src/core/SkFindAndPlaceGlyph.h - skia - 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.
  */

 #ifndef SkFindAndPositionGlyph_DEFINED
 #define SkFindAndPositionGlyph_DEFINED

 #include "SkArenaAlloc.h"
 #include "SkGlyph.h"
 #include "SkMatrixPriv.h"
 #include "SkPaint.h"
 #include "SkStrike.h"
 #include "SkTemplates.h"
 #include "SkUTF.h"
 #include <utility>

 class SkFindAndPlaceGlyph {
 public:
     // ProcessPosText handles all cases for finding and positioning glyphs. It has a very large
     // multiplicity. It figures out the glyph, position and rounding and pass those parameters to
     // processOneGlyph.
     //
     // The routine processOneGlyph passed in by the client has the following signature:
     // void f(const SkGlyph& glyph, SkPoint position, SkPoint rounding);
     //
     // * Sub-pixel positioning (2) - use sub-pixel positioning.
     // * Text alignment (3) - text alignment with respect to the glyph's width.
     // * Matrix type (3) - special cases for translation and X-coordinate scaling.
     // * Components per position (2) - the positions vector can have a common Y with different
     //   Xs, or XY-pairs.
     // * Axis Alignment (for sub-pixel positioning) (3) - when using sub-pixel positioning, round
     //   to a whole coordinate instead of using sub-pixel positioning.
     // The number of variations is 108 for sub-pixel and 36 for full-pixel.
     // This routine handles all of them using inline polymorphic variable (no heap allocation).
     template<typename ProcessOneGlyph>
     static void ProcessPosText(
         const SkGlyphID[], int count,
         SkPoint offset, const SkMatrix& matrix, const SkScalar pos[], int scalarsPerPosition,
         SkStrike* cache, ProcessOneGlyph&& processOneGlyph);

     // The SubpixelAlignment function produces a suitable position for the glyph cache to
     // produce the correct sub-pixel alignment. If a position is aligned with an axis a shortcut
     // of 0 is used for the sub-pixel position.
     static SkIPoint SubpixelAlignment(SkAxisAlignment axisAlignment, SkPoint position) {

         if (!SkScalarsAreFinite(position.fX, position.fY)) {
             return {0, 0};
         }

         // Only the fractional part of position.fX and position.fY matter, because the result of
         // this function will just be passed to FixedToSub.
         switch (axisAlignment) {
             case kX_SkAxisAlignment:
                 return {SkScalarToFixed(SkScalarFraction(position.fX) + kSubpixelRounding), 0};
             case kY_SkAxisAlignment:
                 return {0, SkScalarToFixed(SkScalarFraction(position.fY) + kSubpixelRounding)};
             case kNone_SkAxisAlignment:
                 return {SkScalarToFixed(SkScalarFraction(position.fX) + kSubpixelRounding),
                         SkScalarToFixed(SkScalarFraction(position.fY) + kSubpixelRounding)};
         }
         SK_ABORT("Should not get here.");
         return {0, 0};
     }

     // The SubpixelPositionRounding function returns a point suitable for rounding a sub-pixel
     // positioned glyph.
     static SkPoint SubpixelPositionRounding(SkAxisAlignment axisAlignment) {
         switch (axisAlignment) {
             case kX_SkAxisAlignment:
                 return {kSubpixelRounding, SK_ScalarHalf};
             case kY_SkAxisAlignment:
                 return {SK_ScalarHalf, kSubpixelRounding};
             case kNone_SkAxisAlignment:
                 return {kSubpixelRounding, kSubpixelRounding};
         }
         SK_ABORT("Should not get here.");
         return {0.0f, 0.0f};
     }

