src/gpu/GrStencilAndCoverTextContext.cpp - platform/external/skqp - 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.
  */

 #include "GrStencilAndCoverTextContext.h"
 #include "GrBitmapTextContext.h"
 #include "GrDrawTarget.h"
 #include "GrGpu.h"
 #include "GrPath.h"
 #include "GrPathRange.h"
 #include "SkAutoKern.h"
 #include "SkDraw.h"
 #include "SkDrawProcs.h"
 #include "SkGlyphCache.h"
 #include "SkGpuDevice.h"
 #include "SkPath.h"
 #include "SkTextMapStateProc.h"
 #include "SkTextFormatParams.h"

 GrStencilAndCoverTextContext::GrStencilAndCoverTextContext(
     GrContext* context, const SkDeviceProperties& properties)
     : GrTextContext(context, properties)
     , fPendingGlyphCount(0) {
 }

 GrStencilAndCoverTextContext* GrStencilAndCoverTextContext::Create(GrContext* context,
                                                                  const SkDeviceProperties& props) {
     GrStencilAndCoverTextContext* textContext = SkNEW_ARGS(GrStencilAndCoverTextContext,
                                                            (context, props));
     textContext->fFallbackTextContext = GrBitmapTextContext::Create(context, props);

     return textContext;
 }

 GrStencilAndCoverTextContext::~GrStencilAndCoverTextContext() {
 }

 bool GrStencilAndCoverTextContext::canDraw(const SkPaint& paint) {
     if (paint.getRasterizer()) {
         return false;
     }
     if (paint.getMaskFilter()) {
         return false;
     }
     if (paint.getPathEffect()) {
         return false;
     }

     // No hairlines unless we can map the 1 px width to the object space.
     if (paint.getStyle() == SkPaint::kStroke_Style
         && paint.getStrokeWidth() == 0
         && fContext->getMatrix().hasPerspective()) {
         return false;
     }

     // No color bitmap fonts.
     SkScalerContext::Rec    rec;
     SkScalerContext::MakeRec(paint, &fDeviceProperties, NULL, &rec);
     return rec.getFormat() != SkMask::kARGB32_Format;
 }

 void GrStencilAndCoverTextContext::onDrawText(const GrPaint& paint,
                                             const SkPaint& skPaint,
                                             const char text[],
                                             size_t byteLength,
                                             SkScalar x, SkScalar y) {
     SkASSERT(byteLength == 0 || text != NULL);

     if (text == NULL || byteLength == 0 /*|| fRC->isEmpty()*/) {
         return;
     }

     // This is the slow path, mainly used by Skia unit tests.  The other
     // backends (8888, gpu, ...) use device-space dependent glyph caches. In
     // order to match the glyph positions that the other code paths produce, we
     // must also use device-space dependent glyph cache. This has the
     // side-effect that the glyph shape outline will be in device-space,
     // too. This in turn has the side-effect that NVPR can not stroke the paths,
     // as the stroke in NVPR is defined in object-space.
     // NOTE: here we have following coincidence that works at the moment:
     // - When using the device-space glyphs, the transforms we pass to NVPR
     // instanced drawing are the global transforms, and the view transform is
     // identity. NVPR can not use non-affine transforms in the instanced
     // drawing. This is taken care of by SkDraw::ShouldDrawTextAsPaths since it
     // will turn off the use of device-space glyphs when perspective transforms
     // are in use.

     this->init(paint, skPaint, byteLength, kMaxAccuracy_RenderMode);

     // Transform our starting point.
     if (fNeedsDeviceSpaceGlyphs) {
         SkPoint loc;
         fContextInitialMatrix.mapXY(x, y, &loc);
         x = loc.fX;
         y = loc.fY;
     }

     SkDrawCacheProc glyphCacheProc = fSkPaint.getDrawCacheProc();

     const char* stop = text + byteLength;

