src/core/SkGlyphRun.cpp - skia - Git at Google

 /*
  * Copyright 2018 The Android Open Source Project
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #include "SkGlyphRun.h"

 #include "SkDevice.h"
 #include "SkFont.h"
 #include "SkFontPriv.h"
 #include "SkPaint.h"
 #include "SkStrike.h"
 #include "SkStrikeCache.h"
 #include "SkTextBlob.h"
 #include "SkTextBlobPriv.h"
 #include "SkTo.h"
 #include "SkUtils.h"

 // -- SkGlyphRun -----------------------------------------------------------------------------------
 SkGlyphRun::SkGlyphRun(const SkFont& font,
                        SkSpan<const SkPoint> positions,
                        SkSpan<const SkGlyphID> glyphIDs,
                        SkSpan<const char> text,
                        SkSpan<const uint32_t> clusters)
         : fPositions{positions}
         , fGlyphIDs{glyphIDs}
         , fText{text}
         , fClusters{clusters}
         , fFont{font} {}

 SkGlyphRun::SkGlyphRun(const SkGlyphRun& that, const SkFont& font)
     : fPositions{that.fPositions}
     , fGlyphIDs{that.fGlyphIDs}
     , fText{that.fText}
     , fClusters{that.fClusters}
     , fFont{font} {}

 void SkGlyphRun::filloutGlyphsAndPositions(SkGlyphID* glyphIDs, SkPoint* positions) {
     memcpy(glyphIDs, fGlyphIDs.data(), fGlyphIDs.size_bytes());
     memcpy(positions, fPositions.data(), fPositions.size_bytes());
 }

 // -- SkGlyphRunList -------------------------------------------------------------------------------
 SkGlyphRunList::SkGlyphRunList() = default;
 SkGlyphRunList::SkGlyphRunList(
         const SkPaint& paint,
         const SkTextBlob* blob,
         SkPoint origin,
         SkSpan<const SkGlyphRun> glyphRunList)
         : fOriginalPaint{&paint}
         , fOriginalTextBlob{blob}
         , fOrigin{origin}
         , fGlyphRuns{glyphRunList} { }

 SkGlyphRunList::SkGlyphRunList(const SkGlyphRun& glyphRun, const SkPaint& paint)
         : fOriginalPaint{&paint}
         , fOriginalTextBlob{nullptr}
         , fOrigin{SkPoint::Make(0, 0)}
         , fGlyphRuns{SkSpan<const SkGlyphRun>{&glyphRun, 1}} {}

 uint64_t SkGlyphRunList::uniqueID() const {
     return fOriginalTextBlob != nullptr ? fOriginalTextBlob->uniqueID()
                                         : SK_InvalidUniqueID;
 }

 bool SkGlyphRunList::anyRunsLCD() const {
     for (const auto& r : fGlyphRuns) {
         if (r.font().getEdging() == SkFont::Edging::kSubpixelAntiAlias) {
             return true;
         }
     }
     return false;
 }

 bool SkGlyphRunList::anyRunsSubpixelPositioned() const {
     for (const auto& r : fGlyphRuns) {
         if (r.font().isSubpixel()) {
             return true;
         }
     }
     return false;
 }

 bool SkGlyphRunList::allFontsFinite() const {
     for (const auto& r : fGlyphRuns) {
         if (!SkFontPriv::IsFinite(r.font())) {
             return false;
         }
     }
     return true;
 }

 void SkGlyphRunList::temporaryShuntBlobNotifyAddedToCache(uint32_t cacheID) const {
     SkASSERT(fOriginalTextBlob != nullptr);
     fOriginalTextBlob->notifyAddedToCache(cacheID);
 }

