third_party/skia/src/gpu/text/GrTextBlob.cpp - cobalt - Git at Google

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

 #include "include/core/SkColorFilter.h"
 #include "include/gpu/GrContext.h"
 #include "src/core/SkMaskFilterBase.h"
 #include "src/core/SkPaintPriv.h"
 #include "src/gpu/GrBlurUtils.h"
 #include "src/gpu/GrClip.h"
 #include "src/gpu/GrStyle.h"
 #include "src/gpu/geometry/GrShape.h"
 #include "src/gpu/ops/GrAtlasTextOp.h"
 #include "src/gpu/text/GrTextBlob.h"
 #include "src/gpu/text/GrTextTarget.h"

 #include <new>

 template <size_t N> static size_t sk_align(size_t s) {
     return ((s + (N-1)) / N) * N;
 }

 sk_sp<GrTextBlob> GrTextBlob::Make(int glyphCount,
                                    int runCount,
                                    GrColor color,
                                    GrStrikeCache* strikeCache) {
     // We allocate size for the GrTextBlob itself, plus size for the vertices array,
     // and size for the glyphIds array.
     size_t verticesCount = glyphCount * kVerticesPerGlyph * kMaxVASize;

     size_t blobStart = 0;
     size_t vertex = sk_align<alignof(char)>           (blobStart + sizeof(GrTextBlob) * 1);
     size_t glyphs = sk_align<alignof(GrGlyph*)>       (vertex + sizeof(char) * verticesCount);
     size_t   runs = sk_align<alignof(GrTextBlob::Run)>(glyphs + sizeof(GrGlyph*) * glyphCount);
     size_t   size =                                   (runs + sizeof(GrTextBlob::Run) * runCount);

     void* allocation = ::operator new (size);

     if (CACHE_SANITY_CHECK) {
         sk_bzero(allocation, size);
     }

     sk_sp<GrTextBlob> blob{new (allocation) GrTextBlob{strikeCache}};
     blob->fSize = size;

     // setup offsets for vertices / glyphs
     blob->fVertices = SkTAddOffset<char>(blob.get(), vertex);
     blob->fGlyphs = SkTAddOffset<GrGlyph*>(blob.get(), glyphs);
     blob->fRuns = SkTAddOffset<GrTextBlob::Run>(blob.get(), runs);

     // Initialize runs
     for (int i = 0; i < runCount; i++) {
         new (&blob->fRuns[i]) GrTextBlob::Run{blob.get(), color};
     }
     blob->fRunCountLimit = runCount;
     return blob;
 }

 void GrTextBlob::Run::setupFont(const SkStrikeSpec& strikeSpec) {

     if (fFallbackStrikeSpec != nullptr) {
         *fFallbackStrikeSpec = strikeSpec;
     } else {
         fStrikeSpec = strikeSpec;
     }
 }

 void GrTextBlob::Run::appendPathGlyph(const SkPath& path, SkPoint position,
                                       SkScalar scale, bool preTransformed) {
     fPathGlyphs.push_back(PathGlyph(path, position.x(), position.y(), scale, preTransformed));
 }

 bool GrTextBlob::mustRegenerate(const SkPaint& paint, bool anyRunHasSubpixelPosition,
                                 const SkMaskFilterBase::BlurRec& blurRec,
                                 const SkMatrix& viewMatrix, SkScalar x, SkScalar y) {
     // If we have LCD text then our canonical color will be set to transparent, in this case we have
     // to regenerate the blob on any color change
     // We use the grPaint to get any color filter effects
     if (fKey.fCanonicalColor == SK_ColorTRANSPARENT &&
         fLuminanceColor != SkPaintPriv::ComputeLuminanceColor(paint)) {
         return true;
     }

     if (fInitialViewMatrix.hasPerspective() != viewMatrix.hasPerspective()) {
         return true;
     }

     /** This could be relaxed for blobs with only distance field glyphs. */
     if (fInitialViewMatrix.hasPerspective() && !fInitialViewMatrix.cheapEqualTo(viewMatrix)) {
         return true;
     }

     // We only cache one masked version
     if (fKey.fHasBlur &&
         (fBlurRec.fSigma != blurRec.fSigma || fBlurRec.fStyle != blurRec.fStyle)) {
         return true;
     }

     // Similarly, we only cache one version for each style
     if (fKey.fStyle != SkPaint::kFill_Style &&
         (fStrokeInfo.fFrameWidth != paint.getStrokeWidth() ||
          fStrokeInfo.fMiterLimit != paint.getStrokeMiter() ||
          fStrokeInfo.fJoin != paint.getStrokeJoin())) {
         return true;
     }

     // Mixed blobs must be regenerated.  We could probably figure out a way to do integer scrolls
     // for mixed blobs if this becomes an issue.
     if (this->hasBitmap() && this->hasDistanceField()) {
         // Identical viewmatrices and we can reuse in all cases
         if (fInitialViewMatrix.cheapEqualTo(viewMatrix) && x == fInitialX && y == fInitialY) {
             return false;
         }
         return true;
     }

     if (this->hasBitmap()) {
         if (fInitialViewMatrix.getScaleX() != viewMatrix.getScaleX() ||
             fInitialViewMatrix.getScaleY() != viewMatrix.getScaleY() ||
             fInitialViewMatrix.getSkewX() != viewMatrix.getSkewX() ||
             fInitialViewMatrix.getSkewY() != viewMatrix.getSkewY()) {
             return true;
         }

         // TODO(herb): this is not needed for full pixel glyph choice, but is needed to adjust
         //  the quads properly. Devise a system that regenerates the quads from original data
         //  using the transform to allow this to be used in general.

