modules/svg/src/SkSVGText.cpp - skia - Git at Google

 /*
  * 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 "modules/svg/include/SkSVGText.h"

 #include <limits>

 #include "include/core/SkCanvas.h"
 #include "include/core/SkContourMeasure.h"
 #include "include/core/SkFont.h"
 #include "include/core/SkFontMgr.h"
 #include "include/core/SkFontStyle.h"
 #include "include/core/SkPathBuilder.h"
 #include "include/core/SkRSXform.h"
 #include "include/core/SkString.h"
 #include "modules/skshaper/include/SkShaper.h"
 #include "modules/svg/include/SkSVGRenderContext.h"
 #include "modules/svg/include/SkSVGValue.h"
 #include "modules/svg/src/SkSVGTextPriv.h"
 #include "src/core/SkTextBlobPriv.h"
 #include "src/utils/SkUTF.h"

 namespace {

 static SkFont ResolveFont(const SkSVGRenderContext& ctx) {
     auto weight = [](const SkSVGFontWeight& w) {
         switch (w.type()) {
             case SkSVGFontWeight::Type::k100:     return SkFontStyle::kThin_Weight;
             case SkSVGFontWeight::Type::k200:     return SkFontStyle::kExtraLight_Weight;
             case SkSVGFontWeight::Type::k300:     return SkFontStyle::kLight_Weight;
             case SkSVGFontWeight::Type::k400:     return SkFontStyle::kNormal_Weight;
             case SkSVGFontWeight::Type::k500:     return SkFontStyle::kMedium_Weight;
             case SkSVGFontWeight::Type::k600:     return SkFontStyle::kSemiBold_Weight;
             case SkSVGFontWeight::Type::k700:     return SkFontStyle::kBold_Weight;
             case SkSVGFontWeight::Type::k800:     return SkFontStyle::kExtraBold_Weight;
             case SkSVGFontWeight::Type::k900:     return SkFontStyle::kBlack_Weight;
             case SkSVGFontWeight::Type::kNormal:  return SkFontStyle::kNormal_Weight;
             case SkSVGFontWeight::Type::kBold:    return SkFontStyle::kBold_Weight;
             case SkSVGFontWeight::Type::kBolder:  return SkFontStyle::kExtraBold_Weight;
             case SkSVGFontWeight::Type::kLighter: return SkFontStyle::kLight_Weight;
             case SkSVGFontWeight::Type::kInherit: {
                 SkASSERT(false);
                 return SkFontStyle::kNormal_Weight;
             }
         }
         SkUNREACHABLE;
     };

     auto slant = [](const SkSVGFontStyle& s) {
         switch (s.type()) {
             case SkSVGFontStyle::Type::kNormal:  return SkFontStyle::kUpright_Slant;
             case SkSVGFontStyle::Type::kItalic:  return SkFontStyle::kItalic_Slant;
             case SkSVGFontStyle::Type::kOblique: return SkFontStyle::kOblique_Slant;
             case SkSVGFontStyle::Type::kInherit: {
                 SkASSERT(false);
                 return SkFontStyle::kUpright_Slant;
             }
         }
         SkUNREACHABLE;
     };

     const auto& family = ctx.presentationContext().fInherited.fFontFamily->family();
     const SkFontStyle style(weight(*ctx.presentationContext().fInherited.fFontWeight),
                             SkFontStyle::kNormal_Width,
                             slant(*ctx.presentationContext().fInherited.fFontStyle));

     const auto size =
             ctx.lengthContext().resolve(ctx.presentationContext().fInherited.fFontSize->size(),
                                         SkSVGLengthContext::LengthType::kVertical);

     // TODO: we likely want matchFamilyStyle here, but switching away from legacyMakeTypeface
     // changes all the results when using the default fontmgr.
     auto tf = ctx.fontMgr()->legacyMakeTypeface(family.c_str(), style);

     SkFont font(std::move(tf), size);
     font.setHinting(SkFontHinting::kNone);
     font.setSubpixel(true);
     font.setLinearMetrics(true);
     font.setBaselineSnap(false);
     font.setEdging(SkFont::Edging::kAntiAlias);

     return font;
 }

 static std::vector<float> ResolveLengths(const SkSVGLengthContext& lctx,
                                          const std::vector<SkSVGLength>& lengths,
                                          SkSVGLengthContext::LengthType lt) {
     std::vector<float> resolved;
     resolved.reserve(lengths.size());

     for (const auto& l : lengths) {
         resolved.push_back(lctx.resolve(l, lt));
     }

     return resolved;
 }

 static float ComputeAlignmentFactor(const SkSVGPresentationContext& pctx) {
     switch (pctx.fInherited.fTextAnchor->type()) {
     case SkSVGTextAnchor::Type::kStart : return  0.0f;
     case SkSVGTextAnchor::Type::kMiddle: return -0.5f;
     case SkSVGTextAnchor::Type::kEnd   : return -1.0f;
     case SkSVGTextAnchor::Type::kInherit:
         SkASSERT(false);
         return 0.0f;
     }
     SkUNREACHABLE;
 }

 } // namespace

 SkSVGTextContext::ScopedPosResolver::ScopedPosResolver(const SkSVGTextContainer& txt,
                                                        const SkSVGLengthContext& lctx,
                                                        SkSVGTextContext* tctx,
                                                        size_t charIndexOffset)
     : fTextContext(tctx)
     , fParent(tctx->fPosResolver)
     , fCharIndexOffset(charIndexOffset)
     , fX(ResolveLengths(lctx, txt.getX(), SkSVGLengthContext::LengthType::kHorizontal))
     , fY(ResolveLengths(lctx, txt.getY(), SkSVGLengthContext::LengthType::kVertical))
     , fDx(ResolveLengths(lctx, txt.getDx(), SkSVGLengthContext::LengthType::kHorizontal))
     , fDy(ResolveLengths(lctx, txt.getDy(), SkSVGLengthContext::LengthType::kVertical))
     , fRotate(txt.getRotate())
 {
     fTextContext->fPosResolver = this;
 }

 SkSVGTextContext::ScopedPosResolver::ScopedPosResolver(const SkSVGTextContainer& txt,
                                                        const SkSVGLengthContext& lctx,
                                                        SkSVGTextContext* tctx)
     : ScopedPosResolver(txt, lctx, tctx, tctx->fCurrentCharIndex) {}

 SkSVGTextContext::ScopedPosResolver::~ScopedPosResolver() {
     fTextContext->fPosResolver = fParent;
 }