 // -- SkGlyphIDSet ---------------------------------------------------------------------------------
 // A faster set implementation that does not need any initialization, and reading the set items
 // is order the number of items, and not the size of the universe.
 // This implementation is based on the paper by Briggs and Torczon, "An Efficient Representation
 // for Sparse Sets"
 //
 // This implementation assumes that the unique glyphs added are appended to a vector that may
 // already have unique glyph from a previous computation. This allows the packing of multiple
 // UniqueID sequences in a single vector.
 SkSpan<const SkGlyphID> SkGlyphIDSet::uniquifyGlyphIDs(
         uint32_t universeSize,
         SkSpan<const SkGlyphID> glyphIDs,
         SkGlyphID* uniqueGlyphIDs,
         uint16_t* denseIndices) {
     static constexpr SkGlyphID  kUndefGlyph{0};

     if (universeSize > fUniverseToUniqueSize) {
         fUniverseToUnique.reset(universeSize);
         fUniverseToUniqueSize = universeSize;
         // If the following bzero becomes a performance problem, the memory can be marked as
         // initialized for valgrind and msan.
         // valgrind = VALGRIND_MAKE_MEM_DEFINED(fUniverseToUnique, universeSize * sizeof(SkGlyphID))
         // msan = sk_msan_mark_initialized(fUniverseToUnique, universeSize * sizeof(SkGlyphID))
         sk_bzero(fUniverseToUnique, universeSize * sizeof(SkGlyphID));
     }

     // No need to clear fUniverseToUnique here... the set insertion algorithm is designed to work
     // correctly even when the fUniverseToUnique buffer is uninitialized!

     size_t uniqueSize = 0;
     size_t denseIndicesCursor = 0;
     for (auto glyphID : glyphIDs) {

         // If the glyphID is not in range then it is the undefined glyph.
         if (glyphID >= universeSize) {
             glyphID = kUndefGlyph;
         }

         // The index into the unique ID vector.
         auto uniqueIndex = fUniverseToUnique[glyphID];

         if (uniqueIndex >= uniqueSize || uniqueGlyphIDs[uniqueIndex] != glyphID) {
             uniqueIndex = SkTo<uint16_t>(uniqueSize);
             uniqueGlyphIDs[uniqueSize] = glyphID;
             fUniverseToUnique[glyphID] = uniqueIndex;
             uniqueSize += 1;
         }

         denseIndices[denseIndicesCursor++] = uniqueIndex;
     }

     // If we're hanging onto these arrays for a long time, we don't want their size to drift
     // endlessly upwards. It's unusual to see a typeface with more than 4096 possible glyphs.
     if (fUniverseToUniqueSize > 4096) {
         fUniverseToUnique.reset(4096);
         sk_bzero(fUniverseToUnique, 4096 * sizeof(SkGlyphID));
         fUniverseToUniqueSize = 4096;
     }

     return SkSpan<const SkGlyphID>(uniqueGlyphIDs, uniqueSize);
 }

 // -- SkGlyphRunBuilder ----------------------------------------------------------------------------
 void SkGlyphRunBuilder::drawTextUTF8(const SkPaint& paint, const SkFont& font, const void* bytes,
                                      size_t byteLength, SkPoint origin) {
     auto glyphIDs = textToGlyphIDs(font, bytes, byteLength, kUTF8_SkTextEncoding);
     if (!glyphIDs.empty()) {
         this->initialize(glyphIDs.size());
         this->simplifyDrawText(font, glyphIDs, origin, fPositions);
     }

     this->makeGlyphRunList(paint, nullptr, SkPoint::Make(0, 0));
 }

 void SkGlyphRunBuilder::drawTextBlob(const SkPaint& paint, const SkTextBlob& blob, SkPoint origin,
                                      SkBaseDevice* device) {
     // Figure out all the storage needed to pre-size everything below.
     size_t totalGlyphs = 0;
     for (SkTextBlobRunIterator it(&blob); !it.done(); it.next()) {
         totalGlyphs += it.glyphCount();
     }

     // Pre-size all the buffers so they don't move during processing.
     this->initialize(totalGlyphs);