         // We can update the positions in the text blob without regenerating the whole
         // blob, but only for integer translations.
         // This cool bit of math will determine the necessary translation to apply to the
         // already generated vertex coordinates to move them to the correct position.
         // Figure out the translation in view space given a translation in source space.
         SkScalar transX = viewMatrix.getTranslateX() +
                           viewMatrix.getScaleX() * (x - fInitialX) +
                           viewMatrix.getSkewX() * (y - fInitialY) -
                           fInitialViewMatrix.getTranslateX();
         SkScalar transY = viewMatrix.getTranslateY() +
                           viewMatrix.getSkewY() * (x - fInitialX) +
                           viewMatrix.getScaleY() * (y - fInitialY) -
                           fInitialViewMatrix.getTranslateY();
         if (!SkScalarIsInt(transX) || !SkScalarIsInt(transY)) {
             return true;
         }
     } else if (this->hasDistanceField()) {
         // A scale outside of [blob.fMaxMinScale, blob.fMinMaxScale] would result in a different
         // distance field being generated, so we have to regenerate in those cases
         SkScalar newMaxScale = viewMatrix.getMaxScale();
         SkScalar oldMaxScale = fInitialViewMatrix.getMaxScale();
         SkScalar scaleAdjust = newMaxScale / oldMaxScale;
         if (scaleAdjust < fMaxMinScale || scaleAdjust > fMinMaxScale) {
             return true;
         }
     }

     // It is possible that a blob has neither distanceField nor bitmaptext.  This is in the case
     // when all of the runs inside the blob are drawn as paths.  In this case, we always regenerate
     // the blob anyways at flush time, so no need to regenerate explicitly
     return false;
 }

 inline std::unique_ptr<GrAtlasTextOp> GrTextBlob::makeOp(
         const SubRun& info, int glyphCount, uint16_t run, uint16_t subRun,
         const SkMatrix& viewMatrix, SkScalar x, SkScalar y, const SkIRect& clipRect,
         const SkPaint& paint, const SkPMColor4f& filteredColor, const SkSurfaceProps& props,
         const GrDistanceFieldAdjustTable* distanceAdjustTable, GrTextTarget* target) {
     GrMaskFormat format = info.maskFormat();

     GrPaint grPaint;
     target->makeGrPaint(info.maskFormat(), paint, viewMatrix, &grPaint);
     std::unique_ptr<GrAtlasTextOp> op;
     if (info.drawAsDistanceFields()) {
         // TODO: Can we be even smarter based on the dest transfer function?
         op = GrAtlasTextOp::MakeDistanceField(
                 target->getContext(), std::move(grPaint), glyphCount, distanceAdjustTable,
                 target->colorInfo().isLinearlyBlended(), SkPaintPriv::ComputeLuminanceColor(paint),
                 props, info.isAntiAliased(), info.hasUseLCDText());
     } else {
         op = GrAtlasTextOp::MakeBitmap(target->getContext(), std::move(grPaint), format, glyphCount,
                                        info.needsTransform());
     }
     GrAtlasTextOp::Geometry& geometry = op->geometry();
     geometry.fViewMatrix = viewMatrix;
     geometry.fClipRect = clipRect;
     geometry.fBlob = SkRef(this);
     geometry.fRun = run;
     geometry.fSubRun = subRun;
     geometry.fColor = info.maskFormat() == kARGB_GrMaskFormat ? SK_PMColor4fWHITE : filteredColor;
     geometry.fX = x;
     geometry.fY = y;
     op->init();
     return op;
 }

 static void calculate_translation(bool applyVM,
                                   const SkMatrix& newViewMatrix, SkScalar newX, SkScalar newY,
                                   const SkMatrix& currentViewMatrix, SkScalar currentX,
                                   SkScalar currentY, SkScalar* transX, SkScalar* transY) {
     if (applyVM) {
         *transX = newViewMatrix.getTranslateX() +
                   newViewMatrix.getScaleX() * (newX - currentX) +
                   newViewMatrix.getSkewX() * (newY - currentY) -
                   currentViewMatrix.getTranslateX();

         *transY = newViewMatrix.getTranslateY() +
                   newViewMatrix.getSkewY() * (newX - currentX) +
                   newViewMatrix.getScaleY() * (newY - currentY) -
                   currentViewMatrix.getTranslateY();
     } else {
         *transX = newX - currentX;
         *transY = newY - currentY;
     }
 }

 void GrTextBlob::flush(GrTextTarget* target, const SkSurfaceProps& props,
                        const GrDistanceFieldAdjustTable* distanceAdjustTable,
                        const SkPaint& paint, const SkPMColor4f& filteredColor, const GrClip& clip,
                        const SkMatrix& viewMatrix, SkScalar x, SkScalar y) {