 SkSVGTextContext::PosAttrs SkSVGTextContext::ScopedPosResolver::resolve(size_t charIndex) const {
     PosAttrs attrs;

     if (charIndex < fLastPosIndex) {
         SkASSERT(charIndex >= fCharIndexOffset);
         const auto localCharIndex = charIndex - fCharIndexOffset;

         const auto hasAllLocal = localCharIndex < fX.size() &&
                                  localCharIndex < fY.size() &&
                                  localCharIndex < fDx.size() &&
                                  localCharIndex < fDy.size() &&
                                  localCharIndex < fRotate.size();
         if (!hasAllLocal && fParent) {
             attrs = fParent->resolve(charIndex);
         }

         if (localCharIndex < fX.size()) {
             attrs[PosAttrs::kX] = fX[localCharIndex];
         }
         if (localCharIndex < fY.size()) {
             attrs[PosAttrs::kY] = fY[localCharIndex];
         }
         if (localCharIndex < fDx.size()) {
             attrs[PosAttrs::kDx] = fDx[localCharIndex];
         }
         if (localCharIndex < fDy.size()) {
             attrs[PosAttrs::kDy] = fDy[localCharIndex];
         }

         // Rotation semantics are interestingly different [1]:
         //
         //   - values are not cumulative
         //   - if explicit values are present at any level in the ancestor chain, those take
         //     precedence (closest ancestor)
         //   - last specified value applies to all remaining chars (closest ancestor)
         //   - these rules apply at node scope (not chunk scope)
         //
         // This means we need to discriminate between explicit rotation (rotate value provided for
         // current char) and implicit rotation (ancestor has some values - but not for the requested
         // char - we use the last specified value).
         //
         // [1] https://www.w3.org/TR/SVG11/text.html#TSpanElementRotateAttribute
         if (!fRotate.empty()) {
             if (localCharIndex < fRotate.size()) {
                 // Explicit rotation value overrides anything in the ancestor chain.
                 attrs[PosAttrs::kRotate] = fRotate[localCharIndex];
                 attrs.setImplicitRotate(false);
             } else if (!attrs.has(PosAttrs::kRotate) || attrs.isImplicitRotate()){
                 // Local implicit rotation (last specified value) overrides ancestor implicit
                 // rotation.
                 attrs[PosAttrs::kRotate] = fRotate.back();
                 attrs.setImplicitRotate(true);
             }
         }

         if (!attrs.hasAny()) {
             // Once we stop producing explicit position data, there is no reason to
             // continue trying for higher indices.  We can suppress future lookups.
             fLastPosIndex = charIndex;
         }
     }

     return attrs;
 }

 void SkSVGTextContext::ShapeBuffer::append(SkUnichar ch, PositionAdjustment pos) {
     // relative pos adjustments are cumulative
     if (!fUtf8PosAdjust.empty()) {
         pos.offset += fUtf8PosAdjust.back().offset;
     }

     char utf8_buf[SkUTF::kMaxBytesInUTF8Sequence];
     const auto utf8_len = SkToInt(SkUTF::ToUTF8(ch, utf8_buf));
     fUtf8         .push_back_n(utf8_len, utf8_buf);
     fUtf8PosAdjust.push_back_n(utf8_len, pos);
 }

 void SkSVGTextContext::shapePendingBuffer(const SkFont& font) {
     // TODO: directionality hints?
     const auto LTR  = true;

     // Initiate shaping: this will generate a series of runs via callbacks.
     fShaper->shape(fShapeBuffer.fUtf8.data(), fShapeBuffer.fUtf8.size(),
                    font, LTR, SK_ScalarMax, this);
     fShapeBuffer.reset();
 }

 SkSVGTextContext::SkSVGTextContext(const SkSVGRenderContext& ctx, const ShapedTextCallback& cb,
                                    const SkSVGTextPath* tpath)
     : fRenderContext(ctx)
     , fCallback(cb)
     , fShaper(SkShaper::Make(ctx.fontMgr()))
     , fChunkAlignmentFactor(ComputeAlignmentFactor(ctx.presentationContext()))
 {
     if (tpath) {
         fPathData = std::make_unique<PathData>(ctx, *tpath);

         // https://www.w3.org/TR/SVG11/text.html#TextPathElementStartOffsetAttribute
         auto resolve_offset = [this](const SkSVGLength& offset) {
             if (offset.unit() != SkSVGLength::Unit::kPercentage) {
                 // "If a <length> other than a percentage is given, then the ‘startOffset’
                 // represents a distance along the path measured in the current user coordinate
                 // system."
                 return fRenderContext.lengthContext()
                                      .resolve(offset, SkSVGLengthContext::LengthType::kHorizontal);
             }

             // "If a percentage is given, then the ‘startOffset’ represents a percentage distance
             // along the entire path."
             return offset.value() * fPathData->length() / 100;
         };

         // startOffset acts as an initial absolute position
         fChunkPos.fX = resolve_offset(tpath->getStartOffset());
     }
 }

 SkSVGTextContext::~SkSVGTextContext() {
     this->flushChunk(fRenderContext);
 }

 void SkSVGTextContext::shapeFragment(const SkString& txt, const SkSVGRenderContext& ctx,
                                      SkSVGXmlSpace xs) {
     // https://www.w3.org/TR/SVG11/text.html#WhiteSpace
     // https://www.w3.org/TR/2008/REC-xml-20081126/#NT-S
     auto filterWSDefault = [this](SkUnichar ch) -> SkUnichar {
         // Remove all newline chars.
         if (ch == '\n') {
             return -1;
         }

         // Convert tab chars to space.
         if (ch == '\t') {
             ch = ' ';
         }

         // Consolidate contiguous space chars and strip leading spaces (fPrevCharSpace
         // starts off as true).
         if (fPrevCharSpace && ch == ' ') {
             return -1;
         }

         // TODO: Strip trailing WS?  Doing this across chunks would require another buffering
         //   layer.  In general, trailing WS should have no rendering side effects. Skipping
         //   for now.
         return ch;
     };
     auto filterWSPreserve = [](SkUnichar ch) -> SkUnichar {
         // Convert newline and tab chars to space.
         if (ch == '\n' || ch == '\t') {
             ch = ' ';
         }
         return ch;
     };

     // Stash paints for access from SkShaper callbacks.
     fCurrentFill   = ctx.fillPaint();
     fCurrentStroke = ctx.strokePaint();

     const auto font = ResolveFont(ctx);
     fShapeBuffer.reserve(txt.size());

     const char* ch_ptr = txt.c_str();
     const char* ch_end = ch_ptr + txt.size();

     while (ch_ptr < ch_end) {
         auto ch = SkUTF::NextUTF8(&ch_ptr, ch_end);
         ch = (xs == SkSVGXmlSpace::kDefault)
                 ? filterWSDefault(ch)
                 : filterWSPreserve(ch);

         if (ch < 0) {
             // invalid utf or char filtered out
             continue;
         }

         SkASSERT(fPosResolver);
         const auto pos = fPosResolver->resolve(fCurrentCharIndex++);

         // Absolute position adjustments define a new chunk.
         // (https://www.w3.org/TR/SVG11/text.html#TextLayoutIntroduction)
         if (pos.has(PosAttrs::kX) || pos.has(PosAttrs::kY)) {
             this->shapePendingBuffer(font);
             this->flushChunk(ctx);

