/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*- */ /* vim: set ts=8 sts=2 et sw=2 tw=80: */ /* This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this * file, You can obtain one at http://mozilla.org/MPL/2.0/. */ // Main header first: #include "SVGTextFrame.h" // Keep others in (case-insensitive) order: #include "DOMSVGPoint.h" #include "gfx2DGlue.h" #include "gfxContext.h" #include "gfxFont.h" #include "gfxSkipChars.h" #include "gfxTypes.h" #include "gfxUtils.h" #include "LookAndFeel.h" #include "nsAlgorithm.h" #include "nsBidiPresUtils.h" #include "nsBlockFrame.h" #include "nsCaret.h" #include "nsContentUtils.h" #include "nsGkAtoms.h" #include "nsQuickSort.h" #include "SVGPaintServerFrame.h" #include "nsTArray.h" #include "nsTextFrame.h" #include "SVGAnimatedNumberList.h" #include "SVGContentUtils.h" #include "SVGContextPaint.h" #include "SVGLengthList.h" #include "SVGNumberList.h" #include "nsLayoutUtils.h" #include "nsFrameSelection.h" #include "nsStyleStructInlines.h" #include "mozilla/Likely.h" #include "mozilla/PresShell.h" #include "mozilla/SVGObserverUtils.h" #include "mozilla/SVGOuterSVGFrame.h" #include "mozilla/SVGUtils.h" #include "mozilla/dom/DOMPointBinding.h" #include "mozilla/dom/Selection.h" #include "mozilla/dom/SVGGeometryElement.h" #include "mozilla/dom/SVGRect.h" #include "mozilla/dom/SVGTextContentElementBinding.h" #include "mozilla/dom/SVGTextPathElement.h" #include "mozilla/dom/Text.h" #include "mozilla/gfx/2D.h" #include "mozilla/gfx/PatternHelpers.h" #include "nsDisplayList.h" #include #include #include using namespace mozilla::dom; using namespace mozilla::dom::SVGTextContentElement_Binding; using namespace mozilla::gfx; using namespace mozilla::image; namespace mozilla { // ============================================================================ // Utility functions /** * Using the specified gfxSkipCharsIterator, converts an offset and length * in original char indexes to skipped char indexes. * * @param aIterator The gfxSkipCharsIterator to use for the conversion. * @param aOriginalOffset The original offset. * @param aOriginalLength The original length. */ static gfxTextRun::Range ConvertOriginalToSkipped( gfxSkipCharsIterator& aIterator, uint32_t aOriginalOffset, uint32_t aOriginalLength) { uint32_t start = aIterator.ConvertOriginalToSkipped(aOriginalOffset); aIterator.AdvanceOriginal(aOriginalLength); return gfxTextRun::Range(start, aIterator.GetSkippedOffset()); } /** * Converts an nsPoint from app units to user space units using the specified * nsPresContext and returns it as a gfxPoint. */ static gfxPoint AppUnitsToGfxUnits(const nsPoint& aPoint, const nsPresContext* aContext) { return gfxPoint(aContext->AppUnitsToGfxUnits(aPoint.x), aContext->AppUnitsToGfxUnits(aPoint.y)); } /** * Converts a gfxRect that is in app units to CSS pixels using the specified * nsPresContext and returns it as a gfxRect. */ static gfxRect AppUnitsToFloatCSSPixels(const gfxRect& aRect, const nsPresContext* aContext) { return gfxRect(nsPresContext::AppUnitsToFloatCSSPixels(aRect.x), nsPresContext::AppUnitsToFloatCSSPixels(aRect.y), nsPresContext::AppUnitsToFloatCSSPixels(aRect.width), nsPresContext::AppUnitsToFloatCSSPixels(aRect.height)); } /** * Returns whether a gfxPoint lies within a gfxRect. */ static bool Inside(const gfxRect& aRect, const gfxPoint& aPoint) { return aPoint.x >= aRect.x && aPoint.x < aRect.XMost() && aPoint.y >= aRect.y && aPoint.y < aRect.YMost(); } /** * Gets the measured ascent and descent of the text in the given nsTextFrame * in app units. * * @param aFrame The text frame. * @param aAscent The ascent in app units (output). * @param aDescent The descent in app units (output). */ static void GetAscentAndDescentInAppUnits(nsTextFrame* aFrame, gfxFloat& aAscent, gfxFloat& aDescent) { gfxSkipCharsIterator it = aFrame->EnsureTextRun(nsTextFrame::eInflated); gfxTextRun* textRun = aFrame->GetTextRun(nsTextFrame::eInflated); gfxTextRun::Range range = ConvertOriginalToSkipped( it, aFrame->GetContentOffset(), aFrame->GetContentLength()); textRun->GetLineHeightMetrics(range, aAscent, aDescent); } /** * Updates an interval by intersecting it with another interval. * The intervals are specified using a start index and a length. */ static void IntersectInterval(uint32_t& aStart, uint32_t& aLength, uint32_t aStartOther, uint32_t aLengthOther) { uint32_t aEnd = aStart + aLength; uint32_t aEndOther = aStartOther + aLengthOther; if (aStartOther >= aEnd || aStart >= aEndOther) { aLength = 0; } else { if (aStartOther >= aStart) aStart = aStartOther; aLength = std::min(aEnd, aEndOther) - aStart; } } /** * Intersects an interval as IntersectInterval does but by taking * the offset and length of the other interval from a * nsTextFrame::TrimmedOffsets object. */ static void TrimOffsets(uint32_t& aStart, uint32_t& aLength, const nsTextFrame::TrimmedOffsets& aTrimmedOffsets) { IntersectInterval(aStart, aLength, aTrimmedOffsets.mStart, aTrimmedOffsets.mLength); } /** * Returns the closest ancestor-or-self node that is not an SVG * element. */ static nsIContent* GetFirstNonAAncestor(nsIContent* aContent) { while (aContent && aContent->IsSVGElement(nsGkAtoms::a)) { aContent = aContent->GetParent(); } return aContent; } /** * Returns whether the given node is a text content element[1], taking into * account whether it has a valid parent. * * For example, in: * * * * * * * true would be returned for the outer element and the element, * and false for the inner element (since a is not allowed * to be a child of another ) and the element (because it * must be inside a subtree). * * Note that we don't support the element yet and this function * returns false for it. * * [1] https://svgwg.org/svg2-draft/intro.html#TermTextContentElement */ static bool IsTextContentElement(nsIContent* aContent) { if (aContent->IsSVGElement(nsGkAtoms::text)) { nsIContent* parent = GetFirstNonAAncestor(aContent->GetParent()); return !parent || !IsTextContentElement(parent); } if (aContent->IsSVGElement(nsGkAtoms::textPath)) { nsIContent* parent = GetFirstNonAAncestor(aContent->GetParent()); return parent && parent->IsSVGElement(nsGkAtoms::text); } return aContent->IsAnyOfSVGElements(nsGkAtoms::a, nsGkAtoms::tspan); } /** * Returns whether the specified frame is an nsTextFrame that has some text * content. */ static bool IsNonEmptyTextFrame(nsIFrame* aFrame) { nsTextFrame* textFrame = do_QueryFrame(aFrame); if (!textFrame) { return false; } return textFrame->GetContentLength() != 0; } /** * Takes an nsIFrame and if it is a text frame that has some text content, * returns it as an nsTextFrame and its corresponding Text. * * @param aFrame The frame to look at. * @param aTextFrame aFrame as an nsTextFrame (output). * @param aTextNode The Text content of aFrame (output). * @return true if aFrame is a non-empty text frame, false otherwise. */ static bool GetNonEmptyTextFrameAndNode(nsIFrame* aFrame, nsTextFrame*& aTextFrame, Text*& aTextNode) { nsTextFrame* text = do_QueryFrame(aFrame); bool isNonEmptyTextFrame = text && text->GetContentLength() != 0; if (isNonEmptyTextFrame) { nsIContent* content = text->GetContent(); NS_ASSERTION(content && content->IsText(), "unexpected content type for nsTextFrame"); Text* node = content->AsText(); MOZ_ASSERT(node->TextLength() != 0, "frame's GetContentLength() should be 0 if the text node " "has no content"); aTextFrame = text; aTextNode = node; } MOZ_ASSERT(IsNonEmptyTextFrame(aFrame) == isNonEmptyTextFrame, "our logic should agree with IsNonEmptyTextFrame"); return isNonEmptyTextFrame; } /** * Returns whether the specified atom is for one of the five * glyph positioning attributes that can appear on SVG text * elements -- x, y, dx, dy or rotate. */ static bool IsGlyphPositioningAttribute(nsAtom* aAttribute) { return aAttribute == nsGkAtoms::x || aAttribute == nsGkAtoms::y || aAttribute == nsGkAtoms::dx || aAttribute == nsGkAtoms::dy || aAttribute == nsGkAtoms::rotate; } /** * Returns the position in app units of a given baseline (using an * SVG dominant-baseline property value) for a given nsTextFrame. * * @param aFrame The text frame to inspect. * @param aTextRun The text run of aFrame. * @param aDominantBaseline The dominant-baseline value to use. */ static nscoord GetBaselinePosition(nsTextFrame* aFrame, gfxTextRun* aTextRun, StyleDominantBaseline aDominantBaseline, float aFontSizeScaleFactor) { WritingMode writingMode = aFrame->GetWritingMode(); gfxFloat ascent, descent; aTextRun->GetLineHeightMetrics(ascent, descent); auto convertIfVerticalRL = [&](gfxFloat dominantBaseline) { return writingMode.IsVerticalRL() ? ascent + descent - dominantBaseline : dominantBaseline; }; switch (aDominantBaseline) { case StyleDominantBaseline::Hanging: return convertIfVerticalRL(ascent * 0.2); case StyleDominantBaseline::TextBeforeEdge: return convertIfVerticalRL(0); case StyleDominantBaseline::Alphabetic: return writingMode.IsVerticalRL() ? ascent * 0.5 : aFrame->GetLogicalBaseline(writingMode); case StyleDominantBaseline::Auto: return convertIfVerticalRL(aFrame->GetLogicalBaseline(writingMode)); case StyleDominantBaseline::Middle: return convertIfVerticalRL(aFrame->GetLogicalBaseline(writingMode) - SVGContentUtils::GetFontXHeight(aFrame) / 2.0 * AppUnitsPerCSSPixel() * aFontSizeScaleFactor); case StyleDominantBaseline::TextAfterEdge: case StyleDominantBaseline::Ideographic: return writingMode.IsVerticalLR() ? 0 : ascent + descent; case StyleDominantBaseline::Central: return (ascent + descent) / 2.0; case StyleDominantBaseline::Mathematical: return convertIfVerticalRL(ascent / 2.0); } MOZ_ASSERT_UNREACHABLE("unexpected dominant-baseline value"); return convertIfVerticalRL(aFrame->GetLogicalBaseline(writingMode)); } /** * Truncates an array to be at most the length of another array. * * @param aArrayToTruncate The array to truncate. * @param aReferenceArray The array whose length will be used to truncate * aArrayToTruncate to. */ template static void TruncateTo(nsTArray& aArrayToTruncate, const nsTArray& aReferenceArray) { uint32_t length = aReferenceArray.Length(); if (aArrayToTruncate.Length() > length) { aArrayToTruncate.TruncateLength(length); } } /** * Asserts that the anonymous block child of the SVGTextFrame has been * reflowed (or does not exist). Returns null if the child has not been * reflowed, and the frame otherwise. * * We check whether the kid has been reflowed and not the frame itself * since we sometimes need to call this function during reflow, after the * kid has been reflowed but before we have cleared the dirty bits on the * frame itself. */ static SVGTextFrame* FrameIfAnonymousChildReflowed(SVGTextFrame* aFrame) { MOZ_ASSERT(aFrame, "aFrame must not be null"); nsIFrame* kid = aFrame->PrincipalChildList().FirstChild(); if (kid->IsSubtreeDirty()) { MOZ_ASSERT(false, "should have already reflowed the anonymous block child"); return nullptr; } return aFrame; } static double GetContextScale(const gfxMatrix& aMatrix) { // The context scale is the ratio of the length of the transformed // diagonal vector (1,1) to the length of the untransformed diagonal // (which is sqrt(2)). gfxPoint p = aMatrix.TransformPoint(gfxPoint(1, 1)) - aMatrix.TransformPoint(gfxPoint(0, 0)); return SVGContentUtils::ComputeNormalizedHypotenuse(p.x, p.y); } // ============================================================================ // Utility classes // ---------------------------------------------------------------------------- // TextRenderedRun /** * A run of text within a single nsTextFrame whose glyphs can all be painted * with a single call to nsTextFrame::PaintText. A text rendered run can * be created for a sequence of two or more consecutive glyphs as long as: * * - Only the first glyph has (or none of the glyphs have) been positioned * with SVG text positioning attributes * - All of the glyphs have zero rotation * - The glyphs are not on a text path * - The glyphs correspond to content within the one nsTextFrame * * A TextRenderedRunIterator produces TextRenderedRuns required for painting a * whole SVGTextFrame. */ struct TextRenderedRun { using Range = gfxTextRun::Range; /** * Constructs a TextRenderedRun that is uninitialized except for mFrame * being null. */ TextRenderedRun() : mFrame(nullptr) {} /** * Constructs a TextRenderedRun with all of the information required to * paint it. See the comments documenting the member variables below * for descriptions of the arguments. */ TextRenderedRun(nsTextFrame* aFrame, const gfxPoint& aPosition, float aLengthAdjustScaleFactor, double aRotate, float aFontSizeScaleFactor, nscoord aBaseline, uint32_t aTextFrameContentOffset, uint32_t aTextFrameContentLength, uint32_t aTextElementCharIndex) : mFrame(aFrame), mPosition(aPosition), mLengthAdjustScaleFactor(aLengthAdjustScaleFactor), mRotate(static_cast(aRotate)), mFontSizeScaleFactor(aFontSizeScaleFactor), mBaseline(aBaseline), mTextFrameContentOffset(aTextFrameContentOffset), mTextFrameContentLength(aTextFrameContentLength), mTextElementCharIndex(aTextElementCharIndex) {} /** * Returns the text run for the text frame that this rendered run is part of. */ gfxTextRun* GetTextRun() const { mFrame->EnsureTextRun(nsTextFrame::eInflated); return mFrame->GetTextRun(nsTextFrame::eInflated); } /** * Returns whether this rendered run is RTL. */ bool IsRightToLeft() const { return GetTextRun()->IsRightToLeft(); } /** * Returns whether this rendered run is vertical. */ bool IsVertical() const { return GetTextRun()->IsVertical(); } /** * Returns the transform that converts from a element's user space into * the coordinate space that rendered runs can be painted directly in. * * The difference between this method and * GetTransformFromRunUserSpaceToUserSpace is that when calling in to * nsTextFrame::PaintText, it will already take into account any left clip * edge (that is, it doesn't just apply a visual clip to the rendered text, it * shifts the glyphs over so that they are painted with their left edge at the * x coordinate passed in to it). Thus we need to account for this in our * transform. * * * Assume that we have: * * abcdef. * * This would result in four text rendered runs: * * - one for "ab" * - one for "c" * - one for "de" * - one for "f" * * Assume now that we are painting the third TextRenderedRun. It will have * a left clip edge that is the sum of the advances of "abc", and it will * have a right clip edge that is the advance of "f". In * SVGTextFrame::PaintSVG(), we pass in nsPoint() (i.e., the origin) * as the point at which to paint the text frame, and we pass in the * clip edge values. The nsTextFrame will paint the substring of its * text such that the top-left corner of the "d"'s glyph cell will be at * (0, 0) in the current coordinate system. * * Thus, GetTransformFromUserSpaceForPainting must return a transform from * whatever user space the element is in to a coordinate space in * device pixels (as that's what nsTextFrame works in) where the origin is at * the same position as our user space mPositions[i].mPosition value for * the "d" glyph, which will be (100 + userSpaceAdvance("abc"), 100). * The translation required to do this (ignoring the scale to get from * user space to device pixels, and ignoring the * (100 + userSpaceAdvance("abc"), 100) translation) is: * * (-leftEdge, -baseline) * * where baseline is the distance between the baseline of the text and the top * edge of the nsTextFrame. We translate by -leftEdge horizontally because * the nsTextFrame will already shift the glyphs over by that amount and start * painting glyphs at x = 0. We translate by -baseline vertically so that * painting the top edges of the glyphs at y = 0 will result in their * baselines being at our desired y position. * * * Now for an example with RTL text. Assume our content is now * WERBEH. We'd have * the following text rendered runs: * * - one for "EH" * - one for "B" * - one for "ER" * - one for "W" * * Again, we are painting the third TextRenderedRun. The left clip edge * is the advance of the "W" and the right clip edge is the sum of the * advances of "BEH". Our translation to get the rendered "ER" glyphs * in the right place this time is: * * (-frameWidth + rightEdge, -baseline) * * which is equivalent to: * * (-(leftEdge + advance("ER")), -baseline) * * The reason we have to shift left additionally by the width of the run * of glyphs we are painting is that although the nsTextFrame is RTL, * we still supply the top-left corner to paint the frame at when calling * nsTextFrame::PaintText, even though our user space positions for each * glyph in mPositions specifies the origin of each glyph, which for RTL * glyphs is at the right edge of the glyph cell. * * * For any other use of an nsTextFrame in the context of a particular run * (such as hit testing, or getting its rectangle), * GetTransformFromRunUserSpaceToUserSpace should be used. * * @param aContext The context to use for unit conversions. */ gfxMatrix GetTransformFromUserSpaceForPainting( nsPresContext* aContext, const nscoord aVisIStartEdge, const nscoord aVisIEndEdge) const; /** * Returns the transform that converts from "run user space" to a * element's user space. Run user space is a coordinate system that has the * same size as the 's user space but rotated and translated such that * (0,0) is the top-left of the rectangle that bounds the text. * * @param aContext The context to use for unit conversions. */ gfxMatrix GetTransformFromRunUserSpaceToUserSpace( nsPresContext* aContext) const; /** * Returns the transform that converts from "run user space" to float pixels * relative to the nsTextFrame that this rendered run is a part of. * * @param aContext The context to use for unit conversions. */ gfxMatrix GetTransformFromRunUserSpaceToFrameUserSpace( nsPresContext* aContext) const; /** * Flag values used for the aFlags arguments of GetRunUserSpaceRect, * GetFrameUserSpaceRect and GetUserSpaceRect. */ enum { // Includes the fill geometry of the text in the returned rectangle. eIncludeFill = 1, // Includes the stroke geometry of the text in the returned rectangle. eIncludeStroke = 2, // Includes any text shadow in the returned rectangle. eIncludeTextShadow = 4, // Don't include any horizontal glyph overflow in the returned rectangle. eNoHorizontalOverflow = 8 }; /** * Returns a rectangle that bounds the fill and/or stroke of the rendered run * in run user space. * * @param aContext The context to use for unit conversions. * @param aFlags A combination of the flags above (eIncludeFill and * eIncludeStroke) indicating what parts of the text to include in * the rectangle. */ SVGBBox GetRunUserSpaceRect(nsPresContext* aContext, uint32_t aFlags) const; /** * Returns a rectangle that covers the fill and/or stroke of the rendered run * in "frame user space". * * Frame user space is a coordinate space of the same scale as the * element's user space, but with its rotation set to the rotation of * the glyphs within this rendered run and its origin set to the position * such that placing the nsTextFrame there would result in the glyphs in * this rendered run being at their correct positions. * * For example, say we have ab. Assume * the advance of both the "a" and the "b" is 12 user units, and the * ascent of the text is 8 user units and its descent is 6 user units, * and that we are not measuing the stroke of the text, so that we stay * entirely within the glyph cells. * * There will be two text rendered runs, one for "a" and one for "b". * * The frame user space for the "a" run will have its origin at * (100, 100 - 8) in the element's user space and will have its * axes aligned with the user space (since there is no rotate="" or * text path involve) and with its scale the same as the user space. * The rect returned by this method will be (0, 0, 12, 14), since the "a" * glyph is right at the left of the nsTextFrame. * * The frame user space for the "b" run will have its origin at * (150 - 12, 100 - 8), and scale/rotation the same as above. The rect * returned by this method will be (12, 0, 12, 14), since we are * advance("a") horizontally in to the text frame. * * @param aContext The context to use for unit conversions. * @param aFlags A combination of the flags above (eIncludeFill and * eIncludeStroke) indicating what parts of the text to include in * the rectangle. */ SVGBBox GetFrameUserSpaceRect(nsPresContext* aContext, uint32_t aFlags) const; /** * Returns a rectangle that covers the fill and/or stroke of the rendered run * in the element's user space. * * @param aContext The context to use for unit conversions. * @param aFlags A combination of the flags above indicating what parts of * the text to include in the rectangle. * @param aAdditionalTransform