargestInverted();
	// To ensure we always have one subrun, we push back a fresh run here
	fSubRunInfo.push_back();
	}
	struct SubRunInfo {
	SubRunInfo()
	: fAtlasGeneration(GrBatchAtlas::kInvalidAtlasGeneration)
	, fVertexStartIndex(0)
	, fVertexEndIndex(0)
	, fGlyphStartIndex(0)
	, fGlyphEndIndex(0)
	, fDrawAsDistanceFields(false) {}
	// Distance field text cannot draw coloremoji, and so has to fall back. However,
	// though the distance field text and the coloremoji may share the same run, they
	// will have different descriptors. If fOverrideDescriptor is non-NULL, then it
	// will be used in place of the run's descriptor to regen texture coords
	// TODO we could have a descriptor cache, it would reduce the size of these blobs
	// significantly, and then the subrun could just have a refed pointer to the
	// correct descriptor.
	GrBatchAtlas::BulkUseTokenUpdater fBulkUseToken;
	uint64_t fAtlasGeneration;
	size_t fVertexStartIndex;
	size_t fVertexEndIndex;
	uint32_t fGlyphStartIndex;
	uint32_t fGlyphEndIndex;
	SkScalar fTextRatio; // df property
	GrMaskFormat fMaskFormat;
	bool fDrawAsDistanceFields; // df property
	bool fUseLCDText; // df property
	};

	SubRunInfo& push_back() {
	// Forward glyph / vertex information to seed the new sub run
	SubRunInfo& prevSubRun = fSubRunInfo.back();
	SubRunInfo& newSubRun = fSubRunInfo.push_back();
	newSubRun.fGlyphStartIndex = prevSubRun.fGlyphEndIndex;
	newSubRun.fGlyphEndIndex = prevSubRun.fGlyphEndIndex;

	newSubRun.fVertexStartIndex = prevSubRun.fVertexEndIndex;
	newSubRun.fVertexEndIndex = prevSubRun.fVertexEndIndex;
	return newSubRun;
	}
	static const int kMinSubRuns = 1;
	SkAutoTUnref<GrBatchTextStrike> fStrike;
	SkAutoTUnref<SkTypeface> fTypeface;
	SkRect fVertexBounds;
	SkSTArray<kMinSubRuns, SubRunInfo> fSubRunInfo;
	SkAutoDescriptor fDescriptor;
	SkAutoTDelete<SkAutoDescriptor> fOverrideDescriptor; // df properties
	GrColor fColor;
	bool fInitialized;
	bool fDrawAsPaths;
	};

	struct BigGlyph {
	BigGlyph(const SkPath& path, SkScalar vx, SkScalar vy)
	: fPath(path)
	, fVx(vx)
	, fVy(vy) {}
	SkPath fPath;
	SkScalar fVx;
	SkScalar fVy;
	};

	struct Key {
	Key() {
	sk_bzero(this, sizeof(Key));
	}
	uint32_t fUniqueID;
	// Color may affect the gamma of the mask we generate, but in a fairly limited way.
	// Each color is assigned to on of a fixed number of buckets based on its
	// luminance. For each luminance bucket there is a "canonical color" that
	// represents the bucket. This functionality is currently only supported for A8
	SkColor fCanonicalColor;
	SkPaint::Style fStyle;
	SkPixelGeometry fPixelGeometry;
	bool fHasBlur;

	bool operator==(const Key& other) const {
	return 0 == memcmp(this, &other, sizeof(Key));
	}
	};

	struct StrokeInfo {
	SkScalar fFrameWidth;
	SkScalar fMiterLimit;
	SkPaint::Join fJoin;
	};

	enum TextType {
	kHasDistanceField_TextType = 0x1,
	kHasBitmap_TextType = 0x2,
	};

	// all glyph / vertex offsets are into these pools.
	unsigned char* fVertices;
	GrGlyph** fGlyphs;
	Run* fRuns;
	GrMemoryPool* fPool;
	SkMaskFilter::BlurRec fBlurRec;
	StrokeInfo fStrokeInfo;
	SkTArray<BigGlyph> fBigGlyphs;
	Key fKey;
	SkMatrix fViewMatrix;
	SkColor fPaintColor;
	SkScalar fX;
	SkScalar fY;

	// We can reuse distance field text, but only if the new viewmatrix would not result in
	// a mip change. Because there can be multiple runs in a blob, we track the overall
	// maximum minimum scale, and minimum maximum scale, we can support before we need to regen
	SkScalar fMaxMinScale;
	SkScalar fMinMaxScale;
	int fRunCount;
	uint8_t fTextType;