     // Measure first if needed.
     if (fSkPaint.getTextAlign() != SkPaint::kLeft_Align) {
         SkFixed    stopX = 0;
         SkFixed    stopY = 0;

         const char* textPtr = text;
         while (textPtr < stop) {
             // We don't need x, y here, since all subpixel variants will have the
             // same advance.
             const SkGlyph& glyph = glyphCacheProc(fGlyphCache, &textPtr, 0, 0);

             stopX += glyph.fAdvanceX;
             stopY += glyph.fAdvanceY;
         }
         SkASSERT(textPtr == stop);

         SkScalar alignX = SkFixedToScalar(stopX) * fTextRatio;
         SkScalar alignY = SkFixedToScalar(stopY) * fTextRatio;

         if (fSkPaint.getTextAlign() == SkPaint::kCenter_Align) {
             alignX = SkScalarHalf(alignX);
             alignY = SkScalarHalf(alignY);
         }

         x -= alignX;
         y -= alignY;
     }

     SkAutoKern autokern;

     SkFixed fixedSizeRatio = SkScalarToFixed(fTextRatio);

     SkFixed fx = SkScalarToFixed(x);
     SkFixed fy = SkScalarToFixed(y);
     while (text < stop) {
         const SkGlyph& glyph = glyphCacheProc(fGlyphCache, &text, 0, 0);
         fx += SkFixedMul_portable(autokern.adjust(glyph), fixedSizeRatio);
         if (glyph.fWidth) {
             this->appendGlyph(glyph.getGlyphID(), SkFixedToScalar(fx), SkFixedToScalar(fy));
         }

         fx += SkFixedMul_portable(glyph.fAdvanceX, fixedSizeRatio);
         fy += SkFixedMul_portable(glyph.fAdvanceY, fixedSizeRatio);
     }

     this->finish();
 }

 void GrStencilAndCoverTextContext::onDrawPosText(const GrPaint& paint,
                                                const SkPaint& skPaint,
                                                const char text[],
                                                size_t byteLength,
                                                const SkScalar pos[],
                                                int scalarsPerPosition,
                                                const SkPoint& offset) {
     SkASSERT(byteLength == 0 || text != NULL);
     SkASSERT(1 == scalarsPerPosition || 2 == scalarsPerPosition);

     // nothing to draw
     if (text == NULL || byteLength == 0/* || fRC->isEmpty()*/) {
         return;
     }

     // This is the fast path.  Here we do not bake in the device-transform to
     // the glyph outline or the advances. This is because we do not need to
     // position the glyphs at all, since the caller has done the positioning.
     // The positioning is based on SkPaint::measureText of individual
     // glyphs. That already uses glyph cache without device transforms. Device
     // transform is not part of SkPaint::measureText API, and thus we use the
     // same glyphs as what were measured.

     this->init(paint, skPaint, byteLength, kMaxPerformance_RenderMode);

     SkDrawCacheProc glyphCacheProc = fSkPaint.getDrawCacheProc();

     const char* stop = text + byteLength;

     SkTextMapStateProc tmsProc(SkMatrix::I(), offset, scalarsPerPosition);
     SkTextAlignProcScalar alignProc(fSkPaint.getTextAlign());
     while (text < stop) {
         const SkGlyph& glyph = glyphCacheProc(fGlyphCache, &text, 0, 0);
         if (glyph.fWidth) {
             SkPoint tmsLoc;
             tmsProc(pos, &tmsLoc);
             SkPoint loc;
             alignProc(tmsLoc, glyph, &loc);

             this->appendGlyph(glyph.getGlyphID(), loc.x(), loc.y());
         }
         pos += scalarsPerPosition;
     }

     this->finish();
 }

 static GrPathRange* get_gr_glyphs(GrContext* ctx,
                                   const SkTypeface* typeface,
                                   const SkDescriptor* desc,
                                   const SkStrokeRec& stroke) {
     static const GrCacheID::Domain gGlyphsDomain = GrCacheID::GenerateDomain();

     GrCacheID::Key key;
     uint64_t* keyData = key.fData64;
     keyData[0] = desc ? desc->getChecksum() : 0;
     keyData[0] = (keyData[0] << 32) | (typeface ? typeface->uniqueID() : 0);
     keyData[1] = GrPath::ComputeStrokeKey(stroke);
     GrResourceKey resourceKey = GrResourceKey(GrCacheID(gGlyphsDomain, key),
                                               GrPathRange::resourceType(), 0);