             // New chunk position.
             if (pos.has(PosAttrs::kX)) {
                 fChunkPos.fX = pos[PosAttrs::kX];
             }
             if (pos.has(PosAttrs::kY)) {
                 fChunkPos.fY = pos[PosAttrs::kY];
             }
         }

         fShapeBuffer.append(ch, {
             {
                 pos.has(PosAttrs::kDx) ? pos[PosAttrs::kDx] : 0,
                 pos.has(PosAttrs::kDy) ? pos[PosAttrs::kDy] : 0,
             },
             pos.has(PosAttrs::kRotate) ? SkDegreesToRadians(pos[PosAttrs::kRotate]) : 0,
         });

         fPrevCharSpace = (ch == ' ');
     }

     this->shapePendingBuffer(font);

     // Note: at this point we have shaped and buffered RunRecs for the current fragment.
     // The active text chunk continues until an explicit or implicit flush.
 }

 SkSVGTextContext::PathData::PathData(const SkSVGRenderContext& ctx, const SkSVGTextPath& tpath)
 {
     const auto ref = ctx.findNodeById(tpath.getHref());
     if (!ref) {
         return;
     }

     SkContourMeasureIter cmi(ref->asPath(ctx), false);
     while (sk_sp<SkContourMeasure> contour = cmi.next()) {
         fLength += contour->length();
         fContours.push_back(std::move(contour));
     }
 }

 SkMatrix SkSVGTextContext::PathData::getMatrixAt(float offset) const {
     if (offset >= 0) {
         for (const auto& contour : fContours) {
             const auto contour_len = contour->length();
             if (offset < contour_len) {
                 SkMatrix m;
                 return contour->getMatrix(offset, &m) ? m : SkMatrix::I();
             }
             offset -= contour_len;
         }
     }

     // Quick & dirty way to "skip" rendering of glyphs off path.
     return SkMatrix::Translate(std::numeric_limits<float>::infinity(),
                                std::numeric_limits<float>::infinity());
 }

 SkRSXform SkSVGTextContext::computeGlyphXform(SkGlyphID glyph, const SkFont& font,
                                               const SkPoint& glyph_pos,
                                               const PositionAdjustment& pos_adjust) const {
     SkPoint pos = fChunkPos + glyph_pos + pos_adjust.offset + fChunkAdvance * fChunkAlignmentFactor;
     if (!fPathData) {
         return SkRSXform::MakeFromRadians(/*scale=*/ 1, pos_adjust.rotation, pos.fX, pos.fY, 0, 0);
     }

     // We're in a textPath scope, reposition the glyph on path.
     // (https://www.w3.org/TR/SVG11/text.html#TextpathLayoutRules)

     // Path positioning is based on the glyph center (horizontal component).
     float glyph_width;
     font.getWidths(&glyph, 1, &glyph_width);
     auto path_offset = pos.fX + glyph_width * .5f;

     // In addition to the path matrix, the final glyph matrix also includes:
     //
     //   -- vertical position adjustment "dy" ("dx" is factored into path_offset)
     //   -- glyph origin adjustment (undoing the glyph center offset above)
     //   -- explicit rotation adjustment (composing with the path glyph rotation)
     const auto m = fPathData->getMatrixAt(path_offset) *
             SkMatrix::Translate(-glyph_width * .5f, pos_adjust.offset.fY) *
             SkMatrix::RotateRad(pos_adjust.rotation);

     return SkRSXform::Make(m.getScaleX(), m.getSkewY(), m.getTranslateX(), m.getTranslateY());
 }

 void SkSVGTextContext::flushChunk(const SkSVGRenderContext& ctx) {
     SkTextBlobBuilder blobBuilder;

     for (const auto& run : fRuns) {
         const auto& buf = blobBuilder.allocRunRSXform(run.font, SkToInt(run.glyphCount));
         std::copy(run.glyphs.get(), run.glyphs.get() + run.glyphCount, buf.glyphs);
         for (size_t i = 0; i < run.glyphCount; ++i) {
             buf.xforms()[i] = this->computeGlyphXform(run.glyphs[i],
                                                       run.font,
                                                       run.glyphPos[i],
                                                       run.glyhPosAdjust[i]);
         }

         fCallback(ctx, blobBuilder.make(), run.fillPaint.get(), run.strokePaint.get());
     }

     fChunkPos += fChunkAdvance;
     fChunkAdvance = {0,0};
     fChunkAlignmentFactor = ComputeAlignmentFactor(ctx.presentationContext());

     fRuns.clear();
 }

 SkShaper::RunHandler::Buffer SkSVGTextContext::runBuffer(const RunInfo& ri) {
     SkASSERT(ri.glyphCount);

     fRuns.push_back({
         ri.fFont,
         fCurrentFill.isValid()   ? std::make_unique<SkPaint>(*fCurrentFill)   : nullptr,
         fCurrentStroke.isValid() ? std::make_unique<SkPaint>(*fCurrentStroke) : nullptr,
         std::make_unique<SkGlyphID[]         >(ri.glyphCount),
         std::make_unique<SkPoint[]           >(ri.glyphCount),
         std::make_unique<PositionAdjustment[]>(ri.glyphCount),
         ri.glyphCount,
         ri.fAdvance,
     });

     // Ensure sufficient space to temporarily fetch cluster information.
     fShapeClusterBuffer.resize(std::max(fShapeClusterBuffer.size(), ri.glyphCount));

     return {
         fRuns.back().glyphs.get(),
         fRuns.back().glyphPos.get(),
         nullptr,
         fShapeClusterBuffer.data(),
         fChunkAdvance,
     };
 }

 void SkSVGTextContext::commitRunBuffer(const RunInfo& ri) {
     const auto& current_run = fRuns.back();

     // stash position adjustments
     for (size_t i = 0; i < ri.glyphCount; ++i) {
         const auto utf8_index = fShapeClusterBuffer[i];
         current_run.glyhPosAdjust[i] = fShapeBuffer.fUtf8PosAdjust[SkToInt(utf8_index)];
     }

     // Offset adjustments are cumulative - we only need to advance the current chunk
     // with the last value.
     fChunkAdvance += ri.fAdvance + fShapeBuffer.fUtf8PosAdjust.back().offset;
 }

 void SkSVGTextFragment::renderText(const SkSVGRenderContext& ctx, SkSVGTextContext* tctx,
                                    SkSVGXmlSpace xs) const {
     // N.B.: unlike regular elements, text fragments do not establish a new OBB scope -- they
     // always defer to the root <text> element for OBB resolution.
     SkSVGRenderContext localContext(ctx);

     if (this->onPrepareToRender(&localContext)) {
         this->onShapeText(localContext, tctx, xs);
     }
 }