	BitmapTextBlob()
	: fMaxMinScale(-SK_ScalarMax)
	, fMinMaxScale(SK_ScalarMax)
	, fTextType(0) {}

	~BitmapTextBlob() override {
	for (int i = 0; i < fRunCount; i++) {
	fRuns[i].~Run();
	}
	}

	static const Key& GetKey(const BitmapTextBlob& blob) {
	return blob.fKey;
	}

	static uint32_t Hash(const Key& key) {
	return SkChecksum::Murmur3(&key, sizeof(Key));
	}

	void operator delete(void* p) {
	BitmapTextBlob* blob = reinterpret_cast<BitmapTextBlob*>(p);
	blob->fPool->release(p);
	}
	void* operator new(size_t) {
	SkFAIL("All blobs are created by placement new.");
	return sk_malloc_throw(0);
	}

	void* operator new(size_t, void* p) { return p; }
	void operator delete(void* target, void* placement) {
	::operator delete(target, placement);
	}

	bool hasDistanceField() const { return SkToBool(fTextType & kHasDistanceField_TextType); }
	bool hasBitmap() const { return SkToBool(fTextType & kHasBitmap_TextType); }
	void setHasDistanceField() { fTextType \|= kHasDistanceField_TextType; }
	void setHasBitmap() { fTextType \|= kHasBitmap_TextType; }
	};

	typedef BitmapTextBlob::Run Run;
	typedef Run::SubRunInfo PerSubRunInfo;

	inline bool canDrawAsDistanceFields(const SkPaint&, const SkMatrix& viewMatrix);
	BitmapTextBlob* setupDFBlob(int glyphCount, const SkPaint& origPaint,
	const SkMatrix& viewMatrix, SkGlyphCache** cache,
	SkPaint* dfPaint, SkScalar* textRatio);
	void bmpAppendGlyph(BitmapTextBlob*, int runIndex, GrGlyph::PackedID, int left, int top,
	GrColor color, GrFontScaler*, const SkIRect& clipRect);
	bool dfAppendGlyph(BitmapTextBlob*, int runIndex, GrGlyph::PackedID, SkScalar sx, SkScalar sy,
	GrColor color, GrFontScaler*, const SkIRect& clipRect, SkScalar textRatio,
	const SkMatrix& viewMatrix);
	inline void appendGlyphPath(BitmapTextBlob* blob, GrGlyph* glyph,
	GrFontScaler* scaler, SkScalar x, SkScalar y);
	inline void appendGlyphCommon(BitmapTextBlob, Run, Run::SubRunInfo*,
	const SkRect& positions, GrColor color,
	size_t vertexStride, bool useVertexColor,
	GrGlyph*);

	inline void flushRunAsPaths(GrRenderTarget*,
	const SkTextBlob::RunIterator&, const GrClip& clip,
	const SkPaint&, SkDrawFilter*,
	const SkMatrix& viewMatrix, const SkIRect& clipBounds, SkScalar x,
	SkScalar y);
	inline BitmapTextBatch* createBatch(BitmapTextBlob*, const PerSubRunInfo&,
	int glyphCount, int run, int subRun,
	GrColor, SkScalar transX, SkScalar transY,
	const SkPaint&);
	inline void flushRun(GrPipelineBuilder, BitmapTextBlob, int run, GrColor,
	SkScalar transX, SkScalar transY, const SkPaint&);
	inline void flushBigGlyphs(BitmapTextBlob* cacheBlob, GrRenderTarget*,
	const GrClip& clip, const SkPaint& skPaint,
	SkScalar transX, SkScalar transY, const SkIRect& clipBounds);

	// We have to flush SkTextBlobs differently from drawText / drawPosText
	void flush(const SkTextBlob, BitmapTextBlob, GrRenderTarget*,
	const SkPaint&, const GrPaint&, SkDrawFilter*, const GrClip&,
	const SkMatrix& viewMatrix, const SkIRect& clipBounds, SkScalar x, SkScalar y,
	SkScalar transX, SkScalar transY);
	void flush(BitmapTextBlob, GrRenderTarget, const SkPaint&,
	const GrPaint&, const GrClip&, const SkIRect& clipBounds);