     SkAutoTUnref<GrPathRange> glyphs(
         static_cast<GrPathRange*>(ctx->findAndRefCachedResource(resourceKey)));
     if (NULL == glyphs || (NULL != desc && !glyphs->isEqualTo(*desc))) {
         glyphs.reset(ctx->getGpu()->pathRendering()->createGlyphs(typeface, desc, stroke));
         ctx->addResourceToCache(resourceKey, glyphs);
     }

     return glyphs.detach();
 }

 void GrStencilAndCoverTextContext::init(const GrPaint& paint,
                                         const SkPaint& skPaint,
                                         size_t textByteLength,
                                         RenderMode renderMode) {
     GrTextContext::init(paint, skPaint);

     fContextInitialMatrix = fContext->getMatrix();

     const bool otherBackendsWillDrawAsPaths =
         SkDraw::ShouldDrawTextAsPaths(skPaint, fContextInitialMatrix);

     fNeedsDeviceSpaceGlyphs = !otherBackendsWillDrawAsPaths &&
                               kMaxAccuracy_RenderMode == renderMode &&
                               SkToBool(fContextInitialMatrix.getType() &
                                        (SkMatrix::kScale_Mask | SkMatrix::kAffine_Mask));

     if (fNeedsDeviceSpaceGlyphs) {
         // SkDraw::ShouldDrawTextAsPaths takes care of perspective transforms.
         SkASSERT(!fContextInitialMatrix.hasPerspective());

         fTextRatio = fTextInverseRatio = 1.0f;

         // Glyphs loaded by GPU path rendering have an inverted y-direction.
         SkMatrix m;
         m.setScale(1, -1);
         fContext->setMatrix(m);

         // Post-flip the initial matrix so we're left with just the flip after
         // the paint preConcats the inverse.
         m = fContextInitialMatrix;
         m.postScale(1, -1);
         fPaint.localCoordChangeInverse(m);

         // The whole shape (including stroke) will be baked into the glyph outlines. Make
         // NVPR just fill the baked shapes.
         fGlyphCache = fSkPaint.detachCache(&fDeviceProperties, &fContextInitialMatrix, false);
         fGlyphs = get_gr_glyphs(fContext, fGlyphCache->getScalerContext()->getTypeface(),
                                 &fGlyphCache->getDescriptor(),
                                 SkStrokeRec(SkStrokeRec::kFill_InitStyle));
     } else {
         // Don't bake strokes into the glyph outlines. We will stroke the glyphs
         // using the GPU instead. This is the fast path.
         SkStrokeRec gpuStroke = SkStrokeRec(fSkPaint);
         fSkPaint.setStyle(SkPaint::kFill_Style);

         if (gpuStroke.isHairlineStyle()) {
             // Approximate hairline stroke.
             SkScalar strokeWidth = SK_Scalar1 /
                 (SkVector::Make(fContextInitialMatrix.getScaleX(),
                                 fContextInitialMatrix.getSkewY()).length());
             gpuStroke.setStrokeStyle(strokeWidth, false /*strokeAndFill*/);

         } else if (fSkPaint.isFakeBoldText() &&
 #ifdef SK_USE_FREETYPE_EMBOLDEN
                    kMaxPerformance_RenderMode == renderMode &&
 #endif
                    SkStrokeRec::kStroke_Style != gpuStroke.getStyle()) {

             // Instead of baking fake bold into the glyph outlines, do it with the GPU stroke.
             SkScalar fakeBoldScale = SkScalarInterpFunc(fSkPaint.getTextSize(),
                                                         kStdFakeBoldInterpKeys,
                                                         kStdFakeBoldInterpValues,
                                                         kStdFakeBoldInterpLength);
             SkScalar extra = SkScalarMul(fSkPaint.getTextSize(), fakeBoldScale);
             gpuStroke.setStrokeStyle(gpuStroke.needToApply() ? gpuStroke.getWidth() + extra : extra,
                                      true /*strokeAndFill*/);

             fSkPaint.setFakeBoldText(false);
         }

         bool canUseRawPaths;

         if (otherBackendsWillDrawAsPaths || kMaxPerformance_RenderMode == renderMode) {
             // We can draw the glyphs from canonically sized paths.
             fTextRatio = fSkPaint.getTextSize() / SkPaint::kCanonicalTextSizeForPaths;
             fTextInverseRatio = SkPaint::kCanonicalTextSizeForPaths / fSkPaint.getTextSize();