     // MapperInterface given a point map it through the matrix. There are several shortcut
     // variants.
     // * TranslationMapper - assumes a translation only matrix.
     // * XScaleMapper - assumes an X scaling and a translation.
     // * GeneralMapper - Does all other matricies.
     class MapperInterface {
     public:
         virtual ~MapperInterface() {}

         virtual SkPoint map(SkPoint position) const = 0;
     };

     static MapperInterface* CreateMapper(const SkMatrix& matrix, const SkPoint& offset,
                                          int scalarsPerPosition, SkArenaAlloc* arena) {
         auto mtype = matrix.getType();
         if (mtype & (SkMatrix::kAffine_Mask | SkMatrix::kPerspective_Mask) ||
             scalarsPerPosition == 2) {
             return arena->make<GeneralMapper>(matrix, offset);
         }

         if (mtype & SkMatrix::kScale_Mask) {
             return arena->make<XScaleMapper>(matrix, offset);
         }

         return arena->make<TranslationMapper>(matrix, offset);
     }

 private:
     // PositionReaderInterface reads a point from the pos vector.
     // * HorizontalPositions - assumes a common Y for many X values.
     // * ArbitraryPositions - a list of (X,Y) pairs.
     class PositionReaderInterface {
     public:
         virtual ~PositionReaderInterface() { }
         virtual SkPoint nextPoint() = 0;
     };

     class HorizontalPositions final : public PositionReaderInterface {
     public:
         explicit HorizontalPositions(const SkScalar* positions)
             : fPositions(positions) { }

         SkPoint nextPoint() override {
             SkScalar x = *fPositions++;
             return {x, 0};
         }

     private:
         const SkScalar* fPositions;
     };

     class ArbitraryPositions final : public PositionReaderInterface {
     public:
         explicit ArbitraryPositions(const SkScalar* positions)
             : fPositions(positions) { }

         SkPoint nextPoint() override {
             SkPoint to_return{fPositions[0], fPositions[1]};
             fPositions += 2;
             return to_return;
         }

     private:
         const SkScalar* fPositions;
     };

     class TranslationMapper final : public MapperInterface {
     public:
         TranslationMapper(const SkMatrix& matrix, const SkPoint origin)
             : fTranslate(matrix.mapXY(origin.fX, origin.fY)) { }

         SkPoint map(SkPoint position) const override {
             return position + fTranslate;
         }

     private:
         const SkPoint fTranslate;
     };

     class XScaleMapper final : public MapperInterface {
     public:
         XScaleMapper(const SkMatrix& matrix, const SkPoint origin)
             : fTranslate(matrix.mapXY(origin.fX, origin.fY)), fXScale(matrix.getScaleX()) { }

         SkPoint map(SkPoint position) const override {
             return {fXScale * position.fX + fTranslate.fX, fTranslate.fY};
         }

     private:
         const SkPoint fTranslate;
         const SkScalar fXScale;
     };

     // The caller must keep matrix alive while this class is used.
     class GeneralMapper final : public MapperInterface {
     public:
         GeneralMapper(const SkMatrix& matrix, const SkPoint origin)
             : fOrigin(origin), fMatrix(matrix), fMapProc(SkMatrixPriv::GetMapXYProc(matrix)) { }

         SkPoint map(SkPoint position) const override {
             SkPoint result;
             fMapProc(fMatrix, position.fX + fOrigin.fX, position.fY + fOrigin.fY, &result);
             return result;
         }

     private:
         const SkPoint fOrigin;
         const SkMatrix& fMatrix;
         const SkMatrixPriv::MapXYProc fMapProc;
     };

     // The "call" to SkFixedToScalar is actually a macro. It's macros all the way down.
     // Needs to be a macro because you can't have a const float unless you make it constexpr.
     static constexpr SkScalar kSubpixelRounding = SkFixedToScalar(SkGlyph::kSubpixelRound);

     // GlyphFindAndPlaceInterface given the text and position finds the correct glyph and does
     // glyph specific position adjustment. The findAndPositionGlyph method takes text and
     // position and calls processOneGlyph with the correct glyph, final position and rounding
     // terms. The final position is not rounded yet and is the responsibility of processOneGlyph.
     template<typename ProcessOneGlyph>
     class GlyphFindAndPlaceInterface : SkNoncopyable {
     public:
         virtual ~GlyphFindAndPlaceInterface() { }

         // findAndPositionGlyph calculates the position of the glyph, finds the glyph, and
         // returns the position of where the next glyph will be using the glyph's advance. The
         // returned position is used by drawText, but ignored by drawPosText.
         // The compiler should prune all this calculation if the return value is not used.
         //
         // This should be a pure virtual, but some versions of GCC <= 4.8 have a bug that causes a
         // compile error.
         // See GCC bug: https://gcc.gnu.org/bugzilla/show_bug.cgi?id=60277
         virtual SkPoint findAndPositionGlyph(
             SkGlyphID, SkPoint position,
             ProcessOneGlyph&& processOneGlyph) {
             SK_ABORT("Should never get here.");
             return {0.0f, 0.0f};
         }
     };