 SkPath SkSVGTextFragment::onAsPath(const SkSVGRenderContext&) const {
     // TODO
     return SkPath();
 }

 void SkSVGTextContainer::appendChild(sk_sp<SkSVGNode> child) {
     // Only allow text content child nodes.
     switch (child->tag()) {
     case SkSVGTag::kTextLiteral:
     case SkSVGTag::kTextPath:
     case SkSVGTag::kTSpan:
         fChildren.push_back(
             sk_sp<SkSVGTextFragment>(static_cast<SkSVGTextFragment*>(child.release())));
         break;
     default:
         break;
     }
 }

 void SkSVGTextContainer::onShapeText(const SkSVGRenderContext& ctx, SkSVGTextContext* tctx,
                                      SkSVGXmlSpace) const {
     SkASSERT(tctx);

     const SkSVGTextContext::ScopedPosResolver resolver(*this, ctx.lengthContext(), tctx);

     for (const auto& frag : fChildren) {
         // Containers always override xml:space with the local value.
         frag->renderText(ctx, tctx, this->getXmlSpace());
     }
 }

 // https://www.w3.org/TR/SVG11/text.html#WhiteSpace
 template <>
 bool SkSVGAttributeParser::parse(SkSVGXmlSpace* xs) {
     static constexpr std::tuple<const char*, SkSVGXmlSpace> gXmlSpaceMap[] = {
             {"default" , SkSVGXmlSpace::kDefault },
             {"preserve", SkSVGXmlSpace::kPreserve},
     };

     return this->parseEnumMap(gXmlSpaceMap, xs) && this->parseEOSToken();
 }

 bool SkSVGTextContainer::parseAndSetAttribute(const char* name, const char* value) {
     return INHERITED::parseAndSetAttribute(name, value) ||
            this->setX(SkSVGAttributeParser::parse<std::vector<SkSVGLength>>("x", name, value)) ||
            this->setY(SkSVGAttributeParser::parse<std::vector<SkSVGLength>>("y", name, value)) ||
            this->setDx(SkSVGAttributeParser::parse<std::vector<SkSVGLength>>("dx", name, value)) ||
            this->setDy(SkSVGAttributeParser::parse<std::vector<SkSVGLength>>("dy", name, value)) ||
            this->setRotate(SkSVGAttributeParser::parse<std::vector<SkSVGNumberType>>("rotate",
                                                                                      name,
                                                                                      value)) ||
            this->setXmlSpace(SkSVGAttributeParser::parse<SkSVGXmlSpace>("xml:space", name, value));
 }

 void SkSVGTextLiteral::onShapeText(const SkSVGRenderContext& ctx, SkSVGTextContext* tctx,
                                    SkSVGXmlSpace xs) const {
     SkASSERT(tctx);

     tctx->shapeFragment(this->getText(), ctx, xs);
 }

 void SkSVGText::onRender(const SkSVGRenderContext& ctx) const {
     const SkSVGTextContext::ShapedTextCallback render_text = [](const SkSVGRenderContext& ctx,
                                                                 const sk_sp<SkTextBlob>& blob,
                                                                 const SkPaint* fill,
                                                                 const SkPaint* stroke) {
         if (fill) {
             ctx.canvas()->drawTextBlob(blob, 0, 0, *fill);
         }
         if (stroke) {
             ctx.canvas()->drawTextBlob(blob, 0, 0, *stroke);
         }
     };

     // Root <text> nodes establish a text layout context.
     SkSVGTextContext tctx(ctx, render_text);

     this->onShapeText(ctx, &tctx, this->getXmlSpace());
 }

 SkRect SkSVGText::onObjectBoundingBox(const SkSVGRenderContext& ctx) const {
     SkRect bounds = SkRect::MakeEmpty();

     const SkSVGTextContext::ShapedTextCallback compute_bounds =
         [&bounds](const SkSVGRenderContext& ctx, const sk_sp<SkTextBlob>& blob, const SkPaint*,
                   const SkPaint*) {
             if (!blob) {
                 return;
             }

             SkAutoSTArray<64, SkRect> glyphBounds;

             SkTextBlobRunIterator it(blob.get());

             for (SkTextBlobRunIterator it(blob.get()); !it.done(); it.next()) {
                 glyphBounds.reset(SkToInt(it.glyphCount()));
                 it.font().getBounds(it.glyphs(), it.glyphCount(), glyphBounds.get(), nullptr);

                 SkASSERT(it.positioning() == SkTextBlobRunIterator::kRSXform_Positioning);
                 SkMatrix m;
                 for (uint32_t i = 0; i < it.glyphCount(); ++i) {
                     m.setRSXform(it.xforms()[i]);
                     bounds.join(m.mapRect(glyphBounds[i]));
                 }
             }
         };

     {
         SkSVGTextContext tctx(ctx, compute_bounds);
         this->onShapeText(ctx, &tctx, this->getXmlSpace());
     }

     return bounds;
 }

 SkPath SkSVGText::onAsPath(const SkSVGRenderContext& ctx) const {
     SkPathBuilder builder;

     const SkSVGTextContext::ShapedTextCallback as_path =
         [&builder](const SkSVGRenderContext& ctx, const sk_sp<SkTextBlob>& blob, const SkPaint*,
                    const SkPaint*) {
             if (!blob) {
                 return;
             }

             SkTextBlobRunIterator it(blob.get());
             for (SkTextBlobRunIterator it(blob.get()); !it.done(); it.next()) {
                 struct GetPathsCtx {
                     SkPathBuilder&   builder;
                     const SkRSXform* xform;
                 } get_paths_ctx {builder, it.xforms()};

                 it.font().getPaths(it.glyphs(), it.glyphCount(), [](const SkPath* path,
                                                                     const SkMatrix& matrix,
                                                                     void* raw_ctx) {
                     auto* get_paths_ctx = static_cast<GetPathsCtx*>(raw_ctx);
                     const auto& glyph_rsx = *get_paths_ctx->xform++;

                     if (!path) {
                         return;
                     }

                     SkMatrix glyph_matrix;
                     glyph_matrix.setRSXform(glyph_rsx);
                     glyph_matrix.preConcat(matrix);

                     get_paths_ctx->builder.addPath(path->makeTransform(glyph_matrix));
                 }, &get_paths_ctx);
             }
         };

     {
         SkSVGTextContext tctx(ctx, as_path);
         this->onShapeText(ctx, &tctx, this->getXmlSpace());
     }

     auto path = builder.detach();
     this->mapToParent(&path);

     return path;
 }

 void SkSVGTextPath::onShapeText(const SkSVGRenderContext& ctx, SkSVGTextContext* parent_tctx,
                                  SkSVGXmlSpace xs) const {
     SkASSERT(parent_tctx);

     // textPath nodes establish a new text layout context.
     SkSVGTextContext tctx(ctx, parent_tctx->getCallback(), this);

     this->INHERITED::onShapeText(ctx, &tctx, xs);
 }

 bool SkSVGTextPath::parseAndSetAttribute(const char* name, const char* value) {
     return INHERITED::parseAndSetAttribute(name, value) ||
         this->setHref(SkSVGAttributeParser::parse<SkSVGIRI>("xlink:href", name, value)) ||
         this->setStartOffset(SkSVGAttributeParser::parse<SkSVGLength>("startOffset", name, value));
 }
	/*
	* 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 "modules/svg/include/SkSVGText.h"

