/* -*- 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: // This is also necessary to ensure our definition of M_SQRT1_2 is picked up #include "SVGContentUtils.h" // Keep others in (case-insensitive) order: #include "gfx2DGlue.h" #include "gfxMatrix.h" #include "gfxPlatform.h" #include "mozilla/gfx/2D.h" #include "mozilla/dom/SVGSVGElement.h" #include "mozilla/PresShell.h" #include "mozilla/RefPtr.h" #include "mozilla/SVGContextPaint.h" #include "mozilla/SVGUtils.h" #include "mozilla/TextUtils.h" #include "nsComputedDOMStyle.h" #include "nsContainerFrame.h" #include "nsFontMetrics.h" #include "nsIFrame.h" #include "nsIScriptError.h" #include "nsLayoutUtils.h" #include "nsMathUtils.h" #include "nsWhitespaceTokenizer.h" #include "SVGAnimatedPreserveAspectRatio.h" #include "SVGGeometryProperty.h" #include "nsContentUtils.h" #include "mozilla/gfx/Types.h" #include "mozilla/FloatingPoint.h" #include "mozilla/ComputedStyle.h" #include "SVGPathDataParser.h" #include "SVGPathData.h" #include "SVGPathElement.h" using namespace mozilla; using namespace mozilla::dom; using namespace mozilla::dom::SVGPreserveAspectRatio_Binding; using namespace mozilla::gfx; static bool ParseNumber(RangedPtr& aIter, const RangedPtr& aEnd, double& aValue) { int32_t sign; if (!SVGContentUtils::ParseOptionalSign(aIter, aEnd, sign)) { return false; } // Absolute value of the integer part of the mantissa. double intPart = 0.0; bool gotDot = *aIter == '.'; if (!gotDot) { if (!mozilla::IsAsciiDigit(*aIter)) { return false; } do { intPart = 10.0 * intPart + mozilla::AsciiAlphanumericToNumber(*aIter); ++aIter; } while (aIter != aEnd && mozilla::IsAsciiDigit(*aIter)); if (aIter != aEnd) { gotDot = *aIter == '.'; } } // Fractional part of the mantissa. double fracPart = 0.0; if (gotDot) { ++aIter; if (aIter == aEnd || !mozilla::IsAsciiDigit(*aIter)) { return false; } // Power of ten by which we need to divide the fraction double divisor = 1.0; do { fracPart = 10.0 * fracPart + mozilla::AsciiAlphanumericToNumber(*aIter); divisor *= 10.0; ++aIter; } while (aIter != aEnd && mozilla::IsAsciiDigit(*aIter)); fracPart /= divisor; } bool gotE = false; int32_t exponent = 0; int32_t expSign; if (aIter != aEnd && (*aIter == 'e' || *aIter == 'E')) { RangedPtr expIter(aIter); ++expIter; if (expIter != aEnd) { expSign = *expIter == '-' ? -1 : 1; if (*expIter == '-' || *expIter == '+') { ++expIter; } if (expIter != aEnd && mozilla::IsAsciiDigit(*expIter)) { // At this point we're sure this is an exponent // and not the start of a unit such as em or ex. gotE = true; } } if (gotE) { aIter = expIter; do { exponent = 10.0 * exponent + mozilla::AsciiAlphanumericToNumber(*aIter); ++aIter; } while (aIter != aEnd && mozilla::IsAsciiDigit(*aIter)); } } // Assemble the number aValue = sign * (intPart + fracPart); if (gotE) { aValue *= pow(10.0, expSign * exponent); } return true; } namespace mozilla { SVGSVGElement* SVGContentUtils::GetOuterSVGElement(SVGElement* aSVGElement) { Element* element = nullptr; Element* ancestor = aSVGElement->GetParentElementCrossingShadowRoot(); while (ancestor && ancestor->IsSVGElement() && !ancestor->IsSVGElement(nsGkAtoms::foreignObject)) { element = ancestor; ancestor = element->GetParentElementCrossingShadowRoot(); } if (element && element->IsSVGElement(nsGkAtoms::svg)) { return static_cast(element); } return nullptr; } enum DashState { eDashedStroke, eContinuousStroke, //< all dashes, no gaps eNoStroke //< all gaps, no dashes }; static DashState GetStrokeDashData( SVGContentUtils::AutoStrokeOptions* aStrokeOptions, SVGElement* aElement, const nsStyleSVG* aStyleSVG, SVGContextPaint* aContextPaint) { size_t dashArrayLength; Float totalLengthOfDashes = 0.0, totalLengthOfGaps = 0.0; Float pathScale = 1.0; if (aStyleSVG->mStrokeDasharray.IsContextValue()) { if (!aContextPaint) { return eContinuousStroke; } const FallibleTArray& dashSrc = aContextPaint->GetStrokeDashArray(); dashArrayLength = dashSrc.Length(); if (dashArrayLength <= 0) { return eContinuousStroke; } Float* dashPattern = aStrokeOptions->InitDashPattern(dashArrayLength); if (!dashPattern) { return eContinuousStroke; } for (size_t i = 0; i < dashArrayLength; i++) { if (dashSrc[i] < 0.0) { return eContinuousStroke; // invalid } dashPattern[i] = Float(dashSrc[i]); (i % 2 ? totalLengthOfGaps : totalLengthOfDashes) += dashSrc[i]; } } else { const auto dasharray = aStyleSVG->mStrokeDasharray.AsValues().AsSpan(); dashArrayLength = dasharray.Length(); if (dashArrayLength <= 0) { return eContinuousStroke; } if (aElement->IsNodeOfType(nsINode::eSHAPE)) { pathScale = static_cast(aElement)->GetPathLengthScale( SVGGeometryElement::eForStroking); if (pathScale <= 0) { return eContinuousStroke; } } Float* dashPattern = aStrokeOptions->InitDashPattern(dashArrayLength); if (!dashPattern) { return eContinuousStroke; } for (uint32_t i = 0; i < dashArrayLength; i++) { Float dashLength = SVGContentUtils::CoordToFloat(aElement, dasharray[i]) * pathScale; if (dashLength < 0.0) { return eContinuousStroke; // invalid } dashPattern[i] = dashLength; (i % 2 ? totalLengthOfGaps : totalLengthOfDashes) += dashLength; } } // Now that aStrokeOptions.mDashPattern is fully initialized (we didn't // return early above) we can safely set mDashLength: aStrokeOptions->mDashLength = dashArrayLength; if ((dashArrayLength % 2) == 1) { // If we have a dash pattern with an odd number of lengths the pattern // repeats a second time, per the SVG spec., and as implemented by Moz2D. // When deciding whether to return eNoStroke or eContinuousStroke below we // need to take into account that in the repeat pattern the dashes become // gaps, and the gaps become dashes. Float origTotalLengthOfDashes = totalLengthOfDashes; totalLengthOfDashes += totalLengthOfGaps; totalLengthOfGaps += origTotalLengthOfDashes; } // Stroking using dashes is much slower than stroking a continuous line // (see bug 609361 comment 40), and much, much slower than not stroking the // line at all. Here we check for cases when the dash pattern causes the // stroke to essentially be continuous or to be nonexistent in which case // we can avoid expensive stroking operations (the underlying platform // graphics libraries don't seem to optimize for this). if (totalLengthOfGaps <= 