src/utils/SkShaperJSONWriter.cpp - platform/external/skia - Gitiles

 /*
  * Copyright 2019 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #include "src/utils/SkShaperJSONWriter.h"

 #include <algorithm>
 #include <limits>
 #include <string>

 #include "src/utils/SkJSONWriter.h"
 #include "src/utils/SkUTF.h"

 SkShaperJSONWriter::SkShaperJSONWriter(SkJSONWriter* JSONWriter, const char* utf8, size_t size)
         : fJSONWriter{JSONWriter}
         , fUTF8{utf8, size} {}

 void SkShaperJSONWriter::beginLine() { }

 void SkShaperJSONWriter::runInfo(const SkShaper::RunHandler::RunInfo& info) { }

 void SkShaperJSONWriter::commitRunInfo() { }

 SkShaper::RunHandler::Buffer
 SkShaperJSONWriter::runBuffer(const SkShaper::RunHandler::RunInfo& info) {
     fGlyphs.resize(info.glyphCount);
     fPositions.resize(info.glyphCount);
     fClusters.resize(info.glyphCount);
     return {fGlyphs.data(), fPositions.data(), nullptr, fClusters.data(), {0, 0}};
 }

 static bool is_one_to_one(const char utf8[], size_t utf8Begin, size_t utf8End,
         std::vector<uint32_t>& clusters) {
     size_t lastUtf8Index = utf8End;

     auto checkCluster = [&](size_t clusterIndex) {
         if (clusters[clusterIndex] >= lastUtf8Index) {
             return false;
         }
         size_t utf8ClusterSize = lastUtf8Index - clusters[clusterIndex];
         if (SkUTF::CountUTF8(&utf8[clusters[clusterIndex]], utf8ClusterSize) != 1) {
             return false;
         }
         lastUtf8Index = clusters[clusterIndex];
         return true;
     };

     if (clusters.front() <= clusters.back()) {
         // left-to-right clusters
         size_t clusterCursor = clusters.size();
         while (clusterCursor > 0) {
             if (!checkCluster(--clusterCursor)) { return false; }
         }
     } else {
         // right-to-left clusters
         size_t clusterCursor = 0;
         while (clusterCursor < clusters.size()) {
             if (!checkCluster(clusterCursor++)) { return false; }
         }
     }

     return true;
 }

 void SkShaperJSONWriter::commitRunBuffer(const SkShaper::RunHandler::RunInfo& info) {
     fJSONWriter->beginObject("run", true);

     // Font name
     SkString fontName;
     info.fFont.getTypeface()->getFamilyName(&fontName);
     fJSONWriter->appendString("font name", fontName.c_str());

     // Font size
     fJSONWriter->appendFloat("font size", info.fFont.getSize());

     if (info.fBidiLevel > 0) {
         std::string bidiType = info.fBidiLevel % 2 == 0 ? "left-to-right" : "right-to-left";
         std::string bidiOutput = bidiType + " lvl " + std::to_string(info.fBidiLevel);
         fJSONWriter->appendString("BiDi", bidiOutput.c_str());
     }

     if (is_one_to_one(fUTF8.c_str(), info.utf8Range.begin(), info.utf8Range.end(), fClusters)) {
         std::string utf8{&fUTF8[info.utf8Range.begin()], info.utf8Range.size()};
         fJSONWriter->appendString("UTF8", utf8.c_str());

         fJSONWriter->beginArray("glyphs", false);
         for (auto glyphID : fGlyphs) {
             fJSONWriter->appendU32(glyphID);
         }
         fJSONWriter->endArray();

         fJSONWriter->beginArray("clusters", false);
         for (auto cluster : fClusters) {
             fJSONWriter->appendU32(cluster);
         }
         fJSONWriter->endArray();
     } else {
         VisualizeClusters(fUTF8.c_str(),
                           info.utf8Range.begin(), info.utf8Range.end(),
                           SkMakeSpan(fGlyphs),
                           SkMakeSpan(fClusters),
                           [this](size_t codePointCount, SkSpan<const char> utf1to1,
                                  SkSpan<const SkGlyphID> glyph1to1) {
                               this->displayMToN(codePointCount, utf1to1, glyph1to1);
                           });
     }