     // GrTextBlob::makeOp only takes uint16_t values for run and subRun indices.
     // Encountering something larger than this is highly unlikely, so we'll just not draw it.
     int lastRun = SkTMin(fRunCountLimit, (1 << 16)) - 1;
     // For each run in the GrTextBlob we're going to churn through all the glyphs.
     // Each run is broken into a path part and a Mask / DFT / ARGB part.
     for (int runIndex = 0; runIndex <= lastRun; runIndex++) {

         Run& run = fRuns[runIndex];

         // first flush any path glyphs
         if (run.fPathGlyphs.count()) {
             SkPaint runPaint{paint};
             runPaint.setAntiAlias(run.fAntiAlias);

             for (int i = 0; i < run.fPathGlyphs.count(); i++) {
                 GrTextBlob::Run::PathGlyph& pathGlyph = run.fPathGlyphs[i];

                 SkMatrix ctm;
                 const SkPath* path = &pathGlyph.fPath;

                 // TmpPath must be in the same scope as GrShape shape below.
                 SkTLazy<SkPath> tmpPath;

                 // The glyph positions and glyph outlines are either in device space or in source
                 // space based on fPreTransformed.
                 if (!pathGlyph.fPreTransformed) {
                     // Positions and outlines are in source space.

                     ctm = viewMatrix;

                     SkMatrix pathMatrix = SkMatrix::MakeScale(pathGlyph.fScale, pathGlyph.fScale);

                     // The origin for the blob may have changed, so figure out the delta.
                     SkVector originShift = SkPoint{x, y} - SkPoint{fInitialX, fInitialY};

                     // Shift the original glyph location in source space to the position of the new
                     // blob.
                     pathMatrix.postTranslate(originShift.x() + pathGlyph.fX,
                                              originShift.y() + pathGlyph.fY);

                     // If there are shaders, blurs or styles, the path must be scaled into source
                     // space independently of the CTM. This allows the CTM to be correct for the
                     // different effects.
                     GrStyle style(runPaint);
                     bool scalePath = runPaint.getShader()
                                      || style.applies()
                                      || runPaint.getMaskFilter();
                     if (!scalePath) {
                         // Scale can be applied to CTM -- no effects.

                         ctm.preConcat(pathMatrix);
                     } else {
                         // Scale the outline into source space.

                         // Transform the path form the normalized outline to source space. This
                         // way the CTM will remain the same so it can be used by the effects.
                         SkPath* sourceOutline = tmpPath.init();
                         path->transform(pathMatrix, sourceOutline);
                         sourceOutline->setIsVolatile(true);
                         path = sourceOutline;
                     }


                 } else {
                     // Positions and outlines are in device space.

                     SkPoint originalOrigin = {fInitialX, fInitialY};
                     fInitialViewMatrix.mapPoints(&originalOrigin, 1);

                     SkPoint newOrigin = {x, y};
                     viewMatrix.mapPoints(&newOrigin, 1);

                     // The origin shift in device space.
                     SkPoint originShift = newOrigin - originalOrigin;

                     // Shift the original glyph location in device space to the position of the
                     // new blob.
                     ctm = SkMatrix::MakeTrans(originShift.x() + pathGlyph.fX,
                                               originShift.y() + pathGlyph.fY);
                 }

                 // TODO: we are losing the mutability of the path here
                 GrShape shape(*path, paint);

                 target->drawShape(clip, runPaint, ctm, shape);
             }
         }

         // then flush each subrun, if any
         if (!run.fInitialized) {
             continue;
         }

         int lastSubRun = SkTMin(run.fSubRunInfo.count(), 1 << 16) - 1;
         for (int subRun = 0; subRun <= lastSubRun; subRun++) {
             const SubRun& info = run.fSubRunInfo[subRun];
             int glyphCount = info.glyphCount();
             if (0 == glyphCount) {
                 continue;
             }

             bool skipClip = false;
             bool submitOp = true;
             SkIRect clipRect = SkIRect::MakeEmpty();
             SkRect rtBounds = SkRect::MakeWH(target->width(), target->height());
             SkRRect clipRRect;
             GrAA aa;
             // We can clip geometrically if we're not using SDFs or transformed glyphs,
             // and we have an axis-aligned rectangular non-AA clip
             if (!info.drawAsDistanceFields() && !info.needsTransform() &&
                 clip.isRRect(rtBounds, &clipRRect, &aa) &&
                 clipRRect.isRect() && GrAA::kNo == aa) {
                 skipClip = true;
                 // We only need to do clipping work if the subrun isn't contained by the clip
                 SkRect subRunBounds;
                 this->computeSubRunBounds(&subRunBounds, runIndex, subRun, viewMatrix, x, y,
                                           false);
                 if (!clipRRect.getBounds().contains(subRunBounds)) {
                     // If the subrun is completely outside, don't add an op for it
                     if (!clipRRect.getBounds().intersects(subRunBounds)) {
                         submitOp = false;
                     }
                     else {
                         clipRRect.getBounds().round(&clipRect);
                     }
                 }
             }

             if (submitOp) {
                 auto op = this->makeOp(info, glyphCount, runIndex, subRun, viewMatrix, x, y,
                                        clipRect, paint, filteredColor, props, distanceAdjustTable,
                                        target);
                 if (op) {
                     if (skipClip) {
                         target->addDrawOp(GrNoClip(), std::move(op));
                     }
                     else {
                         target->addDrawOp(clip, std::move(op));
                     }
                 }
             }
         }