0) { return eContinuousStroke; } // We can only return eNoStroke if the value of stroke-linecap isn't // adding caps to zero length dashes. if (totalLengthOfDashes <= 0 && aStyleSVG->mStrokeLinecap == StyleStrokeLinecap::Butt) { return eNoStroke; } if (aStyleSVG->mStrokeDashoffset.IsContextValue()) { aStrokeOptions->mDashOffset = Float(aContextPaint ? aContextPaint->GetStrokeDashOffset() : 0); } else { aStrokeOptions->mDashOffset = SVGContentUtils::CoordToFloat( aElement, aStyleSVG->mStrokeDashoffset.AsLengthPercentage()) * pathScale; } return eDashedStroke; } void SVGContentUtils::GetStrokeOptions(AutoStrokeOptions* aStrokeOptions, SVGElement* aElement, const ComputedStyle* aComputedStyle, SVGContextPaint* aContextPaint, StrokeOptionFlags aFlags) { auto doCompute = [&](const ComputedStyle* computedStyle) { const nsStyleSVG* styleSVG = computedStyle->StyleSVG(); bool checkedDashAndStrokeIsDashed = false; if (aFlags != eIgnoreStrokeDashing) { DashState dashState = GetStrokeDashData(aStrokeOptions, aElement, styleSVG, aContextPaint); if (dashState == eNoStroke) { // Hopefully this will shortcircuit any stroke operations: aStrokeOptions->mLineWidth = 0; return; } if (dashState == eContinuousStroke && aStrokeOptions->mDashPattern) { // Prevent our caller from wasting time looking at a pattern without // gaps: aStrokeOptions->DiscardDashPattern(); } checkedDashAndStrokeIsDashed = (dashState == eDashedStroke); } aStrokeOptions->mLineWidth = GetStrokeWidth(aElement, computedStyle, aContextPaint); aStrokeOptions->mMiterLimit = Float(styleSVG->mStrokeMiterlimit); switch (styleSVG->mStrokeLinejoin) { case StyleStrokeLinejoin::Miter: aStrokeOptions->mLineJoin = JoinStyle::MITER_OR_BEVEL; break; case StyleStrokeLinejoin::Round: aStrokeOptions->mLineJoin = JoinStyle::ROUND; break; case StyleStrokeLinejoin::Bevel: aStrokeOptions->mLineJoin = JoinStyle::BEVEL; break; } if (ShapeTypeHasNoCorners(aElement) && !checkedDashAndStrokeIsDashed) { // Note: if aFlags == eIgnoreStrokeDashing then we may be returning the // wrong linecap value here, since the actual linecap used on render in // this case depends on whether the stroke is dashed or not. aStrokeOptions->mLineCap = CapStyle::BUTT; } else { switch (styleSVG->mStrokeLinecap) { case StyleStrokeLinecap::Butt: aStrokeOptions->mLineCap = CapStyle::BUTT; break; case StyleStrokeLinecap::Round: aStrokeOptions->mLineCap = CapStyle::ROUND; break; case StyleStrokeLinecap::Square: aStrokeOptions->mLineCap = CapStyle::SQUARE; break; } } }; if (aComputedStyle) { doCompute(aComputedStyle); } else { SVGGeometryProperty::DoForComputedStyle(aElement, doCompute); } } Float SVGContentUtils::GetStrokeWidth(SVGElement* aElement, const ComputedStyle* aComputedStyle, SVGContextPaint* aContextPaint) { Float res = 0.0; auto doCompute = [&](const ComputedStyle* computedStyle) { const nsStyleSVG* styleSVG = computedStyle->StyleSVG(); if (styleSVG->mStrokeWidth.IsContextValue()) { res = aContextPaint ? aContextPaint->GetStrokeWidth() : 1.0; } else { auto& lp = styleSVG->mStrokeWidth.AsLengthPercentage(); if (lp.HasPercent() && aElement) { auto counter = aElement->IsSVGElement(nsGkAtoms::text) ? UseCounter::eUseCounter_custom_PercentageStrokeWidthInSVGText : UseCounter::eUseCounter_custom_PercentageStrokeWidthInSVG; aElement->OwnerDoc()->SetUseCounter(counter); } res = SVGContentUtils::CoordToFloat(aElement, lp); } }; if (aComputedStyle) { doCompute(aComputedStyle); } else { SVGGeometryProperty::DoForComputedStyle(aElement, doCompute); } return res; } float SVGContentUtils::GetFontSize(Element* aElement) { if (!aElement) { return 1.0f; } nsPresContext* pc = nsContentUtils::GetContextForContent(aElement); if (!pc) { return 1.0f; } if (auto* f = aElement->GetPrimaryFrame()) { return GetFontSize(f->Style(), pc); } if (RefPtr style = nsComputedDOMStyle::GetComputedStyleNoFlush(aElement)) { return GetFontSize(style, pc); } // ReportToConsole NS_WARNING("Couldn't get ComputedStyle for content in GetFontStyle"); return 1.0f; } float SVGContentUtils::GetFontSize(nsIFrame* aFrame) { MOZ_ASSERT(aFrame, "NULL frame in GetFontSize"); return GetFontSize(aFrame->Style(), aFrame->PresContext()); } float SVGContentUtils::GetFontSize(const ComputedStyle* aComputedStyle, nsPresContext* aPresContext) { MOZ_ASSERT(aComputedStyle); MOZ_ASSERT(aPresContext); return aComputedStyle->StyleFont()->mSize.ToCSSPixels() / aPresContext->EffectiveTextZoom(); } float SVGContentUtils::GetFontXHeight(Element* aElement) { if (!aElement) { return 1.0f; } nsPresContext* pc = nsContentUtils::GetContextForContent(aElement); if (!pc) { return 1.0f; } if (auto* f = aElement->GetPrimaryFrame()) { return GetFontXHeight(f->Style(), pc); } if (RefPtr style = nsComputedDOMStyle::GetComputedStyleNoFlush(aElement)) { return GetFontXHeight(style, pc); } // ReportToConsole NS_WARNING("Couldn't get ComputedStyle for content in GetFontStyle"); return 1.0f; } float SVGContentUtils::GetFontXHeight(nsIFrame* aFrame) { MOZ_ASSERT(aFrame, "NULL frame in GetFontXHeight"); return GetFontXHeight(aFrame->Style(), aFrame->PresContext()); } float SVGContentUtils::GetFontXHeight(const ComputedStyle* aComputedStyle, nsPresContext* aPresContext) { MOZ_ASSERT(aComputedStyle && aPresContext); RefPtr fontMetrics = nsLayoutUtils::GetFontMetricsForComputedStyle(aComputedStyle, aPresContext); if (!fontMetrics) { // ReportToConsole NS_WARNING("no FontMetrics in GetFontXHeight()"); return 1.0f; } nscoord xHeight = fontMetrics->XHeight(); return nsPresContext::AppUnitsToFloatCSSPixels(xHeight) / aPresContext->EffectiveTextZoom(); } nsresult SVGContentUtils::ReportToConsole(Document* doc, const char* aWarning, const nsTArray& aParams) { return nsContentUtils::ReportToConsole(nsIScriptError::warningFlag, "SVG"_ns, doc, nsContentUtils::eSVG_PROPERTIES, aWarning, aParams); } bool SVGContentUtils::EstablishesViewport(nsIContent* aContent) { // Although SVG 1.1 states that is an element that establishes a // viewport, this is really only for the document it references, not // for any child content, which is what this function is used for. return aContent && aContent->IsAnyOfSVGElements(nsGkAtoms::svg, nsGkAtoms::foreignObject, nsGkAtoms::symbol); } SVGViewportElement* SVGContentUtils::GetNearestViewportElement( const