     if (info.glyphCount > 1) {
         fJSONWriter->beginArray("horizontal positions", false);
         for (auto position : fPositions) {
             fJSONWriter->appendFloat(position.x());
         }
         fJSONWriter->endArray();
     }

     fJSONWriter->beginArray("advances", false);
     for (size_t i = 1; i < info.glyphCount; i++) {
         fJSONWriter->appendFloat(fPositions[i].fX - fPositions[i-1].fX);
     }
     SkPoint lastAdvance = info.fAdvance - (fPositions.back() - fPositions.front());
     fJSONWriter->appendFloat(lastAdvance.fX);
     fJSONWriter->endArray();

     fJSONWriter->endObject();
 }

 void SkShaperJSONWriter::BreakupClusters(size_t utf8Begin, size_t utf8End,
                                          SkSpan<const uint32_t> clusters,
                                          const BreakupCluastersCallback& processMToN) {

     if (clusters.front() <= clusters.back()) {
         // Handle left-to-right text direction
         size_t glyphStartIndex = 0;
         for (size_t glyphEndIndex = 0; glyphEndIndex < clusters.size(); glyphEndIndex++) {

             if (clusters[glyphStartIndex] == clusters[glyphEndIndex]) { continue; }

             processMToN(glyphStartIndex, glyphEndIndex,
                         clusters[glyphStartIndex], clusters[glyphEndIndex]);

             glyphStartIndex = glyphEndIndex;
         }

         processMToN(glyphStartIndex, clusters.size(), clusters[glyphStartIndex], utf8End);

     } else {
         // Handle right-to-left text direction.
         SkASSERT(clusters.size() >= 2);
         size_t glyphStartIndex = 0;
         uint32_t utf8EndIndex = utf8End;
         for (size_t glyphEndIndex = 0; glyphEndIndex < clusters.size(); glyphEndIndex++) {

             if (clusters[glyphStartIndex] == clusters[glyphEndIndex]) { continue; }

             processMToN(glyphStartIndex, glyphEndIndex,
                         clusters[glyphStartIndex], utf8EndIndex);

             utf8EndIndex = clusters[glyphStartIndex];
             glyphStartIndex = glyphEndIndex;
         }
         processMToN(glyphStartIndex, clusters.size(), utf8Begin, clusters[glyphStartIndex-1]);
     }
 }

 void SkShaperJSONWriter::VisualizeClusters(const char* utf8, size_t utf8Begin, size_t utf8End,
                                            SkSpan<const SkGlyphID> glyphIDs,
                                            SkSpan<const uint32_t> clusters,
                                            const VisualizeClustersCallback& processMToN) {

     size_t glyphRangeStart, glyphRangeEnd;
     uint32_t utf8RangeStart, utf8RangeEnd;

     auto resetRanges = [&]() {
         glyphRangeStart = std::numeric_limits<size_t>::max();
         glyphRangeEnd   = 0;
         utf8RangeStart  = std::numeric_limits<uint32_t>::max();
         utf8RangeEnd    = 0;
     };

     auto checkRangesAndProcess = [&]() {
         if (glyphRangeStart < glyphRangeEnd) {
             size_t glyphRangeCount = glyphRangeEnd - glyphRangeStart;
             SkSpan<const char> utf8Span{&utf8[utf8RangeStart], utf8RangeEnd - utf8RangeStart};
             SkSpan<const SkGlyphID> glyphSpan{&glyphIDs[glyphRangeStart], glyphRangeCount};