     }
 }

 std::unique_ptr<GrDrawOp> GrTextBlob::test_makeOp(
         int glyphCount, uint16_t run, uint16_t subRun, const SkMatrix& viewMatrix,
         SkScalar x, SkScalar y, const SkPaint& paint, const SkPMColor4f& filteredColor,
         const SkSurfaceProps& props, const GrDistanceFieldAdjustTable* distanceAdjustTable,
         GrTextTarget* target) {
     const GrTextBlob::SubRun& info = fRuns[run].fSubRunInfo[subRun];
     SkIRect emptyRect = SkIRect::MakeEmpty();
     return this->makeOp(info, glyphCount, run, subRun, viewMatrix, x, y, emptyRect,
                         paint, filteredColor, props, distanceAdjustTable, target);
 }

 void GrTextBlob::AssertEqual(const GrTextBlob& l, const GrTextBlob& r) {
     SkASSERT_RELEASE(l.fSize == r.fSize);

     SkASSERT_RELEASE(l.fBlurRec.fSigma == r.fBlurRec.fSigma);
     SkASSERT_RELEASE(l.fBlurRec.fStyle == r.fBlurRec.fStyle);

     SkASSERT_RELEASE(l.fStrokeInfo.fFrameWidth == r.fStrokeInfo.fFrameWidth);
     SkASSERT_RELEASE(l.fStrokeInfo.fMiterLimit == r.fStrokeInfo.fMiterLimit);
     SkASSERT_RELEASE(l.fStrokeInfo.fJoin == r.fStrokeInfo.fJoin);

     SkASSERT_RELEASE(l.fKey == r.fKey);
     //SkASSERT_RELEASE(l.fPaintColor == r.fPaintColor); // Colors might not actually be identical
     SkASSERT_RELEASE(l.fMaxMinScale == r.fMaxMinScale);
     SkASSERT_RELEASE(l.fMinMaxScale == r.fMinMaxScale);
     SkASSERT_RELEASE(l.fTextType == r.fTextType);

     SkASSERT_RELEASE(l.fRunCountLimit == r.fRunCountLimit);
     for (int i = 0; i < l.fRunCountLimit; i++) {
         const Run& lRun = l.fRuns[i];
         const Run& rRun = r.fRuns[i];

         SkASSERT_RELEASE(lRun.fStrikeSpec.descriptor() == rRun.fStrikeSpec.descriptor());

         // color can be changed
         //SkASSERT(lRun.fColor == rRun.fColor);
         SkASSERT_RELEASE(lRun.fInitialized == rRun.fInitialized);

         SkASSERT_RELEASE(lRun.fSubRunInfo.count() == rRun.fSubRunInfo.count());
         for(int j = 0; j < lRun.fSubRunInfo.count(); j++) {
             const SubRun& lSubRun = lRun.fSubRunInfo[j];
             const SubRun& rSubRun = rRun.fSubRunInfo[j];

             // TODO we can do this check, but we have to apply the VM to the old vertex bounds
             //SkASSERT_RELEASE(lSubRun.vertexBounds() == rSubRun.vertexBounds());

             if (lSubRun.strike()) {
                 SkASSERT_RELEASE(rSubRun.strike());
                 SkASSERT_RELEASE(GrTextStrike::GetKey(*lSubRun.strike()) ==
                                  GrTextStrike::GetKey(*rSubRun.strike()));

             } else {
                 SkASSERT_RELEASE(!rSubRun.strike());
             }

             SkASSERT_RELEASE(lSubRun.vertexStartIndex() == rSubRun.vertexStartIndex());
             SkASSERT_RELEASE(lSubRun.vertexEndIndex() == rSubRun.vertexEndIndex());
             SkASSERT_RELEASE(lSubRun.glyphStartIndex() == rSubRun.glyphStartIndex());
             SkASSERT_RELEASE(lSubRun.glyphEndIndex() == rSubRun.glyphEndIndex());
             SkASSERT_RELEASE(lSubRun.maskFormat() == rSubRun.maskFormat());
             SkASSERT_RELEASE(lSubRun.drawAsDistanceFields() == rSubRun.drawAsDistanceFields());
             SkASSERT_RELEASE(lSubRun.hasUseLCDText() == rSubRun.hasUseLCDText());
         }

         SkASSERT_RELEASE(lRun.fPathGlyphs.count() == rRun.fPathGlyphs.count());
         for (int i = 0; i < lRun.fPathGlyphs.count(); i++) {
             const Run::PathGlyph& lPathGlyph = lRun.fPathGlyphs[i];
             const Run::PathGlyph& rPathGlyph = rRun.fPathGlyphs[i];