     // GlyphFindAndPlaceSubpixel handles finding and placing glyphs when sub-pixel positioning is
     // requested. After it has found and placed the glyph it calls the templated function
     // ProcessOneGlyph in order to actually perform an action.
     template<typename ProcessOneGlyph, SkAxisAlignment kAxisAlignment>
     class GlyphFindAndPlaceSubpixel final : public GlyphFindAndPlaceInterface<ProcessOneGlyph> {
     public:
         explicit GlyphFindAndPlaceSubpixel(SkStrike* cache) : fCache(cache) {}

         SkPoint findAndPositionGlyph(SkGlyphID glyphID, SkPoint position, ProcessOneGlyph&& processOneGlyph) override {
             // Find the glyph.
             SkIPoint lookupPosition = SubpixelAlignment(kAxisAlignment, position);
             const SkGlyph& renderGlyph = fCache->getGlyphIDMetrics(glyphID, lookupPosition.fX, lookupPosition.fY);

             // If the glyph has no width (no pixels) then don't bother processing it.
             if (renderGlyph.fWidth > 0) {
                 processOneGlyph(renderGlyph, position,
                                 SubpixelPositionRounding(kAxisAlignment));
             }
             return position + SkPoint{SkFloatToScalar(renderGlyph.fAdvanceX),
                                       SkFloatToScalar(renderGlyph.fAdvanceY)};
         }

     private:
         SkStrike* fCache;
     };

     // GlyphFindAndPlaceFullPixel handles finding and placing glyphs when no sub-pixel
     // positioning is requested.
     template<typename ProcessOneGlyph>
     class GlyphFindAndPlaceFullPixel final : public GlyphFindAndPlaceInterface<ProcessOneGlyph> {
     public:
         explicit GlyphFindAndPlaceFullPixel(SkStrike* cache) : fCache(cache) {}

         SkPoint findAndPositionGlyph(
             SkGlyphID glyphID, SkPoint position,
             ProcessOneGlyph&& processOneGlyph) override {
             SkPoint finalPosition = position;
             const SkGlyph& glyph = fCache->getGlyphIDMetrics(glyphID);

             if (glyph.fWidth > 0) {
                 processOneGlyph(glyph, finalPosition, {SK_ScalarHalf, SK_ScalarHalf});
             }
             return finalPosition + SkPoint{SkFloatToScalar(glyph.fAdvanceX),
                                            SkFloatToScalar(glyph.fAdvanceY)};
         }

     private:
         SkStrike* fCache;
     };

     template <typename ProcessOneGlyph>
     static GlyphFindAndPlaceInterface<ProcessOneGlyph>* getSubpixel(
         SkArenaAlloc* arena, SkAxisAlignment axisAlignment, SkStrike* cache)
     {
         switch (axisAlignment) {
             case kX_SkAxisAlignment:
                 return arena->make<GlyphFindAndPlaceSubpixel<
                     ProcessOneGlyph, kX_SkAxisAlignment>>(cache);
             case kNone_SkAxisAlignment:
                 return arena->make<GlyphFindAndPlaceSubpixel<
                     ProcessOneGlyph, kNone_SkAxisAlignment>>(cache);
             case kY_SkAxisAlignment:
                 return arena->make<GlyphFindAndPlaceSubpixel<
                     ProcessOneGlyph, kY_SkAxisAlignment>>(cache);
         }
         SK_ABORT("Should never get here.");
         return nullptr;
     }
 };

 template<typename ProcessOneGlyph>
 inline void SkFindAndPlaceGlyph::ProcessPosText(
     const SkGlyphID glyphs[], int count,
     SkPoint offset, const SkMatrix& matrix, const SkScalar pos[], int scalarsPerPosition,
     SkStrike* cache, ProcessOneGlyph&& processOneGlyph) {

     SkAxisAlignment axisAlignment = cache->getScalerContext()->computeAxisAlignmentForHText();
     uint32_t mtype = matrix.getType();