An additional transform to apply to the * frame user space rectangle before its bounds are transformed into * user space. */ SVGBBox GetUserSpaceRect( nsPresContext* aContext, uint32_t aFlags, const gfxMatrix* aAdditionalTransform = nullptr) const; /** * Gets the app unit amounts to clip from the left and right edges of * the nsTextFrame in order to paint just this rendered run. * * Note that if clip edge amounts land in the middle of a glyph, the * glyph won't be painted at all. The clip edges are thus more of * a selection mechanism for which glyphs will be painted, rather * than a geometric clip. */ void GetClipEdges(nscoord& aVisIStartEdge, nscoord& aVisIEndEdge) const; /** * Returns the advance width of the whole rendered run. */ nscoord GetAdvanceWidth() const; /** * Returns the index of the character into this rendered run whose * glyph cell contains the given point, or -1 if there is no such * character. This does not hit test against any overflow. * * @param aContext The context to use for unit conversions. * @param aPoint The point in the user space of the element. */ int32_t GetCharNumAtPosition(nsPresContext* aContext, const gfxPoint& aPoint) const; /** * The text frame that this rendered run lies within. */ nsTextFrame* mFrame; /** * The point in user space that the text is positioned at. * * For a horizontal run: * The x coordinate is the left edge of a LTR run of text or the right edge of * an RTL run. The y coordinate is the baseline of the text. * For a vertical run: * The x coordinate is the baseline of the text. * The y coordinate is the top edge of a LTR run, or bottom of RTL. */ gfxPoint mPosition; /** * The horizontal scale factor to apply when painting glyphs to take * into account textLength="". */ float mLengthAdjustScaleFactor; /** * The rotation in radians in the user coordinate system that the text has. */ float mRotate; /** * The scale factor that was used to transform the text run's original font * size into a sane range for painting and measurement. */ double mFontSizeScaleFactor; /** * The baseline in app units of this text run. The measurement is from the * top of the text frame. (From the left edge if vertical.) */ nscoord mBaseline; /** * The offset and length in mFrame's content Text that corresponds to * this text rendered run. These are original char indexes. */ uint32_t mTextFrameContentOffset; uint32_t mTextFrameContentLength; /** * The character index in the whole SVG element that this text rendered * run begins at. */ uint32_t mTextElementCharIndex; }; gfxMatrix TextRenderedRun::GetTransformFromUserSpaceForPainting( nsPresContext* aContext, const nscoord aVisIStartEdge, const nscoord aVisIEndEdge) const { // We transform to device pixels positioned such that painting the text frame // at (0,0) with aItem will result in the text being in the right place. gfxMatrix m; if (!mFrame) { return m; } float cssPxPerDevPx = nsPresContext::AppUnitsToFloatCSSPixels(aContext->AppUnitsPerDevPixel()); // Glyph position in user space. m.PreTranslate(mPosition / cssPxPerDevPx); // Take into account any font size scaling and scaling due to textLength="". m.PreScale(1.0 / mFontSizeScaleFactor, 1.0 / mFontSizeScaleFactor); // Rotation due to rotate="" or a . m.PreRotate(mRotate); m.PreScale(mLengthAdjustScaleFactor, 1.0); // Translation to get the text frame in the right place. nsPoint t; if (IsVertical()) { t = nsPoint(-mBaseline, IsRightToLeft() ? -mFrame->GetRect().height + aVisIEndEdge : -aVisIStartEdge); } else { t = nsPoint(IsRightToLeft() ? -mFrame->GetRect().width + aVisIEndEdge : -aVisIStartEdge, -mBaseline); } m.PreTranslate(AppUnitsToGfxUnits(t, aContext)); return m; } gfxMatrix TextRenderedRun::GetTransformFromRunUserSpaceToUserSpace( nsPresContext* aContext) const { gfxMatrix m; if (!mFrame) { return m; } float cssPxPerDevPx = nsPresContext::AppUnitsToFloatCSSPixels(aContext->AppUnitsPerDevPixel()); nscoord start, end; GetClipEdges(start, end); // Glyph position in user space. m.PreTranslate(mPosition); // Rotation due to rotate="" or a . m.PreRotate(mRotate); // Scale due to textLength="". m.PreScale(mLengthAdjustScaleFactor, 1.0); // Translation to get the text frame in the right place. nsPoint t; if (IsVertical()) { t = nsPoint(-mBaseline, IsRightToLeft() ? -mFrame->GetRect().height + start + end : 0); } else { t = nsPoint(IsRightToLeft() ? -mFrame->GetRect().width + start + end : 0, -mBaseline); } m.PreTranslate(AppUnitsToGfxUnits(t, aContext) * cssPxPerDevPx / mFontSizeScaleFactor); return m; } gfxMatrix TextRenderedRun::GetTransformFromRunUserSpaceToFrameUserSpace( nsPresContext* aContext) const { gfxMatrix m; if (!mFrame) { return m; } nscoord start, end; GetClipEdges(start, end); // Translate by the horizontal distance into the text frame this // rendered run is. gfxFloat appPerCssPx = AppUnitsPerCSSPixel(); gfxPoint t = IsVertical() ? gfxPoint(0, start / appPerCssPx) : gfxPoint(start / appPerCssPx, 0); return m.PreTranslate(t); } SVGBBox TextRenderedRun::GetRunUserSpaceRect(nsPresContext* aContext, uint32_t aFlags) const { SVGBBox r; if (!mFrame) { return r; } // Determine the amount of overflow above and below the frame's mRect. // // We need to call InkOverflowRectRelativeToSelf because this includes // overflowing decorations, which the MeasureText call below does not. We // assume here the decorations only overflow above and below the frame, never // horizontally. nsRect self = mFrame->InkOverflowRectRelativeToSelf(); nsRect rect = mFrame->GetRect(); bool vertical = IsVertical(); nscoord above = vertical ? -self.x : -self.y; nscoord below = vertical ? self.XMost() - rect.width : self.YMost() - rect.height; gfxSkipCharsIterator it = mFrame->EnsureTextRun(nsTextFrame::eInflated); gfxSkipCharsIterator start = it; gfxTextRun* textRun = mFrame->GetTextRun(nsTextFrame::eInflated); // Get the content range for this rendered run. Range range = ConvertOriginalToSkipped(it, mTextFrameContentOffset, mTextFrameContentLength); if (range.Length() == 0) { return r; } // FIXME(heycam): We could create a single PropertyProvider for all // TextRenderedRuns that correspond to the text frame, rather than recreate // it each time here. nsTextFrame::PropertyProvider provider(mFrame, start); // Measure that range. gfxTextRun::Metrics metrics = textRun->MeasureText( range, gfxFont::LOOSE_INK_EXTENTS, nullptr, &provider); // Make sure it includes the font-box. gfxRect fontBox(0, -metrics.mAscent, metrics.mAdvanceWidth, metrics.mAscent + metrics.mDescent); metrics.mBoundingBox.UnionRect(metrics.mBoundingBox, fontBox); // Determine the rectangle that covers the rendered run's fill, // taking into account the measured vertical overflow due to // decorations. nscoord baseline = NSToCoordRoundWithClamp(metrics.mBoundingBox.y + metrics.mAscent); gfxFloat x, width; if (aFlags & eNoHorizontalOverflow) { x = 0.0; width = textRun->GetAdvanceWidth(range, &provider); if (width < 0.0) { x = width; width = -width; } } else { x = metrics.mBoundingBox.x; width = metrics.mBoundingBox.width; } nsRect fillInAppUnits( NSToCoordRoundWithClamp(x), baseline - above, NSToCoordRoundWithClamp(width), NSToCoordRoundWithClamp(metrics.mBoundingBox.height) + above + below); if (textRun->IsVertical()) { // Swap line-relative textMetrics dimensions to physical coordinates. std::swap(fillInAppUnits.x, fillInAppUnits.y); std::swap(fillInAppUnits.width, fillInAppUnits.height); } // Account for text-shadow. if (aFlags & eIncludeTextShadow) { fillInAppUnits = nsLayoutUtils::GetTextShadowRectsUnion(fillInAppUnits, mFrame); } // Convert the app units rectangle to user units. gfxRect fill = AppUnitsToFloatCSSPixels( gfxRect(fillInAppUnits.x, fillInAppUnits.y, fillInAppUnits.width, fillInAppUnits.height), aContext); // Scale the rectangle up due to any mFontSizeScaleFactor. fill.Scale(1.0 / mFontSizeScaleFactor); // Include the fill if requested. if (aFlags & eIncludeFill) { r = fill; } // Include the stroke if requested. if ((aFlags & eIncludeStroke) && !fill.IsEmpty() && SVGUtils::GetStrokeWidth(mFrame) > 0) { r.UnionEdges( SVGUtils::PathExtentsToMaxStrokeExtents(fill, mFrame, gfxMatrix())); } return r; } SVGBBox TextRenderedRun::GetFrameUserSpaceRect(nsPresContext* aContext, uint32_t aFlags) const { SVGBBox r = GetRunUserSpaceRect(aContext, aFlags); if (r.IsEmpty()) { return r; } gfxMatrix m = GetTransformFromRunUserSpaceToFrameUserSpace(aContext); return m.TransformBounds(r.ToThebesRect()); } SVGBBox TextRenderedRun::GetUserSpaceRect( nsPresContext* aContext, uint32_t aFlags, const gfxMatrix* aAdditionalTransform) const { SVGBBox r = GetRunUserSpaceRect(aContext, aFlags); if (r.IsEmpty()) { return r; } gfxMatrix m = GetTransformFromRunUserSpaceToUserSpace(aContext); if (aAdditionalTransform) { m *= *aAdditionalTransform; } return m.TransformBounds(r.ToThebesRect()); } void TextRenderedRun::GetClipEdges(nscoord& aVisIStartEdge, nscoord& aVisIEndEdge) const { uint32_t contentLength = mFrame->GetContentLength(); if (mTextFrameContentOffset == 0 && mTextFrameContentLength == contentLength) { // If the rendered run covers the entire content, we know we don't need // to clip without having to measure anything. aVisIStartEdge = 0; aVisIEndEdge = 0; return; } gfxSkipCharsIterator it = mFrame->EnsureTextRun(nsTextFrame::eInflated); gfxTextRun* textRun = mFrame->GetTextRun(nsTextFrame::eInflated); nsTextFrame::PropertyProvider provider(mFrame, it); // Get the covered content offset/length for this rendered run in skipped // characters, since that is what GetAdvanceWidth expects. Range runRange = ConvertOriginalToSkipped(it, mTextFrameContentOffset, mTextFrameContentLength); // Get the offset/length of the whole nsTextFrame. uint32_t frameOffset = mFrame->GetContentOffset(); uint32_t frameLength = mFrame->GetContentLength(); // Trim the whole-nsTextFrame offset/length to remove any leading/trailing // white space, as the nsTextFrame when painting does not include them when // interpreting clip edges. nsTextFrame::TrimmedOffsets trimmedOffsets = mFrame->GetTrimmedOffsets(mFrame->TextFragment()); TrimOffsets(frameOffset, frameLength, trimmedOffsets); // Convert the trimmed whole-nsTextFrame offset/length into skipped // characters. Range frameRange = ConvertOriginalToSkipped(it, frameOffset, frameLength); // Measure the advance width in the text run between the start of // frame's content and the start of the rendered run's content, nscoord startEdge = textRun->GetAdvanceWidth( Range(frameRange.start, runRange.start), &provider); // and between the end of the rendered run's content and the end // of the frame's content. nscoord endEdge = textRun->GetAdvanceWidth(Range(runRange.end, frameRange.end), &provider); if (textRun->IsRightToLeft()) { aVisIStartEdge = endEdge; aVisIEndEdge = startEdge; } else { aVisIStartEdge = startEdge; aVisIEndEdge = endEdge; } } nscoord TextRenderedRun::GetAdvanceWidth() const { gfxSkipCharsIterator it = mFrame->EnsureTextRun(nsTextFrame::eInflated); gfxTextRun* textRun = mFrame->GetTextRun(nsTextFrame::eInflated); nsTextFrame::PropertyProvider provider(mFrame, it); Range range = ConvertOriginalToSkipped(it, mTextFrameContentOffset, mTextFrameContentLength); return textRun->GetAdvanceWidth(range, &provider); } int32_t TextRenderedRun::GetCharNumAtPosition(nsPresContext* aContext, const gfxPoint& aPoint) const { if (mTextFrameContentLength == 0) { return -1; } float cssPxPerDevPx = nsPresContext::AppUnitsToFloatCSSPixels(aContext->AppUnitsPerDevPixel()); // Convert the point from user space into run user space, and take // into account any mFontSizeScaleFactor. gfxMatrix m = GetTransformFromRunUserSpaceToUserSpace(aContext); if (!m.Invert()) { return -1; } gfxPoint p = m.TransformPoint(aPoint) / cssPxPerDevPx * mFontSizeScaleFactor; // First check that the point lies vertically between the top and bottom // edges of the text. gfxFloat ascent, descent; GetAscentAndDescentInAppUnits(mFrame, ascent, descent); WritingMode writingMode = mFrame->GetWritingMode(); if (writingMode.IsVertical()) { gfxFloat leftEdge = mFrame->GetLogicalBaseline(writingMode) - (writingMode.IsVerticalRL() ? ascent : descent); gfxFloat rightEdge = leftEdge + ascent + descent; if (p.x < aContext->AppUnitsToGfxUnits(leftEdge) || p.x > aContext->AppUnitsToGfxUnits(rightEdge)) { return -1; } } else { gfxFloat topEdge = mFrame->GetLogicalBaseline(writingMode) - ascent; gfxFloat bottomEdge = topEdge + ascent + descent; if (p.y < aContext->AppUnitsToGfxUnits(topEdge) || p.y > aContext->AppUnitsToGfxUnits(bottomEdge)) { return -1; } } gfxSkipCharsIterator it = mFrame->EnsureTextRun(nsTextFrame::eInflated); gfxTextRun* textRun = mFrame->GetTextRun(nsTextFrame::eInflated); nsTextFrame::PropertyProvider provider(mFrame, it); // Next check that the point lies horizontally within the left and right // edges of the text. Range range = ConvertOriginalToSkipped(it, mTextFrameContentOffset, mTextFrameContentLength); gfxFloat runAdvance = aContext->AppUnitsToGfxUnits(textRun->GetAdvanceWidth(range, &provider)); gfxFloat pos = writingMode.IsVertical() ? p.y : p.x; if (pos < 0 || pos >= runAdvance) { return -1; } // Finally, measure progressively smaller portions of the rendered run to // find which glyph it lies within. This will need to change once we // support letter-spacing and word-spacing. bool rtl = textRun->IsRightToLeft(); for (int32_t i = mTextFrameContentLength - 1; i >= 0; i--) { range = ConvertOriginalToSkipped(it, mTextFrameContentOffset, i); gfxFloat advance = aContext->AppUnitsToGfxUnits( textRun->GetAdvanceWidth(range, &provider)); if ((rtl && pos < runAdvance - advance) || (!rtl && pos >= advance)) { return i; } } return -1; } // ---------------------------------------------------------------------------- // TextNodeIterator enum SubtreePosition { eBeforeSubtree, eWithinSubtree, eAfterSubtree }; /** * An iterator class for Text that are descendants of a given node, the * root. Nodes are iterated in document order. An optional subtree can be * specified, in which case the iterator will track whether the current state of * the traversal over the tree is within that subtree or is past that subtree. */ class TextNodeIterator { public: /** * Constructs a TextNodeIterator with the specified root node and optional * subtree. */ explicit TextNodeIterator(nsIContent* aRoot, nsIContent* aSubtree = nullptr) : mRoot(aRoot), mSubtree(aSubtree == aRoot ? nullptr : aSubtree), mCurrent(aRoot), mSubtreePosition(mSubtree ? eBeforeSubtree : eWithinSubtree) { NS_ASSERTION(aRoot, "expected non-null root"); if (!aRoot->IsText()) { Next(); } } /** * Returns the current Text, or null if the iterator has finished. */ Text* Current() const { return mCurrent ? mCurrent->AsText() : nullptr; } /** * Advances to the next Text and returns it, or null if the end of * iteration has been reached. */ Text* Next(); /** * Returns whether the iterator is currently within the subtree rooted * at mSubtree. Returns true if we are not tracking a subtree (we consider * that we're always within the subtree). */ bool IsWithinSubtree() const { return mSubtreePosition == eWithinSubtree; } /** * Returns whether the iterator is past the subtree rooted at mSubtree. * Returns false if we are not tracking a subtree. */ bool IsAfterSubtree() const { return mSubtreePosition == eAfterSubtree; } private: /** * The root under which all Text will be iterated over. */ nsIContent* const mRoot; /** * The node rooting the subtree to track. */ nsIContent* const mSubtree; /** * The current node during iteration. */ nsIContent* mCurrent; /** * The current iterator position relative to mSubtree. */ SubtreePosition mSubtreePosition; }; Text* TextNodeIterator::Next() { // Starting from mCurrent, we do a non-recursive traversal to the next // Text beneath mRoot, updating mSubtreePosition appropriately if we // encounter mSubtree. if (mCurrent) { do { nsIContent* next = IsTextContentElement(mCurrent) ? mCurrent->GetFirstChild() : nullptr; if (next) { mCurrent = next; if (mCurrent == mSubtree) { mSubtreePosition = eWithinSubtree; } } else { for (;;) { if (mCurrent == mRoot) { mCurrent = nullptr; break; } if (mCurrent == mSubtree) { mSubtreePosition = eAfterSubtree; } next = mCurrent->GetNextSibling(); if (next) { mCurrent = next; if (mCurrent == mSubtree) { mSubtreePosition = eWithinSubtree; } break; } if (mCurrent == mSubtree) { mSubtreePosition = eAfterSubtree; } mCurrent = mCurrent->GetParent(); } } } while (mCurrent && !mCurrent->IsText()); } return mCurrent ? mCurrent->AsText() : nullptr; } // ---------------------------------------------------------------------------- // TextNodeCorrespondenceRecorder /** * TextNodeCorrespondence is used as the value of a frame property that * is stored on all its descendant nsTextFrames. It stores the number of DOM * characters between it and the previous nsTextFrame that did not have an * nsTextFrame created for them, due to either not being in a correctly * parented text content element, or because they were display:none. * These are called "undisplayed characters". * * See also TextNodeCorrespondenceRecorder below, which is what sets the * frame property. */ struct TextNodeCorrespondence { explicit TextNodeCorrespondence(uint32_t aUndisplayedCharacters) : mUndisplayedCharacters(aUndisplayedCharacters) {} uint32_t mUndisplayedCharacters; }; NS_DECLARE_FRAME_PROPERTY_DELETABLE(TextNodeCorrespondenceProperty, TextNodeCorrespondence) /** * Returns the number of undisplayed characters before the specified * nsTextFrame. */ static uint32_t GetUndisplayedCharactersBeforeFrame(nsTextFrame* aFrame) { void* value = aFrame->GetProperty(TextNodeCorrespondenceProperty()); TextNodeCorrespondence* correspondence = static_cast(value); if (!correspondence) { // FIXME bug 903785 NS_ERROR( "expected a TextNodeCorrespondenceProperty on nsTextFrame " "used for SVG text"); return 0; } return correspondence->mUndisplayedCharacters; } /** * Traverses the nsTextFrames for an SVGTextFrame and records a * TextNodeCorrespondenceProperty on each for the number of undisplayed DOM * characters between each frame. This is done by iterating simultaneously * over the Text and nsTextFrames and noting when Text (or * parts of them) are skipped when finding the next nsTextFrame. */ class TextNodeCorrespondenceRecorder { public: /** * Entry point for the TextNodeCorrespondenceProperty recording. */ static void RecordCorrespondence(SVGTextFrame* aRoot); private: explicit TextNodeCorrespondenceRecorder(SVGTextFrame* aRoot) : mNodeIterator(aRoot->GetContent()), mPreviousNode(nullptr), mNodeCharIndex(0) {} void Record(SVGTextFrame* aRoot); void TraverseAndRecord(nsIFrame* aFrame); /** * Returns the next non-empty Text. */ Text* NextNode(); /** * The iterator over the Text that we use as we simultaneously * iterate over the nsTextFrames. */ TextNodeIterator mNodeIterator; /** * The previous Text we iterated over. */ Text* mPreviousNode; /** * The index into the current Text's character content. */ uint32_t mNodeCharIndex; }; /* static */ void TextNodeCorrespondenceRecorder::RecordCorrespondence(SVGTextFrame* aRoot) { if (aRoot->HasAnyStateBits(NS_STATE_SVG_TEXT_CORRESPONDENCE_DIRTY)) { // Resolve bidi so that continuation frames are created if necessary: aRoot->MaybeResolveBidiForAnonymousBlockChild(); TextNodeCorrespondenceRecorder recorder(aRoot); recorder.Record(aRoot); aRoot->RemoveStateBits(NS_STATE_SVG_TEXT_CORRESPONDENCE_DIRTY); } } void TextNodeCorrespondenceRecorder::Record(SVGTextFrame* aRoot) { if (!mNodeIterator.Current()) { // If there are no Text nodes then there is nothing to do. return; } // Traverse over all the nsTextFrames and record the number of undisplayed // characters. TraverseAndRecord(aRoot); // Find how many undisplayed characters there are after the final nsTextFrame. uint32_t undisplayed = 0; if (mNodeIterator.Current()) { if (mPreviousNode && mPreviousNode->TextLength() != mNodeCharIndex) { // The last nsTextFrame ended part way through a Text node. The // remaining characters count as undisplayed. NS_ASSERTION(mNodeCharIndex < mPreviousNode->TextLength(), "incorrect tracking of undisplayed characters in " "text nodes"); undisplayed += mPreviousNode->TextLength() - mNodeCharIndex; } // All the remaining Text that we iterate must also be undisplayed. for (Text* textNode = mNodeIterator.Current(); textNode; textNode = NextNode()) { undisplayed += textNode->TextLength(); } } // Record the trailing number of undisplayed characters on the // SVGTextFrame. aRoot->mTrailingUndisplayedCharacters = undisplayed; } Text* TextNodeCorrespondenceRecorder::NextNode() { mPreviousNode = mNodeIterator.Current(); Text* next; do { next = mNodeIterator.Next(); } while (next && next->TextLength() == 