             // Compensate for the glyphs being scaled by fTextRatio.
             if (!gpuStroke.isFillStyle()) {
                 gpuStroke.setStrokeStyle(gpuStroke.getWidth() / fTextRatio,
                                          SkStrokeRec::kStrokeAndFill_Style == gpuStroke.getStyle());
             }

             fSkPaint.setLinearText(true);
             fSkPaint.setLCDRenderText(false);
             fSkPaint.setAutohinted(false);
             fSkPaint.setHinting(SkPaint::kNo_Hinting);
             fSkPaint.setSubpixelText(true);
             fSkPaint.setTextSize(SkIntToScalar(SkPaint::kCanonicalTextSizeForPaths));

             canUseRawPaths = SK_Scalar1 == fSkPaint.getTextScaleX() &&
                              0 == fSkPaint.getTextSkewX() &&
                              !fSkPaint.isFakeBoldText() &&
                              !fSkPaint.isVerticalText();
         } else {
             fTextRatio = fTextInverseRatio = 1.0f;
             canUseRawPaths = false;
         }

         SkMatrix textMatrix;
         // Glyphs loaded by GPU path rendering have an inverted y-direction.
         textMatrix.setScale(fTextRatio, -fTextRatio);
         fPaint.localCoordChange(textMatrix);
         fContext->concatMatrix(textMatrix);

         fGlyphCache = fSkPaint.detachCache(&fDeviceProperties, NULL, false);
         fGlyphs = canUseRawPaths ?
                       get_gr_glyphs(fContext, fSkPaint.getTypeface(), NULL, gpuStroke) :
                       get_gr_glyphs(fContext, fGlyphCache->getScalerContext()->getTypeface(),
                                     &fGlyphCache->getDescriptor(), gpuStroke);
     }

     fStateRestore.set(fDrawTarget->drawState());

     fDrawTarget->drawState()->setFromPaint(fPaint, fContext->getMatrix(),
                                            fContext->getRenderTarget());

     GR_STATIC_CONST_SAME_STENCIL(kStencilPass,
                                  kZero_StencilOp,
                                  kZero_StencilOp,
                                  kNotEqual_StencilFunc,
                                  0xffff,
                                  0x0000,
                                  0xffff);

     *fDrawTarget->drawState()->stencil() = kStencilPass;

     SkASSERT(0 == fPendingGlyphCount);
 }

 inline void GrStencilAndCoverTextContext::appendGlyph(uint16_t glyphID, float x, float y) {
     if (fPendingGlyphCount >= kGlyphBufferSize) {
         this->flush();
     }

     fIndexBuffer[fPendingGlyphCount] = glyphID;
     fTransformBuffer[2 * fPendingGlyphCount] = fTextInverseRatio * x;
     fTransformBuffer[2 * fPendingGlyphCount + 1] = -fTextInverseRatio * y;

     ++fPendingGlyphCount;
 }

 void GrStencilAndCoverTextContext::flush() {
     if (0 == fPendingGlyphCount) {
         return;
     }

     fDrawTarget->drawPaths(fGlyphs, fIndexBuffer, fPendingGlyphCount, fTransformBuffer,
                            GrPathRendering::kTranslate_PathTransformType,
                            GrPathRendering::kWinding_FillType);

     fPendingGlyphCount = 0;
 }

 void GrStencilAndCoverTextContext::finish() {
     this->flush();

     fGlyphs->unref();
     fGlyphs = NULL;