             SkASSERT_RELEASE(lPathGlyph.fPath == rPathGlyph.fPath);
             // We can't assert that these have the same translations
         }
     }
 }

 void GrTextBlob::SubRun::computeTranslation(const SkMatrix& viewMatrix,
                                                 SkScalar x, SkScalar y, SkScalar* transX,
                                                 SkScalar* transY) {
     // Don't use the matrix to translate on distance field for fallback subruns.
     calculate_translation(!this->drawAsDistanceFields() && !this->isFallback(), viewMatrix,
             x, y, fCurrentViewMatrix, fX, fY, transX, transY);
     fCurrentViewMatrix = viewMatrix;
     fX = x;
     fY = y;
 }
	/*
	* Copyright 2015 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#include "include/core/SkColorFilter.h"
	#include "include/gpu/GrContext.h"
	#include "src/core/SkMaskFilterBase.h"
	#include "src/core/SkPaintPriv.h"
	#include "src/gpu/GrBlurUtils.h"
	#include "src/gpu/GrClip.h"
	#include "src/gpu/GrStyle.h"
	#include "src/gpu/geometry/GrShape.h"
	#include "src/gpu/ops/GrAtlasTextOp.h"
	#include "src/gpu/text/GrTextBlob.h"
	#include "src/gpu/text/GrTextTarget.h"

	#include <new>

	template <size_t N> static size_t sk_align(size_t s) {
	return ((s + (N-1)) / N) * N;
	}

	sk_sp<GrTextBlob> GrTextBlob::Make(int glyphCount,
	int runCount,
	GrColor color,
	GrStrikeCache* strikeCache) {
	// We allocate size for the GrTextBlob itself, plus size for the vertices array,
	// and size for the glyphIds array.
	size_t verticesCount = glyphCount * kVerticesPerGlyph * kMaxVASize;

	size_t blobStart = 0;
	size_t vertex = sk_align<alignof(char)> (blobStart + sizeof(GrTextBlob) * 1);
	size_t glyphs = sk_align<alignof(GrGlyph)> (vertex + sizeof(char) verticesCount);
	size_t runs = sk_align<alignof(GrTextBlob::Run)>(glyphs + sizeof(GrGlyph) glyphCount);
	size_t size = (runs + sizeof(GrTextBlob::Run) * runCount);

	void* allocation = ::operator new (size);

	if (CACHE_SANITY_CHECK) {
	sk_bzero(allocation, size);
	}

	sk_sp<GrTextBlob> blob{new (allocation) GrTextBlob{strikeCache}};
	blob->fSize = size;

	// setup offsets for vertices / glyphs
	blob->fVertices = SkTAddOffset<char>(blob.get(), vertex);
	blob->fGlyphs = SkTAddOffset<GrGlyph*>(blob.get(), glyphs);
	blob->fRuns = SkTAddOffset<GrTextBlob::Run>(blob.get(), runs);

	// Initialize runs
	for (int i = 0; i < runCount; i++) {
	new (&blob->fRuns[i]) GrTextBlob::Run{blob.get(), color};
	}
	blob->fRunCountLimit = runCount;
	return blob;
	}

	void GrTextBlob::Run::setupFont(const SkStrikeSpec& strikeSpec) {

	if (fFallbackStrikeSpec != nullptr) {
	*fFallbackStrikeSpec = strikeSpec;
	} else {
	fStrikeSpec = strikeSpec;
	}
	}

	void GrTextBlob::Run::appendPathGlyph(const SkPath& path, SkPoint position,
	SkScalar scale, bool preTransformed) {
	fPathGlyphs.push_back(PathGlyph(path, position.x(), position.y(), scale, preTransformed));
	}

	bool GrTextBlob::mustRegenerate(const SkPaint& paint, bool anyRunHasSubpixelPosition,
	const SkMaskFilterBase::BlurRec& blurRec,
	const SkMatrix& viewMatrix, SkScalar x, SkScalar y) {
	// If we have LCD text then our canonical color will be set to transparent, in this case we have
	// to regenerate the blob on any color change
	// We use the grPaint to get any color filter effects
	if (fKey.fCanonicalColor == SK_ColorTRANSPARENT &&
	fLuminanceColor != SkPaintPriv::ComputeLuminanceColor(paint)) {
	return true;
	}

	if (fInitialViewMatrix.hasPerspective() != viewMatrix.hasPerspective()) {
	return true;
	}

	/** This could be relaxed for blobs with only distance field glyphs. */
	if (fInitialViewMatrix.hasPerspective() && !fInitialViewMatrix.cheapEqualTo(viewMatrix)) {
	return true;
	}

	// We only cache one masked version
	if (fKey.fHasBlur &&
	(fBlurRec.fSigma != blurRec.fSigma \|\| fBlurRec.fStyle != blurRec.fStyle)) {
	return true;
	}

	// Similarly, we only cache one version for each style
	if (fKey.fStyle != SkPaint::kFill_Style &&
	(fStrokeInfo.fFrameWidth != paint.getStrokeWidth() \|\|
	fStrokeInfo.fMiterLimit != paint.getStrokeMiter() \|\|
	fStrokeInfo.fJoin != paint.getStrokeJoin())) {
	return true;
	}

	// Mixed blobs must be regenerated. We could probably figure out a way to do integer scrolls
	// for mixed blobs if this becomes an issue.
	if (this->hasBitmap() && this->hasDistanceField()) {
	// Identical viewmatrices and we can reuse in all cases
	if (fInitialViewMatrix.cheapEqualTo(viewMatrix) && x == fInitialX && y == fInitialY) {
	return false;
	}
	return true;
	}

	if (this->hasBitmap()) {
	if (fInitialViewMatrix.getScaleX() != viewMatrix.getScaleX() \|\|
	fInitialViewMatrix.getScaleY() != viewMatrix.getScaleY() \|\|
	fInitialViewMatrix.getSkewX() != viewMatrix.getSkewX() \|\|
	fInitialViewMatrix.getSkewY() != viewMatrix.getSkewY()) {
	return true;
	}

	// TODO(herb): this is not needed for full pixel glyph choice, but is needed to adjust
	// the quads properly. Devise a system that regenerates the quads from original data
	// using the transform to allow this to be used in general.