     SkPoint* positions = fPositions;

     for (SkTextBlobRunIterator it(&blob); !it.done(); it.next()) {
         // applyFontToPaint() always overwrites the exact same attributes,
         // so it is safe to not re-seed the paint for this reason.
         size_t runSize = it.glyphCount();

         auto text = SkSpan<const char>(it.text(), it.textSize());
         auto clusters = SkSpan<const uint32_t>(it.clusters(), runSize);
         const SkPoint& offset = it.offset();
         auto glyphIDs = SkSpan<const SkGlyphID>{it.glyphs(), runSize};

         switch (it.positioning()) {
             case SkTextBlobRunIterator::kDefault_Positioning: {
                 this->simplifyDrawText(
                         it.font(), glyphIDs, offset, positions, text, clusters);
             }
                 break;
             case SkTextBlobRunIterator::kHorizontal_Positioning: {
                 auto constY = offset.y();
                 this->simplifyDrawPosTextH(
                         it.font(), glyphIDs, it.pos(), constY, positions, text, clusters);
             }
                 break;
             case SkTextBlobRunIterator::kFull_Positioning:
                 this->simplifyDrawPosText(
                         it.font(), glyphIDs, (const SkPoint*)it.pos(), text, clusters);
                 break;
             case SkTextBlobRunIterator::kRSXform_Positioning: {
                 if (!this->empty()) {
                     this->makeGlyphRunList(paint, &blob, origin);
                     device->drawGlyphRunList(this->useGlyphRunList());
                 }

                 device->drawGlyphRunRSXform(it.font(), it.glyphs(), (const SkRSXform*)it.pos(),
                                             runSize, origin, paint);

                 // re-init in case we keep looping and need the builder again
                 this->initialize(totalGlyphs);
             } break;
         }

         positions += runSize;
     }

     if (!this->empty()) {
         this->makeGlyphRunList(paint, &blob, origin);
         device->drawGlyphRunList(this->useGlyphRunList());
     }
 }

 void SkGlyphRunBuilder::drawGlyphsWithPositions(const SkPaint& paint, const SkFont& font,
                                             SkSpan<const SkGlyphID> glyphIDs, const SkPoint* pos) {
     if (!glyphIDs.empty()) {
         this->initialize(glyphIDs.size());
         this->simplifyDrawPosText(font, glyphIDs, pos);
         this->makeGlyphRunList(paint, nullptr, SkPoint::Make(0, 0));
     }
 }

 const SkGlyphRunList& SkGlyphRunBuilder::useGlyphRunList() {
     return fGlyphRunList;
 }

 void SkGlyphRunBuilder::initialize(size_t totalRunSize) {

     if (totalRunSize > fMaxTotalRunSize) {
         fMaxTotalRunSize = totalRunSize;
         fPositions.reset(fMaxTotalRunSize);
     }

     fGlyphRunListStorage.clear();
 }

 SkSpan<const SkGlyphID> SkGlyphRunBuilder::textToGlyphIDs(
         const SkFont& font, const void* bytes, size_t byteLength, SkTextEncoding encoding) {
     if (encoding != kGlyphID_SkTextEncoding) {
         int count = font.countText(bytes, byteLength, encoding);
         if (count > 0) {
             fScratchGlyphIDs.resize(count);
             font.textToGlyphs(bytes, byteLength, encoding, fScratchGlyphIDs.data(), count);
             return SkSpan<const SkGlyphID>{fScratchGlyphIDs};
         } else {
             return SkSpan<const SkGlyphID>();
         }
     } else {
         return SkSpan<const SkGlyphID>((const SkGlyphID*)bytes, byteLength / 2);
     }
 }

 void SkGlyphRunBuilder::makeGlyphRun(
         const SkFont& font,
         SkSpan<const SkGlyphID> glyphIDs,
         SkSpan<const SkPoint> positions,
         SkSpan<const char> text,
         SkSpan<const uint32_t> clusters) {