             // Glyph count is the same as codepoint count for 1:1.
             processMToN(glyphRangeCount, utf8Span, glyphSpan);
         }
         resetRanges();
     };

     auto gatherRuns = [&](size_t glyphStartIndex, size_t glyphEndIndex,
                           uint32_t utf8StartIndex, uint32_t utf8EndIndex) {
         int possibleCount = SkUTF::CountUTF8(&utf8[utf8StartIndex], utf8EndIndex - utf8StartIndex);
         if (possibleCount == -1) { return; }
         size_t codePointCount = SkTo<size_t>(possibleCount);
         if (codePointCount == 1 && glyphEndIndex - glyphStartIndex == 1) {
             glyphRangeStart = std::min(glyphRangeStart, glyphStartIndex);
             glyphRangeEnd   = std::max(glyphRangeEnd,   glyphEndIndex  );
             utf8RangeStart  = std::min(utf8RangeStart,  utf8StartIndex );
             utf8RangeEnd    = std::max(utf8RangeEnd,    utf8EndIndex   );
         } else {
             checkRangesAndProcess();

             SkSpan<const char> utf8Span{&utf8[utf8StartIndex], utf8EndIndex - utf8StartIndex};
             SkSpan<const SkGlyphID> glyphSpan{&glyphIDs[glyphStartIndex],
                                               glyphEndIndex - glyphStartIndex};

             processMToN(codePointCount, utf8Span, glyphSpan);
         }
     };

     resetRanges();
     BreakupClusters(utf8Begin, utf8End, clusters, gatherRuns);
     checkRangesAndProcess();
 }

 void SkShaperJSONWriter::displayMToN(size_t codePointCount,
                                      SkSpan<const char> utf8,
                                      SkSpan<const SkGlyphID> glyphIDs) {
     std::string nString = std::to_string(codePointCount);
     std::string mString = std::to_string(glyphIDs.size());
     std::string clusterName = "cluster " + nString + " to " + mString;
     fJSONWriter->beginObject(clusterName.c_str(), true);
     std::string utf8String{utf8.data(), utf8.size()};
     fJSONWriter->appendString("UTF", utf8String.c_str());
     fJSONWriter->beginArray("glyphsIDs", false);
     for (auto glyphID : glyphIDs) {
         fJSONWriter->appendU32(glyphID);
     }
     fJSONWriter->endArray();
     fJSONWriter->endObject();
 }
	/*
	* Copyright 2019 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#include "src/utils/SkShaperJSONWriter.h"

	#include <algorithm>
	#include <limits>
	#include <string>

	#include "src/utils/SkJSONWriter.h"
	#include "src/utils/SkUTF.h"

	SkShaperJSONWriter::SkShaperJSONWriter(SkJSONWriter* JSONWriter, const char* utf8, size_t size)
	: fJSONWriter{JSONWriter}
	, fUTF8{utf8, size} {}

	void SkShaperJSONWriter::beginLine() { }

	void SkShaperJSONWriter::runInfo(const SkShaper::RunHandler::RunInfo& info) { }

	void SkShaperJSONWriter::commitRunInfo() { }

	SkShaper::RunHandler::Buffer
	SkShaperJSONWriter::runBuffer(const SkShaper::RunHandler::RunInfo& info) {
	fGlyphs.resize(info.glyphCount);
	fPositions.resize(info.glyphCount);
	fClusters.resize(info.glyphCount);
	return {fGlyphs.data(), fPositions.data(), nullptr, fClusters.data(), {0, 0}};
	}

	static bool is_one_to_one(const char utf8[], size_t utf8Begin, size_t utf8End,
	std::vector<uint32_t>& clusters) {
	size_t lastUtf8Index = utf8End;

	auto checkCluster = [&](size_t clusterIndex) {
	if (clusters[clusterIndex] >= lastUtf8Index) {
	return false;
	}
	size_t utf8ClusterSize = lastUtf8Index - clusters[clusterIndex];
	if (SkUTF::CountUTF8(&utf8[clusters[clusterIndex]], utf8ClusterSize) != 1) {
	return false;
	}
	lastUtf8Index = clusters[clusterIndex];
	return true;
	};

	if (clusters.front() <= clusters.back()) {
	// left-to-right clusters
	size_t clusterCursor = clusters.size();
	while (clusterCursor > 0) {
	if (!checkCluster(--clusterCursor)) { return false; }
	}
	} else {
	// right-to-left clusters
	size_t clusterCursor = 0;
	while (clusterCursor < clusters.size()) {
	if (!checkCluster(clusterCursor++)) { return false; }
	}
	}

	return true;
	}

	void SkShaperJSONWriter::commitRunBuffer(const SkShaper::RunHandler::RunInfo& info) {
	fJSONWriter->beginObject("run", true);