0); return next; } void TextNodeCorrespondenceRecorder::TraverseAndRecord(nsIFrame* aFrame) { // Recursively iterate over the frame tree, for frames that correspond // to text content elements. if (IsTextContentElement(aFrame->GetContent())) { for (nsIFrame* f : aFrame->PrincipalChildList()) { TraverseAndRecord(f); } return; } nsTextFrame* frame; // The current text frame. Text* node; // The text node for the current text frame. if (!GetNonEmptyTextFrameAndNode(aFrame, frame, node)) { // If this isn't an nsTextFrame, or is empty, nothing to do. return; } NS_ASSERTION(frame->GetContentOffset() >= 0, "don't know how to handle negative content indexes"); uint32_t undisplayed = 0; if (!mPreviousNode) { // Must be the very first text frame. NS_ASSERTION(mNodeCharIndex == 0, "incorrect tracking of undisplayed " "characters in text nodes"); if (!mNodeIterator.Current()) { MOZ_ASSERT_UNREACHABLE( "incorrect tracking of correspondence between " "text frames and text nodes"); } else { // Each whole Text we find before we get to the text node for the // first text frame must be undisplayed. while (mNodeIterator.Current() != node) { undisplayed += mNodeIterator.Current()->TextLength(); NextNode(); } // If the first text frame starts at a non-zero content offset, then those // earlier characters are also undisplayed. undisplayed += frame->GetContentOffset(); NextNode(); } } else if (mPreviousNode == node) { // Same text node as last time. if (static_cast(frame->GetContentOffset()) != mNodeCharIndex) { // We have some characters in the middle of the text node // that are undisplayed. NS_ASSERTION( mNodeCharIndex < static_cast(frame->GetContentOffset()), "incorrect tracking of undisplayed characters in " "text nodes"); undisplayed = frame->GetContentOffset() - mNodeCharIndex; } } else { // Different text node from last time. if (mPreviousNode->TextLength() != mNodeCharIndex) { NS_ASSERTION(mNodeCharIndex < mPreviousNode->TextLength(), "incorrect tracking of undisplayed characters in " "text nodes"); // Any trailing characters at the end of the previous Text are // undisplayed. undisplayed = mPreviousNode->TextLength() - mNodeCharIndex; } // Each whole Text we find before we get to the text node for // the current text frame must be undisplayed. while (mNodeIterator.Current() && mNodeIterator.Current() != node) { undisplayed += mNodeIterator.Current()->TextLength(); NextNode(); } // If the current text frame starts at a non-zero content offset, then those // earlier characters are also undisplayed. undisplayed += frame->GetContentOffset(); NextNode(); } // Set the frame property. frame->SetProperty(TextNodeCorrespondenceProperty(), new TextNodeCorrespondence(undisplayed)); // Remember how far into the current Text we are. mNodeCharIndex = frame->GetContentEnd(); } // ---------------------------------------------------------------------------- // TextFrameIterator /** * An iterator class for nsTextFrames that are descendants of an * SVGTextFrame. The iterator can optionally track whether the * current nsTextFrame is for a descendant of, or past, a given subtree * content node or frame. (This functionality is used for example by the SVG * DOM text methods to get only the nsTextFrames for a particular .) * * TextFrameIterator also tracks and exposes other information about the * current nsTextFrame: * * * how many undisplayed characters came just before it * * its position (in app units) relative to the SVGTextFrame's anonymous * block frame * * what nsInlineFrame corresponding to a element it is a * descendant of * * what computed dominant-baseline value applies to it * * Note that any text frames that are empty -- whose ContentLength() is 0 -- * will be skipped over. */ class MOZ_STACK_CLASS TextFrameIterator { public: /** * Constructs a TextFrameIterator for the specified SVGTextFrame * with an optional frame subtree to restrict iterated text frames to. */ explicit TextFrameIterator(SVGTextFrame* aRoot, const nsIFrame* aSubtree = nullptr) : mRootFrame(aRoot), mSubtree(aSubtree), mCurrentFrame(aRoot), mCurrentPosition(), mSubtreePosition(mSubtree ? eBeforeSubtree : eWithinSubtree) { Init(); } /** * Constructs a TextFrameIterator for the specified SVGTextFrame * with an optional frame content subtree to restrict iterated text frames to. */ TextFrameIterator(SVGTextFrame* aRoot, nsIContent* aSubtree) : mRootFrame(aRoot), mSubtree(aRoot && aSubtree && aSubtree != aRoot->GetContent() ? aSubtree->GetPrimaryFrame() : nullptr), mCurrentFrame(aRoot), mCurrentPosition(), mSubtreePosition(mSubtree ? eBeforeSubtree : eWithinSubtree) { Init(); } /** * Returns the root SVGTextFrame this TextFrameIterator is iterating over. */ SVGTextFrame* Root() const { return mRootFrame; } /** * Returns the current nsTextFrame. */ nsTextFrame* Current() const { return do_QueryFrame(mCurrentFrame); } /** * Returns the number of undisplayed characters in the DOM just before the * current frame. */ uint32_t UndisplayedCharacters() const; /** * Returns the current frame's position, in app units, relative to the * root SVGTextFrame's anonymous block frame. */ nsPoint Position() const { return mCurrentPosition; } /** * Advances to the next nsTextFrame and returns it. */ nsTextFrame* Next(); /** * Returns whether the iterator is within the subtree. */ bool IsWithinSubtree() const { return mSubtreePosition == eWithinSubtree; } /** * Returns whether the iterator is past the subtree. */ bool IsAfterSubtree() const { return mSubtreePosition == eAfterSubtree; } /** * Returns the frame corresponding to the element, if we * are inside one. */ nsIFrame* TextPathFrame() const { return mTextPathFrames.IsEmpty() ? nullptr : mTextPathFrames.ElementAt(mTextPathFrames.Length() - 1); } /** * Returns the current frame's computed dominant-baseline value. */ StyleDominantBaseline DominantBaseline() const { return mBaselines.ElementAt(mBaselines.Length() - 1); } /** * Finishes the iterator. */ void Close() { mCurrentFrame = nullptr; } private: /** * Initializes the iterator and advances to the first item. */ void Init() { if (!mRootFrame) { return; } mBaselines.AppendElement(mRootFrame->StyleSVG()->mDominantBaseline); Next(); } /** * Pushes the specified frame's computed dominant-baseline value. * If the value of the property is "auto", then the parent frame's * computed value is used. */ void PushBaseline(nsIFrame* aNextFrame); /** * Pops the current dominant-baseline off the stack. */ void PopBaseline(); /** * The root frame we are iterating through. */ SVGTextFrame* const mRootFrame; /** * The frame for the subtree we are also interested in tracking. */ const nsIFrame* const mSubtree; /** * The current value of the iterator. */ nsIFrame* mCurrentFrame; /** * The position, in app units, of the current frame relative to mRootFrame. */ nsPoint mCurrentPosition; /** * Stack of frames corresponding to elements that are in scope * for the current frame. */ AutoTArray mTextPathFrames; /** * Stack of dominant-baseline values to record as we traverse through the * frame tree. */ AutoTArray mBaselines; /** * The iterator's current position relative to mSubtree. */ SubtreePosition mSubtreePosition; }; uint32_t TextFrameIterator::UndisplayedCharacters() const { MOZ_ASSERT( !mRootFrame->HasAnyStateBits(NS_STATE_SVG_TEXT_CORRESPONDENCE_DIRTY), "Text correspondence must be up to date"); if (!mCurrentFrame) { return mRootFrame->mTrailingUndisplayedCharacters; } nsTextFrame* frame = do_QueryFrame(mCurrentFrame); return GetUndisplayedCharactersBeforeFrame(frame); } nsTextFrame* TextFrameIterator::Next() { // Starting from mCurrentFrame, we do a non-recursive traversal to the next // nsTextFrame beneath mRoot, updating mSubtreePosition appropriately if we // encounter mSubtree. if (mCurrentFrame) { do { nsIFrame* next = IsTextContentElement(mCurrentFrame->GetContent()) ? mCurrentFrame->PrincipalChildList().FirstChild() : nullptr; if (next) { // Descend into this frame, and accumulate its position. mCurrentPosition += next->GetPosition(); if (next->GetContent()->IsSVGElement(nsGkAtoms::textPath)) { // Record this frame. mTextPathFrames.AppendElement(next); } // Record the frame's baseline. PushBaseline(next); mCurrentFrame = next; if (mCurrentFrame == mSubtree) { // If the current frame is mSubtree, we have now moved into it. mSubtreePosition = eWithinSubtree; } } else { for (;;) { // We want to move past the current frame. if (mCurrentFrame == mRootFrame) { // If we've reached the root frame, we're finished. mCurrentFrame = nullptr; break; } // Remove the current frame's position. mCurrentPosition -= mCurrentFrame->GetPosition(); if (mCurrentFrame->GetContent()->IsSVGElement(nsGkAtoms::textPath)) { // Pop off the frame if this is a . mTextPathFrames.RemoveLastElement(); } // Pop off the current baseline. PopBaseline(); if (mCurrentFrame == mSubtree) { // If this was mSubtree, we have now moved past it. mSubtreePosition = eAfterSubtree; } next = mCurrentFrame->GetNextSibling(); if (next) { // Moving to the next sibling. mCurrentPosition += next->GetPosition(); if (next->GetContent()->IsSVGElement(nsGkAtoms::textPath)) { // Record this frame. mTextPathFrames.AppendElement(next); } // Record the frame's baseline. PushBaseline(next); mCurrentFrame = next; if (mCurrentFrame == mSubtree) { // If the current frame is mSubtree, we have now moved into it. mSubtreePosition = eWithinSubtree; } break; } if (mCurrentFrame == mSubtree) { // If there is no next sibling frame, and the current frame is // mSubtree, we have now moved past it. mSubtreePosition = eAfterSubtree; } // Ascend out of this frame. mCurrentFrame = mCurrentFrame->GetParent(); } } } while (mCurrentFrame && !IsNonEmptyTextFrame(mCurrentFrame)); } return Current(); } void TextFrameIterator::PushBaseline(nsIFrame* aNextFrame) { StyleDominantBaseline baseline = aNextFrame->StyleSVG()->mDominantBaseline; mBaselines.AppendElement(baseline); } void TextFrameIterator::PopBaseline() { NS_ASSERTION(!mBaselines.IsEmpty(), "popped too many baselines"); mBaselines.RemoveLastElement(); } // ----------------------------------------------------------------------------- // TextRenderedRunIterator /** * Iterator for TextRenderedRun objects for the SVGTextFrame. */ class TextRenderedRunIterator { public: /** * Values for the aFilter argument of the constructor, to indicate which * frames we should be limited to iterating TextRenderedRun objects for. */ enum RenderedRunFilter { // Iterate TextRenderedRuns for all nsTextFrames. eAllFrames, // Iterate only TextRenderedRuns for nsTextFrames that are // visibility:visible. eVisibleFrames }; /** * Constructs a TextRenderedRunIterator with an optional frame subtree to * restrict iterated rendered runs to. * * @param aSVGTextFrame The SVGTextFrame whose rendered runs to iterate * through. * @param aFilter Indicates whether to iterate rendered runs for non-visible * nsTextFrames. * @param aSubtree An optional frame subtree to restrict iterated rendered * runs to. */ explicit TextRenderedRunIterator(SVGTextFrame* aSVGTextFrame, RenderedRunFilter aFilter = eAllFrames, const nsIFrame* aSubtree = nullptr) : mFrameIterator(FrameIfAnonymousChildReflowed(aSVGTextFrame), aSubtree), mFilter(aFilter), mTextElementCharIndex(0), mFrameStartTextElementCharIndex(0), mFontSizeScaleFactor(aSVGTextFrame->mFontSizeScaleFactor), mCurrent(First()) {} /** * Constructs a TextRenderedRunIterator with a content subtree to restrict * iterated rendered runs to. * * @param aSVGTextFrame The SVGTextFrame whose rendered runs to iterate * through. * @param aFilter Indicates whether to iterate rendered runs for non-visible * nsTextFrames. * @param aSubtree A content subtree to restrict iterated rendered runs to. */ TextRenderedRunIterator(SVGTextFrame* aSVGTextFrame, RenderedRunFilter aFilter, nsIContent* aSubtree) : mFrameIterator(FrameIfAnonymousChildReflowed(aSVGTextFrame), aSubtree), mFilter(aFilter), mTextElementCharIndex(0), mFrameStartTextElementCharIndex(0), mFontSizeScaleFactor(aSVGTextFrame->mFontSizeScaleFactor), mCurrent(First()) {} /** * Returns the current TextRenderedRun. */ TextRenderedRun Current() const { return mCurrent; } /** * Advances to the next TextRenderedRun and returns it. */ TextRenderedRun Next(); private: /** * Returns the root SVGTextFrame this iterator is for. */ SVGTextFrame* Root() const { return mFrameIterator.Root(); } /** * Advances to the first TextRenderedRun and returns it. */ TextRenderedRun First(); /** * The frame iterator to use. */ TextFrameIterator mFrameIterator; /** * The filter indicating which TextRenderedRuns to return. */ RenderedRunFilter mFilter; /** * The character index across the entire element we are currently * up to. */ uint32_t mTextElementCharIndex; /** * The character index across the entire for the start of the current * frame. */ uint32_t mFrameStartTextElementCharIndex; /** * The font-size scale factor we used when constructing the nsTextFrames. */ double mFontSizeScaleFactor; /** * The current TextRenderedRun. */ TextRenderedRun mCurrent; }; TextRenderedRun TextRenderedRunIterator::Next() { if (!mFrameIterator.Current()) { // If there are no more frames, then there are no more rendered runs to // return. mCurrent = TextRenderedRun(); return mCurrent; } // The values we will use to initialize the TextRenderedRun with. nsTextFrame* frame; gfxPoint pt; double rotate; nscoord baseline; uint32_t offset, length; uint32_t charIndex; // We loop, because we want to skip over rendered runs that either aren't // within our subtree of interest, because they don't match the filter, // or because they are hidden due to having fallen off the end of a // . for (;;) { if (mFrameIterator.IsAfterSubtree()) { mCurrent = TextRenderedRun(); return mCurrent; } frame = mFrameIterator.Current(); charIndex = mTextElementCharIndex; // Find the end of the rendered run, by looking through the // SVGTextFrame's positions array until we find one that is recorded // as a run boundary. uint32_t runStart, runEnd; // XXX Replace runStart with mTextElementCharIndex. runStart = mTextElementCharIndex; runEnd = runStart + 1; while (runEnd < Root()->mPositions.Length() && !Root()->mPositions[runEnd].mRunBoundary) { runEnd++; } // Convert the global run start/end indexes into an offset/length into the // current frame's Text. offset = frame->GetContentOffset() + runStart - mFrameStartTextElementCharIndex; length = runEnd - runStart; // If the end of the frame's content comes before the run boundary we found // in SVGTextFrame's position array, we need to shorten the rendered run. uint32_t contentEnd = frame->GetContentEnd(); if (offset + length > contentEnd) { length = contentEnd - offset; } NS_ASSERTION(offset >= uint32_t(frame->GetContentOffset()), "invalid offset"); NS_ASSERTION(offset + length <= contentEnd, "invalid offset or length"); // Get the frame's baseline position. frame->EnsureTextRun(nsTextFrame::eInflated); baseline = GetBaselinePosition( frame, frame->GetTextRun(nsTextFrame::eInflated), mFrameIterator.DominantBaseline(), mFontSizeScaleFactor); // Trim the offset/length to remove any leading/trailing white space. uint32_t untrimmedOffset = offset; uint32_t untrimmedLength = length; nsTextFrame::TrimmedOffsets trimmedOffsets = frame->GetTrimmedOffsets(frame->TextFragment()); TrimOffsets(offset, length, trimmedOffsets); charIndex += offset - untrimmedOffset; // Get the position and rotation of the character that begins this // rendered run. pt = Root()->mPositions[charIndex].mPosition; rotate = Root()->mPositions[charIndex].mAngle; // Determine if we should skip this rendered run. bool skip = !mFrameIterator.IsWithinSubtree() || Root()->mPositions[mTextElementCharIndex].mHidden; if (mFilter == eVisibleFrames) { skip = skip || !frame->StyleVisibility()->IsVisible(); } // Update our global character index to move past the characters // corresponding to this rendered run. mTextElementCharIndex += untrimmedLength; // If we have moved past the end of the current frame's content, we need to // advance to the next frame. if (offset + untrimmedLength >= contentEnd) { mFrameIterator.Next(); mTextElementCharIndex += mFrameIterator.UndisplayedCharacters(); mFrameStartTextElementCharIndex = mTextElementCharIndex; } if (!mFrameIterator.Current()) { if (skip) { // That was the last frame, and we skipped this rendered run. So we // have no rendered run to return. mCurrent = TextRenderedRun(); return mCurrent; } break; } if (length && !skip) { // Only return a rendered run if it didn't get collapsed away entirely // (due to it being all white space) and if we don't want to skip it. break; } } mCurrent = TextRenderedRun(frame, pt, Root()->mLengthAdjustScaleFactor, rotate, mFontSizeScaleFactor, baseline, offset, length, charIndex); return mCurrent; } TextRenderedRun TextRenderedRunIterator::First() { if (!mFrameIterator.Current()) { return TextRenderedRun(); } if (Root()->mPositions.IsEmpty()) { mFrameIterator.Close(); return TextRenderedRun(); } // Get the character index for the start of this rendered run, by skipping // any undisplayed characters. mTextElementCharIndex = mFrameIterator.UndisplayedCharacters(); mFrameStartTextElementCharIndex = mTextElementCharIndex; return Next(); } // ----------------------------------------------------------------------------- // CharIterator /** * Iterator for characters within an SVGTextFrame. */ class MOZ_STACK_CLASS CharIterator { using Range = gfxTextRun::Range; public: /** * Values for the aFilter argument of the constructor, to indicate which * characters we should be iterating over. */ enum CharacterFilter { // Iterate over all original characters from the DOM that are within valid // text content elements. eOriginal, // Iterate only over characters that are not skipped characters. eUnskipped, // Iterate only over characters that are addressable by the positioning // attributes x="", y="", etc. This includes all characters after // collapsing white space as required by the value of 'white-space'. eAddressable, }; /** * Constructs a CharIterator. * * @param aSVGTextFrame The SVGTextFrame whose characters to iterate * through. * @param aFilter Indicates which characters to iterate over. * @param aSubtree A content subtree to track whether the current character * is within. */ CharIterator(SVGTextFrame* aSVGTextFrame, CharacterFilter aFilter, nsIContent* aSubtree, bool aPostReflow = true); /** * Returns whether the iterator is finished. */ bool AtEnd() const { return !mFrameIterator.Current(); } /** * Advances to the next matching character. Returns true if there was a * character to advance to, and false otherwise. */ bool Next(); /** * Advances ahead aCount matching characters. Returns true if there were * enough characters to advance past, and false otherwise. */ bool Next(uint32_t aCount); /** * Advances ahead up to aCount matching characters. */ void NextWithinSubtree(uint32_t aCount); /** * Advances to the character with the specified index. The index is in the * space of original characters (i.e., all DOM characters under the * that are within valid text content elements). */ bool AdvanceToCharacter(uint32_t aTextElementCharIndex); /** * Advances to the first matching character after the current nsTextFrame. */ bool AdvancePastCurrentFrame(); /** * Advances to the first matching character after the frames within * the current . */ bool AdvancePastCurrentTextPathFrame(); /** * Advances to the first matching character of the subtree. Returns true * if we successfully advance to the subtree, or if we are already within * the subtree. Returns false if we are past the subtree. */ bool AdvanceToSubtree(); /** * Returns the nsTextFrame for the current character. */ nsTextFrame* TextFrame() const { return mFrameIterator.Current(); } /** * Returns whether the iterator is within the subtree. */ bool IsWithinSubtree() const { return mFrameIterator.IsWithinSubtree(); } /** * Returns whether the iterator is past the subtree. */ bool IsAfterSubtree() const { return mFrameIterator.IsAfterSubtree(); } /** * Returns whether the current character is a skipped character. */ bool IsOriginalCharSkipped() const { return mSkipCharsIterator.IsOriginalCharSkipped(); } /** * Returns whether the current character is the start of a cluster and * ligature group. */ bool IsClusterAndLigatureGroupStart() const; /** * Returns the glyph run for the current character. */ const gfxTextRun::GlyphRun& GlyphRun() const; /** * Returns whether the current character is trimmed away when painting, * due to it being leading/trailing white space. */ bool IsOriginalCharTrimmed() const; /** * Returns whether the current character is unaddressable from the SVG glyph * positioning attributes. */ bool IsOriginalCharUnaddressable() const { return IsOriginalCharSkipped() || IsOriginalCharTrimmed(); } /** * Returns the text run for the current character. */ gfxTextRun* TextRun() const { return mTextRun; } /** * Returns the current character index. */ uint32_t TextElementCharIndex() const { return mTextElementCharIndex; } /** * Returns the character index for the start of the cluster/ligature group it * is part of. */ uint32_t GlyphStartTextElementCharIndex() const { return mGlyphStartTextElementCharIndex; } /** * Gets the advance, in user units, of the current character. If the * character is a part of ligature, then the advance returned will be * a fraction of the ligature glyph's advance. * * @param aContext The context to use for unit conversions. */ gfxFloat GetAdvance(nsPresContext* aContext) const; /** * Returns the frame corresponding to the that the current * character is within. */ nsIFrame* TextPathFrame() const { return mFrameIterator.TextPathFrame(); } #ifdef DEBUG /** * Returns the subtree we were constructed with. */ nsIContent* GetSubtree() const { return mSubtree; } /** * Returns the CharacterFilter mode in use. */ CharacterFilter Filter() const { return mFilter; } #endif private: /** * Advances to the next character without checking it against the filter. * Returns true if there was a next character to advance to, or false * otherwise. */ bool NextCharacter(); /** * Returns whether the current character matches the filter. */ bool MatchesFilter() const; /** * If this is the start of a glyph, record it. */ void UpdateGlyphStartTextElementCharIndex() { if (!IsOriginalCharSkipped() && IsClusterAndLigatureGroupStart()) { mGlyphStartTextElementCharIndex = mTextElementCharIndex; } } /** * The filter to use. */ CharacterFilter mFilter; /** * The iterator for text frames. */ TextFrameIterator mFrameIterator; #ifdef DEBUG /** * The subtree we were constructed with. */ nsIContent* const mSubtree; #endif /** * A gfxSkipCharsIterator for the text frame the current character is * a part of. */ gfxSkipCharsIterator mSkipCharsIterator; // Cache for information computed by IsOriginalCharTrimmed. mutable nsTextFrame* mFrameForTrimCheck; mutable uint32_t mTrimmedOffset; mutable uint32_t mTrimmedLength; /** * The text run the current character is a part of. */ gfxTextRun* mTextRun; /** * The current character's index. */ uint32_t mTextElementCharIndex; /** * The index of the character that starts the cluster/ligature group the * current character is a part of. */ uint32_t mGlyphStartTextElementCharIndex; /** * The scale factor to apply to glyph advances returned by * GetAdvance etc. to take into account textLength="". */ float mLengthAdjustScaleFactor; /** * Whether the instance of this class is being used after reflow has occurred * or not. */ bool mPostReflow; }; CharIterator::CharIterator(SVGTextFrame* aSVGTextFrame, CharIterator::CharacterFilter aFilter, nsIContent* aSubtree, bool aPostReflow) : mFilter(aFilter), mFrameIterator(aSVGTextFrame, aSubtree), #ifdef DEBUG mSubtree(aSubtree), #endif mFrameForTrimCheck(nullptr), mTrimmedOffset(0), mTrimmedLength(0), mTextRun(nullptr), mTextElementCharIndex(0), mGlyphStartTextElementCharIndex(0), mLengthAdjustScaleFactor(aSVGTextFrame->mLengthAdjustScaleFactor), mPostReflow(aPostReflow) { if (!AtEnd()) { mSkipCharsIterator = TextFrame()->EnsureTextRun(nsTextFrame::eInflated); mTextRun = TextFrame()->GetTextRun(nsTextFrame::eInflated); mTextElementCharIndex = mFrameIterator.UndisplayedCharacters(); UpdateGlyphStartTextElementCharIndex(); if (!MatchesFilter()) { Next(); } } } bool CharIterator::Next() { while (NextCharacter()) { if (MatchesFilter()) { return true; } } return false; } bool CharIterator::Next(uint32_t aCount) { if (aCount == 0 && AtEnd()) { return false; } while (aCount) { if (!Next()) { return false; } aCount--; } return true; } void CharIterator::NextWithinSubtree(uint32_t aCount) { while (IsWithinSubtree() && aCount) { --aCount; if (!Next()) { return; } } } bool CharIterator::AdvanceToCharacter(uint32_t aTextElementCharIndex) { while (mTextElementCharIndex < aTextElementCharIndex) { if (!Next()) { return false; } } return true; } bool CharIterator::AdvancePastCurrentFrame() { // XXX Can do this better than one character at a time if it matters. nsTextFrame* currentFrame = TextFrame(); do { if (!Next()) { return false; } } while (TextFrame() == currentFrame); return true; } bool CharIterator::AdvancePastCurrentTextPathFrame() { nsIFrame* currentTextPathFrame = TextPathFrame(); NS_ASSERTION(currentTextPathFrame, "expected AdvancePastCurrentTextPathFrame to be called only " "within a text path frame"); do { if (!AdvancePastCurrentFrame()) { return false; } } while (TextPathFrame() == currentTextPathFrame); return true; } bool CharIterator::AdvanceToSubtree() { while (!IsWithinSubtree()) { if (IsAfterSubtree()) { return false; } if (!AdvancePastCurrentFrame()) { return false; } } return true; } bool CharIterator::IsClusterAndLigatureGroupStart() const { return mTextRun->IsLigatureGroupStart( mSkipCharsIterator.GetSkippedOffset()) && mTextRun->IsClusterStart(mSkipCharsIterator.GetSkippedOffset()); } const gfxTextRun::GlyphRun& CharIterator::GlyphRun() const { uint32_t numRuns; const gfxTextRun::GlyphRun* glyphRuns = mTextRun->GetGlyphRuns(&numRuns); uint32_t runIndex = mTextRun->FindFirstGlyphRunContaining( mSkipCharsIterator.GetSkippedOffset()); MOZ_ASSERT(runIndex < numRuns); return glyphRuns[runIndex]; } bool CharIterator::IsOriginalCharTrimmed() const { if (mFrameForTrimCheck != TextFrame()) { // Since we do a lot of trim checking, we cache the trimmed offsets and // lengths while we are in the same frame. mFrameForTrimCheck = TextFrame(); uint32_t offset = mFrameForTrimCheck->GetContentOffset(); uint32_t length = mFrameForTrimCheck->GetContentLength(); nsTextFrame::TrimmedOffsets trim = mFrameForTrimCheck->GetTrimmedOffsets( mFrameForTrimCheck->TextFragment(), (mPostReflow ? nsTextFrame::TrimmedOffsetFlags::Default : nsTextFrame::TrimmedOffsetFlags::NotPostReflow)); TrimOffsets(offset, length, trim); mTrimmedOffset = offset; mTrimmedLength = length; } // A character is trimmed if it is outside the mTrimmedOffset/mTrimmedLength // range and it is not a significant newline character. uint32_t index = mSkipCharsIterator.GetOriginalOffset(); return !( (index >= mTrimmedOffset && index < mTrimmedOffset + mTrimmedLength) || (index >= mTrimmedOffset + mTrimmedLength && mFrameForTrimCheck->StyleText()->NewlineIsSignificant( mFrameForTrimCheck) && mFrameForTrimCheck->TextFragment()->CharAt(index) == '\n')); } gfxFloat CharIterator::GetAdvance(nsPresContext* aContext) const { float cssPxPerDevPx = nsPresContext::AppUnitsToFloatCSSPixels(aContext->AppUnitsPerDevPixel()); gfxSkipCharsIterator start = TextFrame()->EnsureTextRun(nsTextFrame::eInflated); nsTextFrame::PropertyProvider provider(TextFrame(), start); uint32_t offset = mSkipCharsIterator.GetSkippedOffset(); gfxFloat advance = mTextRun->GetAdvanceWidth(Range(offset, offset + 1), &provider); return aContext->AppUnitsToGfxUnits(advance) * mLengthAdjustScaleFactor * cssPxPerDevPx; } bool CharIterator::NextCharacter() { if (AtEnd()) { return false; } mTextElementCharIndex++; // Advance within the current text run. mSkipCharsIterator.AdvanceOriginal(1); if (mSkipCharsIterator.GetOriginalOffset() < TextFrame()->GetContentEnd()) { // We're still within the part of the text run for the current text frame. UpdateGlyphStartTextElementCharIndex(); return true; } // Advance to the next frame. mFrameIterator.Next(); // Skip any undisplayed characters. uint32_t undisplayed = mFrameIterator.UndisplayedCharacters(); mTextElementCharIndex += undisplayed; if (!TextFrame()) { // We're at the end. mSkipCharsIterator = gfxSkipCharsIterator(); return false; } mSkipCharsIterator = TextFrame()->EnsureTextRun(nsTextFrame::eInflated); mTextRun = TextFrame()->GetTextRun(nsTextFrame::eInflated); UpdateGlyphStartTextElementCharIndex(); return true; } bool CharIterator::MatchesFilter() const { switch (mFilter) { case eOriginal: return true; case eUnskipped: return !IsOriginalCharSkipped(); case eAddressable: return !IsOriginalCharSkipped() && !IsOriginalCharUnaddressable(); } MOZ_ASSERT_UNREACHABLE("Invalid mFilter value"); return true; } // ----------------------------------------------------------------------------- // SVGTextDrawPathCallbacks /** * Text frame draw callback class that paints the text and text decoration parts * of an nsTextFrame using SVG painting properties, and selection backgrounds * and decorations as they would normally. * * An instance of this class is passed to nsTextFrame::PaintText if painting * cannot be done directly (e.g. if we are using an SVG pattern fill, stroking * the text, etc.). */ class SVGTextDrawPathCallbacks final : public nsTextFrame::DrawPathCallbacks { using imgDrawingParams = image::imgDrawingParams; public: /** * Constructs an SVGTextDrawPathCallbacks. * * @param aSVGTextFrame The ancestor text frame. * @param aContext The context to use for painting. * @param aFrame The nsTextFrame to paint. * @param aCanvasTM The transformation matrix to set when painting; this * should be the FOR_OUTERSVG_TM canvas TM of the text, so that * paint servers are painted correctly. * @param aImgParams Whether we need to synchronously decode images. * @param aShouldPaintSVGGlyphs Whether SVG glyphs should be painted. */ SVGTextDrawPathCallbacks(SVGTextFrame* aSVGTextFrame, gfxContext& aContext, nsTextFrame* aFrame, const gfxMatrix& aCanvasTM, imgDrawingParams& aImgParams, bool aShouldPaintSVGGlyphs) : DrawPathCallbacks(aShouldPaintSVGGlyphs), mSVGTextFrame(aSVGTextFrame), mContext(aContext), mFrame(aFrame), mCanvasTM(aCanvasTM), mImgParams(aImgParams), mColor(0) {} void NotifySelectionBackgroundNeedsFill(const Rect& aBackgroundRect, nscolor aColor, DrawTarget& aDrawTarget) override; void PaintDecorationLine(Rect aPath, nscolor aColor) override; void PaintSelectionDecorationLine(Rect aPath, nscolor aColor) override; void NotifyBeforeText(nscolor aColor) override; void NotifyGlyphPathEmitted() override; void NotifyAfterText() override; private: void SetupContext(); bool IsClipPathChild() const { return mSVGTextFrame->HasAnyStateBits(NS_STATE_SVG_CLIPPATH_CHILD); } /** * Paints a piece of text geometry. This is called when glyphs * or text decorations have been emitted to the gfxContext. */ void HandleTextGeometry(); /** * Sets the gfxContext paint to the appropriate color or pattern * for filling text geometry. */ void MakeFillPattern(GeneralPattern* aOutPattern); /** * Fills and strokes a piece of text geometry, using group opacity * if the selection style requires it. */ void FillAndStrokeGeometry(); /** * Fills a piece of text geometry. */ void FillGeometry(); /** * Strokes a piece of text geometry. */ void StrokeGeometry(); SVGTextFrame* const mSVGTextFrame; gfxContext& mContext; nsTextFrame* const mFrame; const gfxMatrix& mCanvasTM; imgDrawingParams& mImgParams; /** * The color that we were last told from one of the path callback functions. * This color can be the special NS_SAME_AS_FOREGROUND_COLOR, * NS_40PERCENT_FOREGROUND_COLOR and NS_TRANSPARENT colors when we are * painting selections or IME decorations. */ nscolor mColor; }; void SVGTextDrawPathCallbacks::NotifySelectionBackgroundNeedsFill( const Rect& aBackgroundRect, nscolor aColor, DrawTarget& aDrawTarget) { if (IsClipPathChild()) { // Don't paint selection backgrounds when in a clip path. return; } mColor = aColor; // currently needed by MakeFillPattern GeneralPattern fillPattern; MakeFillPattern(&fillPattern); if (fillPattern.GetPattern()) { DrawOptions drawOptions(aColor == NS_40PERCENT_FOREGROUND_COLOR ? 0.4 : 1.0); aDrawTarget.FillRect(aBackgroundRect, fillPattern, drawOptions); } } void SVGTextDrawPathCallbacks::NotifyBeforeText(nscolor aColor) { mColor = aColor; SetupContext(); mContext.NewPath(); } void SVGTextDrawPathCallbacks::NotifyGlyphPathEmitted() { HandleTextGeometry(); mContext.NewPath(); } void SVGTextDrawPathCallbacks::NotifyAfterText() { mContext.Restore(); } void SVGTextDrawPathCallbacks::PaintDecorationLine(Rect aPath, nscolor aColor) { mColor = aColor; AntialiasMode aaMode = SVGUtils::ToAntialiasMode(mFrame->StyleText()->mTextRendering); mContext.Save(); mContext.NewPath(); mContext.SetAntialiasMode(aaMode); mContext.Rectangle(ThebesRect(aPath)); HandleTextGeometry(); mContext.NewPath(); mContext.Restore(); } void SVGTextDrawPathCallbacks::PaintSelectionDecorationLine(Rect aPath, nscolor aColor) { if (IsClipPathChild()) { // Don't paint selection decorations when in a clip path. return; } mColor = aColor; mContext.Save(); mContext.NewPath(); mContext.Rectangle(ThebesRect(aPath)); FillAndStrokeGeometry(); mContext.Restore(); } void SVGTextDrawPathCallbacks::SetupContext() { mContext.Save(); // XXX This is copied from nsSVGGlyphFrame::Render, but cairo doesn't actually // seem to do anything with the antialias mode. So we can perhaps remove it, // or make SetAntialiasMode set cairo text antialiasing too. switch (mFrame->StyleText()->mTextRendering) { case StyleTextRendering::Optimizespeed: mContext.SetAntialiasMode(AntialiasMode::NONE); break; default: mContext.SetAntialiasMode(AntialiasMode::SUBPIXEL); break; } } void SVGTextDrawPathCallbacks::HandleTextGeometry() { if (IsClipPathChild()) { RefPtr path = mContext.GetPath(); ColorPattern white( DeviceColor(1.f, 1.f, 1.f, 1.f)); // for masking, so no ToDeviceColor mContext.GetDrawTarget()->Fill(path, white); } else { // Normal painting. gfxContextMatrixAutoSaveRestore saveMatrix(&mContext); mContext.SetMatrixDouble(mCanvasTM); FillAndStrokeGeometry(); } } void SVGTextDrawPathCallbacks::MakeFillPattern(GeneralPattern* aOutPattern) { if (mColor == NS_SAME_AS_FOREGROUND_COLOR || mColor == NS_40PERCENT_FOREGROUND_COLOR) { SVGUtils::MakeFillPatternFor(mFrame, &mContext, aOutPattern, mImgParams); return; } if (mColor == NS_TRANSPARENT) { return; } aOutPattern->InitColorPattern(ToDeviceColor(mColor)); } void SVGTextDrawPathCallbacks::FillAndStrokeGeometry() { bool pushedGroup = false; if (mColor == NS_40PERCENT_FOREGROUND_COLOR) { pushedGroup = true; mContext.PushGroupForBlendBack(gfxContentType::COLOR_ALPHA, 0.4f); } uint32_t paintOrder = mFrame->StyleSVG()->mPaintOrder; if (!paintOrder) { FillGeometry(); StrokeGeometry(); } else { while (paintOrder) { auto component = StylePaintOrder(paintOrder & kPaintOrderMask); switch (component) { case StylePaintOrder::Fill: FillGeometry(); break; case StylePaintOrder::Stroke: StrokeGeometry(); break; default: MOZ_FALLTHROUGH_ASSERT("Unknown paint-order value"); case StylePaintOrder::Markers: case StylePaintOrder::Normal: break; } paintOrder >>= kPaintOrderShift; } } if (pushedGroup) { mContext.PopGroupAndBlend(); } } void SVGTextDrawPathCallbacks::FillGeometry() { GeneralPattern fillPattern; MakeFillPattern(&fillPattern); if (fillPattern.GetPattern()) { RefPtr path = mContext.GetPath(); FillRule fillRule = SVGUtils::ToFillRule(IsClipPathChild() ? mFrame->StyleSVG()->mClipRule : mFrame->StyleSVG()->mFillRule); if (fillRule != path->GetFillRule()) { RefPtr builder = path->CopyToBuilder(fillRule); path = builder->Finish(); } mContext.GetDrawTarget()->Fill(path, fillPattern); } } void SVGTextDrawPathCallbacks::StrokeGeometry() { // We don't paint the stroke when we are filling with a selection color. if (mColor == NS_SAME_AS_FOREGROUND_COLOR || mColor == NS_40PERCENT_FOREGROUND_COLOR) { if (SVGUtils::HasStroke(mFrame, /*aContextPaint*/ nullptr)) { GeneralPattern strokePattern; SVGUtils::MakeStrokePatternFor(mFrame, &mContext, &strokePattern, mImgParams, /*aContextPaint*/ nullptr); if (strokePattern.GetPattern()) { if (!mFrame->GetParent()->GetContent()->IsSVGElement()) { // The cast that follows would be unsafe MOZ_ASSERT(false, "Our nsTextFrame's parent's content should be SVG"); return; } SVGElement* svgOwner = static_cast(mFrame->GetParent()->GetContent()); // Apply any stroke-specific transform gfxMatrix outerSVGToUser; if (SVGUtils::GetNonScalingStrokeTransform(mFrame, &outerSVGToUser) && outerSVGToUser.Invert()) { mContext.Multiply(outerSVGToUser); } RefPtr path = mContext.GetPath(); SVGContentUtils::AutoStrokeOptions strokeOptions; SVGContentUtils::GetStrokeOptions(&strokeOptions, svgOwner, mFrame->Style(), /*aContextPaint*/ nullptr); DrawOptions drawOptions; drawOptions.mAntialiasMode = SVGUtils::ToAntialiasMode(mFrame->StyleText()->mTextRendering); mContext.GetDrawTarget()->Stroke(path, strokePattern, strokeOptions); } } } } // ============================================================================ // SVGTextFrame // ---------------------------------------------------------------------------- // Display list item class DisplaySVGText final : public nsPaintedDisplayItem { public: DisplaySVGText(nsDisplayListBuilder* aBuilder, SVGTextFrame* aFrame) : nsPaintedDisplayItem(aBuilder, aFrame) { MOZ_COUNT_CTOR(DisplaySVGText); MOZ_ASSERT(aFrame, "Must have a frame!"); } #ifdef NS_BUILD_REFCNT_LOGGING MOZ_COUNTED_DTOR_OVERRIDE(DisplaySVGText) #endif NS_DISPLAY_DECL_NAME("DisplaySVGText", TYPE_SVG_TEXT) virtual void HitTest(nsDisplayListBuilder* aBuilder, const nsRect& aRect, HitTestState* aState, nsTArray* aOutFrames) override; void Paint(nsDisplayListBuilder* aBuilder, gfxContext* aCtx) override; nsDisplayItemGeometry* AllocateGeometry( nsDisplayListBuilder* aBuilder) override { return new nsDisplayItemGenericGeometry(this, aBuilder); } virtual nsRect GetComponentAlphaBounds( nsDisplayListBuilder* aBuilder) const override { bool snap; return GetBounds(aBuilder, &snap); } }; void DisplaySVGText::HitTest(nsDisplayListBuilder* aBuilder, const nsRect& aRect, HitTestState* aState, nsTArray* aOutFrames) { SVGTextFrame* frame = static_cast(mFrame); nsPoint pointRelativeToReferenceFrame = aRect.Center(); // ToReferenceFrame() includes frame->GetPosition(), our user space position. nsPoint userSpacePtInAppUnits = pointRelativeToReferenceFrame - (ToReferenceFrame() - frame->GetPosition()); gfxPoint userSpacePt = gfxPoint(userSpacePtInAppUnits.x, userSpacePtInAppUnits.y) / AppUnitsPerCSSPixel(); nsIFrame* target = frame->GetFrameForPoint(userSpacePt); if (target) { aOutFrames->AppendElement(target); } } void DisplaySVGText::Paint(nsDisplayListBuilder* aBuilder, gfxContext* aCtx) { uint32_t appUnitsPerDevPixel = mFrame->PresContext()->AppUnitsPerDevPixel(); // ToReferenceFrame includes our mRect offset, but painting takes // account of that too. To avoid double counting, we subtract that // here. nsPoint offset = ToReferenceFrame() - mFrame->GetPosition(); gfxPoint devPixelOffset = nsLayoutUtils::PointToGfxPoint(offset, appUnitsPerDevPixel); gfxMatrix tm = SVGUtils::GetCSSPxToDevPxMatrix(mFrame) * gfxMatrix::Translation(devPixelOffset); gfxContext* ctx = aCtx; imgDrawingParams imgParams(aBuilder->GetImageDecodeFlags()); static_cast(mFrame)->PaintSVG(*ctx, tm, imgParams); } // --------------------------------------------------------------------- // nsQueryFrame methods NS_QUERYFRAME_HEAD(SVGTextFrame) NS_QUERYFRAME_ENTRY(SVGTextFrame) NS_QUERYFRAME_TAIL_INHERITING(SVGDisplayContainerFrame) } // namespace mozilla // --------------------------------------------------------------------- // Implementation nsIFrame* NS_NewSVGTextFrame(mozilla::PresShell* aPresShell, mozilla::ComputedStyle* aStyle) { return new (aPresShell) mozilla::SVGTextFrame(aStyle, aPresShell->GetPresContext()); } namespace mozilla { NS_IMPL_FRAMEARENA_HELPERS(SVGTextFrame) // --------------------------------------------------------------------- // nsIFrame methods void SVGTextFrame::Init(nsIContent* aContent, nsContainerFrame* aParent, nsIFrame* aPrevInFlow) { NS_ASSERTION(aContent->IsSVGElement(nsGkAtoms::text), "Content is not an SVG text"); SVGDisplayContainerFrame::Init(aContent, aParent, aPrevInFlow); AddStateBits((aParent->GetStateBits() & NS_STATE_SVG_CLIPPATH_CHILD) | NS_FRAME_SVG_LAYOUT | NS_FRAME_IS_SVG_TEXT); mMutationObserver = new MutationObserver(this); if (mState & NS_FRAME_IS_NONDISPLAY) { // We're inserting a new element into a non-display context. // Ensure that we get reflowed. ScheduleReflowSVGNonDisplayText( IntrinsicDirty::FrameAncestorsAndDescendants); } } void SVGTextFrame::BuildDisplayList(nsDisplayListBuilder* aBuilder, const nsDisplayListSet& aLists) { if (IsSubtreeDirty()) { // We can sometimes be asked to paint before reflow happens and we // have updated mPositions, etc. In this case, we just avoid // painting. return; } if (!IsVisibleForPainting() && aBuilder->IsForPainting()) { return; } DisplayOutline(aBuilder, aLists); aLists.Content()->AppendNewToTop(aBuilder, this); } nsresult SVGTextFrame::AttributeChanged(int32_t aNameSpaceID, nsAtom* aAttribute, int32_t aModType) { if (aNameSpaceID != kNameSpaceID_None) { return NS_OK; } if (aAttribute == nsGkAtoms::transform) { // We don't invalidate for transform changes (the layers code does that). // Also note that SVGTransformableElement::GetAttributeChangeHint will // return nsChangeHint_UpdateOverflow for "transform" attribute changes // and cause DoApplyRenderingChangeToTree to make the SchedulePaint call. if (!