     SkGlyphCache::AttachCache(fGlyphCache);
     fGlyphCache = NULL;

     fDrawTarget->drawState()->stencil()->setDisabled();
     fStateRestore.set(NULL);
     fContext->setMatrix(fContextInitialMatrix);
     GrTextContext::finish();
 }
	/*
	* Copyright 2014 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#include "GrStencilAndCoverTextContext.h"
	#include "GrBitmapTextContext.h"
	#include "GrDrawTarget.h"
	#include "GrGpu.h"
	#include "GrPath.h"
	#include "GrPathRange.h"
	#include "SkAutoKern.h"
	#include "SkDraw.h"
	#include "SkDrawProcs.h"
	#include "SkGlyphCache.h"
	#include "SkGpuDevice.h"
	#include "SkPath.h"
	#include "SkTextMapStateProc.h"
	#include "SkTextFormatParams.h"

	GrStencilAndCoverTextContext::GrStencilAndCoverTextContext(
	GrContext* context, const SkDeviceProperties& properties)
	: GrTextContext(context, properties)
	, fPendingGlyphCount(0) {
	}

	GrStencilAndCoverTextContext* GrStencilAndCoverTextContext::Create(GrContext* context,
	const SkDeviceProperties& props) {
	GrStencilAndCoverTextContext* textContext = SkNEW_ARGS(GrStencilAndCoverTextContext,
	(context, props));
	textContext->fFallbackTextContext = GrBitmapTextContext::Create(context, props);

	return textContext;
	}

	GrStencilAndCoverTextContext::~GrStencilAndCoverTextContext() {
	}

	bool GrStencilAndCoverTextContext::canDraw(const SkPaint& paint) {
	if (paint.getRasterizer()) {
	return false;
	}
	if (paint.getMaskFilter()) {
	return false;
	}
	if (paint.getPathEffect()) {
	return false;
	}

	// No hairlines unless we can map the 1 px width to the object space.
	if (paint.getStyle() == SkPaint::kStroke_Style
	&& paint.getStrokeWidth() == 0
	&& fContext->getMatrix().hasPerspective()) {
	return false;
	}

	// No color bitmap fonts.
	SkScalerContext::Rec rec;
	SkScalerContext::MakeRec(paint, &fDeviceProperties, NULL, &rec);
	return rec.getFormat() != SkMask::kARGB32_Format;
	}

	void GrStencilAndCoverTextContext::onDrawText(const GrPaint& paint,
	const SkPaint& skPaint,
	const char text[],
	size_t byteLength,
	SkScalar x, SkScalar y) {
	SkASSERT(byteLength == 0 \|\| text != NULL);

	if (text == NULL \|\| byteLength == 0 /\|\| fRC->isEmpty()/) {
	return;
	}

	// This is the slow path, mainly used by Skia unit tests. The other
	// backends (8888, gpu, ...) use device-space dependent glyph caches. In
	// order to match the glyph positions that the other code paths produce, we
	// must also use device-space dependent glyph cache. This has the
	// side-effect that the glyph shape outline will be in device-space,
	// too. This in turn has the side-effect that NVPR can not stroke the paths,
	// as the stroke in NVPR is defined in object-space.
	// NOTE: here we have following coincidence that works at the moment:
	// - When using the device-space glyphs, the transforms we pass to NVPR
	// instanced drawing are the global transforms, and the view transform is
	// identity. NVPR can not use non-affine transforms in the instanced
	// drawing. This is taken care of by SkDraw::ShouldDrawTextAsPaths since it
	// will turn off the use of device-space glyphs when perspective transforms
	// are in use.

	this->init(paint, skPaint, byteLength, kMaxAccuracy_RenderMode);

	// Transform our starting point.
	if (fNeedsDeviceSpaceGlyphs) {
	SkPoint loc;
	fContextInitialMatrix.mapXY(x, y, &loc);
	x = loc.fX;
	y = loc.fY;
	}

	SkDrawCacheProc glyphCacheProc = fSkPaint.getDrawCacheProc();

	const char* stop = text + byteLength;