     // Ignore empty runs.
     if (!glyphIDs.empty()) {
         fGlyphRunListStorage.emplace_back(
                 font,
                 positions,
                 glyphIDs,
                 text,
                 clusters);
     }
 }

 void SkGlyphRunBuilder::makeGlyphRunList(
         const SkPaint& paint, const SkTextBlob* blob, SkPoint origin) {

     fGlyphRunList.~SkGlyphRunList();
     new (&fGlyphRunList) SkGlyphRunList{
         paint, blob, origin, SkSpan<const SkGlyphRun>{fGlyphRunListStorage}};
 }

 void SkGlyphRunBuilder::simplifyDrawText(
         const SkFont& font, SkSpan<const SkGlyphID> glyphIDs,
         SkPoint origin, SkPoint* positions,
         SkSpan<const char> text, SkSpan<const uint32_t> clusters) {
     SkASSERT(!glyphIDs.empty());

     auto runSize = glyphIDs.size();

     if (!glyphIDs.empty()) {
         fScratchAdvances.resize(runSize);
         {
             auto cache = SkStrikeCache::FindOrCreateStrikeWithNoDeviceExclusive(font);
             cache->getAdvances(glyphIDs, fScratchAdvances.data());
         }

         SkPoint endOfLastGlyph = origin;

         for (size_t i = 0; i < runSize; i++) {
             positions[i] = endOfLastGlyph;
             endOfLastGlyph += fScratchAdvances[i];
         }

         this->makeGlyphRun(
                 font,
                 glyphIDs,
                 SkSpan<const SkPoint>{positions, runSize},
                 text,
                 clusters);
     }
 }

 void SkGlyphRunBuilder::simplifyDrawPosTextH(
         const SkFont& font, SkSpan<const SkGlyphID> glyphIDs,
         const SkScalar* xpos, SkScalar constY, SkPoint* positions,
         SkSpan<const char> text, SkSpan<const uint32_t> clusters) {

     auto posCursor = positions;
     for (auto x : SkSpan<const SkScalar>{xpos, glyphIDs.size()}) {
         *posCursor++ = SkPoint::Make(x, constY);
     }

     simplifyDrawPosText(font, glyphIDs, positions, text, clusters);
 }

 void SkGlyphRunBuilder::simplifyDrawPosText(
         const SkFont& font, SkSpan<const SkGlyphID> glyphIDs,
         const SkPoint* pos,
         SkSpan<const char> text, SkSpan<const uint32_t> clusters) {
     auto runSize = glyphIDs.size();

     this->makeGlyphRun(
             font,
             glyphIDs,
             SkSpan<const SkPoint>{pos, runSize},
             text,
             clusters);
 }
	/*
	* Copyright 2018 The Android Open Source Project
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#include "SkGlyphRun.h"

	#include "SkDevice.h"
	#include "SkFont.h"
	#include "SkFontPriv.h"
	#include "SkPaint.h"
	#include "SkStrike.h"
	#include "SkStrikeCache.h"
	#include "SkTextBlob.h"
	#include "SkTextBlobPriv.h"
	#include "SkTo.h"
	#include "SkUtils.h"

	// -- SkGlyphRun -----------------------------------------------------------------------------------
	SkGlyphRun::SkGlyphRun(const SkFont& font,
	SkSpan<const SkPoint> positions,
	SkSpan<const SkGlyphID> glyphIDs,
	SkSpan<const char> text,
	SkSpan<const uint32_t> clusters)
	: fPositions{positions}
	, fGlyphIDs{glyphIDs}
	, fText{text}
	, fClusters{clusters}
	, fFont{font} {}

	SkGlyphRun::SkGlyphRun(const SkGlyphRun& that, const SkFont& font)
	: fPositions{that.fPositions}
	, fGlyphIDs{that.fGlyphIDs}
	, fText{that.fText}
	, fClusters{that.fClusters}
	, fFont{font} {}

	void SkGlyphRun::filloutGlyphsAndPositions(SkGlyphID* glyphIDs, SkPoint* positions) {
	memcpy(glyphIDs, fGlyphIDs.data(), fGlyphIDs.size_bytes());
	memcpy(positions, fPositions.data(), fPositions.size_bytes());
	}

	// -- SkGlyphRunList -------------------------------------------------------------------------------
	SkGlyphRunList::SkGlyphRunList() = default;
	SkGlyphRunList::SkGlyphRunList(
	const SkPaint& paint,
	const SkTextBlob* blob,
	SkPoint origin,
	SkSpan<const SkGlyphRun> glyphRunList)
	: fOriginalPaint{&paint}
	, fOriginalTextBlob{blob}
	, fOrigin{origin}
	, fGlyphRuns{glyphRunList} { }