     // Specialized code for handling the most common case for blink.
     if (axisAlignment == kX_SkAxisAlignment
         && cache->isSubpixel()
         && mtype <= SkMatrix::kTranslate_Mask)
     {
         using Positioner =
             GlyphFindAndPlaceSubpixel <
                 ProcessOneGlyph, kX_SkAxisAlignment>;
         HorizontalPositions hPositions{pos};
         ArbitraryPositions  aPositions{pos};
         PositionReaderInterface* positions = nullptr;
         if (scalarsPerPosition == 2) {
             positions = &aPositions;
         } else {
             positions = &hPositions;
         }
         TranslationMapper mapper{matrix, offset};
         Positioner positioner(cache);
         for (int i = 0; i < count; ++i) {
             SkPoint mappedPoint = mapper.TranslationMapper::map(positions->nextPoint());
             positioner.Positioner::findAndPositionGlyph(
                 glyphs[i], mappedPoint, std::forward<ProcessOneGlyph>(processOneGlyph));
         }
         return;
     }

     SkSTArenaAlloc<120> arena;

     PositionReaderInterface* positionReader = nullptr;
     if (2 == scalarsPerPosition) {
         positionReader = arena.make<ArbitraryPositions>(pos);
     } else {
         positionReader = arena.make<HorizontalPositions>(pos);
     }

     MapperInterface* mapper = CreateMapper(matrix, offset, scalarsPerPosition, &arena);
     GlyphFindAndPlaceInterface<ProcessOneGlyph>* findAndPosition = nullptr;
     if (cache->isSubpixel()) {
         findAndPosition = getSubpixel<ProcessOneGlyph>(&arena, axisAlignment, cache);
     } else {
         findAndPosition = arena.make<GlyphFindAndPlaceFullPixel<ProcessOneGlyph>>(cache);
     }

     for (int i = 0; i < count; ++i) {
         SkPoint mappedPoint = mapper->map(positionReader->nextPoint());
         findAndPosition->findAndPositionGlyph(
             glyphs[i], mappedPoint, std::forward<ProcessOneGlyph>(processOneGlyph));
     }
 }

 #endif  // SkFindAndPositionGlyph_DEFINED
	/*
	* 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 SkFindAndPositionGlyph_DEFINED
	#define SkFindAndPositionGlyph_DEFINED

	#include "SkArenaAlloc.h"
	#include "SkGlyph.h"
	#include "SkMatrixPriv.h"
	#include "SkPaint.h"
	#include "SkStrike.h"
	#include "SkTemplates.h"
	#include "SkUTF.h"
	#include <utility>

	class SkFindAndPlaceGlyph {
	public:
	// ProcessPosText handles all cases for finding and positioning glyphs. It has a very large
	// multiplicity. It figures out the glyph, position and rounding and pass those parameters to
	// processOneGlyph.
	//
	// The routine processOneGlyph passed in by the client has the following signature:
	// void f(const SkGlyph& glyph, SkPoint position, SkPoint rounding);
	//
	// * Sub-pixel positioning (2) - use sub-pixel positioning.
	// * Text alignment (3) - text alignment with respect to the glyph's width.
	// * Matrix type (3) - special cases for translation and X-coordinate scaling.
	// * Components per position (2) - the positions vector can have a common Y with different
	// Xs, or XY-pairs.
	// * Axis Alignment (for sub-pixel positioning) (3) - when using sub-pixel positioning, round
	// to a whole coordinate instead of using sub-pixel positioning.
	// The number of variations is 108 for sub-pixel and 36 for full-pixel.
	// This routine handles all of them using inline polymorphic variable (no heap allocation).
	template<typename ProcessOneGlyph>
	static void ProcessPosText(
	const SkGlyphID[], int count,
	SkPoint offset, const SkMatrix& matrix, const SkScalar pos[], int scalarsPerPosition,
	SkStrike* cache, ProcessOneGlyph&& processOneGlyph);