	#include <limits>

	#include "include/core/SkCanvas.h"
	#include "include/core/SkContourMeasure.h"
	#include "include/core/SkFont.h"
	#include "include/core/SkFontMgr.h"
	#include "include/core/SkFontStyle.h"
	#include "include/core/SkPathBuilder.h"
	#include "include/core/SkRSXform.h"
	#include "include/core/SkString.h"
	#include "modules/skshaper/include/SkShaper.h"
	#include "modules/svg/include/SkSVGRenderContext.h"
	#include "modules/svg/include/SkSVGValue.h"
	#include "modules/svg/src/SkSVGTextPriv.h"
	#include "src/core/SkTextBlobPriv.h"
	#include "src/utils/SkUTF.h"

	namespace {

	static SkFont ResolveFont(const SkSVGRenderContext& ctx) {
	auto weight = [](const SkSVGFontWeight& w) {
	switch (w.type()) {
	case SkSVGFontWeight::Type::k100: return SkFontStyle::kThin_Weight;
	case SkSVGFontWeight::Type::k200: return SkFontStyle::kExtraLight_Weight;
	case SkSVGFontWeight::Type::k300: return SkFontStyle::kLight_Weight;
	case SkSVGFontWeight::Type::k400: return SkFontStyle::kNormal_Weight;
	case SkSVGFontWeight::Type::k500: return SkFontStyle::kMedium_Weight;
	case SkSVGFontWeight::Type::k600: return SkFontStyle::kSemiBold_Weight;
	case SkSVGFontWeight::Type::k700: return SkFontStyle::kBold_Weight;
	case SkSVGFontWeight::Type::k800: return SkFontStyle::kExtraBold_Weight;
	case SkSVGFontWeight::Type::k900: return SkFontStyle::kBlack_Weight;
	case SkSVGFontWeight::Type::kNormal: return SkFontStyle::kNormal_Weight;
	case SkSVGFontWeight::Type::kBold: return SkFontStyle::kBold_Weight;
	case SkSVGFontWeight::Type::kBolder: return SkFontStyle::kExtraBold_Weight;
	case SkSVGFontWeight::Type::kLighter: return SkFontStyle::kLight_Weight;
	case SkSVGFontWeight::Type::kInherit: {
	SkASSERT(false);
	return SkFontStyle::kNormal_Weight;
	}
	}
	SkUNREACHABLE;
	};

	auto slant = [](const SkSVGFontStyle& s) {
	switch (s.type()) {
	case SkSVGFontStyle::Type::kNormal: return SkFontStyle::kUpright_Slant;
	case SkSVGFontStyle::Type::kItalic: return SkFontStyle::kItalic_Slant;
	case SkSVGFontStyle::Type::kOblique: return SkFontStyle::kOblique_Slant;
	case SkSVGFontStyle::Type::kInherit: {
	SkASSERT(false);
	return SkFontStyle::kUpright_Slant;
	}
	}
	SkUNREACHABLE;
	};

	const auto& family = ctx.presentationContext().fInherited.fFontFamily->family();
	const SkFontStyle style(weight(*ctx.presentationContext().fInherited.fFontWeight),
	SkFontStyle::kNormal_Width,
	slant(*ctx.presentationContext().fInherited.fFontStyle));

	const auto size =
	ctx.lengthContext().resolve(ctx.presentationContext().fInherited.fFontSize->size(),
	SkSVGLengthContext::LengthType::kVertical);

	// TODO: we likely want matchFamilyStyle here, but switching away from legacyMakeTypeface
	// changes all the results when using the default fontmgr.
	auto tf = ctx.fontMgr()->legacyMakeTypeface(family.c_str(), style);

	SkFont font(std::move(tf), size);
	font.setHinting(SkFontHinting::kNone);
	font.setSubpixel(true);
	font.setLinearMetrics(true);
	font.setBaselineSnap(false);
	font.setEdging(SkFont::Edging::kAntiAlias);

	return font;
	}

	static std::vector<float> ResolveLengths(const SkSVGLengthContext& lctx,
	const std::vector<SkSVGLength>& lengths,
	SkSVGLengthContext::LengthType lt) {
	std::vector<float> resolved;
	resolved.reserve(lengths.size());

	for (const auto& l : lengths) {
	resolved.push_back(lctx.resolve(l, lt));
	}

	return resolved;
	}

	static float ComputeAlignmentFactor(const SkSVGPresentationContext& pctx) {
	switch (pctx.fInherited.fTextAnchor->type()) {
	case SkSVGTextAnchor::Type::kStart : return 0.0f;
	case SkSVGTextAnchor::Type::kMiddle: return -0.5f;
	case SkSVGTextAnchor::Type::kEnd : return -1.0f;
	case SkSVGTextAnchor::Type::kInherit:
	SkASSERT(false);
	return 0.0f;
	}
	SkUNREACHABLE;
	}

	} // namespace

	SkSVGTextContext::ScopedPosResolver::ScopedPosResolver(const SkSVGTextContainer& txt,
	const SkSVGLengthContext& lctx,
	SkSVGTextContext* tctx,
	size_t charIndexOffset)
	: fTextContext(tctx)
	, fParent(tctx->fPosResolver)
	, fCharIndexOffset(charIndexOffset)
	, fX(ResolveLengths(lctx, txt.getX(), SkSVGLengthContext::LengthType::kHorizontal))
	, fY(ResolveLengths(lctx, txt.getY(), SkSVGLengthContext::LengthType::kVertical))
	, fDx(ResolveLengths(lctx, txt.getDx(), SkSVGLengthContext::LengthType::kHorizontal))
	, fDy(ResolveLengths(lctx, txt.getDy(), SkSVGLengthContext::LengthType::kVertical))
	, fRotate(txt.getRotate())
	{
	fTextContext->fPosResolver = this;
	}

	SkSVGTextContext::ScopedPosResolver::ScopedPosResolver(const SkSVGTextContainer& txt,
	const SkSVGLengthContext& lctx,
	SkSVGTextContext* tctx)
	: ScopedPosResolver(txt, lctx, tctx, tctx->fCurrentCharIndex) {}

	SkSVGTextContext::ScopedPosResolver::~ScopedPosResolver() {
	fTextContext->fPosResolver = fParent;
	}