nsIContent* aContent) { nsIContent* element = aContent->GetFlattenedTreeParent(); while (element && element->IsSVGElement()) { if (EstablishesViewport(element)) { if (element->IsSVGElement(nsGkAtoms::foreignObject)) { return nullptr; } MOZ_ASSERT(element->IsAnyOfSVGElements(nsGkAtoms::svg, nsGkAtoms::symbol), "upcoming static_cast is only valid for " "SVGViewportElement subclasses"); return static_cast(element); } element = element->GetFlattenedTreeParent(); } return nullptr; } static gfx::Matrix GetCTMInternal(SVGElement* aElement, bool aScreenCTM, bool aHaveRecursed) { auto getLocalTransformHelper = [](SVGElement const* e, bool shouldIncludeChildToUserSpace) -> gfxMatrix { gfxMatrix ret; if (auto* f = e->GetPrimaryFrame()) { ret = SVGUtils::GetTransformMatrixInUserSpace(f); } else { // FIXME: Ideally we should also return the correct matrix // for display:none, but currently transform related code relies // heavily on the present of a frame. // For now we just fall back to |PrependLocalTransformsTo| which // doesn't account for CSS transform. ret = e->PrependLocalTransformsTo({}, eUserSpaceToParent); } if (shouldIncludeChildToUserSpace) { ret = e->PrependLocalTransformsTo({}, eChildToUserSpace) * ret; } return ret; }; gfxMatrix matrix = getLocalTransformHelper(aElement, aHaveRecursed); SVGElement* element = aElement; nsIContent* ancestor = aElement->GetFlattenedTreeParent(); while (ancestor && ancestor->IsSVGElement() && !ancestor->IsSVGElement(nsGkAtoms::foreignObject)) { element = static_cast(ancestor); matrix *= getLocalTransformHelper(element, true); if (!aScreenCTM && SVGContentUtils::EstablishesViewport(element)) { if (!element->NodeInfo()->Equals(nsGkAtoms::svg, kNameSpaceID_SVG) && !element->NodeInfo()->Equals(nsGkAtoms::symbol, kNameSpaceID_SVG)) { NS_ERROR("New (SVG > 1.1) SVG viewport establishing element?"); return gfx::Matrix(0.0, 0.0, 0.0, 0.0, 0.0, 0.0); // singular } // XXX spec seems to say x,y translation should be undone for IsInnerSVG return gfx::ToMatrix(matrix); } ancestor = ancestor->GetFlattenedTreeParent(); } if (!aScreenCTM) { // didn't find a nearestViewportElement return gfx::Matrix(0.0, 0.0, 0.0, 0.0, 0.0, 0.0); // singular } if (!element->IsSVGElement(nsGkAtoms::svg)) { // Not a valid SVG fragment return gfx::Matrix(0.0, 0.0, 0.0, 0.0, 0.0, 0.0); // singular } if (element == aElement && !aHaveRecursed) { // We get here when getScreenCTM() is called on an outer-. // Consistency with other elements would have us include only the // eFromUserSpace transforms, but we include the eAllTransforms // transforms in this case since that's what we've been doing for // a while, and it keeps us consistent with WebKit and Opera (if not // really with the ambiguous spec). matrix = getLocalTransformHelper(aElement, true); } if (auto* f = element->GetPrimaryFrame()) { if (f->IsSVGOuterSVGFrame()) { nsMargin bp = f->GetUsedBorderAndPadding(); matrix.PostTranslate( NSAppUnitsToFloatPixels(bp.left, AppUnitsPerCSSPixel()), NSAppUnitsToFloatPixels(bp.top, AppUnitsPerCSSPixel())); } } if (!ancestor || !ancestor->IsElement()) { return