	// The SubpixelAlignment function produces a suitable position for the glyph cache to
	// produce the correct sub-pixel alignment. If a position is aligned with an axis a shortcut
	// of 0 is used for the sub-pixel position.
	static SkIPoint SubpixelAlignment(SkAxisAlignment axisAlignment, SkPoint position) {

	if (!SkScalarsAreFinite(position.fX, position.fY)) {
	return {0, 0};
	}

	// Only the fractional part of position.fX and position.fY matter, because the result of
	// this function will just be passed to FixedToSub.
	switch (axisAlignment) {
	case kX_SkAxisAlignment:
	return {SkScalarToFixed(SkScalarFraction(position.fX) + kSubpixelRounding), 0};
	case kY_SkAxisAlignment:
	return {0, SkScalarToFixed(SkScalarFraction(position.fY) + kSubpixelRounding)};
	case kNone_SkAxisAlignment:
	return {SkScalarToFixed(SkScalarFraction(position.fX) + kSubpixelRounding),
	SkScalarToFixed(SkScalarFraction(position.fY) + kSubpixelRounding)};
	}
	SK_ABORT("Should not get here.");
	return {0, 0};
	}

	// The SubpixelPositionRounding function returns a point suitable for rounding a sub-pixel
	// positioned glyph.
	static SkPoint SubpixelPositionRounding(SkAxisAlignment axisAlignment) {
	switch (axisAlignment) {
	case kX_SkAxisAlignment:
	return {kSubpixelRounding, SK_ScalarHalf};
	case kY_SkAxisAlignment:
	return {SK_ScalarHalf, kSubpixelRounding};
	case kNone_SkAxisAlignment:
	return {kSubpixelRounding, kSubpixelRounding};
	}
	SK_ABORT("Should not get here.");
	return {0.0f, 0.0f};
	}

	// MapperInterface given a point map it through the matrix. There are several shortcut
	// variants.
	// * TranslationMapper - assumes a translation only matrix.
	// * XScaleMapper - assumes an X scaling and a translation.
	// * GeneralMapper - Does all other matricies.
	class MapperInterface {
	public:
	virtual ~MapperInterface() {}

	virtual SkPoint map(SkPoint position) const = 0;
	};

	static MapperInterface* CreateMapper(const SkMatrix& matrix, const SkPoint& offset,
	int scalarsPerPosition, SkArenaAlloc* arena) {
	auto mtype = matrix.getType();
	if (mtype & (SkMatrix::kAffine_Mask \| SkMatrix::kPerspective_Mask) \|\|
	scalarsPerPosition == 2) {
	return arena->make<GeneralMapper>(matrix, offset);
	}

	if (mtype & SkMatrix::kScale_Mask) {
	return arena->make<XScaleMapper>(matrix, offset);
	}

	return arena->make<TranslationMapper>(matrix, offset);
	}

	private:
	// PositionReaderInterface reads a point from the pos vector.
	// * HorizontalPositions - assumes a common Y for many X values.
	// * ArbitraryPositions - a list of (X,Y) pairs.
	class PositionReaderInterface {
	public:
	virtual ~PositionReaderInterface() { }
	virtual SkPoint nextPoint() = 0;
	};

	class HorizontalPositions final : public PositionReaderInterface {
	public:
	explicit HorizontalPositions(const SkScalar* positions)
	: fPositions(positions) { }

	SkPoint nextPoint() override {
	SkScalar x = *fPositions++;
	return {x, 0};
	}

	private:
	const SkScalar* fPositions;
	};

	class ArbitraryPositions final : public PositionReaderInterface {
	public:
	explicit ArbitraryPositions(const SkScalar* positions)
	: fPositions(positions) { }

	SkPoint nextPoint() override {
	SkPoint to_return{fPositions[0], fPositions[1]};
	fPositions += 2;
	return to_return;
	}

	private:
	const SkScalar* fPositions;
	};

	class TranslationMapper final : public MapperInterface {
	public:
	TranslationMapper(const SkMatrix& matrix, const SkPoint origin)
	: fTranslate(matrix.mapXY(origin.fX, origin.fY)) { }

	SkPoint map(SkPoint position) const override {
	return position + fTranslate;
	}

	private:
	const SkPoint fTranslate;
	};

	class XScaleMapper final : public MapperInterface {
	public:
	XScaleMapper(const SkMatrix& matrix, const SkPoint origin)
	: fTranslate(matrix.mapXY(origin.fX, origin.fY)), fXScale(matrix.getScaleX()) { }