	// A helper for drawing BitmapText in a run of distance fields
	inline void fallbackDrawPosText(BitmapTextBlob*, int runIndex,
	GrRenderTarget*, const GrClip&,
	const GrPaint&,
	const SkPaint&, const SkMatrix& viewMatrix,
	const SkTDArray<char>& fallbackTxt,
	const SkTDArray<SkScalar>& fallbackPos,
	int scalarsPerPosition,
	const SkPoint& offset,
	const SkIRect& clipRect);

	void internalDrawBMPText(BitmapTextBlob, int runIndex, SkGlyphCache, const SkPaint&,
	GrColor color, const SkMatrix& viewMatrix,
	const char text[], size_t byteLength,
	SkScalar x, SkScalar y, const SkIRect& clipRect);
	void internalDrawBMPPosText(BitmapTextBlob, int runIndex, SkGlyphCache, const SkPaint&,
	GrColor color, const SkMatrix& viewMatrix,
	const char text[], size_t byteLength,
	const SkScalar pos[], int scalarsPerPosition,
	const SkPoint& offset, const SkIRect& clipRect);

	void internalDrawDFText(BitmapTextBlob, int runIndex, SkGlyphCache, const SkPaint&,
	GrColor color, const SkMatrix& viewMatrix,
	const char text[], size_t byteLength,
	SkScalar x, SkScalar y, const SkIRect& clipRect,
	SkScalar textRatio,
	SkTDArray<char>* fallbackTxt,
	SkTDArray<SkScalar>* fallbackPos,
	SkPoint* offset, const SkPaint& origPaint);
	void internalDrawDFPosText(BitmapTextBlob, int runIndex, SkGlyphCache, const SkPaint&,
	GrColor color, const SkMatrix& viewMatrix,
	const char text[], size_t byteLength,
	const SkScalar pos[], int scalarsPerPosition,
	const SkPoint& offset, const SkIRect& clipRect,
	SkScalar textRatio,
	SkTDArray<char>* fallbackTxt,
	SkTDArray<SkScalar>* fallbackPos);

	// sets up the descriptor on the blob and returns a detached cache. Client must attach
	inline static GrColor ComputeCanonicalColor(const SkPaint&, bool lcd);
	inline SkGlyphCache* setupCache(Run, const SkPaint&, const SkMatrix viewMatrix, bool noGamma);
	static inline bool MustRegenerateBlob(SkScalar* outTransX, SkScalar* outTransY,
	const BitmapTextBlob&, const SkPaint&,
	const SkMaskFilter::BlurRec&,
	const SkMatrix& viewMatrix, SkScalar x, SkScalar y);
	void regenerateTextBlob(BitmapTextBlob* bmp, const SkPaint& skPaint, GrColor,
	const SkMatrix& viewMatrix,
	const SkTextBlob* blob, SkScalar x, SkScalar y,
	SkDrawFilter* drawFilter, const SkIRect& clipRect, GrRenderTarget*,
	const GrClip&, const GrPaint&);
	inline static bool HasLCD(const SkTextBlob*);
	inline void initDistanceFieldPaint(BitmapTextBlob, SkPaint, SkScalar* textRatio,
	const SkMatrix&);

	// Test methods
	// TODO this is really ugly. It'd be much nicer if positioning could be moved to batch
	inline BitmapTextBlob* createDrawTextBlob(GrRenderTarget*, const GrClip&, const GrPaint&,
	const SkPaint&, const SkMatrix& viewMatrix,
	const char text[], size_t byteLength,
	SkScalar x, SkScalar y,
	const SkIRect& regionClipBounds);
	inline BitmapTextBlob* createDrawPosTextBlob(GrRenderTarget*, const GrClip&, const GrPaint&,
	const SkPaint&, const SkMatrix& viewMatrix,
	const char text[], size_t byteLength,
	const SkScalar pos[], int scalarsPerPosition,
	const SkPoint& offset,
	const SkIRect& regionClipBounds);

	// Distance field text needs this table to compute a value for use in the fragment shader.
	// Because the GrAtlasTextContext can go out of scope before the final flush, this needs to be
	// refcnted and malloced
	struct DistanceAdjustTable : public SkNVRefCnt<DistanceAdjustTable> {
	DistanceAdjustTable() { this->buildDistanceAdjustTable(); }
	~DistanceAdjustTable() { SkDELETE_ARRAY(fTable); }

	const SkScalar& operator[] (int i) const {
	return fTable[i];
	}

	private:
	void buildDistanceAdjustTable();

	SkScalar* fTable;
	};

	GrBatchTextStrike* fCurrStrike;
	GrTextBlobCache* fCache;
	SkAutoTUnref<DistanceAdjustTable> fDistanceAdjustTable;

	friend class GrTextBlobCache;
	friend class BitmapTextBatch;

	#ifdef GR_TEST_UTILS
	BATCH_TEST_FRIEND(TextBlobBatch);
	#endif

	typedef GrTextContext INHERITED;
	};

	#endif