	// Font name
	SkString fontName;
	info.fFont.getTypeface()->getFamilyName(&fontName);
	fJSONWriter->appendString("font name", fontName.c_str());

	// Font size
	fJSONWriter->appendFloat("font size", info.fFont.getSize());

	if (info.fBidiLevel > 0) {
	std::string bidiType = info.fBidiLevel % 2 == 0 ? "left-to-right" : "right-to-left";
	std::string bidiOutput = bidiType + " lvl " + std::to_string(info.fBidiLevel);
	fJSONWriter->appendString("BiDi", bidiOutput.c_str());
	}

	if (is_one_to_one(fUTF8.c_str(), info.utf8Range.begin(), info.utf8Range.end(), fClusters)) {
	std::string utf8{&fUTF8[info.utf8Range.begin()], info.utf8Range.size()};
	fJSONWriter->appendString("UTF8", utf8.c_str());

	fJSONWriter->beginArray("glyphs", false);
	for (auto glyphID : fGlyphs) {
	fJSONWriter->appendU32(glyphID);
	}
	fJSONWriter->endArray();

	fJSONWriter->beginArray("clusters", false);
	for (auto cluster : fClusters) {
	fJSONWriter->appendU32(cluster);
	}
	fJSONWriter->endArray();
	} else {
	VisualizeClusters(fUTF8.c_str(),
	info.utf8Range.begin(), info.utf8Range.end(),
	SkMakeSpan(fGlyphs),
	SkMakeSpan(fClusters),
	[this](size_t codePointCount, SkSpan<const char> utf1to1,
	SkSpan<const SkGlyphID> glyph1to1) {
	this->displayMToN(codePointCount, utf1to1, glyph1to1);
	});
	}

	if (info.glyphCount > 1) {
	fJSONWriter->beginArray("horizontal positions", false);
	for (auto position : fPositions) {
	fJSONWriter->appendFloat(position.x());
	}
	fJSONWriter->endArray();
	}

	fJSONWriter->beginArray("advances", false);
	for (size_t i = 1; i < info.glyphCount; i++) {
	fJSONWriter->appendFloat(fPositions[i].fX - fPositions[i-1].fX);
	}
	SkPoint lastAdvance = info.fAdvance - (fPositions.back() - fPositions.front());
	fJSONWriter->appendFloat(lastAdvance.fX);
	fJSONWriter->endArray();

	fJSONWriter->endObject();
	}

	void SkShaperJSONWriter::BreakupClusters(size_t utf8Begin, size_t utf8End,
	SkSpan<const uint32_t> clusters,
	const BreakupCluastersCallback& processMToN) {

	if (clusters.front() <= clusters.back()) {
	// Handle left-to-right text direction
	size_t glyphStartIndex = 0;
	for (size_t glyphEndIndex = 0; glyphEndIndex < clusters.size(); glyphEndIndex++) {

	if (clusters[glyphStartIndex] == clusters[glyphEndIndex]) { continue; }

	processMToN(glyphStartIndex, glyphEndIndex,
	clusters[glyphStartIndex], clusters[glyphEndIndex]);

	glyphStartIndex = glyphEndIndex;
	}

	processMToN(glyphStartIndex, clusters.size(), clusters[glyphStartIndex], utf8End);