	SkPoint map(SkPoint position) const override {
	return {fXScale * position.fX + fTranslate.fX, fTranslate.fY};
	}

	private:
	const SkPoint fTranslate;
	const SkScalar fXScale;
	};

	// The caller must keep matrix alive while this class is used.
	class GeneralMapper final : public MapperInterface {
	public:
	GeneralMapper(const SkMatrix& matrix, const SkPoint origin)
	: fOrigin(origin), fMatrix(matrix), fMapProc(SkMatrixPriv::GetMapXYProc(matrix)) { }

	SkPoint map(SkPoint position) const override {
	SkPoint result;
	fMapProc(fMatrix, position.fX + fOrigin.fX, position.fY + fOrigin.fY, &result);
	return result;
	}

	private:
	const SkPoint fOrigin;
	const SkMatrix& fMatrix;
	const SkMatrixPriv::MapXYProc fMapProc;
	};

	// The "call" to SkFixedToScalar is actually a macro. It's macros all the way down.
	// Needs to be a macro because you can't have a const float unless you make it constexpr.
	static constexpr SkScalar kSubpixelRounding = SkFixedToScalar(SkGlyph::kSubpixelRound);

	// GlyphFindAndPlaceInterface given the text and position finds the correct glyph and does
	// glyph specific position adjustment. The findAndPositionGlyph method takes text and
	// position and calls processOneGlyph with the correct glyph, final position and rounding
	// terms. The final position is not rounded yet and is the responsibility of processOneGlyph.
	template<typename ProcessOneGlyph>
	class GlyphFindAndPlaceInterface : SkNoncopyable {
	public:
	virtual ~GlyphFindAndPlaceInterface() { }

	// findAndPositionGlyph calculates the position of the glyph, finds the glyph, and
	// returns the position of where the next glyph will be using the glyph's advance. The
	// returned position is used by drawText, but ignored by drawPosText.
	// The compiler should prune all this calculation if the return value is not used.
	//
	// This should be a pure virtual, but some versions of GCC <= 4.8 have a bug that causes a
	// compile error.
	// See GCC bug: https://gcc.gnu.org/bugzilla/show_bug.cgi?id=60277
	virtual SkPoint findAndPositionGlyph(
	SkGlyphID, SkPoint position,
	ProcessOneGlyph&& processOneGlyph) {
	SK_ABORT("Should never get here.");
	return {0.0f, 0.0f};
	}
	};

	// GlyphFindAndPlaceSubpixel handles finding and placing glyphs when sub-pixel positioning is
	// requested. After it has found and placed the glyph it calls the templated function
	// ProcessOneGlyph in order to actually perform an action.
	template<typename ProcessOneGlyph, SkAxisAlignment kAxisAlignment>
	class GlyphFindAndPlaceSubpixel final : public GlyphFindAndPlaceInterface<ProcessOneGlyph> {
	public:
	explicit GlyphFindAndPlaceSubpixel(SkStrike* cache) : fCache(cache) {}

	SkPoint findAndPositionGlyph(SkGlyphID glyphID, SkPoint position, ProcessOneGlyph&& processOneGlyph) override {
	// Find the glyph.
	SkIPoint lookupPosition = SubpixelAlignment(kAxisAlignment, position);
	const SkGlyph& renderGlyph = fCache->getGlyphIDMetrics(glyphID, lookupPosition.fX, lookupPosition.fY);

	// If the glyph has no width (no pixels) then don't bother processing it.
	if (renderGlyph.fWidth > 0) {
	processOneGlyph(renderGlyph, position,
	SubpixelPositionRounding(kAxisAlignment));
	}
	return position + SkPoint{SkFloatToScalar(renderGlyph.fAdvanceX),
	SkFloatToScalar(renderGlyph.fAdvanceY)};
	}

	private:
	SkStrike* fCache;
	};

	// GlyphFindAndPlaceFullPixel handles finding and placing glyphs when no sub-pixel
	// positioning is requested.
	template<typename ProcessOneGlyph>
	class GlyphFindAndPlaceFullPixel final : public GlyphFindAndPlaceInterface<ProcessOneGlyph> {
	public:
	explicit GlyphFindAndPlaceFullPixel(SkStrike* cache) : fCache(cache) {}