(mState & NS_FRAME_FIRST_REFLOW) && mCanvasTM && mCanvasTM->IsSingular()) { // We won't have calculated the glyph positions correctly. NotifyGlyphMetricsChange(); } mCanvasTM = nullptr; } else if (IsGlyphPositioningAttribute(aAttribute) || aAttribute == nsGkAtoms::textLength || aAttribute == nsGkAtoms::lengthAdjust) { NotifyGlyphMetricsChange(); } return NS_OK; } void SVGTextFrame::ReflowSVGNonDisplayText() { MOZ_ASSERT(SVGUtils::AnyOuterSVGIsCallingReflowSVG(this), "only call ReflowSVGNonDisplayText when an outer SVG frame is " "under ReflowSVG"); MOZ_ASSERT(mState & NS_FRAME_IS_NONDISPLAY, "only call ReflowSVGNonDisplayText if the frame is " "NS_FRAME_IS_NONDISPLAY"); // We had a style change, so we mark this frame as dirty so that the next // time it is painted, we reflow the anonymous block frame. this->MarkSubtreeDirty(); // Finally, we need to actually reflow the anonymous block frame and update // mPositions, in case we are being reflowed immediately after a DOM // mutation that needs frame reconstruction. MaybeReflowAnonymousBlockChild(); UpdateGlyphPositioning(); } void SVGTextFrame::ScheduleReflowSVGNonDisplayText(IntrinsicDirty aReason) { MOZ_ASSERT(!SVGUtils::OuterSVGIsCallingReflowSVG(this), "do not call ScheduleReflowSVGNonDisplayText when the outer SVG " "frame is under ReflowSVG"); MOZ_ASSERT(!(mState & NS_STATE_SVG_TEXT_IN_REFLOW), "do not call ScheduleReflowSVGNonDisplayText while reflowing the " "anonymous block child"); // We need to find an ancestor frame that we can call FrameNeedsReflow // on that will cause the document to be marked as needing relayout, // and for that ancestor (or some further ancestor) to be marked as // a root to reflow. We choose the closest ancestor frame that is not // NS_FRAME_IS_NONDISPLAY and which is either an outer SVG frame or a // non-SVG frame. (We don't consider displayed SVG frame ancestors other // than SVGOuterSVGFrame, since calling FrameNeedsReflow on those other // SVG frames would do a bunch of unnecessary work on the SVG frames up to // the SVGOuterSVGFrame.) nsIFrame* f = this; while (f) { if (!f->HasAnyStateBits(NS_FRAME_IS_NONDISPLAY)) { if (f->IsSubtreeDirty()) { // This is a displayed frame, so if it is already dirty, we will be // reflowed soon anyway. No need to call FrameNeedsReflow again, then. return; } if (!f->IsFrameOfType(eSVG) || f->IsSVGOuterSVGFrame()) { break; } f->AddStateBits(NS_FRAME_HAS_DIRTY_CHILDREN); } f = f->GetParent(); } MOZ_ASSERT(f, "should have found an ancestor frame to reflow"); PresShell()->FrameNeedsReflow(f, aReason, NS_FRAME_IS_DIRTY); } NS_IMPL_ISUPPORTS(SVGTextFrame::MutationObserver, nsIMutationObserver) void SVGTextFrame::MutationObserver::ContentAppended( nsIContent* aFirstNewContent) { mFrame->NotifyGlyphMetricsChange(); } void SVGTextFrame::MutationObserver::ContentInserted(nsIContent* aChild) { mFrame->NotifyGlyphMetricsChange(); } void SVGTextFrame::MutationObserver::ContentRemoved( nsIContent* aChild, nsIContent* aPreviousSibling) { mFrame->NotifyGlyphMetricsChange(); } void SVGTextFrame::MutationObserver::CharacterDataChanged( nsIContent* aContent, const CharacterDataChangeInfo&) { mFrame->NotifyGlyphMetricsChange(); } void SVGTextFrame::MutationObserver::AttributeChanged( Element* aElement, int32_t aNameSpaceID, nsAtom* aAttribute, int32_t aModType, const nsAttrValue* aOldValue) { if (!aElement->IsSVGElement()) { return; } // Attribute changes on this element will be handled by // SVGTextFrame::AttributeChanged. if (aElement == mFrame->GetContent()) { return; } mFrame->HandleAttributeChangeInDescendant(aElement, aNameSpaceID, aAttribute); } void SVGTextFrame::HandleAttributeChangeInDescendant(Element* aElement, int32_t aNameSpaceID, nsAtom* aAttribute) { if (aElement->IsSVGElement(nsGkAtoms::textPath)) { if (aNameSpaceID == kNameSpaceID_None && (aAttribute == nsGkAtoms::startOffset || aAttribute == nsGkAtoms::path || aAttribute == nsGkAtoms::side_)) { NotifyGlyphMetricsChange(); } else if ((aNameSpaceID == kNameSpaceID_XLink || aNameSpaceID == kNameSpaceID_None) && aAttribute == nsGkAtoms::href) { // Blow away our reference, if any nsIFrame* childElementFrame = aElement->GetPrimaryFrame(); if (childElementFrame) { SVGObserverUtils::RemoveTextPathObserver(childElementFrame); NotifyGlyphMetricsChange(); } } } else { if (aNameSpaceID == kNameSpaceID_None && IsGlyphPositioningAttribute(aAttribute)) { NotifyGlyphMetricsChange(); } } } void SVGTextFrame::FindCloserFrameForSelection( const nsPoint& aPoint, FrameWithDistance* aCurrentBestFrame) { if (HasAnyStateBits(NS_FRAME_IS_NONDISPLAY)) { return; } UpdateGlyphPositioning(); nsPresContext* presContext = PresContext(); // Find the frame that has the closest rendered run rect to aPoint. TextRenderedRunIterator it(this); for (TextRenderedRun run = it.Current(); run.mFrame; run = it.Next()) { uint32_t flags = TextRenderedRun::eIncludeFill | TextRenderedRun::eIncludeStroke | TextRenderedRun::eNoHorizontalOverflow; SVGBBox userRect = run.GetUserSpaceRect(presContext, flags); float devPxPerCSSPx = presContext->CSSPixelsToDevPixels(1.f); userRect.Scale(devPxPerCSSPx); if (!userRect.IsEmpty()) { gfxMatrix m; if (!NS_SVGDisplayListHitTestingEnabled()) { m = GetCanvasTM(); } nsRect rect = SVGUtils::ToCanvasBounds(userRect.ToThebesRect(), m, presContext); if (nsLayoutUtils::PointIsCloserToRect(aPoint, rect, aCurrentBestFrame->mXDistance, aCurrentBestFrame->mYDistance)) { aCurrentBestFrame->mFrame = run.mFrame; } } } } //---------------------------------------------------------------------- // ISVGDisplayableFrame methods void SVGTextFrame::NotifySVGChanged(uint32_t aFlags) { MOZ_ASSERT(aFlags & (TRANSFORM_CHANGED | COORD_CONTEXT_CHANGED), "Invalidation logic may need adjusting"); bool needNewBounds = false; bool needGlyphMetricsUpdate = false; bool needNewCanvasTM = false; if ((aFlags & COORD_CONTEXT_CHANGED) && (mState & NS_STATE_SVG_POSITIONING_MAY_USE_PERCENTAGES)) { needGlyphMetricsUpdate = true; } if (aFlags & TRANSFORM_CHANGED) { needNewCanvasTM = true; if (mCanvasTM && mCanvasTM->IsSingular()) { // We won't have calculated the glyph positions correctly. needNewBounds = true; needGlyphMetricsUpdate = true; } if (StyleSVGReset()->HasNonScalingStroke()) { // Stroke currently contributes to our mRect, and our stroke depends on // the transform to our outer- if |vector-effect:non-scaling-stroke|. needNewBounds = true; } } // If the scale at which we computed our mFontSizeScaleFactor has changed by // at least a factor of two, reflow the text. This avoids reflowing text // at every tick of a transform animation, but ensures our glyph metrics // do not get too far out of sync with the final font size on the screen. if (needNewCanvasTM && mLastContextScale != 0.0f) { mCanvasTM = nullptr; // If we are a non-display frame, then we don't want to call // GetCanvasTM(), since the context scale does not use it. gfxMatrix newTM = (mState & NS_FRAME_IS_NONDISPLAY) ? gfxMatrix() : GetCanvasTM(); // Compare the old and new context scales. float scale = GetContextScale(newTM); float change = scale / mLastContextScale; if (change >= 2.0f || change <= 0.5f) { needNewBounds = true; needGlyphMetricsUpdate = true; } } if (needNewBounds) { // Ancestor changes can't affect how we render from the perspective of // any rendering observers that we may have, so we don't need to // invalidate them. We also don't need to invalidate ourself, since our // changed ancestor will have invalidated its entire area, which includes // our area. ScheduleReflowSVG(); } if (needGlyphMetricsUpdate) { // If we are positioned using percentage values we need to update our // position whenever our viewport's dimensions change. But only do this if // we have been reflowed once, otherwise the glyph positioning will be // wrong. (We need to wait until bidi reordering has been done.) if (!(mState & NS_FRAME_FIRST_REFLOW)) { NotifyGlyphMetricsChange(); } } } /** * Gets the offset into a DOM node that the specified caret is positioned at. */ static int32_t GetCaretOffset(nsCaret* aCaret) { RefPtr selection = aCaret->GetSelection(); if (!selection) { return -1; } return selection->AnchorOffset(); } /** * Returns whether the caret should be painted for a given TextRenderedRun * by checking whether the caret is in the range covered by the rendered run. * * @param aThisRun The TextRenderedRun to be painted. * @param aCaret The caret. */ static bool ShouldPaintCaret(const TextRenderedRun& aThisRun, nsCaret* aCaret) { int32_t caretOffset = GetCaretOffset(aCaret); if (caretOffset < 0) { return false; } return uint32_t(caretOffset) >= aThisRun.mTextFrameContentOffset && uint32_t(caretOffset) < aThisRun.mTextFrameContentOffset + aThisRun.mTextFrameContentLength; } void SVGTextFrame::PaintSVG(gfxContext& aContext, const gfxMatrix& aTransform, imgDrawingParams& aImgParams, const nsIntRect* aDirtyRect) { DrawTarget& aDrawTarget = *aContext.GetDrawTarget(); nsIFrame* kid = PrincipalChildList().FirstChild(); if (!kid) { return; } nsPresContext* presContext = PresContext(); gfxMatrix initialMatrix = aContext.CurrentMatrixDouble(); if (mState & NS_FRAME_IS_NONDISPLAY) { // If we are in a canvas DrawWindow call that used the // DRAWWINDOW_DO_NOT_FLUSH flag, then we may still have out // of date frames. Just don't paint anything if they are // dirty. if (presContext->PresShell()->InDrawWindowNotFlushing() && IsSubtreeDirty()) { return; } // Text frames inside , , etc. will never have had // ReflowSVG called on them, so call UpdateGlyphPositioning to do this now. UpdateGlyphPositioning(); } else if (IsSubtreeDirty()) { // If we are asked to paint before reflow has recomputed mPositions etc. // directly via PaintSVG, rather than via a display list, then we need // to bail out here too. return; } const float epsilon = 0.0001; if (abs(mLengthAdjustScaleFactor) < epsilon) { // A zero scale factor can be caused by having forced the text length to // zero. In this situation there is nothing to show. return; } if (aTransform.IsSingular()) { NS_WARNING("Can't render text element!"); return; } gfxMatrix matrixForPaintServers = aTransform * initialMatrix; // Check if we need to draw anything. if (aDirtyRect) { NS_ASSERTION(!NS_SVGDisplayListPaintingEnabled() || (mState & NS_FRAME_IS_NONDISPLAY), "Display lists handle dirty rect intersection test"); nsRect dirtyRect(aDirtyRect->x, aDirtyRect->y, aDirtyRect->width, aDirtyRect->height); gfxFloat appUnitsPerDevPixel = presContext->AppUnitsPerDevPixel(); gfxRect frameRect( mRect.x / appUnitsPerDevPixel, mRect.y / appUnitsPerDevPixel, mRect.width / appUnitsPerDevPixel, mRect.height / appUnitsPerDevPixel); nsRect canvasRect = nsLayoutUtils::RoundGfxRectToAppRect( GetCanvasTM().TransformBounds(frameRect), 1); if (!canvasRect.Intersects(dirtyRect)) { return; } } // SVG frames' PaintSVG methods paint in CSS px, but normally frames paint in // dev pixels. Here we multiply a CSS-px-to-dev-pixel factor onto aTransform // so our non-SVG nsTextFrame children paint correctly. auto auPerDevPx = presContext->AppUnitsPerDevPixel(); float cssPxPerDevPx = nsPresContext::AppUnitsToFloatCSSPixels(auPerDevPx); gfxMatrix canvasTMForChildren = aTransform; canvasTMForChildren.PreScale(cssPxPerDevPx, cssPxPerDevPx); initialMatrix.PreScale(1 / cssPxPerDevPx, 1 / cssPxPerDevPx); gfxContextMatrixAutoSaveRestore matSR(&aContext); aContext.NewPath(); aContext.Multiply(canvasTMForChildren); gfxMatrix currentMatrix = aContext.CurrentMatrixDouble(); RefPtr caret = presContext->PresShell()->GetCaret(); nsRect caretRect; nsIFrame* caretFrame = caret->GetPaintGeometry(&caretRect); gfxContextAutoSaveRestore ctxSR; TextRenderedRunIterator it(this, TextRenderedRunIterator::eVisibleFrames); TextRenderedRun run = it.Current(); SVGContextPaint* outerContextPaint = SVGContextPaint::GetContextPaint(GetContent()); while (run.mFrame) { nsTextFrame* frame = run.mFrame; RefPtr contextPaint = new SVGContextPaintImpl(); DrawMode drawMode = contextPaint->Init(&aDrawTarget, initialMatrix, frame, outerContextPaint, aImgParams); if (drawMode & DrawMode::GLYPH_STROKE) { ctxSR.EnsureSaved(&aContext); // This may change the gfxContext's transform (for non-scaling stroke), // in which case this needs to happen before we call SetMatrix() below. SVGUtils::SetupStrokeGeometry(frame->GetParent(), &aContext, outerContextPaint); } nscoord startEdge, endEdge; run.GetClipEdges(startEdge, endEdge); // Set up the transform for painting the text frame for the substring // indicated by the run. gfxMatrix runTransform = run.GetTransformFromUserSpaceForPainting( presContext, startEdge, endEdge) * currentMatrix; aContext.SetMatrixDouble(runTransform); if (drawMode != DrawMode(0)) { bool paintSVGGlyphs; nsTextFrame::PaintTextParams params(&aContext); params.framePt = Point(); params.dirtyRect = LayoutDevicePixel::FromAppUnits(frame->InkOverflowRect(), auPerDevPx); params.contextPaint = contextPaint; const bool isSelected = frame->IsSelected(); if (ShouldRenderAsPath(frame, paintSVGGlyphs)) { SVGTextDrawPathCallbacks callbacks(this, aContext, frame, matrixForPaintServers, aImgParams, paintSVGGlyphs); params.callbacks = &callbacks; frame->PaintText(params, startEdge, endEdge, nsPoint(), isSelected); } else { frame->PaintText(params, startEdge, endEdge, nsPoint(), isSelected); } } if (frame == caretFrame && ShouldPaintCaret(run, caret)) { // XXX Should we be looking at the fill/stroke colours to paint the // caret with, rather than using the color property? caret->PaintCaret(aDrawTarget, frame, nsPoint()); aContext.NewPath(); } run = it.Next(); } } nsIFrame* SVGTextFrame::GetFrameForPoint(const gfxPoint& aPoint) { NS_ASSERTION(PrincipalChildList().FirstChild(), "must have a child frame"); if (mState & NS_FRAME_IS_NONDISPLAY) { // Text frames inside will never have had ReflowSVG called on // them, so call UpdateGlyphPositioning to do this now. (Text frames // inside and other non-display containers will never need to // be hit tested.) UpdateGlyphPositioning(); } else { NS_ASSERTION(!IsSubtreeDirty(), "reflow should have happened"); } // Hit-testing any clip-path will typically be a lot quicker than the // hit-testing of our text frames in the loop below, so we do the former up // front to avoid unnecessarily wasting cycles on the latter. if (!SVGUtils::HitTestClip(this, aPoint)) { return nullptr; } nsPresContext* presContext = PresContext(); // Ideally we'd iterate backwards so that we can just return the first frame // that is under aPoint. In practice this will rarely matter though since it // is rare for text in/under an SVG element to overlap (i.e. the first // text frame that is hit will likely be the only text frame that is hit). TextRenderedRunIterator it(this); nsIFrame* hit = nullptr; for (TextRenderedRun run = it.Current(); run.mFrame; run = it.Next()) { uint16_t hitTestFlags = SVGUtils::GetGeometryHitTestFlags(run.mFrame); if (!(hitTestFlags & (SVG_HIT_TEST_FILL | SVG_HIT_TEST_STROKE))) { continue; } gfxMatrix m = run.GetTransformFromRunUserSpaceToUserSpace(presContext); if (!m.Invert()) { return nullptr; } gfxPoint pointInRunUserSpace = m.TransformPoint(aPoint); gfxRect frameRect = run.GetRunUserSpaceRect( presContext, TextRenderedRun::eIncludeFill | TextRenderedRun::eIncludeStroke) .ToThebesRect(); if (Inside(frameRect, pointInRunUserSpace)) { hit = run.mFrame; } } return hit; } void SVGTextFrame::ReflowSVG() { MOZ_ASSERT(SVGUtils::AnyOuterSVGIsCallingReflowSVG(this), "This call is probaby a wasteful mistake"); MOZ_ASSERT(!HasAnyStateBits(NS_FRAME_IS_NONDISPLAY), "ReflowSVG mechanism not designed for this"); if (!SVGUtils::NeedsReflowSVG(this)) { MOZ_ASSERT(!HasAnyStateBits(NS_STATE_SVG_TEXT_CORRESPONDENCE_DIRTY | NS_STATE_SVG_POSITIONING_DIRTY), "How did this happen?"); return; } MaybeReflowAnonymousBlockChild(); UpdateGlyphPositioning(); nsPresContext* presContext = PresContext(); SVGBBox r; TextRenderedRunIterator it(this, TextRenderedRunIterator::eAllFrames); for (TextRenderedRun run = it.Current(); run.mFrame; run = it.Next()) { uint32_t runFlags = 0; if (!run.mFrame->StyleSVG()->mFill.kind.IsNone()) { runFlags |= TextRenderedRun::eIncludeFill | TextRenderedRun::eIncludeTextShadow; } if (SVGUtils::HasStroke(run.mFrame)) { runFlags |= TextRenderedRun::eIncludeStroke | TextRenderedRun::eIncludeTextShadow; } // Our "visual" overflow rect needs to be valid for building display lists // for hit testing, which means that for certain values of 'pointer-events' // it needs to include the geometry of the fill or stroke even when the // fill/ stroke don't actually render (e.g. when stroke="none" or // stroke-opacity="0"). GetGeometryHitTestFlags accounts for // 'pointer-events'. The text-shadow is not part of the hit-test area. uint16_t hitTestFlags = SVGUtils::GetGeometryHitTestFlags(run.mFrame); if (hitTestFlags & SVG_HIT_TEST_FILL) { runFlags |= TextRenderedRun::eIncludeFill; } if (hitTestFlags & SVG_HIT_TEST_STROKE) { runFlags |= TextRenderedRun::eIncludeStroke; } if (runFlags) { r.UnionEdges(run.GetUserSpaceRect(presContext, runFlags)); } } if (r.IsEmpty()) { mRect.SetEmpty(); } else { mRect = nsLayoutUtils::RoundGfxRectToAppRect(r.ToThebesRect(), AppUnitsPerCSSPixel()); // Due to rounding issues when we have a transform applied, we sometimes // don't include an additional row of pixels. For now, just inflate our // covered region. mRect.Inflate(ceil(presContext->AppUnitsPerDevPixel() / mLastContextScale)); } if (mState & NS_FRAME_FIRST_REFLOW) { // Make sure we have our filter property (if any) before calling // FinishAndStoreOverflow (subsequent filter changes are handled off // nsChangeHint_UpdateEffects): SVGObserverUtils::UpdateEffects(this); } // Now unset the various reflow bits. Do this before calling // FinishAndStoreOverflow since FinishAndStoreOverflow can require glyph // positions (to resolve transform-origin). RemoveStateBits(NS_FRAME_FIRST_REFLOW | NS_FRAME_IS_DIRTY | NS_FRAME_HAS_DIRTY_CHILDREN); nsRect overflow = nsRect(nsPoint(0, 0), mRect.Size()); OverflowAreas overflowAreas(overflow, overflow); FinishAndStoreOverflow(overflowAreas, mRect.Size()); // XXX SVGContainerFrame::ReflowSVG only looks at its ISVGDisplayableFrame // children, and calls ConsiderChildOverflow on them. Does it matter // that ConsiderChildOverflow won't be called on our children? SVGDisplayContainerFrame::ReflowSVG(); } /** * Converts SVGUtils::eBBox* flags into TextRenderedRun flags appropriate * for the specified rendered run. */ static uint32_t TextRenderedRunFlagsForBBoxContribution( const TextRenderedRun& aRun, uint32_t aBBoxFlags) { uint32_t flags = 0; if ((aBBoxFlags & SVGUtils::eBBoxIncludeFillGeometry) || ((aBBoxFlags & SVGUtils::eBBoxIncludeFill) && !aRun.mFrame->StyleSVG()->mFill.kind.IsNone())) { flags |= TextRenderedRun::eIncludeFill; } if ((aBBoxFlags & SVGUtils::eBBoxIncludeStrokeGeometry) || ((aBBoxFlags & SVGUtils::eBBoxIncludeStroke) && SVGUtils::HasStroke(aRun.mFrame))) { flags |= TextRenderedRun::eIncludeStroke; } return flags; } SVGBBox SVGTextFrame::GetBBoxContribution(const Matrix& aToBBoxUserspace, uint32_t aFlags) { NS_ASSERTION(PrincipalChildList().FirstChild(), "must have a child frame"); SVGBBox bbox; if (aFlags & SVGUtils::eForGetClientRects) { Rect rect = NSRectToRect(mRect, AppUnitsPerCSSPixel()); if (!rect.IsEmpty()) { bbox = aToBBoxUserspace.TransformBounds(rect); } return bbox; } nsIFrame* kid = PrincipalChildList().FirstChild(); if (kid && kid->IsSubtreeDirty()) { // Return an empty bbox if our kid's subtree is dirty. This may be called // in that situation, e.g. when we're building a display list after an // interrupted reflow. This can also be called during reflow before we've // been reflowed, e.g. if an earlier sibling is calling // FinishAndStoreOverflow and needs our parent's perspective matrix, which // depends on the SVG bbox contribution of this frame. In the latter // situation, when all siblings have been reflowed, the parent will compute // its perspective and rerun FinishAndStoreOverflow for all its children. return bbox; } UpdateGlyphPositioning(); nsPresContext* presContext = PresContext(); TextRenderedRunIterator it(this); for (TextRenderedRun run = it.Current(); run.mFrame; run = it.Next()) { uint32_t flags = TextRenderedRunFlagsForBBoxContribution(run, aFlags); gfxMatrix m = ThebesMatrix(aToBBoxUserspace); SVGBBox bboxForRun = run.GetUserSpaceRect(presContext, flags, &m); bbox.UnionEdges(bboxForRun); } return bbox; } //---------------------------------------------------------------------- // SVGTextFrame SVG DOM methods /** * Returns whether the specified node has any non-empty Text * beneath it. */ static bool HasTextContent(nsIContent* aContent) { NS_ASSERTION(aContent, "expected non-null aContent"); TextNodeIterator it(aContent); for (Text* text = it.Current(); text; text = it.Next()) { if (text->TextLength() != 0) { return true; } } return false; } /** * Returns the number of DOM characters beneath the specified node. */ static uint32_t GetTextContentLength(nsIContent* aContent) { NS_ASSERTION(aContent, "expected non-null aContent"); uint32_t length = 0; TextNodeIterator it(aContent); for (Text* text = it.Current(); text; text = it.Next()) { length += text->TextLength(); } return length; } int32_t SVGTextFrame::ConvertTextElementCharIndexToAddressableIndex( int32_t aIndex, nsIContent* aContent) { CharIterator it(this, CharIterator::eOriginal, aContent); if (!it.AdvanceToSubtree()) { return -1; } int32_t result = 0; int32_t textElementCharIndex; while (!it.AtEnd() && it.IsWithinSubtree()) { bool addressable = !it.IsOriginalCharUnaddressable(); textElementCharIndex = it.TextElementCharIndex(); it.Next(); uint32_t delta = it.TextElementCharIndex() - textElementCharIndex; aIndex -= delta; if (addressable) { if (aIndex < 0) { return result; } result += delta; } } return -1; } /** * Implements the SVG DOM GetNumberOfChars method for the specified * text content element. */ uint32_t SVGTextFrame::GetNumberOfChars(nsIContent* aContent) { nsIFrame* kid = PrincipalChildList().FirstChild(); if (kid->IsSubtreeDirty()) { // We're never reflowed if we're under a non-SVG element that is // never reflowed (such as the HTML 'caption' element). return 0; } UpdateGlyphPositioning(); uint32_t n = 0; CharIterator it(this, CharIterator::eAddressable, aContent); if (it.AdvanceToSubtree()) { while (!it.AtEnd() && it.IsWithinSubtree()) { n++; it.Next(); } } return n; } /** * Implements the SVG DOM GetComputedTextLength method for the specified * text child element. */ float SVGTextFrame::GetComputedTextLength(nsIContent* aContent) { nsIFrame* kid = PrincipalChildList().FirstChild(); if (kid->IsSubtreeDirty()) { // We're never reflowed if we're under a non-SVG element that is // never reflowed (such as the HTML 'caption' element). // // If we ever decide that we need to return accurate values here, // we could do similar work to GetSubStringLength. return 0; } UpdateGlyphPositioning(); float cssPxPerDevPx = nsPresContext::AppUnitsToFloatCSSPixels( PresContext()->AppUnitsPerDevPixel()); nscoord length = 0; TextRenderedRunIterator it(this, TextRenderedRunIterator::eAllFrames, aContent); for (TextRenderedRun run = it.Current(); run.mFrame; run = it.Next()) { length += run.GetAdvanceWidth(); } return PresContext()->AppUnitsToGfxUnits(length) * cssPxPerDevPx * mLengthAdjustScaleFactor / mFontSizeScaleFactor; } /** * Implements the SVG DOM SelectSubString method for the specified * text content element. */ void SVGTextFrame::SelectSubString(nsIContent* aContent, uint32_t charnum, uint32_t nchars, ErrorResult& aRv) { nsIFrame* kid = PrincipalChildList().FirstChild(); if (kid->IsSubtreeDirty()) { // We're never reflowed if we're under a non-SVG element that is // never reflowed (such as the HTML 'caption' element). // XXXbz Should this just return without throwing like the no-frame case? aRv.ThrowInvalidStateError("No layout information available for SVG text"); return; } UpdateGlyphPositioning(); // Convert charnum/nchars from addressable characters relative to // aContent to global character indices. CharIterator chit(this, CharIterator::eAddressable, aContent); if (!chit.AdvanceToSubtree() || !chit.Next(charnum) || chit.IsAfterSubtree()) { aRv.ThrowIndexSizeError("Character index out of range"); return; } charnum = chit.TextElementCharIndex(); const RefPtr content = chit.TextFrame()->GetContent(); chit.NextWithinSubtree(nchars); nchars = chit.TextElementCharIndex() - charnum; RefPtr frameSelection = GetFrameSelection(); frameSelection->HandleClick(content, charnum, charnum + nchars, nsFrameSelection::FocusMode::kCollapseToNewPoint, CARET_ASSOCIATE_BEFORE); } /** * Implements the SVG DOM GetSubStringLength method for the specified * text content element. */ float SVGTextFrame::GetSubStringLength(nsIContent* aContent, uint32_t charnum, uint32_t nchars, ErrorResult& aRv) { // For some content we cannot (or currently cannot) compute the length // without reflowing. In those cases we need to fall back to using // GetSubStringLengthSlowFallback. // // We fall back for textPath since we need glyph positioning in order to // tell if any characters should be ignored due to having fallen off the // end of the textPath. // // We fall back for bidi because GetTrimmedOffsets does not produce the // correct results for bidi continuations when passed aPostReflow = false. // XXX It may be possible to determine which continuations to trim from (and // which sides), but currently we don't do that. It would require us to // identify the visual (rather than logical) start and end of the line, to // avoid trimming at line-internal frame boundaries. Maybe nsBidiPresUtils // methods like GetFrameToRightOf and GetFrameToLeftOf would help? // TextFrameIterator frameIter(this); for (nsTextFrame* frame = frameIter.Current(); frame; frame = frameIter.Next()) { if (frameIter.TextPathFrame() || frame->GetNextContinuation()) { return GetSubStringLengthSlowFallback(aContent, charnum, nchars, aRv); } } // We only need our text correspondence to be up to date (no need to call // UpdateGlyphPositioning). TextNodeCorrespondenceRecorder::RecordCorrespondence(this); // Convert charnum/nchars from addressable characters relative to // aContent to global character indices. CharIterator chit(this, CharIterator::eAddressable, aContent, /* aPostReflow */ false); if (!chit.AdvanceToSubtree() || !chit.Next(charnum) || chit.IsAfterSubtree()) { aRv.ThrowIndexSizeError("Character index out of range"); return 0; } // We do this after the ThrowIndexSizeError() bit so JS calls correctly throw // when necessary. if (nchars == 0) { return 0.0f; } charnum = chit.TextElementCharIndex(); chit.NextWithinSubtree(nchars); nchars = chit.TextElementCharIndex() - charnum; // Sum of the substring advances. nscoord textLength = 0; TextFrameIterator frit(this); // aSubtree = nullptr // Index of the first non-skipped char in the frame, and of a subsequent char // that we're interested in. Both are relative to the index of the first // non-skipped char in the ancestor element. uint32_t frameStartTextElementCharIndex = 0; uint32_t textElementCharIndex; for (nsTextFrame* frame = frit.Current(); frame; frame = frit.Next()) { frameStartTextElementCharIndex += frit.UndisplayedCharacters(); textElementCharIndex = frameStartTextElementCharIndex; // Offset into frame's Text: const uint32_t untrimmedOffset = frame->GetContentOffset(); const uint32_t untrimmedLength = frame->GetContentEnd() - untrimmedOffset; // Trim the offset/length to remove any leading/trailing white space. uint32_t trimmedOffset = untrimmedOffset; uint32_t trimmedLength = untrimmedLength; nsTextFrame::TrimmedOffsets trimmedOffsets = frame->GetTrimmedOffsets( frame->TextFragment(), nsTextFrame::TrimmedOffsetFlags::NotPostReflow); TrimOffsets(trimmedOffset, trimmedLength, trimmedOffsets); textElementCharIndex += trimmedOffset - untrimmedOffset; if (textElementCharIndex >= charnum + nchars) { break; // we're past the end of the substring } uint32_t offset = textElementCharIndex; // Intersect the substring we are interested in with the range covered by // the nsTextFrame. IntersectInterval(offset, trimmedLength, charnum, nchars); if (trimmedLength != 0) { // Convert offset into an index into the frame. offset += trimmedOffset - textElementCharIndex; gfxSkipCharsIterator it = frame->EnsureTextRun(nsTextFrame::eInflated); gfxTextRun* textRun = frame->GetTextRun(nsTextFrame::eInflated); nsTextFrame::PropertyProvider provider(frame, it); Range range = ConvertOriginalToSkipped(it, offset, trimmedLength); // Accumulate the advance. textLength += textRun->GetAdvanceWidth(range, &provider); } // Advance, ready for next call: frameStartTextElementCharIndex += untrimmedLength; } nsPresContext* presContext = PresContext(); float cssPxPerDevPx = nsPresContext::AppUnitsToFloatCSSPixels( presContext->AppUnitsPerDevPixel()); return presContext->AppUnitsToGfxUnits(textLength) * cssPxPerDevPx / mFontSizeScaleFactor; } float SVGTextFrame::GetSubStringLengthSlowFallback(nsIContent* aContent, uint32_t charnum, uint32_t nchars, ErrorResult& aRv) { // We need to make sure that we've been reflowed before updating the glyph // positioning. // XXX perf: It may be possible to limit reflow to just calling ReflowSVG, // but we would still need to resort to full reflow for percentage // positioning attributes. For now we just do a full reflow regardless since // the cases that would cause us to be called are relatively uncommon. RefPtr presShell = PresShell(); presShell->FlushPendingNotifications(FlushType::Layout); UpdateGlyphPositioning(); // Convert charnum/nchars from addressable characters relative to // aContent to global character indices. CharIterator chit(this, CharIterator::eAddressable, aContent); if (!chit.AdvanceToSubtree() || !chit.Next(charnum) || chit.IsAfterSubtree()) { aRv.ThrowIndexSizeError("Character index out of range"); return 0; } if (nchars == 0) { return 0.0f; } charnum = chit.TextElementCharIndex(); chit.NextWithinSubtree(nchars); nchars = chit.TextElementCharIndex() - charnum; // Find each rendered run that intersects with the range defined // by charnum/nchars. nscoord textLength = 0; TextRenderedRunIterator runIter(this, TextRenderedRunIterator::eAllFrames); TextRenderedRun run = runIter.Current(); while (run.mFrame) { // If this rendered run is past the substring we are interested in, we // are done. uint32_t offset = run.mTextElementCharIndex; if (offset >= charnum + nchars) { break; } // Intersect the substring we are interested in with the range covered by // the rendered run. uint32_t length = run.mTextFrameContentLength; IntersectInterval(offset, length, charnum, nchars); if (length != 0) { // Convert offset into an index into the frame. offset += run.mTextFrameContentOffset - run.mTextElementCharIndex; gfxSkipCharsIterator it = run.mFrame->EnsureTextRun(nsTextFrame::eInflated); gfxTextRun* textRun = run.mFrame->GetTextRun(nsTextFrame::eInflated); nsTextFrame::PropertyProvider provider(run.mFrame, it); Range range = ConvertOriginalToSkipped(it, offset, length); // Accumulate the advance. textLength += textRun->GetAdvanceWidth(range, &provider); } run = runIter.Next(); } nsPresContext* presContext = PresContext(); float cssPxPerDevPx = nsPresContext::AppUnitsToFloatCSSPixels( presContext->AppUnitsPerDevPixel()); return presContext->AppUnitsToGfxUnits(textLength) * cssPxPerDevPx / mFontSizeScaleFactor; } /** * Implements the SVG DOM GetCharNumAtPosition method for the specified * text content element. */ int32_t SVGTextFrame::GetCharNumAtPosition(nsIContent* aContent, const DOMPointInit& aPoint) { nsIFrame* kid = PrincipalChildList().FirstChild(); if (kid->IsSubtreeDirty()) { // We're never reflowed if we're under a non-SVG element that is // never reflowed (such as the HTML 'caption' element). return -1; } UpdateGlyphPositioning(); nsPresContext* context = PresContext(); gfxPoint p(aPoint.mX, aPoint.mY); int32_t result = -1; TextRenderedRunIterator it(this, TextRenderedRunIterator::eAllFrames, aContent); for (TextRenderedRun run = it.Current(); run.mFrame; run = it.Next()) { // Hit test this rendered run. Later runs will override earlier ones. int32_t index = run.GetCharNumAtPosition(context, p); if (index != -1) { result = index + run.mTextElementCharIndex; } } if (result == -1) { return result; } return ConvertTextElementCharIndexToAddressableIndex(result, aContent); } /** * Implements the SVG DOM GetStartPositionOfChar method for the specified * text content element. */ already_AddRefed SVGTextFrame::GetStartPositionOfChar( nsIContent* aContent, uint32_t aCharNum, ErrorResult& aRv) { nsIFrame* kid = PrincipalChildList().FirstChild(); if (kid->IsSubtreeDirty()) { // We're never reflowed if we're under a non-SVG element that is // never reflowed (such as the HTML 'caption' element). aRv.ThrowInvalidStateError("No layout information available for SVG text"); return nullptr; } UpdateGlyphPositioning(); CharIterator it(this, CharIterator::eAddressable, aContent); if (!it.AdvanceToSubtree() || !it.Next(aCharNum)) { aRv.ThrowIndexSizeError("Character index out of range"); return nullptr; } // We need to return the start position of the whole glyph. uint32_t startIndex = it.GlyphStartTextElementCharIndex(); RefPtr point = new DOMSVGPoint(ToPoint(mPositions[startIndex].mPosition)); return point.forget(); } /** * Returns the advance of the entire glyph whose starting character is at * aTextElementCharIndex. * * aIterator, if provided, must be a CharIterator that already points to * aTextElementCharIndex that is restricted to aContent and is using * filter mode eAddressable. */ static gfxFloat GetGlyphAdvance(SVGTextFrame* aFrame, nsIContent* aContent, uint32_t aTextElementCharIndex, CharIterator* aIterator) { MOZ_ASSERT(!aIterator || (aIterator->Filter() == CharIterator::eAddressable && aIterator->GetSubtree() == aContent && aIterator->GlyphStartTextElementCharIndex() == aTextElementCharIndex), "Invalid aIterator"); Maybe newIterator; CharIterator* it = aIterator; if (!it) { newIterator.emplace(aFrame, CharIterator::eAddressable, aContent); if (!newIterator->AdvanceToSubtree()) { MOZ_ASSERT_UNREACHABLE("Invalid aContent"); return 0.0; } it = newIterator.ptr(); } while (it->GlyphStartTextElementCharIndex() != aTextElementCharIndex) { if (!it->Next()) { MOZ_ASSERT_UNREACHABLE("Invalid aTextElementCharIndex"); return 0.0; } } if (it->AtEnd()) { MOZ_ASSERT_UNREACHABLE("Invalid aTextElementCharIndex"); return 0.0; } nsPresContext* presContext = aFrame->PresContext(); gfxFloat advance = 0.0; for (;;) { advance += it->GetAdvance(presContext); if (!it->Next() || it->GlyphStartTextElementCharIndex() != aTextElementCharIndex) { break; } } return advance; } /** * Implements the SVG DOM GetEndPositionOfChar method for the specified * text content element. */ already_AddRefed SVGTextFrame::GetEndPositionOfChar( nsIContent* aContent, uint32_t aCharNum, ErrorResult& aRv) { nsIFrame* kid = PrincipalChildList().FirstChild(); if (kid->IsSubtreeDirty()) { // We're never reflowed if we're under a non-SVG element that is // never reflowed (such as the HTML 'caption' element). aRv.ThrowInvalidStateError("No layout information available for SVG text"); return nullptr; } UpdateGlyphPositioning(); CharIterator it(this, CharIterator::eAddressable, aContent); if (!it.AdvanceToSubtree() || !it.Next(aCharNum)) { aRv.ThrowIndexSizeError("Character index out of range"); return nullptr; } // We need to return the end position of the whole glyph. uint32_t startIndex = it.GlyphStartTextElementCharIndex(); // Get the advance of the glyph. gfxFloat advance = GetGlyphAdvance(this, aContent, startIndex, it.IsClusterAndLigatureGroupStart() ? &it : nullptr); if (it.TextRun()->IsRightToLeft()) { advance = -advance; } // The end position is the start position plus the advance in the direction // of the glyph's rotation. Matrix m = Matrix::Rotation(mPositions[startIndex].mAngle) * Matrix::Translation(ToPoint(mPositions[startIndex].mPosition)); Point p = m.TransformPoint(Point(advance / mFontSizeScaleFactor, 0)); RefPtr point = new DOMSVGPoint(p); return point.forget(); } /** * Implements the SVG DOM GetExtentOfChar method for the specified * text content element. */ already_AddRefed SVGTextFrame::GetExtentOfChar(nsIContent* aContent, uint32_t aCharNum, ErrorResult& aRv) { nsIFrame* kid = PrincipalChildList().FirstChild(); if (kid->IsSubtreeDirty()) { // We're never reflowed if we're under a non-SVG element that is // never reflowed (such as the HTML 'caption' element). aRv.ThrowInvalidStateError("No layout information available for SVG text"); return nullptr; } UpdateGlyphPositioning(); // Search for the character whose addressable index is aCharNum. CharIterator it(this, CharIterator::eAddressable, aContent); if (!it.AdvanceToSubtree() || !it.Next(aCharNum)) { aRv.ThrowIndexSizeError("Character index out of range"); return nullptr; } nsPresContext* presContext = PresContext(); float cssPxPerDevPx = nsPresContext::AppUnitsToFloatCSSPixels( presContext->AppUnitsPerDevPixel()); nsTextFrame* textFrame = it.TextFrame(); uint32_t startIndex = it.GlyphStartTextElementCharIndex(); bool isRTL = it.TextRun()->IsRightToLeft(); bool isVertical = it.TextRun()->IsVertical(); // Get the glyph advance. gfxFloat advance = GetGlyphAdvance(this, aContent, startIndex, it.IsClusterAndLigatureGroupStart() ? &it : nullptr); gfxFloat x = isRTL ? -advance : 0.0; // The ascent and descent gives the height of the glyph. gfxFloat ascent, descent; GetAscentAndDescentInAppUnits(textFrame, ascent, descent); // The horizontal extent is the origin of the glyph plus the advance // in the direction of the glyph's rotation. gfxMatrix m; m.PreTranslate(mPositions[startIndex].mPosition); m.PreRotate(mPositions[startIndex].mAngle); m.PreScale(1 / mFontSizeScaleFactor, 1 / mFontSizeScaleFactor); gfxRect glyphRect; if (isVertical) { glyphRect = gfxRect( -presContext->AppUnitsToGfxUnits(descent) * cssPxPerDevPx, x, presContext->AppUnitsToGfxUnits(ascent + descent) * cssPxPerDevPx, advance); } else { glyphRect = gfxRect( x, -presContext->AppUnitsToGfxUnits(ascent) * cssPxPerDevPx, advance, presContext->AppUnitsToGfxUnits(ascent + descent) * cssPxPerDevPx); } // Transform the glyph's rect into user space. gfxRect r = m.TransformBounds(glyphRect); RefPtr rect = new SVGRect(aContent, ToRect(r)); return rect.forget(); } /** * Implements the SVG DOM GetRotationOfChar method for the specified * text content element. */ float SVGTextFrame::GetRotationOfChar(nsIContent* aContent, uint32_t aCharNum, ErrorResult& aRv) { nsIFrame* kid = PrincipalChildList().FirstChild(); if (kid->IsSubtreeDirty()) { // We're never reflowed if we're under a non-SVG element that is // never reflowed (such as the HTML 'caption' element). aRv.ThrowInvalidStateError("No layout information available for SVG text"); return 0; } UpdateGlyphPositioning(); CharIterator it(this, CharIterator::eAddressable, aContent); if (!it.AdvanceToSubtree() || !it.Next(aCharNum)) { aRv.ThrowIndexSizeError("Character index out of range"); return 0; } // we need to account for the glyph's underlying orientation const gfxTextRun::GlyphRun& glyphRun = it.GlyphRun(); int32_t glyphOrientation = 90 * (glyphRun.IsSidewaysRight() - glyphRun.IsSidewaysLeft()); return mPositions[it.TextElementCharIndex()].mAngle * 180.0 / M_PI + glyphOrientation; } //---------------------------------------------------------------------- // SVGTextFrame text layout methods /** * Given the character position array before values have been filled in * to any unspecified positions, and an array of dx/dy values, returns whether * a character at a given index should start a new rendered run. * * @param aPositions The array of character positions before unspecified * positions have been filled in and dx/dy values have been added to them. * @param aDeltas The array of dx/dy values. * @param aIndex The character index in question. */ static bool ShouldStartRunAtIndex(const nsTArray& aPositions, const nsTArray& aDeltas, uint32_t aIndex) { if (aIndex == 0) { return true; } if (aIndex < aPositions.Length()) { // If an explicit x or y value was given, start a new run. if (aPositions[aIndex].IsXSpecified() || aPositions[aIndex].IsYSpecified()) { return true; } // If a non-zero rotation was given, or the previous character had a non- // zero rotation, start a new run. if ((aPositions[aIndex].IsAngleSpecified() && aPositions[aIndex].mAngle != 0.0f) || (aPositions[aIndex - 1].IsAngleSpecified() && (aPositions[aIndex - 1].mAngle != 0.0f))) { return true; } } if (aIndex < aDeltas.Length()) { // If a non-zero dx or dy value was given, start a new run. if (aDeltas[aIndex].x != 0.0 || aDeltas[aIndex].y != 0.0) { return true; } } return false; } bool SVGTextFrame::ResolvePositionsForNode(nsIContent* aContent, uint32_t& aIndex, bool aInTextPath, bool& aForceStartOfChunk, nsTArray& aDeltas) { if (aContent->IsText()) { // We found a text node. uint32_t length = aContent->AsText()->TextLength(); if (length) { uint32_t end = aIndex + length; if (MOZ_UNLIKELY(end > mPositions.Length())) { MOZ_ASSERT_UNREACHABLE( "length of mPositions does not match characters " "found by iterating content"); return false; } if (aForceStartOfChunk) { // Note this character as starting a new anchored chunk. mPositions[aIndex].mStartOfChunk = true; aForceStartOfChunk = false; } while (aIndex < end) { // Record whether each of these characters should start a new rendered // run. That is always the case for characters on a text path. // // Run boundaries due to rotate="" values are handled in // DoGlyphPositioning. if (aInTextPath || ShouldStartRunAtIndex(mPositions, aDeltas, aIndex)) { mPositions[aIndex].mRunBoundary = true; } aIndex++; } } return true; } // Skip past elements that aren't text content elements. if (!IsTextContentElement(aContent)) { return true; } if (aContent->IsSVGElement(nsGkAtoms::textPath)) { // Any ‘y’ attributes on horizontal elements are ignored. // Similarly, for vertical s x attributes are ignored. // elements behave as if they have x="0" y="0" on them, but only // if there is not a value for the non-ignored coordinate that got inherited // from a parent. We skip this if there is no text content, so that empty // s don't interrupt the layout of text in the parent element. if (HasTextContent(aContent)) { if (MOZ_UNLIKELY(aIndex >= mPositions.Length())) { MOZ_ASSERT_UNREACHABLE( "length of mPositions does not match characters " "found by iterating content"); return false; } bool vertical = GetWritingMode().IsVertical(); if (vertical || !mPositions[aIndex].IsXSpecified()) { mPositions[aIndex].mPosition.x = 0.0; } if (!vertical || !mPositions[aIndex].IsYSpecified()) { mPositions[aIndex].mPosition.y = 0.0; } mPositions[aIndex].mStartOfChunk = true; } } else if (!aContent->IsSVGElement(nsGkAtoms::a)) { MOZ_ASSERT(aContent->IsSVGElement()); // We have a text content element that can have x/y/dx/dy/rotate attributes. SVGElement* element = static_cast(aContent); // Get x, y, dx, dy. SVGUserUnitList x, y, dx, dy; element->GetAnimatedLengthListValues(&x, &y, &dx, &dy, nullptr); // Get rotate. const SVGNumberList* rotate = nullptr; SVGAnimatedNumberList* animatedRotate = element->GetAnimatedNumberList(nsGkAtoms::rotate); if (animatedRotate) { rotate = &animatedRotate->GetAnimValue(); } bool percentages = false; uint32_t count = GetTextContentLength(aContent); if (MOZ_UNLIKELY(aIndex + count > mPositions.Length())) { MOZ_ASSERT_UNREACHABLE( "length of mPositions does not match characters " "found by iterating content"); return false; } // New text anchoring chunks start at each character assigned a position // with x="" or y="", or if we forced one with aForceStartOfChunk due to // being just after a . uint32_t newChunkCount = std::max(x.Length(), y.Length()); if (!newChunkCount && aForceStartOfChunk) { newChunkCount = 1; } for (uint32_t i = 0, j = 0; i < newChunkCount && j < count; j++) { if (!mPositions[aIndex + j].mUnaddressable) { mPositions[aIndex + j].mStartOfChunk = true; i++; } } // Copy dx="" and dy="" values into aDeltas. if (!dx.IsEmpty() || !dy.IsEmpty()) { // Any unspecified deltas when we grow the array just get left as 0s. aDeltas.EnsureLengthAtLeast(aIndex + count); for (uint32_t i = 0, j = 0; i < dx.Length() && j < count; j++) { if (!mPositions[aIndex + j].mUnaddressable) { aDeltas[aIndex + j].x = dx[i]; percentages = percentages || dx.HasPercentageValueAt(i); i++; } } for (uint32_t i = 0, j = 0; i < dy.Length() && j < count; j++) { if (!mPositions[aIndex + j].mUnaddressable) { aDeltas[aIndex + j].y = dy[i]; percentages = percentages || dy.HasPercentageValueAt(i); i++; } } } // Copy x="" and y="" values. for (uint32_t i = 0, j = 0; i < x.Length() && j < count; j++) { if (!mPositions[aIndex + j].mUnaddressable) { mPositions[aIndex + j].mPosition.x = x[i]; percentages = percentages || x.HasPercentageValueAt(i); i++; } } for (uint32_t i = 0, j = 0; i < y.Length() && j < count; j++) { if (!mPositions[aIndex + j].mUnaddressable) { mPositions[aIndex + j].mPosition.y = y[i]; percentages = percentages || y.HasPercentageValueAt(i); i++; } } // Copy rotate="" values. if (rotate && !rotate->IsEmpty()) { uint32_t i = 0, j = 0; while (i < rotate->Length() && j < count) { if (!mPositions[aIndex + j].mUnaddressable) { mPositions[aIndex + j].mAngle = M_PI * (*rotate)[i] / 180.0; i++; } j++; } // Propagate final rotate="" value to the end of this element. while (j < count) { mPositions[aIndex + j].mAngle = mPositions[aIndex + j - 1].mAngle; j++; } } if (percentages) { AddStateBits(NS_STATE_SVG_POSITIONING_MAY_USE_PERCENTAGES); } } // Recurse to children. bool inTextPath = aInTextPath || aContent->IsSVGElement(nsGkAtoms::textPath); for (nsIContent* child = aContent->GetFirstChild(); child; child = child->GetNextSibling()) { bool ok = ResolvePositionsForNode(child, aIndex, inTextPath, aForceStartOfChunk, aDeltas); if (!ok) { return false; } } if (aContent->IsSVGElement(nsGkAtoms::textPath)) { // Force a new anchored chunk just after a . aForceStartOfChunk = true; } return true; } bool SVGTextFrame::ResolvePositions(nsTArray& aDeltas, bool aRunPerGlyph) { NS_ASSERTION(mPositions.IsEmpty(), "expected mPositions to be empty"); RemoveStateBits(NS_STATE_SVG_POSITIONING_MAY_USE_PERCENTAGES); CharIterator it(this, CharIterator::eOriginal, /* aSubtree */ nullptr); if (it.AtEnd()) { return false; } // We assume the first character position is (0,0) unless we later see // otherwise, and note it as unaddressable if it is. bool firstCharUnaddressable = it.IsOriginalCharUnaddressable(); mPositions.AppendElement(CharPosition::Unspecified(firstCharUnaddressable)); // Fill in unspecified positions for all remaining characters, noting // them as unaddressable if they are. uint32_t index = 0; while (it.Next()) { while (++index < it.TextElementCharIndex()) { mPositions.AppendElement(CharPosition::Unspecified(false)); } mPositions.AppendElement( CharPosition::Unspecified(it.IsOriginalCharUnaddressable())); } while (++index < it.TextElementCharIndex()) { mPositions.AppendElement(CharPosition::Unspecified(false)); } // Recurse over the content and fill in character positions as we go. bool forceStartOfChunk = false; index = 0; bool ok = ResolvePositionsForNode(mContent, index, aRunPerGlyph, forceStartOfChunk, aDeltas); return ok && index > 0; } void SVGTextFrame::DetermineCharPositions(nsTArray& aPositions) { NS_ASSERTION(aPositions.IsEmpty(), "expected aPositions to be empty"); nsPoint position; TextFrameIterator frit(this); for (nsTextFrame* frame = frit.Current(); frame; frame = frit.Next()) { gfxSkipCharsIterator it = frame->EnsureTextRun(nsTextFrame::eInflated); gfxTextRun* textRun = frame->GetTextRun(nsTextFrame::eInflated); nsTextFrame::PropertyProvider provider(frame, it); // Reset the position to the new frame's position. position = frit.Position(); if (textRun->IsVertical()) { if (textRun->IsRightToLeft()) { position.y += frame->GetRect().height; } position.x += GetBaselinePosition(frame, textRun, frit.DominantBaseline(), mFontSizeScaleFactor); } else { if (textRun->IsRightToLeft()) { position.x += frame->GetRect().width; } position.y += GetBaselinePosition(frame, textRun, frit.DominantBaseline(), mFontSizeScaleFactor); } // Any characters not in a frame, e.g. when display:none. for (uint32_t i = 0; i < frit.UndisplayedCharacters(); i++) { aPositions.AppendElement(position); } // Any white space characters trimmed at the start of the line of text. nsTextFrame::TrimmedOffsets trimmedOffsets = frame->GetTrimmedOffsets(frame->TextFragment()); while (it.GetOriginalOffset() < trimmedOffsets.mStart) { aPositions.AppendElement(position); it.AdvanceOriginal(1); } // Visible characters in the text frame. while (it.GetOriginalOffset() < frame->GetContentEnd()) { aPositions.AppendElement(position); if (!it.IsOriginalCharSkipped()) { // Accumulate partial ligature advance into position. (We must get // partial advances rather than get the advance of the whole ligature // group / cluster at once, since the group may span text frames, and // the PropertyProvider only has spacing information for the current // text frame.) uint32_t offset = it.GetSkippedOffset(); nscoord advance = textRun->GetAdvanceWidth(Range(offset, offset + 1), &provider); (textRun->IsVertical() ? position.y : position.x) += textRun->IsRightToLeft() ? -advance : advance; } it.AdvanceOriginal(1); } } // Finally any characters at the end that are not in a frame. for (uint32_t i = 0; i < frit.UndisplayedCharacters(); i++) { aPositions.AppendElement(position); } } /** * Physical text-anchor values. */ enum TextAnchorSide { eAnchorLeft, eAnchorMiddle, eAnchorRight }; /** * Converts a logical text-anchor value to its physical value, based on whether * it is for an RTL frame. */ static TextAnchorSide ConvertLogicalTextAnchorToPhysical( StyleTextAnchor aTextAnchor, bool aIsRightToLeft) { NS_ASSERTION(uint8_t(aTextAnchor) <= 3, "unexpected value for aTextAnchor"); if (!aIsRightToLeft) { return TextAnchorSide(uint8_t(aTextAnchor)); } return TextAnchorSide(2 - uint8_t(aTextAnchor)); } /** * Shifts the recorded character positions for an anchored chunk. * * @param aCharPositions The recorded character positions. * @param aChunkStart The character index the starts the anchored chunk. This * character's initial position is the anchor point. * @param aChunkEnd The character index just after the end of the anchored * chunk. * @param aVisIStartEdge The left/top-most edge of any of the glyphs within the * anchored chunk. * @param aVisIEndEdge The right/bottom-most edge of any of the glyphs within * the anchored chunk. * @param aAnchorSide The direction to anchor. */ static void ShiftAnchoredChunk(nsTArray& aCharPositions, uint32_t aChunkStart, uint32_t aChunkEnd, gfxFloat aVisIStartEdge, gfxFloat aVisIEndEdge, TextAnchorSide aAnchorSide, bool aVertical) { NS_ASSERTION(aVisIStartEdge <= aVisIEndEdge, "unexpected anchored chunk edges"); NS_ASSERTION(aChunkStart < aChunkEnd, "unexpected values for aChunkStart and aChunkEnd"); gfxFloat shift = aVertical ? aCharPositions[aChunkStart].mPosition.y : aCharPositions[aChunkStart].mPosition.x; switch (aAnchorSide) { case eAnchorLeft: shift -= aVisIStartEdge; break; case eAnchorMiddle: shift -= (aVisIStartEdge + aVisIEndEdge) / 2; break; case eAnchorRight: shift -= aVisIEndEdge; break; default: MOZ_ASSERT_UNREACHABLE("unexpected value for aAnchorSide"); } if (shift != 0.0) { if (aVertical) { for (uint32_t i = aChunkStart; i < aChunkEnd; i++) { aCharPositions[i].mPosition.y += shift; } } else { for (uint32_t i = aChunkStart; i < aChunkEnd; i++) { aCharPositions[i].mPosition.x += shift; } } } } void SVGTextFrame::AdjustChunksForLineBreaks() { nsBlockFrame* block = do_QueryFrame(PrincipalChildList().FirstChild()); NS_ASSERTION(block, "expected block frame"); nsBlockFrame::LineIterator line = block->LinesBegin(); CharIterator it(this, CharIterator::eOriginal, /* aSubtree */ nullptr); while (!it.AtEnd() && line != block->LinesEnd()) { if (it.TextFrame() == line->mFirstChild) { mPositions[it.TextElementCharIndex()].mStartOfChunk = true; line++; } it.AdvancePastCurrentFrame(); } } void SVGTextFrame::AdjustPositionsForClusters() { nsPresContext* presContext = PresContext(); // Find all of the characters that are in the middle of a cluster or // ligature group, and adjust their positions and rotations to match // the first character of the cluster/group. // // Also move the boundaries of text rendered runs and anchored chunks to // not lie in the middle of cluster/group. // The partial advance of the current cluster or ligature group that we // have accumulated. gfxFloat partialAdvance = 0.0; CharIterator it(this, CharIterator::eUnskipped, /* aSubtree */ nullptr); while (!it.AtEnd()) { if (it.IsClusterAndLigatureGroupStart()) { // If we're at the start of a new cluster or ligature group, reset our // accumulated partial advance. partialAdvance = 0.0; } else { // Otherwise, we're in the middle of a cluster or ligature group, and // we need to use the currently accumulated partial advance to adjust // the character's position and rotation. // Find the start of the cluster/ligature group. uint32_t charIndex = it.TextElementCharIndex(); uint32_t startIndex = it.GlyphStartTextElementCharIndex(); MOZ_ASSERT(charIndex != startIndex, "If the current character is in the middle of a cluster or " "ligature group, then charIndex must be different from " "startIndex"); mPositions[charIndex].mClusterOrLigatureGroupMiddle = true; // Don't allow different rotations on ligature parts. bool rotationAdjusted = false; double angle = mPositions[startIndex].mAngle; if (mPositions[charIndex].mAngle != angle) { mPositions[charIndex].mAngle = angle; rotationAdjusted = true; } // Update the character position. gfxFloat advance = partialAdvance / mFontSizeScaleFactor; gfxPoint direction = gfxPoint(cos(angle), sin(angle)) * (it.TextRun()->IsRightToLeft() ? -1.0 : 1.0); if (it.TextRun()->IsVertical()) { std::swap(direction.x, direction.y); } mPositions[charIndex].mPosition = mPositions[startIndex].mPosition + direction * advance; // Ensure any runs that would end in the middle of a ligature now end just // after the ligature. if (mPositions[charIndex].mRunBoundary) { mPositions[charIndex].mRunBoundary = false; if (charIndex + 1 < mPositions.Length()) { mPositions[charIndex + 1].mRunBoundary = true; } } else if (rotationAdjusted) { if (charIndex + 1 < mPositions.Length()) { mPositions[charIndex + 1].mRunBoundary = true; } } // Ensure any anchored chunks that would begin in the middle of a ligature // now begin just after the ligature. if (mPositions[charIndex].mStartOfChunk) { mPositions[charIndex].mStartOfChunk = false; if (charIndex + 1 < mPositions.Length()) { mPositions[charIndex + 1].mStartOfChunk = true; } } } // Accumulate the current character's partial advance. partialAdvance += it.GetAdvance(presContext); it.Next(); } } already_AddRefed SVGTextFrame::GetTextPath(nsIFrame* aTextPathFrame) { nsIContent* content = aTextPathFrame->GetContent(); SVGTextPathElement* tp = static_cast(content); if (tp->mPath.IsRendered()) { // This is just an attribute so there's no transform that can apply // so we can just return the path directly. return tp->mPath.GetAnimValue().BuildPathForMeasuring(); } SVGGeometryElement* geomElement = SVGObserverUtils::GetAndObserveTextPathsPath(aTextPathFrame); if (!geomElement) { return nullptr; } RefPtr path = geomElement->GetOrBuildPathForMeasuring(); if (!path) { return nullptr; } gfxMatrix matrix = geomElement->PrependLocalTransformsTo(gfxMatrix()); if (!matrix.IsIdentity()) { // Apply the geometry element's transform RefPtr builder = path->TransformedCopyToBuilder(ToMatrix(matrix)); path = builder->Finish(); } return path.forget(); } gfxFloat SVGTextFrame::GetOffsetScale(nsIFrame* aTextPathFrame) { nsIContent* content = aTextPathFrame->GetContent(); SVGTextPathElement* tp = static_cast(content); if (tp->mPath.IsRendered()) { // A path attribute has no pathLength or transform // so we return a unit scale. return 1.0; } SVGGeometryElement* geomElement = SVGObserverUtils::GetAndObserveTextPathsPath(aTextPathFrame); if (!geomElement) { return 1.0; } return geomElement->GetPathLengthScale(SVGGeometryElement::eForTextPath); } gfxFloat SVGTextFrame::GetStartOffset(nsIFrame* aTextPathFrame) { SVGTextPathElement* tp = static_cast(aTextPathFrame->GetContent()); SVGAnimatedLength* length = &tp->mLengthAttributes[SVGTextPathElement::STARTOFFSET]; if (length->IsPercentage()) { RefPtr data = GetTextPath(aTextPathFrame); return data ? length->GetAnimValInSpecifiedUnits() * data->ComputeLength() / 100.0 : 0.0; } return length->GetAnimValue(tp) * GetOffsetScale(aTextPathFrame); } void SVGTextFrame::DoTextPathLayout() { nsPresContext* context = PresContext(); CharIterator it(this, CharIterator::eOriginal, /* aSubtree */ nullptr); while (!it.AtEnd()) { nsIFrame* textPathFrame = it.TextPathFrame(); if (!textPathFrame) { // Skip past this frame if we're not in a text path. it.AdvancePastCurrentFrame(); continue; } // Get the path itself. RefPtr path = GetTextPath(textPathFrame); if (!path) { uint32_t start = it.TextElementCharIndex(); it.AdvancePastCurrentTextPathFrame(); uint32_t end = it.TextElementCharIndex(); for (uint32_t i = start; i < end; i++) { mPositions[i].mHidden = true; } continue; } SVGTextPathElement* textPath = static_cast(textPathFrame->GetContent()); uint16_t side = textPath->EnumAttributes()[SVGTextPathElement::SIDE].GetAnimValue(); gfxFloat offset = GetStartOffset(textPathFrame); Float pathLength = path->ComputeLength(); // If the first character within the text path is in the middle of a // cluster or ligature group, just skip it and don't apply text path // positioning. while (!it.AtEnd()) { if (it.IsOriginalCharSkipped()) { it.Next(); continue; } if (it.IsClusterAndLigatureGroupStart()) { break; } it.Next(); } bool skippedEndOfTextPath = false; // Loop for each character in the text path. while (!it.AtEnd() && it.TextPathFrame() && it.TextPathFrame()->GetContent() == textPath) { // The index of the cluster or ligature group's first character. uint32_t i = it.TextElementCharIndex(); // The index of the next character of the cluster or ligature. // We track this as we loop over the characters below so that we // can detect undisplayed characters and append entries into // partialAdvances for them. uint32_t j = i + 1; MOZ_ASSERT(!mPositions[i].mClusterOrLigatureGroupMiddle); gfxFloat sign = it.TextRun()->IsRightToLeft() ? -1.0 : 1.0; bool vertical = it.TextRun()->IsVertical(); // Compute cumulative advances for each character of the cluster or // ligature group. AutoTArray partialAdvances; gfxFloat partialAdvance = it.GetAdvance(context); partialAdvances.AppendElement(partialAdvance); while (it.Next()) { // Append entries for any undisplayed characters the CharIterator // skipped over. MOZ_ASSERT(j <= it.TextElementCharIndex()); while (j < it.TextElementCharIndex()) { partialAdvances.AppendElement(partialAdvance); ++j; } // This loop may end up outside of the current text path, but // that's OK; we'll consider any complete cluster or ligature // group that begins inside the text path as being affected // by it. if (it.IsOriginalCharSkipped()) { if (!it.TextPathFrame()) { skippedEndOfTextPath = true; break; } // Leave partialAdvance unchanged. } else if (it.IsClusterAndLigatureGroupStart()) { break; } else { partialAdvance += it.GetAdvance(context); } partialAdvances.AppendElement(partialAdvance); } if (skippedEndOfTextPath) { break; } // Any final undisplayed characters the CharIterator skipped over. MOZ_ASSERT(j <= it.TextElementCharIndex()); while (j < it.TextElementCharIndex()) { partialAdvances.AppendElement(partialAdvance); ++j; } gfxFloat halfAdvance = partialAdvances.LastElement() / mFontSizeScaleFactor / 2.0; gfxFloat midx = (vertical ? mPositions[i].mPosition.y : mPositions[i].mPosition.x) + sign * halfAdvance + offset; // Hide the character if it falls off the end of the path. mPositions[i].mHidden = midx < 0 || midx > pathLength; // Position the character on the path at the right angle. Point tangent; // Unit vector tangent to the point we find. Point pt; if (side == TEXTPATH_SIDETYPE_RIGHT) { pt = path->ComputePointAtLength(Float(pathLength - midx), &tangent); tangent = -tangent; } else { pt = path->ComputePointAtLength(Float(midx), &tangent); } Float rotation = vertical ? atan2f(-tangent.x, tangent.y) : atan2f(tangent.y, tangent.x); Point normal(-tangent.y, tangent.x); // Unit vector normal to the point. Point offsetFromPath = normal * (vertical ? -mPositions[i].mPosition.x : mPositions[i].mPosition.y); pt += offsetFromPath; Point direction = tangent * sign; mPositions[i].mPosition = ThebesPoint(pt) - ThebesPoint(direction) * halfAdvance; mPositions[i].mAngle += rotation; // Position any characters for a partial ligature. for (uint32_t k = i + 1; k < j; k++) { gfxPoint partialAdvance = ThebesPoint(direction) * partialAdvances[k - i] / mFontSizeScaleFactor; mPositions[k].mPosition = mPositions[i].mPosition + partialAdvance; mPositions[k].mAngle = mPositions[i].mAngle; mPositions[k].mHidden = mPositions[i].mHidden; } } } } void SVGTextFrame::DoAnchoring() { nsPresContext* presContext = PresContext(); CharIterator it(this, CharIterator::eOriginal, /* aSubtree */ nullptr); // Don't need to worry about skipped or trimmed characters. while (!it.AtEnd() && (it.IsOriginalCharSkipped() || it.IsOriginalCharTrimmed())) { it.Next(); } bool vertical = GetWritingMode().IsVertical(); uint32_t start = it.TextElementCharIndex(); while (start < mPositions.Length()) { it.AdvanceToCharacter(start); nsTextFrame* chunkFrame = it.TextFrame(); // Measure characters in this chunk to find the left-most and right-most // edges of all glyphs within the chunk. uint32_t