	// Measure first if needed.
	if (fSkPaint.getTextAlign() != SkPaint::kLeft_Align) {
	SkFixed stopX = 0;
	SkFixed stopY = 0;

	const char* textPtr = text;
	while (textPtr < stop) {
	// We don't need x, y here, since all subpixel variants will have the
	// same advance.
	const SkGlyph& glyph = glyphCacheProc(fGlyphCache, &textPtr, 0, 0);

	stopX += glyph.fAdvanceX;
	stopY += glyph.fAdvanceY;
	}
	SkASSERT(textPtr == stop);

	SkScalar alignX = SkFixedToScalar(stopX) * fTextRatio;
	SkScalar alignY = SkFixedToScalar(stopY) * fTextRatio;

	if (fSkPaint.getTextAlign() == SkPaint::kCenter_Align) {
	alignX = SkScalarHalf(alignX);
	alignY = SkScalarHalf(alignY);
	}

	x -= alignX;
	y -= alignY;
	}

	SkAutoKern autokern;

	SkFixed fixedSizeRatio = SkScalarToFixed(fTextRatio);

	SkFixed fx = SkScalarToFixed(x);
	SkFixed fy = SkScalarToFixed(y);
	while (text < stop) {
	const SkGlyph& glyph = glyphCacheProc(fGlyphCache, &text, 0, 0);
	fx += SkFixedMul_portable(autokern.adjust(glyph), fixedSizeRatio);
	if (glyph.fWidth) {
	this->appendGlyph(glyph.getGlyphID(), SkFixedToScalar(fx), SkFixedToScalar(fy));
	}

	fx += SkFixedMul_portable(glyph.fAdvanceX, fixedSizeRatio);
	fy += SkFixedMul_portable(glyph.fAdvanceY, fixedSizeRatio);
	}

	this->finish();
	}

	void GrStencilAndCoverTextContext::onDrawPosText(const GrPaint& paint,
	const SkPaint& skPaint,
	const char text[],
	size_t byteLength,
	const SkScalar pos[],
	int scalarsPerPosition,
	const SkPoint& offset) {
	SkASSERT(byteLength == 0 \|\| text != NULL);
	SkASSERT(1 == scalarsPerPosition \|\| 2 == scalarsPerPosition);

	// nothing to draw
	if (text == NULL \|\| byteLength == 0/* \|\| fRC->isEmpty()*/) {
	return;
	}

	// This is the fast path. Here we do not bake in the device-transform to
	// the glyph outline or the advances. This is because we do not need to
	// position the glyphs at all, since the caller has done the positioning.
	// The positioning is based on SkPaint::measureText of individual
	// glyphs. That already uses glyph cache without device transforms. Device
	// transform is not part of SkPaint::measureText API, and thus we use the
	// same glyphs as what were measured.

	this->init(paint, skPaint, byteLength, kMaxPerformance_RenderMode);

	SkDrawCacheProc glyphCacheProc = fSkPaint.getDrawCacheProc();

	const char* stop = text + byteLength;

	SkTextMapStateProc tmsProc(SkMatrix::I(), offset, scalarsPerPosition);
	SkTextAlignProcScalar alignProc(fSkPaint.getTextAlign());
	while (text < stop) {
	const SkGlyph& glyph = glyphCacheProc(fGlyphCache, &text, 0, 0);
	if (glyph.fWidth) {
	SkPoint tmsLoc;
	tmsProc(pos, &tmsLoc);
	SkPoint loc;
	alignProc(tmsLoc, glyph, &loc);

	this->appendGlyph(glyph.getGlyphID(), loc.x(), loc.y());
	}
	pos += scalarsPerPosition;
	}

	this->finish();
	}

	static GrPathRange* get_gr_glyphs(GrContext* ctx,
	const SkTypeface* typeface,
	const SkDescriptor* desc,
	const SkStrokeRec& stroke) {
	static const GrCacheID::Domain gGlyphsDomain = GrCacheID::GenerateDomain();

	GrCacheID::Key key;
	uint64_t* keyData = key.fData64;
	keyData[0] = desc ? desc->getChecksum() : 0;
	keyData[0] = (keyData[0] << 32) \| (typeface ? typeface->uniqueID() : 0);
	keyData[1] = GrPath::ComputeStrokeKey(stroke);
	GrResourceKey resourceKey = GrResourceKey(GrCacheID(gGlyphsDomain, key),
	GrPathRange::resourceType(), 0);