	SkPoint findAndPositionGlyph(
	SkGlyphID glyphID, SkPoint position,
	ProcessOneGlyph&& processOneGlyph) override {
	SkPoint finalPosition = position;
	const SkGlyph& glyph = fCache->getGlyphIDMetrics(glyphID);

	if (glyph.fWidth > 0) {
	processOneGlyph(glyph, finalPosition, {SK_ScalarHalf, SK_ScalarHalf});
	}
	return finalPosition + SkPoint{SkFloatToScalar(glyph.fAdvanceX),
	SkFloatToScalar(glyph.fAdvanceY)};
	}

	private:
	SkStrike* fCache;
	};

	template <typename ProcessOneGlyph>
	static GlyphFindAndPlaceInterface<ProcessOneGlyph>* getSubpixel(
	SkArenaAlloc* arena, SkAxisAlignment axisAlignment, SkStrike* cache)
	{
	switch (axisAlignment) {
	case kX_SkAxisAlignment:
	return arena->make<GlyphFindAndPlaceSubpixel<
	ProcessOneGlyph, kX_SkAxisAlignment>>(cache);
	case kNone_SkAxisAlignment:
	return arena->make<GlyphFindAndPlaceSubpixel<
	ProcessOneGlyph, kNone_SkAxisAlignment>>(cache);
	case kY_SkAxisAlignment:
	return arena->make<GlyphFindAndPlaceSubpixel<
	ProcessOneGlyph, kY_SkAxisAlignment>>(cache);
	}
	SK_ABORT("Should never get here.");
	return nullptr;
	}
	};

	template<typename ProcessOneGlyph>
	inline void SkFindAndPlaceGlyph::ProcessPosText(
	const SkGlyphID glyphs[], int count,
	SkPoint offset, const SkMatrix& matrix, const SkScalar pos[], int scalarsPerPosition,
	SkStrike* cache, ProcessOneGlyph&& processOneGlyph) {

	SkAxisAlignment axisAlignment = cache->getScalerContext()->computeAxisAlignmentForHText();
	uint32_t mtype = matrix.getType();

	// Specialized code for handling the most common case for blink.
	if (axisAlignment == kX_SkAxisAlignment
	&& cache->isSubpixel()
	&& mtype <= SkMatrix::kTranslate_Mask)
	{
	using Positioner =
	GlyphFindAndPlaceSubpixel <
	ProcessOneGlyph, kX_SkAxisAlignment>;
	HorizontalPositions hPositions{pos};
	ArbitraryPositions aPositions{pos};
	PositionReaderInterface* positions = nullptr;
	if (scalarsPerPosition == 2) {
	positions = &aPositions;
	} else {
	positions = &hPositions;
	}
	TranslationMapper mapper{matrix, offset};
	Positioner positioner(cache);
	for (int i = 0; i < count; ++i) {
	SkPoint mappedPoint = mapper.TranslationMapper::map(positions->nextPoint());
	positioner.Positioner::findAndPositionGlyph(
	glyphs[i], mappedPoint, std::forward<ProcessOneGlyph>(processOneGlyph));
	}
	return;
	}

	SkSTArenaAlloc<120> arena;

	PositionReaderInterface* positionReader = nullptr;
	if (2 == scalarsPerPosition) {
	positionReader = arena.make<ArbitraryPositions>(pos);
	} else {
	positionReader = arena.make<HorizontalPositions>(pos);
	}

	MapperInterface* mapper = CreateMapper(matrix, offset, scalarsPerPosition, &arena);
	GlyphFindAndPlaceInterface<ProcessOneGlyph>* findAndPosition = nullptr;
	if (cache->isSubpixel()) {
	findAndPosition = getSubpixel<ProcessOneGlyph>(&arena, axisAlignment, cache);
	} else {
	findAndPosition = arena.make<GlyphFindAndPlaceFullPixel<ProcessOneGlyph>>(cache);
	}

	for (int i = 0; i < count; ++i) {
	SkPoint mappedPoint = mapper->map(positionReader->nextPoint());
	findAndPosition->findAndPositionGlyph(
	glyphs[i], mappedPoint, std::forward<ProcessOneGlyph>(processOneGlyph));
	}
	}

	#endif // SkFindAndPositionGlyph_DEFINED