	SkGlyphRunList::SkGlyphRunList(const SkGlyphRun& glyphRun, const SkPaint& paint)
	: fOriginalPaint{&paint}
	, fOriginalTextBlob{nullptr}
	, fOrigin{SkPoint::Make(0, 0)}
	, fGlyphRuns{SkSpan<const SkGlyphRun>{&glyphRun, 1}} {}

	uint64_t SkGlyphRunList::uniqueID() const {
	return fOriginalTextBlob != nullptr ? fOriginalTextBlob->uniqueID()
	: SK_InvalidUniqueID;
	}

	bool SkGlyphRunList::anyRunsLCD() const {
	for (const auto& r : fGlyphRuns) {
	if (r.font().getEdging() == SkFont::Edging::kSubpixelAntiAlias) {
	return true;
	}
	}
	return false;
	}

	bool SkGlyphRunList::anyRunsSubpixelPositioned() const {
	for (const auto& r : fGlyphRuns) {
	if (r.font().isSubpixel()) {
	return true;
	}
	}
	return false;
	}

	bool SkGlyphRunList::allFontsFinite() const {
	for (const auto& r : fGlyphRuns) {
	if (!SkFontPriv::IsFinite(r.font())) {
	return false;
	}
	}
	return true;
	}

	void SkGlyphRunList::temporaryShuntBlobNotifyAddedToCache(uint32_t cacheID) const {
	SkASSERT(fOriginalTextBlob != nullptr);
	fOriginalTextBlob->notifyAddedToCache(cacheID);
	}

	// -- SkGlyphIDSet ---------------------------------------------------------------------------------
	// A faster set implementation that does not need any initialization, and reading the set items
	// is order the number of items, and not the size of the universe.
	// This implementation is based on the paper by Briggs and Torczon, "An Efficient Representation
	// for Sparse Sets"
	//
	// This implementation assumes that the unique glyphs added are appended to a vector that may
	// already have unique glyph from a previous computation. This allows the packing of multiple
	// UniqueID sequences in a single vector.
	SkSpan<const SkGlyphID> SkGlyphIDSet::uniquifyGlyphIDs(
	uint32_t universeSize,
	SkSpan<const SkGlyphID> glyphIDs,
	SkGlyphID* uniqueGlyphIDs,
	uint16_t* denseIndices) {
	static constexpr SkGlyphID kUndefGlyph{0};

	if (universeSize > fUniverseToUniqueSize) {
	fUniverseToUnique.reset(universeSize);
	fUniverseToUniqueSize = universeSize;
	// If the following bzero becomes a performance problem, the memory can be marked as
	// initialized for valgrind and msan.
	// valgrind = VALGRIND_MAKE_MEM_DEFINED(fUniverseToUnique, universeSize * sizeof(SkGlyphID))
	// msan = sk_msan_mark_initialized(fUniverseToUnique, universeSize * sizeof(SkGlyphID))
	sk_bzero(fUniverseToUnique, universeSize * sizeof(SkGlyphID));
	}

	// No need to clear fUniverseToUnique here... the set insertion algorithm is designed to work
	// correctly even when the fUniverseToUnique buffer is uninitialized!

	size_t uniqueSize = 0;
	size_t denseIndicesCursor = 0;
	for (auto glyphID : glyphIDs) {

	// If the glyphID is not in range then it is the undefined glyph.
	if (glyphID >= universeSize) {
	glyphID = kUndefGlyph;
	}