index = it.TextElementCharIndex(); uint32_t end = start; gfxFloat left = std::numeric_limits::infinity(); gfxFloat right = -std::numeric_limits::infinity(); do { if (!it.IsOriginalCharSkipped() && !it.IsOriginalCharTrimmed()) { gfxFloat advance = it.GetAdvance(presContext) / mFontSizeScaleFactor; gfxFloat pos = it.TextRun()->IsVertical() ? mPositions[index].mPosition.y : mPositions[index].mPosition.x; if (it.TextRun()->IsRightToLeft()) { left = std::min(left, pos - advance); right = std::max(right, pos); } else { left = std::min(left, pos); right = std::max(right, pos + advance); } } it.Next(); index = end = it.TextElementCharIndex(); } while (!it.AtEnd() && !mPositions[end].mStartOfChunk); if (left != std::numeric_limits::infinity()) { bool isRTL = chunkFrame->StyleVisibility()->mDirection == StyleDirection::Rtl; TextAnchorSide anchor = ConvertLogicalTextAnchorToPhysical( chunkFrame->StyleSVG()->mTextAnchor, isRTL); ShiftAnchoredChunk(mPositions, start, end, left, right, anchor, vertical); } start = it.TextElementCharIndex(); } } void SVGTextFrame::DoGlyphPositioning() { mPositions.Clear(); RemoveStateBits(NS_STATE_SVG_POSITIONING_DIRTY); nsIFrame* kid = PrincipalChildList().FirstChild(); if (kid && kid->IsSubtreeDirty()) { MOZ_ASSERT(false, "should have already reflowed the kid"); return; } // Since we can be called directly via GetBBoxContribution, our correspondence // may not be up to date. TextNodeCorrespondenceRecorder::RecordCorrespondence(this); // Determine the positions of each character in app units. nsTArray charPositions; DetermineCharPositions(charPositions); if (charPositions.IsEmpty()) { // No characters, so nothing to do. return; } // If the textLength="" attribute was specified, then we need ResolvePositions // to record that a new run starts with each glyph. SVGTextContentElement* element = static_cast(GetContent()); SVGAnimatedLength* textLengthAttr = element->GetAnimatedLength(nsGkAtoms::textLength); uint16_t lengthAdjust = element->EnumAttributes()[SVGTextContentElement::LENGTHADJUST] .GetAnimValue(); bool adjustingTextLength = textLengthAttr->IsExplicitlySet(); float expectedTextLength = textLengthAttr->GetAnimValue(element); if (adjustingTextLength && (expectedTextLength < 0.0f || lengthAdjust == LENGTHADJUST_UNKNOWN)) { // If textLength="" is less than zero or lengthAdjust is unknown, ignore it. adjustingTextLength = false; } // Get the x, y, dx, dy, rotate values for the subtree. nsTArray deltas; if (!ResolvePositions(deltas, adjustingTextLength)) { // If ResolvePositions returned false, it means either there were some // characters in the DOM but none of them are displayed, or there was // an error in processing mPositions. Clear out mPositions so that we don't // attempt to do any painting later. mPositions.Clear(); return; } // XXX We might be able to do less work when there is at most a single // x/y/dx/dy position. // Truncate the positioning arrays to the actual number of characters present. TruncateTo(deltas, charPositions); TruncateTo(mPositions, charPositions); // Fill in an unspecified character position at index 0. if (!mPositions[0].IsXSpecified()) { mPositions[0].mPosition.x = 0.0; } if (!mPositions[0].IsYSpecified()) { mPositions[0].mPosition.y = 0.0; } if (!mPositions[0].IsAngleSpecified()) { mPositions[0].mAngle = 0.0; } nsPresContext* presContext = PresContext(); bool vertical = GetWritingMode().IsVertical(); float cssPxPerDevPx = nsPresContext::AppUnitsToFloatCSSPixels( presContext->AppUnitsPerDevPixel()); double factor = cssPxPerDevPx / mFontSizeScaleFactor; // Determine how much to compress or expand glyph positions due to // textLength="" and lengthAdjust="". double adjustment = 0.0; mLengthAdjustScaleFactor = 1.0f; if (adjustingTextLength) { nscoord frameLength = vertical ? PrincipalChildList().FirstChild()->GetRect().height : PrincipalChildList().FirstChild()->GetRect().width; float actualTextLength = static_cast( presContext->AppUnitsToGfxUnits(frameLength) * factor); switch (lengthAdjust) { case LENGTHADJUST_SPACINGANDGLYPHS: // Scale the glyphs and their positions. if (actualTextLength > 0) { mLengthAdjustScaleFactor = expectedTextLength / actualTextLength; } break; default: MOZ_ASSERT(lengthAdjust == LENGTHADJUST_SPACING); // Just add space between each glyph. int32_t adjustableSpaces = 0; for (uint32_t i = 1; i < mPositions.Length(); i++) { if (!mPositions[i].mUnaddressable) { adjustableSpaces++; } } if (adjustableSpaces) { adjustment = (expectedTextLength - actualTextLength) / adjustableSpaces; } break; } } // Fill in any unspecified character positions based on the positions recorded // in charPositions, and also add in the dx/dy values. if (!deltas.IsEmpty()) { mPositions[0].mPosition += deltas[0]; } gfxFloat xLengthAdjustFactor = vertical ? 1.0 : mLengthAdjustScaleFactor; gfxFloat yLengthAdjustFactor = vertical ? mLengthAdjustScaleFactor : 1.0; for (uint32_t i = 1; i < mPositions.Length(); i++) { // Fill in unspecified x position. if (!mPositions[i].IsXSpecified()) { nscoord d = charPositions[i].x - charPositions[i - 1].x; mPositions[i].mPosition.x = mPositions[i - 1].mPosition.x + presContext->AppUnitsToGfxUnits(d) * factor * xLengthAdjustFactor; if (!vertical && !mPositions[i].mUnaddressable) { mPositions[i].mPosition.x += adjustment; } } // Fill in unspecified y position. if (!mPositions[i].IsYSpecified()) { nscoord d = charPositions[i].y - charPositions[i - 1].y; mPositions[i].mPosition.y = mPositions[i - 1].mPosition.y + presContext->AppUnitsToGfxUnits(d) * factor * yLengthAdjustFactor; if (vertical && !mPositions[i].mUnaddressable) { mPositions[i].mPosition.y += adjustment; } } // Add in dx/dy. if (i < deltas.Length()) { mPositions[i].mPosition += deltas[i]; } // Fill in unspecified rotation values. if (!mPositions[i].IsAngleSpecified()) { mPositions[i].mAngle = 0.0f; } } MOZ_ASSERT(mPositions.Length() == charPositions.Length()); AdjustChunksForLineBreaks(); AdjustPositionsForClusters(); DoAnchoring(); DoTextPathLayout(); } bool SVGTextFrame::ShouldRenderAsPath(nsTextFrame* aFrame, bool& aShouldPaintSVGGlyphs) { // Rendering to a clip path. if (HasAnyStateBits(NS_STATE_SVG_CLIPPATH_CHILD)) { aShouldPaintSVGGlyphs = false; return true; } aShouldPaintSVGGlyphs = true; const nsStyleSVG* style = aFrame->StyleSVG(); // Fill is a non-solid paint, has a non-default fill-rule or has // non-1 opacity. if (!(style->mFill.kind.IsNone() || (style->mFill.kind.IsColor() && style->mFillOpacity.IsOpacity() && style->mFillOpacity.AsOpacity() == 1))) { return true; } // Text has a stroke. if (style->HasStroke()) { if (style->mStrokeWidth.IsContextValue()) { return true; } if (SVGContentUtils::CoordToFloat( static_cast(GetContent()), style->mStrokeWidth.AsLengthPercentage()) > 0) { return true; } } return false; } void SVGTextFrame::ScheduleReflowSVG() { if (mState & NS_FRAME_IS_NONDISPLAY) { ScheduleReflowSVGNonDisplayText( IntrinsicDirty::FrameAncestorsAndDescendants); } else { SVGUtils::ScheduleReflowSVG(this); } } void SVGTextFrame::NotifyGlyphMetricsChange() { // TODO: perf - adding NS_STATE_SVG_TEXT_CORRESPONDENCE_DIRTY is overly // aggressive here. Ideally we would only set that bit when our descendant // frame tree changes (i.e. after frame construction). AddStateBits(NS_STATE_SVG_TEXT_CORRESPONDENCE_DIRTY | NS_STATE_SVG_POSITIONING_DIRTY); nsLayoutUtils::PostRestyleEvent(mContent->AsElement(), RestyleHint{0}, nsChangeHint_InvalidateRenderingObservers); ScheduleReflowSVG(); } void SVGTextFrame::UpdateGlyphPositioning() { nsIFrame* kid = PrincipalChildList().FirstChild(); if (!kid) { return; } if (mState & NS_STATE_SVG_POSITIONING_DIRTY) { DoGlyphPositioning(); } } void SVGTextFrame::MaybeResolveBidiForAnonymousBlockChild() { nsIFrame* kid = PrincipalChildList().FirstChild(); if (kid && kid->HasAnyStateBits(NS_BLOCK_NEEDS_BIDI_RESOLUTION) && PresContext()->BidiEnabled()) { MOZ_ASSERT(static_cast(do_QueryFrame(kid)), "Expect anonymous child to be an nsBlockFrame"); nsBidiPresUtils::Resolve(static_cast(kid)); } } void SVGTextFrame::MaybeReflowAnonymousBlockChild() { nsIFrame* kid = PrincipalChildList().FirstChild(); if (!kid) { return; } NS_ASSERTION(!kid->HasAnyStateBits(NS_FRAME_IN_REFLOW), "should not be in reflow when about to reflow again"); if (IsSubtreeDirty()) { if (mState & NS_FRAME_IS_DIRTY) { // If we require a full reflow, ensure our kid is marked fully dirty. // (Note that our anonymous nsBlockFrame is not an ISVGDisplayableFrame, // so even when we are called via our ReflowSVG this will not be done for // us by SVGDisplayContainerFrame::ReflowSVG.) kid->MarkSubtreeDirty(); } // The RecordCorrespondence and DoReflow calls can result in new text frames // being created (due to bidi resolution or reflow). We set this bit to // guard against unnecessarily calling back in to // ScheduleReflowSVGNonDisplayText from nsIFrame::DidSetComputedStyle on // those new text frames. AddStateBits(NS_STATE_SVG_TEXT_IN_REFLOW); TextNodeCorrespondenceRecorder::RecordCorrespondence(this); MOZ_ASSERT(SVGUtils::AnyOuterSVGIsCallingReflowSVG(this), "should be under ReflowSVG"); nsPresContext::InterruptPreventer noInterrupts(PresContext()); DoReflow(); RemoveStateBits(NS_STATE_SVG_TEXT_IN_REFLOW); } } void SVGTextFrame::DoReflow() { MOZ_ASSERT(HasAnyStateBits(NS_STATE_SVG_TEXT_IN_REFLOW)); // Since we are going to reflow the anonymous block frame, we will // need to update mPositions. // We also mark our text correspondence as dirty since we can end up needing // reflow in ways that do not set NS_STATE_SVG_TEXT_CORRESPONDENCE_DIRTY. // (We'd then fail the "expected a TextNodeCorrespondenceProperty" assertion // when UpdateGlyphPositioning() is called after we return.) AddStateBits(NS_STATE_SVG_TEXT_CORRESPONDENCE_DIRTY | NS_STATE_SVG_POSITIONING_DIRTY); if (mState & NS_FRAME_IS_NONDISPLAY) { // Normally, these dirty flags would be cleared in ReflowSVG(), but that // doesn't get called for non-display frames. We don't want to reflow our // descendants every time SVGTextFrame::PaintSVG makes sure that we have // valid positions by calling UpdateGlyphPositioning(), so we need to clear // these dirty bits. Note that this also breaks an invalidation loop where // our descendants invalidate as they reflow, which invalidates rendering // observers, which reschedules the frame that is currently painting by // referencing us to paint again. See bug 839958 comment 7. Hopefully we // will break that loop more convincingly at some point. RemoveStateBits(NS_FRAME_IS_DIRTY | NS_FRAME_HAS_DIRTY_CHILDREN); } nsPresContext* presContext = PresContext(); nsIFrame* kid = PrincipalChildList().FirstChild(); if (!kid) { return; } RefPtr renderingContext = presContext->PresShell()->CreateReferenceRenderingContext(); if (UpdateFontSizeScaleFactor()) { // If the font size scale factor changed, we need the block to report // an updated preferred width. kid->MarkIntrinsicISizesDirty(); } nscoord inlineSize = kid->GetPrefISize(renderingContext); WritingMode wm = kid->GetWritingMode(); ReflowInput reflowInput(presContext, kid, renderingContext, LogicalSize(wm, inlineSize, NS_UNCONSTRAINEDSIZE)); ReflowOutput desiredSize(reflowInput); nsReflowStatus status; NS_ASSERTION( reflowInput.ComputedPhysicalBorderPadding() == nsMargin(0, 0, 0, 0) && reflowInput.ComputedPhysicalMargin() == nsMargin(0, 0, 0, 0), "style system should ensure that :-moz-svg-text " "does not get styled"); kid->Reflow(presContext, desiredSize, reflowInput, status); kid->DidReflow(presContext, &reflowInput); kid->SetSize(wm, desiredSize.Size(wm)); } // Usable font size range in devpixels / user-units #define CLAMP_MIN_SIZE 8.0 #define CLAMP_MAX_SIZE 200.0 #define PRECISE_SIZE 200.0 bool SVGTextFrame::UpdateFontSizeScaleFactor() { double oldFontSizeScaleFactor = mFontSizeScaleFactor; nsPresContext* presContext = PresContext(); bool geometricPrecision = false; CSSCoord min = std::numeric_limits::max(); CSSCoord max = std::numeric_limits::min(); bool anyText = false; // Find the minimum and maximum font sizes used over all the // nsTextFrames. TextFrameIterator it(this); nsTextFrame* f = it.Current(); while (f) { if (!geometricPrecision) { // Unfortunately we can't treat text-rendering:geometricPrecision // separately for each text frame. geometricPrecision = f->StyleText()->mTextRendering == StyleTextRendering::Geometricprecision; } const auto& fontSize = f->StyleFont()->mFont.size; if (!fontSize.IsZero()) { min = std::min(min, fontSize.ToCSSPixels()); max = std::max(max, fontSize.ToCSSPixels()); anyText = true; } f = it.Next(); } if (!anyText) { // No text, so no need for scaling. mFontSizeScaleFactor = 1.0; return mFontSizeScaleFactor != oldFontSizeScaleFactor; } if (geometricPrecision) { // We want to ensure minSize is scaled to PRECISE_SIZE. mFontSizeScaleFactor = PRECISE_SIZE / min; return mFontSizeScaleFactor != oldFontSizeScaleFactor; } // When we are non-display, we could be painted in different coordinate // spaces, and we don't want to have to reflow for each of these. We // just assume that the context scale is 1.0 for them all, so we don't // get stuck with a font size scale factor based on whichever referencing // frame happens to reflow first. double contextScale = 1.0; if (!(mState & NS_FRAME_IS_NONDISPLAY)) { gfxMatrix m(GetCanvasTM()); if (!m.IsSingular()) { contextScale = GetContextScale(m); if (!std::isfinite(contextScale)) { contextScale = 1.0f; } } } mLastContextScale = contextScale; // But we want to ignore any scaling required due to HiDPI displays, since // regular CSS text frames will still create text runs using the font size // in CSS pixels, and we want SVG text to have the same rendering as HTML // text for regular font sizes. float cssPxPerDevPx = nsPresContext::AppUnitsToFloatCSSPixels( presContext->AppUnitsPerDevPixel()); contextScale *= cssPxPerDevPx; double minTextRunSize = min * contextScale; double maxTextRunSize = max * contextScale; if (minTextRunSize >= CLAMP_MIN_SIZE && maxTextRunSize <= CLAMP_MAX_SIZE) { // We are already in the ideal font size range for all text frames, // so we only have to take into account the contextScale. mFontSizeScaleFactor = contextScale; } else if (max / min > CLAMP_MAX_SIZE / CLAMP_MIN_SIZE) { // We can't scale the font sizes so that all of the text frames lie // within our ideal font size range. // Heuristically, if the maxTextRunSize is within the CLAMP_MAX_SIZE // as a reasonable value, it's likely to be the user's intent to // get a valid font for the maxTextRunSize one, we should honor it. // The same for minTextRunSize. if (maxTextRunSize <= CLAMP_MAX_SIZE) { mFontSizeScaleFactor = CLAMP_MAX_SIZE / max; } else if (minTextRunSize >= CLAMP_MIN_SIZE) { mFontSizeScaleFactor = CLAMP_MIN_SIZE / min; } else { // So maxTextRunSize is too big, minTextRunSize is too small, // we can't really do anything for this case, just leave it as is. mFontSizeScaleFactor = contextScale; } } else if (minTextRunSize < CLAMP_MIN_SIZE) { mFontSizeScaleFactor = CLAMP_MIN_SIZE / min; } else { mFontSizeScaleFactor = CLAMP_MAX_SIZE / max; } return mFontSizeScaleFactor != oldFontSizeScaleFactor; } double SVGTextFrame::GetFontSizeScaleFactor() const { return mFontSizeScaleFactor; } /** * Take aPoint, which is in the element's user space, and convert * it to the appropriate frame user space of aChildFrame according to * which rendered run the point hits. */ Point SVGTextFrame::TransformFramePointToTextChild( const Point& aPoint, const nsIFrame* aChildFrame) { NS_ASSERTION(aChildFrame && nsLayoutUtils::GetClosestFrameOfType( aChildFrame->GetParent(), LayoutFrameType::SVGText) == this, "aChildFrame must be a descendant of this frame"); UpdateGlyphPositioning(); nsPresContext* presContext = PresContext(); // Add in the mRect offset to aPoint, as that will have been taken into // account when transforming the point from the ancestor frame down // to this one. float cssPxPerDevPx = nsPresContext::AppUnitsToFloatCSSPixels( presContext->AppUnitsPerDevPixel()); float factor = AppUnitsPerCSSPixel(); Point framePosition(NSAppUnitsToFloatPixels(mRect.x, factor), NSAppUnitsToFloatPixels(mRect.y, factor)); Point pointInUserSpace = aPoint * cssPxPerDevPx + framePosition; // Find the closest rendered run for the text frames beneath aChildFrame. TextRenderedRunIterator it(this, TextRenderedRunIterator::eAllFrames, aChildFrame); TextRenderedRun hit; gfxPoint pointInRun; nscoord dx = nscoord_MAX; nscoord dy = nscoord_MAX; for (TextRenderedRun run = it.Current(); run.mFrame; run = it.Next()) { uint32_t flags = TextRenderedRun::eIncludeFill | TextRenderedRun::eIncludeStroke | TextRenderedRun::eNoHorizontalOverflow; gfxRect runRect = run.GetRunUserSpaceRect(presContext, flags).ToThebesRect(); gfxMatrix m = run.GetTransformFromRunUserSpaceToUserSpace(presContext); if (!m.Invert()) { return aPoint; } gfxPoint pointInRunUserSpace = m.TransformPoint(ThebesPoint(pointInUserSpace)); if (Inside(runRect, pointInRunUserSpace)) { // The point was inside the rendered run's rect, so we choose it. dx = 0; dy = 0; pointInRun = pointInRunUserSpace; hit = run; } else if (nsLayoutUtils::PointIsCloserToRect(pointInRunUserSpace, runRect, dx, dy)) { // The point was closer to this rendered run's rect than any others // we've seen so far. pointInRun.x = clamped(pointInRunUserSpace.x.value, runRect.X(), runRect.XMost()); pointInRun.y = clamped(pointInRunUserSpace.y.value, runRect.Y(), runRect.YMost()); hit = run; } } if (!hit.mFrame) { // We didn't find any rendered runs for the frame. return aPoint; } // Return the point in user units relative to the nsTextFrame, // but taking into account mFontSizeScaleFactor. gfxMatrix m = hit.GetTransformFromRunUserSpaceToFrameUserSpace(presContext); m.PreScale(mFontSizeScaleFactor, mFontSizeScaleFactor); return ToPoint(m.TransformPoint(pointInRun) / cssPxPerDevPx); } /** * For each rendered run beneath aChildFrame, translate aRect from * aChildFrame to the run's text frame, transform it then into * the run's frame user space, intersect it with the run's * frame user space rect, then transform it up to user space. * The result is the union of all of these. */ gfxRect SVGTextFrame::TransformFrameRectFromTextChild( const nsRect& aRect, const nsIFrame* aChildFrame) { NS_ASSERTION(aChildFrame && nsLayoutUtils::GetClosestFrameOfType( aChildFrame->GetParent(), LayoutFrameType::SVGText) == this, "aChildFrame must be a descendant of this frame"); UpdateGlyphPositioning(); nsPresContext* presContext = PresContext(); gfxRect result; TextRenderedRunIterator it(this, TextRenderedRunIterator::eAllFrames, aChildFrame); for (TextRenderedRun run = it.Current(); run.mFrame; run = it.Next()) { // First, translate aRect from aChildFrame to this run's frame. nsRect rectInTextFrame = aRect + aChildFrame->GetOffsetTo(run.mFrame); // Scale it into frame user space. gfxRect rectInFrameUserSpace = AppUnitsToFloatCSSPixels( gfxRect(rectInTextFrame.x, rectInTextFrame.y, rectInTextFrame.width, rectInTextFrame.height), presContext); // Intersect it with the run. uint32_t flags = TextRenderedRun::eIncludeFill | TextRenderedRun::eIncludeStroke; if (rectInFrameUserSpace.IntersectRect( rectInFrameUserSpace, run.GetFrameUserSpaceRect(presContext, flags).ToThebesRect())) { // Transform it up to user space of the gfxMatrix m = run.GetTransformFromRunUserSpaceToUserSpace(presContext); gfxRect rectInUserSpace = m.TransformRect(rectInFrameUserSpace); // Union it into the result. result.UnionRect(result, rectInUserSpace); } } // Subtract the mRect offset from the result, as our user space for // this frame is relative to the top-left of mRect. float factor = AppUnitsPerCSSPixel(); gfxPoint framePosition(NSAppUnitsToFloatPixels(mRect.x, factor), NSAppUnitsToFloatPixels(mRect.y, factor)); return result - framePosition; } Rect SVGTextFrame::TransformFrameRectFromTextChild( const Rect& aRect, const nsIFrame* aChildFrame) { nscoord appUnitsPerDevPixel = PresContext()->AppUnitsPerDevPixel(); nsRect r = LayoutDevicePixel::ToAppUnits( LayoutDeviceRect::FromUnknownRect(aRect), appUnitsPerDevPixel); gfxRect resultCssUnits = TransformFrameRectFromTextChild(r, aChildFrame); float devPixelPerCSSPixel = float(AppUnitsPerCSSPixel()) / appUnitsPerDevPixel; resultCssUnits.Scale(devPixelPerCSSPixel); return ToRect(resultCssUnits); } Point SVGTextFrame::TransformFramePointFromTextChild( const Point& aPoint, const nsIFrame* aChildFrame) { return TransformFrameRectFromTextChild(Rect(aPoint, Size(1, 1)), aChildFrame) .TopLeft(); } void SVGTextFrame::AppendDirectlyOwnedAnonBoxes( nsTArray& aResult) { MOZ_ASSERT(PrincipalChildList().FirstChild(), "Must have our anon box"); aResult.AppendElement(OwnedAnonBox(PrincipalChildList().FirstChild())); } } // namespace mozilla