	SkSVGTextContext::PosAttrs SkSVGTextContext::ScopedPosResolver::resolve(size_t charIndex) const {
	PosAttrs attrs;

	if (charIndex < fLastPosIndex) {
	SkASSERT(charIndex >= fCharIndexOffset);
	const auto localCharIndex = charIndex - fCharIndexOffset;

	const auto hasAllLocal = localCharIndex < fX.size() &&
	localCharIndex < fY.size() &&
	localCharIndex < fDx.size() &&
	localCharIndex < fDy.size() &&
	localCharIndex < fRotate.size();
	if (!hasAllLocal && fParent) {
	attrs = fParent->resolve(charIndex);
	}

	if (localCharIndex < fX.size()) {
	attrs[PosAttrs::kX] = fX[localCharIndex];
	}
	if (localCharIndex < fY.size()) {
	attrs[PosAttrs::kY] = fY[localCharIndex];
	}
	if (localCharIndex < fDx.size()) {
	attrs[PosAttrs::kDx] = fDx[localCharIndex];
	}
	if (localCharIndex < fDy.size()) {
	attrs[PosAttrs::kDy] = fDy[localCharIndex];
	}

	// Rotation semantics are interestingly different [1]:
	//
	// - values are not cumulative
	// - if explicit values are present at any level in the ancestor chain, those take
	// precedence (closest ancestor)
	// - last specified value applies to all remaining chars (closest ancestor)
	// - these rules apply at node scope (not chunk scope)
	//
	// This means we need to discriminate between explicit rotation (rotate value provided for
	// current char) and implicit rotation (ancestor has some values - but not for the requested
	// char - we use the last specified value).
	//
	// [1] https://www.w3.org/TR/SVG11/text.html#TSpanElementRotateAttribute
	if (!fRotate.empty()) {
	if (localCharIndex < fRotate.size()) {
	// Explicit rotation value overrides anything in the ancestor chain.
	attrs[PosAttrs::kRotate] = fRotate[localCharIndex];
	attrs.setImplicitRotate(false);
	} else if (!attrs.has(PosAttrs::kRotate) \|\| attrs.isImplicitRotate()){
	// Local implicit rotation (last specified value) overrides ancestor implicit
	// rotation.
	attrs[PosAttrs::kRotate] = fRotate.back();
	attrs.setImplicitRotate(true);
	}
	}

	if (!attrs.hasAny()) {
	// Once we stop producing explicit position data, there is no reason to
	// continue trying for higher indices. We can suppress future lookups.
	fLastPosIndex = charIndex;
	}
	}

	return attrs;
	}

	void SkSVGTextContext::ShapeBuffer::append(SkUnichar ch, PositionAdjustment pos) {
	// relative pos adjustments are cumulative
	if (!fUtf8PosAdjust.empty()) {
	pos.offset += fUtf8PosAdjust.back().offset;
	}

	char utf8_buf[SkUTF::kMaxBytesInUTF8Sequence];
	const auto utf8_len = SkToInt(SkUTF::ToUTF8(ch, utf8_buf));
	fUtf8 .push_back_n(utf8_len, utf8_buf);
	fUtf8PosAdjust.push_back_n(utf8_len, pos);
	}

	void SkSVGTextContext::shapePendingBuffer(const SkFont& font) {
	// TODO: directionality hints?
	const auto LTR = true;

	// Initiate shaping: this will generate a series of runs via callbacks.
	fShaper->shape(fShapeBuffer.fUtf8.data(), fShapeBuffer.fUtf8.size(),
	font, LTR, SK_ScalarMax, this);
	fShapeBuffer.reset();
	}

	SkSVGTextContext::SkSVGTextContext(const SkSVGRenderContext& ctx, const ShapedTextCallback& cb,
	const SkSVGTextPath* tpath)
	: fRenderContext(ctx)
	, fCallback(cb)
	, fShaper(SkShaper::Make(ctx.fontMgr()))
	, fChunkAlignmentFactor(ComputeAlignmentFactor(ctx.presentationContext()))
	{
	if (tpath) {
	fPathData = std::make_unique<PathData>(ctx, *tpath);

	// https://www.w3.org/TR/SVG11/text.html#TextPathElementStartOffsetAttribute
	auto resolve_offset = [this](const SkSVGLength& offset) {
	if (offset.unit() != SkSVGLength::Unit::kPercentage) {
	// "If a <length> other than a percentage is given, then the ‘startOffset’
	// represents a distance along the path measured in the current user coordinate
	// system."
	return fRenderContext.lengthContext()
	.resolve(offset, SkSVGLengthContext::LengthType::kHorizontal);
	}

	// "If a percentage is given, then the ‘startOffset’ represents a percentage distance
	// along the entire path."
	return offset.value() * fPathData->length() / 100;
	};

	// startOffset acts as an initial absolute position
	fChunkPos.fX = resolve_offset(tpath->getStartOffset());
	}
	}

	SkSVGTextContext::~SkSVGTextContext() {
	this->flushChunk(fRenderContext);
	}

	void SkSVGTextContext::shapeFragment(const SkString& txt, const SkSVGRenderContext& ctx,
	SkSVGXmlSpace xs) {
	// https://www.w3.org/TR/SVG11/text.html#WhiteSpace
	// https://www.w3.org/TR/2008/REC-xml-20081126/#NT-S
	auto filterWSDefault = [this](SkUnichar ch) -> SkUnichar {
	// Remove all newline chars.
	if (ch == '\n') {
	return -1;
	}

	// Convert tab chars to space.
	if (ch == '\t') {
	ch = ' ';
	}

	// Consolidate contiguous space chars and strip leading spaces (fPrevCharSpace
	// starts off as true).
	if (fPrevCharSpace && ch == ' ') {
	return -1;
	}

	// TODO: Strip trailing WS? Doing this across chunks would require another buffering
	// layer. In general, trailing WS should have no rendering side effects. Skipping
	// for now.
	return ch;
	};
	auto filterWSPreserve = [](SkUnichar ch) -> SkUnichar {
	// Convert newline and tab chars to space.
	if (ch == '\n' \|\| ch == '\t') {
	ch = ' ';
	}
	return ch;
	};

	// Stash paints for access from SkShaper callbacks.
	fCurrentFill = ctx.fillPaint();
	fCurrentStroke = ctx.strokePaint();

	const auto font = ResolveFont(ctx);
	fShapeBuffer.reserve(txt.size());

	const char* ch_ptr = txt.c_str();
	const char* ch_end = ch_ptr + txt.size();

	while (ch_ptr < ch_end) {
	auto ch = SkUTF::NextUTF8(&ch_ptr, ch_end);
	ch = (xs == SkSVGXmlSpace::kDefault)
	? filterWSDefault(ch)
	: filterWSPreserve(ch);

	if (ch < 0) {
	// invalid utf or char filtered out
	continue;
	}

	SkASSERT(fPosResolver);
	const auto pos = fPosResolver->resolve(fCurrentCharIndex++);

	// Absolute position adjustments define a new chunk.
	// (https://www.w3.org/TR/SVG11/text.html#TextLayoutIntroduction)
	if (pos.has(PosAttrs::kX) \|\| pos.has(PosAttrs::kY)) {
	this->shapePendingBuffer(font);
	this->flushChunk(ctx);