	// We can update the positions in the text blob without regenerating the whole
	// blob, but only for integer translations.
	// This cool bit of math will determine the necessary translation to apply to the
	// already generated vertex coordinates to move them to the correct position.
	// Figure out the translation in view space given a translation in source space.
	SkScalar transX = viewMatrix.getTranslateX() +
	viewMatrix.getScaleX() * (x - fInitialX) +
	viewMatrix.getSkewX() * (y - fInitialY) -
	fInitialViewMatrix.getTranslateX();
	SkScalar transY = viewMatrix.getTranslateY() +
	viewMatrix.getSkewY() * (x - fInitialX) +
	viewMatrix.getScaleY() * (y - fInitialY) -
	fInitialViewMatrix.getTranslateY();
	if (!SkScalarIsInt(transX) \|\| !SkScalarIsInt(transY)) {
	return true;
	}
	} else if (this->hasDistanceField()) {
	// A scale outside of [blob.fMaxMinScale, blob.fMinMaxScale] would result in a different
	// distance field being generated, so we have to regenerate in those cases
	SkScalar newMaxScale = viewMatrix.getMaxScale();
	SkScalar oldMaxScale = fInitialViewMatrix.getMaxScale();
	SkScalar scaleAdjust = newMaxScale / oldMaxScale;
	if (scaleAdjust < fMaxMinScale \|\| scaleAdjust > fMinMaxScale) {
	return true;
	}
	}

	// It is possible that a blob has neither distanceField nor bitmaptext. This is in the case
	// when all of the runs inside the blob are drawn as paths. In this case, we always regenerate
	// the blob anyways at flush time, so no need to regenerate explicitly
	return false;
	}

	inline std::unique_ptr<GrAtlasTextOp> GrTextBlob::makeOp(
	const SubRun& info, int glyphCount, uint16_t run, uint16_t subRun,
	const SkMatrix& viewMatrix, SkScalar x, SkScalar y, const SkIRect& clipRect,
	const SkPaint& paint, const SkPMColor4f& filteredColor, const SkSurfaceProps& props,
	const GrDistanceFieldAdjustTable* distanceAdjustTable, GrTextTarget* target) {
	GrMaskFormat format = info.maskFormat();

	GrPaint grPaint;
	target->makeGrPaint(info.maskFormat(), paint, viewMatrix, &grPaint);
	std::unique_ptr<GrAtlasTextOp> op;
	if (info.drawAsDistanceFields()) {
	// TODO: Can we be even smarter based on the dest transfer function?
	op = GrAtlasTextOp::MakeDistanceField(
	target->getContext(), std::move(grPaint), glyphCount, distanceAdjustTable,
	target->colorInfo().isLinearlyBlended(), SkPaintPriv::ComputeLuminanceColor(paint),
	props, info.isAntiAliased(), info.hasUseLCDText());
	} else {
	op = GrAtlasTextOp::MakeBitmap(target->getContext(), std::move(grPaint), format, glyphCount,
	info.needsTransform());
	}
	GrAtlasTextOp::Geometry& geometry = op->geometry();
	geometry.fViewMatrix = viewMatrix;
	geometry.fClipRect = clipRect;
	geometry.fBlob = SkRef(this);
	geometry.fRun = run;
	geometry.fSubRun = subRun;
	geometry.fColor = info.maskFormat() == kARGB_GrMaskFormat ? SK_PMColor4fWHITE : filteredColor;
	geometry.fX = x;
	geometry.fY = y;
	op->init();
	return op;
	}

	static void calculate_translation(bool applyVM,
	const SkMatrix& newViewMatrix, SkScalar newX, SkScalar newY,
	const SkMatrix& currentViewMatrix, SkScalar currentX,
	SkScalar currentY, SkScalar* transX, SkScalar* transY) {
	if (applyVM) {
	*transX = newViewMatrix.getTranslateX() +
	newViewMatrix.getScaleX() * (newX - currentX) +
	newViewMatrix.getSkewX() * (newY - currentY) -
	currentViewMatrix.getTranslateX();

	*transY = newViewMatrix.getTranslateY() +
	newViewMatrix.getSkewY() * (newX - currentX) +
	newViewMatrix.getScaleY() * (newY - currentY) -
	currentViewMatrix.getTranslateY();
	} else {
	*transX = newX - currentX;
	*transY = newY - currentY;
	}
	}

	void GrTextBlob::flush(GrTextTarget* target, const SkSurfaceProps& props,
	const GrDistanceFieldAdjustTable* distanceAdjustTable,
	const SkPaint& paint, const SkPMColor4f& filteredColor, const GrClip& clip,
	const SkMatrix& viewMatrix, SkScalar x, SkScalar y) {