	// The index into the unique ID vector.
	auto uniqueIndex = fUniverseToUnique[glyphID];

	if (uniqueIndex >= uniqueSize \|\| uniqueGlyphIDs[uniqueIndex] != glyphID) {
	uniqueIndex = SkTo<uint16_t>(uniqueSize);
	uniqueGlyphIDs[uniqueSize] = glyphID;
	fUniverseToUnique[glyphID] = uniqueIndex;
	uniqueSize += 1;
	}

	denseIndices[denseIndicesCursor++] = uniqueIndex;
	}

	// If we're hanging onto these arrays for a long time, we don't want their size to drift
	// endlessly upwards. It's unusual to see a typeface with more than 4096 possible glyphs.
	if (fUniverseToUniqueSize > 4096) {
	fUniverseToUnique.reset(4096);
	sk_bzero(fUniverseToUnique, 4096 * sizeof(SkGlyphID));
	fUniverseToUniqueSize = 4096;
	}

	return SkSpan<const SkGlyphID>(uniqueGlyphIDs, uniqueSize);
	}

	// -- SkGlyphRunBuilder ----------------------------------------------------------------------------
	void SkGlyphRunBuilder::drawTextUTF8(const SkPaint& paint, const SkFont& font, const void* bytes,
	size_t byteLength, SkPoint origin) {
	auto glyphIDs = textToGlyphIDs(font, bytes, byteLength, kUTF8_SkTextEncoding);
	if (!glyphIDs.empty()) {
	this->initialize(glyphIDs.size());
	this->simplifyDrawText(font, glyphIDs, origin, fPositions);
	}

	this->makeGlyphRunList(paint, nullptr, SkPoint::Make(0, 0));
	}

	void SkGlyphRunBuilder::drawTextBlob(const SkPaint& paint, const SkTextBlob& blob, SkPoint origin,
	SkBaseDevice* device) {
	// Figure out all the storage needed to pre-size everything below.
	size_t totalGlyphs = 0;
	for (SkTextBlobRunIterator it(&blob); !it.done(); it.next()) {
	totalGlyphs += it.glyphCount();
	}

	// Pre-size all the buffers so they don't move during processing.
	this->initialize(totalGlyphs);

	SkPoint* positions = fPositions;

	for (SkTextBlobRunIterator it(&blob); !it.done(); it.next()) {
	// applyFontToPaint() always overwrites the exact same attributes,
	// so it is safe to not re-seed the paint for this reason.
	size_t runSize = it.glyphCount();

	auto text = SkSpan<const char>(it.text(), it.textSize());
	auto clusters = SkSpan<const uint32_t>(it.clusters(), runSize);
	const SkPoint& offset = it.offset();
	auto glyphIDs = SkSpan<const SkGlyphID>{it.glyphs(), runSize};

	switch (it.positioning()) {
	case SkTextBlobRunIterator::kDefault_Positioning: {
	this->simplifyDrawText(
	it.font(), glyphIDs, offset, positions, text, clusters);
	}
	break;
	case SkTextBlobRunIterator::kHorizontal_Positioning: {
	auto constY = offset.y();
	this->simplifyDrawPosTextH(
	it.font(), glyphIDs, it.pos(), constY, positions, text, clusters);
	}
	break;
	case SkTextBlobRunIterator::kFull_Positioning:
	this->simplifyDrawPosText(
	it.font(), glyphIDs, (const SkPoint*)it.pos(), text, clusters);
	break;
	case SkTextBlobRunIterator::kRSXform_Positioning: {
	if (!this->empty()) {
	this->makeGlyphRunList(paint, &blob, origin);
	device->drawGlyphRunList(this->useGlyphRunList());
	}

	device->drawGlyphRunRSXform(it.font(), it.glyphs(), (const SkRSXform*)it.pos(),
	runSize, origin, paint);

	// re-init in case we keep looping and need the builder again
	this->initialize(totalGlyphs);
	} break;
	}

	positions += runSize;
	}

	if (!this->empty()) {
	this->makeGlyphRunList(paint, &blob, origin);
	device->drawGlyphRunList(this->useGlyphRunList());
	}
	}

	void SkGlyphRunBuilder::drawGlyphsWithPositions(const SkPaint& paint, const SkFont& font,
	SkSpan<const SkGlyphID> glyphIDs, const SkPoint* pos) {
	if (!glyphIDs.empty()) {
	this->initialize(glyphIDs.size());
	this->simplifyDrawPosText(font, glyphIDs, pos);
	this->makeGlyphRunList(paint, nullptr, SkPoint::Make(0, 0));
	}
	}