	// New chunk position.
	if (pos.has(PosAttrs::kX)) {
	fChunkPos.fX = pos[PosAttrs::kX];
	}
	if (pos.has(PosAttrs::kY)) {
	fChunkPos.fY = pos[PosAttrs::kY];
	}
	}

	fShapeBuffer.append(ch, {
	{
	pos.has(PosAttrs::kDx) ? pos[PosAttrs::kDx] : 0,
	pos.has(PosAttrs::kDy) ? pos[PosAttrs::kDy] : 0,
	},
	pos.has(PosAttrs::kRotate) ? SkDegreesToRadians(pos[PosAttrs::kRotate]) : 0,
	});

	fPrevCharSpace = (ch == ' ');
	}

	this->shapePendingBuffer(font);

	// Note: at this point we have shaped and buffered RunRecs for the current fragment.
	// The active text chunk continues until an explicit or implicit flush.
	}

	SkSVGTextContext::PathData::PathData(const SkSVGRenderContext& ctx, const SkSVGTextPath& tpath)
	{
	const auto ref = ctx.findNodeById(tpath.getHref());
	if (!ref) {
	return;
	}

	SkContourMeasureIter cmi(ref->asPath(ctx), false);
	while (sk_sp<SkContourMeasure> contour = cmi.next()) {
	fLength += contour->length();
	fContours.push_back(std::move(contour));
	}
	}

	SkMatrix SkSVGTextContext::PathData::getMatrixAt(float offset) const {
	if (offset >= 0) {
	for (const auto& contour : fContours) {
	const auto contour_len = contour->length();
	if (offset < contour_len) {
	SkMatrix m;
	return contour->getMatrix(offset, &m) ? m : SkMatrix::I();
	}
	offset -= contour_len;
	}
	}

	// Quick & dirty way to "skip" rendering of glyphs off path.
	return SkMatrix::Translate(std::numeric_limits<float>::infinity(),
	std::numeric_limits<float>::infinity());
	}

	SkRSXform SkSVGTextContext::computeGlyphXform(SkGlyphID glyph, const SkFont& font,
	const SkPoint& glyph_pos,
	const PositionAdjustment& pos_adjust) const {
	SkPoint pos = fChunkPos + glyph_pos + pos_adjust.offset + fChunkAdvance * fChunkAlignmentFactor;
	if (!fPathData) {
	return SkRSXform::MakeFromRadians(/scale=/ 1, pos_adjust.rotation, pos.fX, pos.fY, 0, 0);
	}

	// We're in a textPath scope, reposition the glyph on path.
	// (https://www.w3.org/TR/SVG11/text.html#TextpathLayoutRules)

	// Path positioning is based on the glyph center (horizontal component).
	float glyph_width;
	font.getWidths(&glyph, 1, &glyph_width);
	auto path_offset = pos.fX + glyph_width * .5f;

	// In addition to the path matrix, the final glyph matrix also includes:
	//
	// -- vertical position adjustment "dy" ("dx" is factored into path_offset)
	// -- glyph origin adjustment (undoing the glyph center offset above)
	// -- explicit rotation adjustment (composing with the path glyph rotation)
	const auto m = fPathData->getMatrixAt(path_offset) *
	SkMatrix::Translate(-glyph_width * .5f, pos_adjust.offset.fY) *
	SkMatrix::RotateRad(pos_adjust.rotation);

	return SkRSXform::Make(m.getScaleX(), m.getSkewY(), m.getTranslateX(), m.getTranslateY());
	}

	void SkSVGTextContext::flushChunk(const SkSVGRenderContext& ctx) {
	SkTextBlobBuilder blobBuilder;

	for (const auto& run : fRuns) {
	const auto& buf = blobBuilder.allocRunRSXform(run.font, SkToInt(run.glyphCount));
	std::copy(run.glyphs.get(), run.glyphs.get() + run.glyphCount, buf.glyphs);
	for (size_t i = 0; i < run.glyphCount; ++i) {
	buf.xforms()[i] = this->computeGlyphXform(run.glyphs[i],
	run.font,
	run.glyphPos[i],
	run.glyhPosAdjust[i]);
	}

	fCallback(ctx, blobBuilder.make(), run.fillPaint.get(), run.strokePaint.get());
	}

	fChunkPos += fChunkAdvance;
	fChunkAdvance = {0,0};
	fChunkAlignmentFactor = ComputeAlignmentFactor(ctx.presentationContext());

	fRuns.clear();
	}

	SkShaper::RunHandler::Buffer SkSVGTextContext::runBuffer(const RunInfo& ri) {
	SkASSERT(ri.glyphCount);

	fRuns.push_back({
	ri.fFont,
	fCurrentFill.isValid() ? std::make_unique<SkPaint>(*fCurrentFill) : nullptr,
	fCurrentStroke.isValid() ? std::make_unique<SkPaint>(*fCurrentStroke) : nullptr,
	std::make_unique<SkGlyphID[] >(ri.glyphCount),
	std::make_unique<SkPoint[] >(ri.glyphCount),
	std::make_unique<PositionAdjustment[]>(ri.glyphCount),
	ri.glyphCount,
	ri.fAdvance,
	});

	// Ensure sufficient space to temporarily fetch cluster information.
	fShapeClusterBuffer.resize(std::max(fShapeClusterBuffer.size(), ri.glyphCount));

	return {
	fRuns.back().glyphs.get(),
	fRuns.back().glyphPos.get(),
	nullptr,
	fShapeClusterBuffer.data(),
	fChunkAdvance,
	};
	}

	void SkSVGTextContext::commitRunBuffer(const RunInfo& ri) {
	const auto& current_run = fRuns.back();

	// stash position adjustments
	for (size_t i = 0; i < ri.glyphCount; ++i) {
	const auto utf8_index = fShapeClusterBuffer[i];
	current_run.glyhPosAdjust[i] = fShapeBuffer.fUtf8PosAdjust[SkToInt(utf8_index)];
	}

	// Offset adjustments are cumulative - we only need to advance the current chunk
	// with the last value.
	fChunkAdvance += ri.fAdvance + fShapeBuffer.fUtf8PosAdjust.back().offset;
	}

	void SkSVGTextFragment::renderText(const SkSVGRenderContext& ctx, SkSVGTextContext* tctx,
	SkSVGXmlSpace xs) const {
	// N.B.: unlike regular elements, text fragments do not establish a new OBB scope -- they
	// always defer to the root <text> element for OBB resolution.
	SkSVGRenderContext localContext(ctx);

	if (this->onPrepareToRender(&localContext)) {
	this->onShapeText(localContext, tctx, xs);
	}
	}