	} else {
	// Handle right-to-left text direction.
	SkASSERT(clusters.size() >= 2);
	size_t glyphStartIndex = 0;
	uint32_t utf8EndIndex = utf8End;
	for (size_t glyphEndIndex = 0; glyphEndIndex < clusters.size(); glyphEndIndex++) {

	if (clusters[glyphStartIndex] == clusters[glyphEndIndex]) { continue; }

	processMToN(glyphStartIndex, glyphEndIndex,
	clusters[glyphStartIndex], utf8EndIndex);

	utf8EndIndex = clusters[glyphStartIndex];
	glyphStartIndex = glyphEndIndex;
	}
	processMToN(glyphStartIndex, clusters.size(), utf8Begin, clusters[glyphStartIndex-1]);
	}
	}

	void SkShaperJSONWriter::VisualizeClusters(const char* utf8, size_t utf8Begin, size_t utf8End,
	SkSpan<const SkGlyphID> glyphIDs,
	SkSpan<const uint32_t> clusters,
	const VisualizeClustersCallback& processMToN) {

	size_t glyphRangeStart, glyphRangeEnd;
	uint32_t utf8RangeStart, utf8RangeEnd;

	auto resetRanges = [&]() {
	glyphRangeStart = std::numeric_limits<size_t>::max();
	glyphRangeEnd = 0;
	utf8RangeStart = std::numeric_limits<uint32_t>::max();
	utf8RangeEnd = 0;
	};

	auto checkRangesAndProcess = [&]() {
	if (glyphRangeStart < glyphRangeEnd) {
	size_t glyphRangeCount = glyphRangeEnd - glyphRangeStart;
	SkSpan<const char> utf8Span{&utf8[utf8RangeStart], utf8RangeEnd - utf8RangeStart};
	SkSpan<const SkGlyphID> glyphSpan{&glyphIDs[glyphRangeStart], glyphRangeCount};

	// Glyph count is the same as codepoint count for 1:1.
	processMToN(glyphRangeCount, utf8Span, glyphSpan);
	}
	resetRanges();
	};

	auto gatherRuns = [&](size_t glyphStartIndex, size_t glyphEndIndex,
	uint32_t utf8StartIndex, uint32_t utf8EndIndex) {
	int possibleCount = SkUTF::CountUTF8(&utf8[utf8StartIndex], utf8EndIndex - utf8StartIndex);
	if (possibleCount == -1) { return; }
	size_t codePointCount = SkTo<size_t>(possibleCount);
	if (codePointCount == 1 && glyphEndIndex - glyphStartIndex == 1) {
	glyphRangeStart = std::min(glyphRangeStart, glyphStartIndex);
	glyphRangeEnd = std::max(glyphRangeEnd, glyphEndIndex );
	utf8RangeStart = std::min(utf8RangeStart, utf8StartIndex );
	utf8RangeEnd = std::max(utf8RangeEnd, utf8EndIndex );
	} else {
	checkRangesAndProcess();

	SkSpan<const char> utf8Span{&utf8[utf8StartIndex], utf8EndIndex - utf8StartIndex};
	SkSpan<const SkGlyphID> glyphSpan{&glyphIDs[glyphStartIndex],
	glyphEndIndex - glyphStartIndex};

	processMToN(codePointCount, utf8Span, glyphSpan);
	}
	};

	resetRanges();
	BreakupClusters(utf8Begin, utf8End, clusters, gatherRuns);
	checkRangesAndProcess();
	}

	void SkShaperJSONWriter::displayMToN(size_t codePointCount,
	SkSpan<const char> utf8,
	SkSpan<const SkGlyphID> glyphIDs) {
	std::string nString = std::to_string(codePointCount);
	std::string mString = std::to_string(glyphIDs.size());
	std::string clusterName = "cluster " + nString + " to " + mString;
	fJSONWriter->beginObject(clusterName.c_str(), true);
	std::string utf8String{utf8.data(), utf8.size()};
	fJSONWriter->appendString("UTF", utf8String.c_str());
	fJSONWriter->beginArray("glyphsIDs", false);
	for (auto glyphID : glyphIDs) {
	fJSONWriter->appendU32(glyphID);
	}
	fJSONWriter->endArray();
	fJSONWriter->endObject();
	}