	// GrTextBlob::makeOp only takes uint16_t values for run and subRun indices.
	// Encountering something larger than this is highly unlikely, so we'll just not draw it.
	int lastRun = SkTMin(fRunCountLimit, (1 << 16)) - 1;
	// For each run in the GrTextBlob we're going to churn through all the glyphs.
	// Each run is broken into a path part and a Mask / DFT / ARGB part.
	for (int runIndex = 0; runIndex <= lastRun; runIndex++) {

	Run& run = fRuns[runIndex];

	// first flush any path glyphs
	if (run.fPathGlyphs.count()) {
	SkPaint runPaint{paint};
	runPaint.setAntiAlias(run.fAntiAlias);

	for (int i = 0; i < run.fPathGlyphs.count(); i++) {
	GrTextBlob::Run::PathGlyph& pathGlyph = run.fPathGlyphs[i];

	SkMatrix ctm;
	const SkPath* path = &pathGlyph.fPath;

	// TmpPath must be in the same scope as GrShape shape below.
	SkTLazy<SkPath> tmpPath;

	// The glyph positions and glyph outlines are either in device space or in source
	// space based on fPreTransformed.
	if (!pathGlyph.fPreTransformed) {
	// Positions and outlines are in source space.

	ctm = viewMatrix;

	SkMatrix pathMatrix = SkMatrix::MakeScale(pathGlyph.fScale, pathGlyph.fScale);

	// The origin for the blob may have changed, so figure out the delta.
	SkVector originShift = SkPoint{x, y} - SkPoint{fInitialX, fInitialY};

	// Shift the original glyph location in source space to the position of the new
	// blob.
	pathMatrix.postTranslate(originShift.x() + pathGlyph.fX,
	originShift.y() + pathGlyph.fY);

	// If there are shaders, blurs or styles, the path must be scaled into source
	// space independently of the CTM. This allows the CTM to be correct for the
	// different effects.
	GrStyle style(runPaint);
	bool scalePath = runPaint.getShader()
	\|\| style.applies()
	\|\| runPaint.getMaskFilter();
	if (!scalePath) {
	// Scale can be applied to CTM -- no effects.

	ctm.preConcat(pathMatrix);
	} else {
	// Scale the outline into source space.

	// Transform the path form the normalized outline to source space. This
	// way the CTM will remain the same so it can be used by the effects.
	SkPath* sourceOutline = tmpPath.init();
	path->transform(pathMatrix, sourceOutline);
	sourceOutline->setIsVolatile(true);
	path = sourceOutline;
	}


	} else {
	// Positions and outlines are in device space.

	SkPoint originalOrigin = {fInitialX, fInitialY};
	fInitialViewMatrix.mapPoints(&originalOrigin, 1);

	SkPoint newOrigin = {x, y};
	viewMatrix.mapPoints(&newOrigin, 1);

	// The origin shift in device space.
	SkPoint originShift = newOrigin - originalOrigin;

	// Shift the original glyph location in device space to the position of the
	// new blob.
	ctm = SkMatrix::MakeTrans(originShift.x() + pathGlyph.fX,
	originShift.y() + pathGlyph.fY);
	}

	// TODO: we are losing the mutability of the path here
	GrShape shape(*path, paint);

	target->drawShape(clip, runPaint, ctm, shape);
	}
	}

	// then flush each subrun, if any
	if (!run.fInitialized) {
	continue;
	}

	int lastSubRun = SkTMin(run.fSubRunInfo.count(), 1 << 16) - 1;
	for (int subRun = 0; subRun <= lastSubRun; subRun++) {
	const SubRun& info = run.fSubRunInfo[subRun];
	int glyphCount = info.glyphCount();
	if (0 == glyphCount) {
	continue;
	}

	bool skipClip = false;
	bool submitOp = true;
	SkIRect clipRect = SkIRect::MakeEmpty();
	SkRect rtBounds = SkRect::MakeWH(target->width(), target->height());
	SkRRect clipRRect;
	GrAA aa;
	// We can clip geometrically if we're not using SDFs or transformed glyphs,
	// and we have an axis-aligned rectangular non-AA clip
	if (!info.drawAsDistanceFields() && !info.needsTransform() &&
	clip.isRRect(rtBounds, &clipRRect, &aa) &&
	clipRRect.isRect() && GrAA::kNo == aa) {
	skipClip = true;
	// We only need to do clipping work if the subrun isn't contained by the clip
	SkRect subRunBounds;
	this->computeSubRunBounds(&subRunBounds, runIndex, subRun, viewMatrix, x, y,
	false);
	if (!clipRRect.getBounds().contains(subRunBounds)) {
	// If the subrun is completely outside, don't add an op for it
	if (!clipRRect.getBounds().intersects(subRunBounds)) {
	submitOp = false;
	}
	else {
	clipRRect.getBounds().round(&clipRect);
	}
	}
	}

	if (submitOp) {
	auto op = this->makeOp(info, glyphCount, runIndex, subRun, viewMatrix, x, y,
	clipRect, paint, filteredColor, props, distanceAdjustTable,
	target);
	if (op) {
	if (skipClip) {
	target->addDrawOp(GrNoClip(), std::move(op));
	}
	else {
	target->addDrawOp(clip, std::move(op));
	}
	}
	}
	}