	SkAutoTUnref<GrPathRange> glyphs(
	static_cast<GrPathRange*>(ctx->findAndRefCachedResource(resourceKey)));
	if (NULL == glyphs \|\| (NULL != desc && !glyphs->isEqualTo(*desc))) {
	glyphs.reset(ctx->getGpu()->pathRendering()->createGlyphs(typeface, desc, stroke));
	ctx->addResourceToCache(resourceKey, glyphs);
	}

	return glyphs.detach();
	}

	void GrStencilAndCoverTextContext::init(const GrPaint& paint,
	const SkPaint& skPaint,
	size_t textByteLength,
	RenderMode renderMode) {
	GrTextContext::init(paint, skPaint);

	fContextInitialMatrix = fContext->getMatrix();

	const bool otherBackendsWillDrawAsPaths =
	SkDraw::ShouldDrawTextAsPaths(skPaint, fContextInitialMatrix);

	fNeedsDeviceSpaceGlyphs = !otherBackendsWillDrawAsPaths &&
	kMaxAccuracy_RenderMode == renderMode &&
	SkToBool(fContextInitialMatrix.getType() &
	(SkMatrix::kScale_Mask \| SkMatrix::kAffine_Mask));

	if (fNeedsDeviceSpaceGlyphs) {
	// SkDraw::ShouldDrawTextAsPaths takes care of perspective transforms.
	SkASSERT(!fContextInitialMatrix.hasPerspective());

	fTextRatio = fTextInverseRatio = 1.0f;

	// Glyphs loaded by GPU path rendering have an inverted y-direction.
	SkMatrix m;
	m.setScale(1, -1);
	fContext->setMatrix(m);

	// Post-flip the initial matrix so we're left with just the flip after
	// the paint preConcats the inverse.
	m = fContextInitialMatrix;
	m.postScale(1, -1);
	fPaint.localCoordChangeInverse(m);

	// The whole shape (including stroke) will be baked into the glyph outlines. Make
	// NVPR just fill the baked shapes.
	fGlyphCache = fSkPaint.detachCache(&fDeviceProperties, &fContextInitialMatrix, false);
	fGlyphs = get_gr_glyphs(fContext, fGlyphCache->getScalerContext()->getTypeface(),
	&fGlyphCache->getDescriptor(),
	SkStrokeRec(SkStrokeRec::kFill_InitStyle));
	} else {
	// Don't bake strokes into the glyph outlines. We will stroke the glyphs
	// using the GPU instead. This is the fast path.
	SkStrokeRec gpuStroke = SkStrokeRec(fSkPaint);
	fSkPaint.setStyle(SkPaint::kFill_Style);

	if (gpuStroke.isHairlineStyle()) {
	// Approximate hairline stroke.
	SkScalar strokeWidth = SK_Scalar1 /
	(SkVector::Make(fContextInitialMatrix.getScaleX(),
	fContextInitialMatrix.getSkewY()).length());
	gpuStroke.setStrokeStyle(strokeWidth, false /strokeAndFill/);

	} else if (fSkPaint.isFakeBoldText() &&
	#ifdef SK_USE_FREETYPE_EMBOLDEN
	kMaxPerformance_RenderMode == renderMode &&
	#endif
	SkStrokeRec::kStroke_Style != gpuStroke.getStyle()) {

	// Instead of baking fake bold into the glyph outlines, do it with the GPU stroke.
	SkScalar fakeBoldScale = SkScalarInterpFunc(fSkPaint.getTextSize(),
	kStdFakeBoldInterpKeys,
	kStdFakeBoldInterpValues,
	kStdFakeBoldInterpLength);
	SkScalar extra = SkScalarMul(fSkPaint.getTextSize(), fakeBoldScale);
	gpuStroke.setStrokeStyle(gpuStroke.needToApply() ? gpuStroke.getWidth() + extra : extra,
	true /strokeAndFill/);

	fSkPaint.setFakeBoldText(false);
	}

	bool canUseRawPaths;

	if (otherBackendsWillDrawAsPaths \|\| kMaxPerformance_RenderMode == renderMode) {
	// We can draw the glyphs from canonically sized paths.
	fTextRatio = fSkPaint.getTextSize() / SkPaint::kCanonicalTextSizeForPaths;
	fTextInverseRatio = SkPaint::kCanonicalTextSizeForPaths / fSkPaint.getTextSize();