gfx::ToMatrix(matrix); } if (ancestor->IsSVGElement()) { return gfx::ToMatrix(matrix) * GetCTMInternal(static_cast(ancestor), true, true); } // XXX this does not take into account CSS transform, or that the non-SVG // content that we've hit may itself be inside an SVG foreignObject higher up Document* currentDoc = aElement->GetComposedDoc(); float x = 0.0f, y = 0.0f; if (currentDoc && element->NodeInfo()->Equals(nsGkAtoms::svg, kNameSpaceID_SVG)) { PresShell* presShell = currentDoc->GetPresShell(); if (presShell) { nsIFrame* frame = element->GetPrimaryFrame(); nsIFrame* ancestorFrame = presShell->GetRootFrame(); if (frame && ancestorFrame) { nsPoint point = frame->GetOffsetTo(ancestorFrame); x = nsPresContext::AppUnitsToFloatCSSPixels(point.x); y = nsPresContext::AppUnitsToFloatCSSPixels(point.y); } } } return ToMatrix(matrix).PostTranslate(x, y); } gfx::Matrix SVGContentUtils::GetCTM(SVGElement* aElement, bool aScreenCTM) { return GetCTMInternal(aElement, aScreenCTM, false); } void SVGContentUtils::RectilinearGetStrokeBounds( const Rect& aRect, const Matrix& aToBoundsSpace, const Matrix& aToNonScalingStrokeSpace, float aStrokeWidth, Rect* aBounds) { MOZ_ASSERT(aToBoundsSpace.IsRectilinear(), "aToBoundsSpace must be rectilinear"); MOZ_ASSERT(aToNonScalingStrokeSpace.IsRectilinear(), "aToNonScalingStrokeSpace must be rectilinear"); Matrix nonScalingToSource = aToNonScalingStrokeSpace.Inverse(); Matrix nonScalingToBounds = nonScalingToSource * aToBoundsSpace; *aBounds = aToBoundsSpace.TransformBounds(aRect); // Compute the amounts dx and dy that nonScalingToBounds scales a half-width // stroke in the x and y directions, and then inflate aBounds by those amounts // so that when aBounds is transformed back to non-scaling-stroke space // it will map onto the correct stroked bounds. Float dx = 0.0f; Float dy = 0.0f; // nonScalingToBounds is rectilinear, so either _12 and _21 are zero or _11 // and _22 are zero, and in each case the non-zero entries (from among _11, // _12, _21, _22) simply scale the stroke width in the x and y directions. if (FuzzyEqual(nonScalingToBounds._12, 0) && FuzzyEqual(nonScalingToBounds._21, 0)) { dx = (aStrokeWidth / 2.0f) * std::abs(nonScalingToBounds._11); dy = (aStrokeWidth / 2.0f) * std::abs(nonScalingToBounds._22); } else { dx = (aStrokeWidth / 2.0f) * std::abs(nonScalingToBounds._21); dy = (aStrokeWidth / 2.0f) * std::abs(nonScalingToBounds._12); } aBounds->Inflate(dx, dy); } double SVGContentUtils::ComputeNormalizedHypotenuse(double aWidth, double aHeight) { return NS_hypot(aWidth, aHeight) / M_SQRT2; } float SVGContentUtils::AngleBisect(float a1, float a2) { float delta = std::fmod(a2 - a1, static_cast(2 * M_PI)); if (delta < 0) { delta += static_cast(2 * M_PI); } /* delta is now the angle from a1 around to a2, in the range [0, 2*M_PI) */ float r = a1 + delta / 2; if (delta >= M_PI) { /* the arc from a2 to a1 is smaller, so use the ray on that side */ r += static_cast(M_PI); } return r; } gfx::Matrix SVGContentUtils::GetViewBoxTransform( float aViewportWidth, float aViewportHeight, float aViewboxX, float aViewboxY, float aViewboxWidth, float