	}
	}

	std::unique_ptr<GrDrawOp> GrTextBlob::test_makeOp(
	int glyphCount, uint16_t run, uint16_t subRun, const SkMatrix& viewMatrix,
	SkScalar x, SkScalar y, const SkPaint& paint, const SkPMColor4f& filteredColor,
	const SkSurfaceProps& props, const GrDistanceFieldAdjustTable* distanceAdjustTable,
	GrTextTarget* target) {
	const GrTextBlob::SubRun& info = fRuns[run].fSubRunInfo[subRun];
	SkIRect emptyRect = SkIRect::MakeEmpty();
	return this->makeOp(info, glyphCount, run, subRun, viewMatrix, x, y, emptyRect,
	paint, filteredColor, props, distanceAdjustTable, target);
	}

	void GrTextBlob::AssertEqual(const GrTextBlob& l, const GrTextBlob& r) {
	SkASSERT_RELEASE(l.fSize == r.fSize);

	SkASSERT_RELEASE(l.fBlurRec.fSigma == r.fBlurRec.fSigma);
	SkASSERT_RELEASE(l.fBlurRec.fStyle == r.fBlurRec.fStyle);

	SkASSERT_RELEASE(l.fStrokeInfo.fFrameWidth == r.fStrokeInfo.fFrameWidth);
	SkASSERT_RELEASE(l.fStrokeInfo.fMiterLimit == r.fStrokeInfo.fMiterLimit);
	SkASSERT_RELEASE(l.fStrokeInfo.fJoin == r.fStrokeInfo.fJoin);

	SkASSERT_RELEASE(l.fKey == r.fKey);
	//SkASSERT_RELEASE(l.fPaintColor == r.fPaintColor); // Colors might not actually be identical
	SkASSERT_RELEASE(l.fMaxMinScale == r.fMaxMinScale);
	SkASSERT_RELEASE(l.fMinMaxScale == r.fMinMaxScale);
	SkASSERT_RELEASE(l.fTextType == r.fTextType);

	SkASSERT_RELEASE(l.fRunCountLimit == r.fRunCountLimit);
	for (int i = 0; i < l.fRunCountLimit; i++) {
	const Run& lRun = l.fRuns[i];
	const Run& rRun = r.fRuns[i];

	SkASSERT_RELEASE(lRun.fStrikeSpec.descriptor() == rRun.fStrikeSpec.descriptor());

	// color can be changed
	//SkASSERT(lRun.fColor == rRun.fColor);
	SkASSERT_RELEASE(lRun.fInitialized == rRun.fInitialized);

	SkASSERT_RELEASE(lRun.fSubRunInfo.count() == rRun.fSubRunInfo.count());
	for(int j = 0; j < lRun.fSubRunInfo.count(); j++) {
	const SubRun& lSubRun = lRun.fSubRunInfo[j];
	const SubRun& rSubRun = rRun.fSubRunInfo[j];

	// TODO we can do this check, but we have to apply the VM to the old vertex bounds
	//SkASSERT_RELEASE(lSubRun.vertexBounds() == rSubRun.vertexBounds());

	if (lSubRun.strike()) {
	SkASSERT_RELEASE(rSubRun.strike());
	SkASSERT_RELEASE(GrTextStrike::GetKey(*lSubRun.strike()) ==
	GrTextStrike::GetKey(*rSubRun.strike()));

	} else {
	SkASSERT_RELEASE(!rSubRun.strike());
	}

	SkASSERT_RELEASE(lSubRun.vertexStartIndex() == rSubRun.vertexStartIndex());
	SkASSERT_RELEASE(lSubRun.vertexEndIndex() == rSubRun.vertexEndIndex());
	SkASSERT_RELEASE(lSubRun.glyphStartIndex() == rSubRun.glyphStartIndex());
	SkASSERT_RELEASE(lSubRun.glyphEndIndex() == rSubRun.glyphEndIndex());
	SkASSERT_RELEASE(lSubRun.maskFormat() == rSubRun.maskFormat());
	SkASSERT_RELEASE(lSubRun.drawAsDistanceFields() == rSubRun.drawAsDistanceFields());
	SkASSERT_RELEASE(lSubRun.hasUseLCDText() == rSubRun.hasUseLCDText());
	}

	SkASSERT_RELEASE(lRun.fPathGlyphs.count() == rRun.fPathGlyphs.count());
	for (int i = 0; i < lRun.fPathGlyphs.count(); i++) {
	const Run::PathGlyph& lPathGlyph = lRun.fPathGlyphs[i];
	const Run::PathGlyph& rPathGlyph = rRun.fPathGlyphs[i];

	SkASSERT_RELEASE(lPathGlyph.fPath == rPathGlyph.fPath);
	// We can't assert that these have the same translations
	}
	}
	}

	void GrTextBlob::SubRun::computeTranslation(const SkMatrix& viewMatrix,
	SkScalar x, SkScalar y, SkScalar* transX,
	SkScalar* transY) {
	// Don't use the matrix to translate on distance field for fallback subruns.
	calculate_translation(!this->drawAsDistanceFields() && !this->isFallback(), viewMatrix,
	x, y, fCurrentViewMatrix, fX, fY, transX, transY);
	fCurrentViewMatrix = viewMatrix;
	fX = x;
	fY = y;
	}