	// Compensate for the glyphs being scaled by fTextRatio.
	if (!gpuStroke.isFillStyle()) {
	gpuStroke.setStrokeStyle(gpuStroke.getWidth() / fTextRatio,
	SkStrokeRec::kStrokeAndFill_Style == gpuStroke.getStyle());
	}

	fSkPaint.setLinearText(true);
	fSkPaint.setLCDRenderText(false);
	fSkPaint.setAutohinted(false);
	fSkPaint.setHinting(SkPaint::kNo_Hinting);
	fSkPaint.setSubpixelText(true);
	fSkPaint.setTextSize(SkIntToScalar(SkPaint::kCanonicalTextSizeForPaths));

	canUseRawPaths = SK_Scalar1 == fSkPaint.getTextScaleX() &&
	0 == fSkPaint.getTextSkewX() &&
	!fSkPaint.isFakeBoldText() &&
	!fSkPaint.isVerticalText();
	} else {
	fTextRatio = fTextInverseRatio = 1.0f;
	canUseRawPaths = false;
	}

	SkMatrix textMatrix;
	// Glyphs loaded by GPU path rendering have an inverted y-direction.
	textMatrix.setScale(fTextRatio, -fTextRatio);
	fPaint.localCoordChange(textMatrix);
	fContext->concatMatrix(textMatrix);

	fGlyphCache = fSkPaint.detachCache(&fDeviceProperties, NULL, false);
	fGlyphs = canUseRawPaths ?
	get_gr_glyphs(fContext, fSkPaint.getTypeface(), NULL, gpuStroke) :
	get_gr_glyphs(fContext, fGlyphCache->getScalerContext()->getTypeface(),
	&fGlyphCache->getDescriptor(), gpuStroke);
	}

	fStateRestore.set(fDrawTarget->drawState());

	fDrawTarget->drawState()->setFromPaint(fPaint, fContext->getMatrix(),
	fContext->getRenderTarget());

	GR_STATIC_CONST_SAME_STENCIL(kStencilPass,
	kZero_StencilOp,
	kZero_StencilOp,
	kNotEqual_StencilFunc,
	0xffff,
	0x0000,
	0xffff);

	*fDrawTarget->drawState()->stencil() = kStencilPass;

	SkASSERT(0 == fPendingGlyphCount);
	}

	inline void GrStencilAndCoverTextContext::appendGlyph(uint16_t glyphID, float x, float y) {
	if (fPendingGlyphCount >= kGlyphBufferSize) {
	this->flush();
	}

	fIndexBuffer[fPendingGlyphCount] = glyphID;
	fTransformBuffer[2 * fPendingGlyphCount] = fTextInverseRatio * x;
	fTransformBuffer[2 * fPendingGlyphCount + 1] = -fTextInverseRatio * y;

	++fPendingGlyphCount;
	}

	void GrStencilAndCoverTextContext::flush() {
	if (0 == fPendingGlyphCount) {
	return;
	}

	fDrawTarget->drawPaths(fGlyphs, fIndexBuffer, fPendingGlyphCount, fTransformBuffer,
	GrPathRendering::kTranslate_PathTransformType,
	GrPathRendering::kWinding_FillType);

	fPendingGlyphCount = 0;
	}

	void GrStencilAndCoverTextContext::finish() {
	this->flush();

	fGlyphs->unref();
	fGlyphs = NULL;

	SkGlyphCache::AttachCache(fGlyphCache);
	fGlyphCache = NULL;

	fDrawTarget->drawState()->stencil()->setDisabled();
	fStateRestore.set(NULL);
	fContext->setMatrix(fContextInitialMatrix);
	GrTextContext::finish();
	}