aViewboxHeight, const SVGAnimatedPreserveAspectRatio& aPreserveAspectRatio) { return GetViewBoxTransform(aViewportWidth, aViewportHeight, aViewboxX, aViewboxY, aViewboxWidth, aViewboxHeight, aPreserveAspectRatio.GetAnimValue()); } gfx::Matrix SVGContentUtils::GetViewBoxTransform( float aViewportWidth, float aViewportHeight, float aViewboxX, float aViewboxY, float aViewboxWidth, float aViewboxHeight, const SVGPreserveAspectRatio& aPreserveAspectRatio) { NS_ASSERTION(aViewportWidth >= 0, "viewport width must be nonnegative!"); NS_ASSERTION(aViewportHeight >= 0, "viewport height must be nonnegative!"); NS_ASSERTION(aViewboxWidth > 0, "viewBox width must be greater than zero!"); NS_ASSERTION(aViewboxHeight > 0, "viewBox height must be greater than zero!"); uint16_t align = aPreserveAspectRatio.GetAlign(); uint16_t meetOrSlice = aPreserveAspectRatio.GetMeetOrSlice(); // default to the defaults if (align == SVG_PRESERVEASPECTRATIO_UNKNOWN) align = SVG_PRESERVEASPECTRATIO_XMIDYMID; if (meetOrSlice == SVG_MEETORSLICE_UNKNOWN) meetOrSlice = SVG_MEETORSLICE_MEET; float a, d, e, f; a = aViewportWidth / aViewboxWidth; d = aViewportHeight / aViewboxHeight; e = 0.0f; f = 0.0f; if (align != SVG_PRESERVEASPECTRATIO_NONE && a != d) { if ((meetOrSlice == SVG_MEETORSLICE_MEET && a < d) || (meetOrSlice == SVG_MEETORSLICE_SLICE && d < a)) { d = a; switch (align) { case SVG_PRESERVEASPECTRATIO_XMINYMIN: case SVG_PRESERVEASPECTRATIO_XMIDYMIN: case SVG_PRESERVEASPECTRATIO_XMAXYMIN: break; case SVG_PRESERVEASPECTRATIO_XMINYMID: case SVG_PRESERVEASPECTRATIO_XMIDYMID: case SVG_PRESERVEASPECTRATIO_XMAXYMID: f = (aViewportHeight - a * aViewboxHeight) / 2.0f; break; case SVG_PRESERVEASPECTRATIO_XMINYMAX: case SVG_PRESERVEASPECTRATIO_XMIDYMAX: case SVG_PRESERVEASPECTRATIO_XMAXYMAX: f = aViewportHeight - a * aViewboxHeight; break; default: MOZ_ASSERT_UNREACHABLE("Unknown value for align"); } } else if ((meetOrSlice == SVG_MEETORSLICE_MEET && d < a) || (meetOrSlice == SVG_MEETORSLICE_SLICE && a < d)) { a = d; switch (align) { case SVG_PRESERVEASPECTRATIO_XMINYMIN: case SVG_PRESERVEASPECTRATIO_XMINYMID: case SVG_PRESERVEASPECTRATIO_XMINYMAX: break; case SVG_PRESERVEASPECTRATIO_XMIDYMIN: case SVG_PRESERVEASPECTRATIO_XMIDYMID: case SVG_PRESERVEASPECTRATIO_XMIDYMAX: e = (aViewportWidth - a * aViewboxWidth) / 2.0f; break; case SVG_PRESERVEASPECTRATIO_XMAXYMIN: case SVG_PRESERVEASPECTRATIO_XMAXYMID: case SVG_PRESERVEASPECTRATIO_XMAXYMAX: e = aViewportWidth - a * aViewboxWidth; break; default: MOZ_ASSERT_UNREACHABLE("Unknown value for align"); } } else MOZ_ASSERT_UNREACHABLE("Unknown value for meetOrSlice"); } if (aViewboxX) e += -a * aViewboxX; if (aViewboxY) f += -d * aViewboxY; return gfx::Matrix(a, 0.0f, 0.0f, d, e, f); } template bool SVGContentUtils::ParseNumber(RangedPtr& aIter, const RangedPtr& aEnd, floatType& aValue) { RangedPtr iter(aIter); double value; if (!::ParseNumber(iter, aEnd, value)) { return false; } floatType floatValue = floatType(value); if (!IsFinite(floatValue)) { return false; } aValue = floatValue; aIter = iter; return true; } template bool SVGContentUtils::ParseNumber( RangedPtr& aIter, const