	SkPath SkSVGTextFragment::onAsPath(const SkSVGRenderContext&) const {
	// TODO
	return SkPath();
	}

	void SkSVGTextContainer::appendChild(sk_sp<SkSVGNode> child) {
	// Only allow text content child nodes.
	switch (child->tag()) {
	case SkSVGTag::kTextLiteral:
	case SkSVGTag::kTextPath:
	case SkSVGTag::kTSpan:
	fChildren.push_back(
	sk_sp<SkSVGTextFragment>(static_cast<SkSVGTextFragment*>(child.release())));
	break;
	default:
	break;
	}
	}

	void SkSVGTextContainer::onShapeText(const SkSVGRenderContext& ctx, SkSVGTextContext* tctx,
	SkSVGXmlSpace) const {
	SkASSERT(tctx);

	const SkSVGTextContext::ScopedPosResolver resolver(*this, ctx.lengthContext(), tctx);

	for (const auto& frag : fChildren) {
	// Containers always override xml:space with the local value.
	frag->renderText(ctx, tctx, this->getXmlSpace());
	}
	}

	// https://www.w3.org/TR/SVG11/text.html#WhiteSpace
	template <>
	bool SkSVGAttributeParser::parse(SkSVGXmlSpace* xs) {
	static constexpr std::tuple<const char*, SkSVGXmlSpace> gXmlSpaceMap[] = {
	{"default" , SkSVGXmlSpace::kDefault },
	{"preserve", SkSVGXmlSpace::kPreserve},
	};

	return this->parseEnumMap(gXmlSpaceMap, xs) && this->parseEOSToken();
	}

	bool SkSVGTextContainer::parseAndSetAttribute(const char* name, const char* value) {
	return INHERITED::parseAndSetAttribute(name, value) \|\|
	this->setX(SkSVGAttributeParser::parse<std::vector<SkSVGLength>>("x", name, value)) \|\|
	this->setY(SkSVGAttributeParser::parse<std::vector<SkSVGLength>>("y", name, value)) \|\|
	this->setDx(SkSVGAttributeParser::parse<std::vector<SkSVGLength>>("dx", name, value)) \|\|
	this->setDy(SkSVGAttributeParser::parse<std::vector<SkSVGLength>>("dy", name, value)) \|\|
	this->setRotate(SkSVGAttributeParser::parse<std::vector<SkSVGNumberType>>("rotate",
	name,
	value)) \|\|
	this->setXmlSpace(SkSVGAttributeParser::parse<SkSVGXmlSpace>("xml:space", name, value));
	}

	void SkSVGTextLiteral::onShapeText(const SkSVGRenderContext& ctx, SkSVGTextContext* tctx,
	SkSVGXmlSpace xs) const {
	SkASSERT(tctx);

	tctx->shapeFragment(this->getText(), ctx, xs);
	}

	void SkSVGText::onRender(const SkSVGRenderContext& ctx) const {
	const SkSVGTextContext::ShapedTextCallback render_text = [](const SkSVGRenderContext& ctx,
	const sk_sp<SkTextBlob>& blob,
	const SkPaint* fill,
	const SkPaint* stroke) {
	if (fill) {
	ctx.canvas()->drawTextBlob(blob, 0, 0, *fill);
	}
	if (stroke) {
	ctx.canvas()->drawTextBlob(blob, 0, 0, *stroke);
	}
	};

	// Root <text> nodes establish a text layout context.
	SkSVGTextContext tctx(ctx, render_text);

	this->onShapeText(ctx, &tctx, this->getXmlSpace());
	}

	SkRect SkSVGText::onObjectBoundingBox(const SkSVGRenderContext& ctx) const {
	SkRect bounds = SkRect::MakeEmpty();

	const SkSVGTextContext::ShapedTextCallback compute_bounds =
	[&bounds](const SkSVGRenderContext& ctx, const sk_sp<SkTextBlob>& blob, const SkPaint*,
	const SkPaint*) {
	if (!blob) {
	return;
	}

	SkAutoSTArray<64, SkRect> glyphBounds;

	SkTextBlobRunIterator it(blob.get());

	for (SkTextBlobRunIterator it(blob.get()); !it.done(); it.next()) {
	glyphBounds.reset(SkToInt(it.glyphCount()));
	it.font().getBounds(it.glyphs(), it.glyphCount(), glyphBounds.get(), nullptr);

	SkASSERT(it.positioning() == SkTextBlobRunIterator::kRSXform_Positioning);
	SkMatrix m;
	for (uint32_t i = 0; i < it.glyphCount(); ++i) {
	m.setRSXform(it.xforms()[i]);
	bounds.join(m.mapRect(glyphBounds[i]));
	}
	}
	};

	{
	SkSVGTextContext tctx(ctx, compute_bounds);
	this->onShapeText(ctx, &tctx, this->getXmlSpace());
	}

	return bounds;
	}

	SkPath SkSVGText::onAsPath(const SkSVGRenderContext& ctx) const {
	SkPathBuilder builder;

	const SkSVGTextContext::ShapedTextCallback as_path =
	[&builder](const SkSVGRenderContext& ctx, const sk_sp<SkTextBlob>& blob, const SkPaint*,
	const SkPaint*) {
	if (!blob) {
	return;
	}

	SkTextBlobRunIterator it(blob.get());
	for (SkTextBlobRunIterator it(blob.get()); !it.done(); it.next()) {
	struct GetPathsCtx {
	SkPathBuilder& builder;
	const SkRSXform* xform;
	} get_paths_ctx {builder, it.xforms()};

	it.font().getPaths(it.glyphs(), it.glyphCount(), [](const SkPath* path,
	const SkMatrix& matrix,
	void* raw_ctx) {
	auto* get_paths_ctx = static_cast<GetPathsCtx*>(raw_ctx);
	const auto& glyph_rsx = *get_paths_ctx->xform++;

	if (!path) {
	return;
	}

	SkMatrix glyph_matrix;
	glyph_matrix.setRSXform(glyph_rsx);
	glyph_matrix.preConcat(matrix);

	get_paths_ctx->builder.addPath(path->makeTransform(glyph_matrix));
	}, &get_paths_ctx);
	}
	};

	{
	SkSVGTextContext tctx(ctx, as_path);
	this->onShapeText(ctx, &tctx, this->getXmlSpace());
	}

	auto path = builder.detach();
	this->mapToParent(&path);

	return path;
	}

	void SkSVGTextPath::onShapeText(const SkSVGRenderContext& ctx, SkSVGTextContext* parent_tctx,
	SkSVGXmlSpace xs) const {
	SkASSERT(parent_tctx);

	// textPath nodes establish a new text layout context.
	SkSVGTextContext tctx(ctx, parent_tctx->getCallback(), this);

	this->INHERITED::onShapeText(ctx, &tctx, xs);
	}

	bool SkSVGTextPath::parseAndSetAttribute(const char* name, const char* value) {
	return INHERITED::parseAndSetAttribute(name, value) \|\|
	this->setHref(SkSVGAttributeParser::parse<SkSVGIRI>("xlink:href", name, value)) \|\|
	this->setStartOffset(SkSVGAttributeParser::parse<SkSVGLength>("startOffset", name, value));
	}