	const SkGlyphRunList& SkGlyphRunBuilder::useGlyphRunList() {
	return fGlyphRunList;
	}

	void SkGlyphRunBuilder::initialize(size_t totalRunSize) {

	if (totalRunSize > fMaxTotalRunSize) {
	fMaxTotalRunSize = totalRunSize;
	fPositions.reset(fMaxTotalRunSize);
	}

	fGlyphRunListStorage.clear();
	}

	SkSpan<const SkGlyphID> SkGlyphRunBuilder::textToGlyphIDs(
	const SkFont& font, const void* bytes, size_t byteLength, SkTextEncoding encoding) {
	if (encoding != kGlyphID_SkTextEncoding) {
	int count = font.countText(bytes, byteLength, encoding);
	if (count > 0) {
	fScratchGlyphIDs.resize(count);
	font.textToGlyphs(bytes, byteLength, encoding, fScratchGlyphIDs.data(), count);
	return SkSpan<const SkGlyphID>{fScratchGlyphIDs};
	} else {
	return SkSpan<const SkGlyphID>();
	}
	} else {
	return SkSpan<const SkGlyphID>((const SkGlyphID*)bytes, byteLength / 2);
	}
	}

	void SkGlyphRunBuilder::makeGlyphRun(
	const SkFont& font,
	SkSpan<const SkGlyphID> glyphIDs,
	SkSpan<const SkPoint> positions,
	SkSpan<const char> text,
	SkSpan<const uint32_t> clusters) {

	// Ignore empty runs.
	if (!glyphIDs.empty()) {
	fGlyphRunListStorage.emplace_back(
	font,
	positions,
	glyphIDs,
	text,
	clusters);
	}
	}

	void SkGlyphRunBuilder::makeGlyphRunList(
	const SkPaint& paint, const SkTextBlob* blob, SkPoint origin) {

	fGlyphRunList.~SkGlyphRunList();
	new (&fGlyphRunList) SkGlyphRunList{
	paint, blob, origin, SkSpan<const SkGlyphRun>{fGlyphRunListStorage}};
	}

	void SkGlyphRunBuilder::simplifyDrawText(
	const SkFont& font, SkSpan<const SkGlyphID> glyphIDs,
	SkPoint origin, SkPoint* positions,
	SkSpan<const char> text, SkSpan<const uint32_t> clusters) {
	SkASSERT(!glyphIDs.empty());

	auto runSize = glyphIDs.size();

	if (!glyphIDs.empty()) {
	fScratchAdvances.resize(runSize);
	{
	auto cache = SkStrikeCache::FindOrCreateStrikeWithNoDeviceExclusive(font);
	cache->getAdvances(glyphIDs, fScratchAdvances.data());
	}

	SkPoint endOfLastGlyph = origin;

	for (size_t i = 0; i < runSize; i++) {
	positions[i] = endOfLastGlyph;
	endOfLastGlyph += fScratchAdvances[i];
	}

	this->makeGlyphRun(
	font,
	glyphIDs,
	SkSpan<const SkPoint>{positions, runSize},
	text,
	clusters);
	}
	}

	void SkGlyphRunBuilder::simplifyDrawPosTextH(
	const SkFont& font, SkSpan<const SkGlyphID> glyphIDs,
	const SkScalar* xpos, SkScalar constY, SkPoint* positions,
	SkSpan<const char> text, SkSpan<const uint32_t> clusters) {

	auto posCursor = positions;
	for (auto x : SkSpan<const SkScalar>{xpos, glyphIDs.size()}) {
	*posCursor++ = SkPoint::Make(x, constY);
	}

	simplifyDrawPosText(font, glyphIDs, positions, text, clusters);
	}

	void SkGlyphRunBuilder::simplifyDrawPosText(
	const SkFont& font, SkSpan<const SkGlyphID> glyphIDs,
	const SkPoint* pos,
	SkSpan<const char> text, SkSpan<const uint32_t> clusters) {
	auto runSize = glyphIDs.size();

	this->makeGlyphRun(
	font,
	glyphIDs,
	SkSpan<const SkPoint>{pos, runSize},
	text,
	clusters);
	}