RangedPtr& aEnd, float& aValue); template bool SVGContentUtils::ParseNumber( RangedPtr& aIter, const RangedPtr& aEnd, double& aValue); RangedPtr SVGContentUtils::GetStartRangedPtr( const nsAString& aString) { return RangedPtr(aString.Data(), aString.Length()); } RangedPtr SVGContentUtils::GetEndRangedPtr( const nsAString& aString) { return RangedPtr(aString.Data() + aString.Length(), aString.Data(), aString.Length()); } template bool SVGContentUtils::ParseNumber(const nsAString& aString, floatType& aValue) { RangedPtr iter = GetStartRangedPtr(aString); const RangedPtr end = GetEndRangedPtr(aString); return ParseNumber(iter, end, aValue) && iter == end; } template bool SVGContentUtils::ParseNumber(const nsAString& aString, float& aValue); template bool SVGContentUtils::ParseNumber(const nsAString& aString, double& aValue); /* static */ bool SVGContentUtils::ParseInteger(RangedPtr& aIter, const RangedPtr& aEnd, int32_t& aValue) { RangedPtr iter(aIter); int32_t sign; if (!ParseOptionalSign(iter, aEnd, sign)) { return false; } if (!mozilla::IsAsciiDigit(*iter)) { return false; } int64_t value = 0; do { if (value <= std::numeric_limits::max()) { value = 10 * value + mozilla::AsciiAlphanumericToNumber(*iter); } ++iter; } while (iter != aEnd && mozilla::IsAsciiDigit(*iter)); aIter = iter; aValue = int32_t(clamped(sign * value, int64_t(std::numeric_limits::min()), int64_t(std::numeric_limits::max()))); return true; } /* static */ bool SVGContentUtils::ParseInteger(const nsAString& aString, int32_t& aValue) { RangedPtr iter = GetStartRangedPtr(aString); const RangedPtr end = GetEndRangedPtr(aString); return ParseInteger(iter, end, aValue) && iter == end; } float SVGContentUtils::CoordToFloat(SVGElement* aContent, const LengthPercentage& aLength, uint8_t aCtxType) { float result = aLength.ResolveToCSSPixelsWith([&] { SVGViewportElement* ctx = aContent->GetCtx(); return CSSCoord(ctx ? ctx->GetLength(aCtxType) : 0.0f); }); if (aLength.IsCalc()) { const auto& calc = aLength.AsCalc(); if (calc.clamping_mode == StyleAllowedNumericType::NonNegative) { result = std::max(result, 0.0f); } else { MOZ_ASSERT(calc.clamping_mode == StyleAllowedNumericType::All); } } return result; } already_AddRefed SVGContentUtils::GetPath( const nsAString& aPathString) { SVGPathData pathData; SVGPathDataParser parser(aPathString, &pathData); if (!parser.Parse()) { return nullptr; } RefPtr drawTarget = gfxPlatform::ThreadLocalScreenReferenceDrawTarget(); RefPtr builder = drawTarget->CreatePathBuilder(FillRule::FILL_WINDING); return pathData.BuildPath(builder, StyleStrokeLinecap::Butt, 1); } bool SVGContentUtils::ShapeTypeHasNoCorners(const nsIContent* aContent) { return aContent && aContent->IsAnyOfSVGElements(nsGkAtoms::circle, nsGkAtoms::ellipse); } nsDependentSubstring SVGContentUtils::GetAndEnsureOneToken( const nsAString& aString, bool& aSuccess) { nsWhitespaceTokenizerTemplate tokenizer( aString); aSuccess = false; if (!tokenizer.hasMoreTokens()) { return {}; } auto token = tokenizer.nextToken(); if (tokenizer.hasMoreTokens()) { return {}; } aSuccess = true; return token; } } // namespace mozilla