/* -*- Mode: C++; tab-width: 2; indent-tabs-mode: nil; c-basic-offset: 2 -*- * 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/. */ #include "CanvasRenderingContext2D.h" #include "mozilla/gfx/Helpers.h" #include "nsXULElement.h" #include "nsIServiceManager.h" #include "nsMathUtils.h" #include "SVGImageContext.h" #include "nsContentUtils.h" #include "nsIDocument.h" #include "mozilla/dom/HTMLCanvasElement.h" #include "nsSVGEffects.h" #include "nsPresContext.h" #include "nsIPresShell.h" #include "nsIInterfaceRequestorUtils.h" #include "nsIFrame.h" #include "nsError.h" #include "nsCSSParser.h" #include "mozilla/css/StyleRule.h" #include "mozilla/css/Declaration.h" #include "nsComputedDOMStyle.h" #include "nsStyleSet.h" #include "nsPrintfCString.h" #include "nsReadableUtils.h" #include "nsColor.h" #include "nsGfxCIID.h" #include "nsIDocShell.h" #include "nsIDOMWindow.h" #include "nsPIDOMWindow.h" #include "nsDisplayList.h" #include "nsFocusManager.h" #include "nsTArray.h" #include "ImageEncoder.h" #include "ImageRegion.h" #include "gfxContext.h" #include "gfxASurface.h" #include "gfxImageSurface.h" #include "gfxPlatform.h" #include "gfxFont.h" #include "gfxBlur.h" #include "gfxPrefs.h" #include "gfxUtils.h" #include "nsFrameLoader.h" #include "nsBidi.h" #include "nsBidiPresUtils.h" #include "Layers.h" #include "CanvasUtils.h" #include "nsIMemoryReporter.h" #include "nsStyleUtil.h" #include "CanvasImageCache.h" #include #include "jsapi.h" #include "jsfriendapi.h" #include "js/Conversions.h" #include "mozilla/Alignment.h" #include "mozilla/Assertions.h" #include "mozilla/CheckedInt.h" #include "mozilla/DebugOnly.h" #include "mozilla/dom/ContentParent.h" #include "mozilla/dom/ImageBitmap.h" #include "mozilla/dom/ImageData.h" #include "mozilla/dom/PBrowserParent.h" #include "mozilla/dom/ToJSValue.h" #include "mozilla/dom/TypedArray.h" #include "mozilla/Endian.h" #include "mozilla/gfx/2D.h" #include "mozilla/gfx/Helpers.h" #include "mozilla/gfx/PathHelpers.h" #include "mozilla/gfx/DataSurfaceHelpers.h" #include "mozilla/gfx/PatternHelpers.h" #include "mozilla/ipc/DocumentRendererParent.h" #include "mozilla/ipc/PDocumentRendererParent.h" #include "mozilla/layers/PersistentBufferProvider.h" #include "mozilla/MathAlgorithms.h" #include "mozilla/Preferences.h" #include "mozilla/Telemetry.h" #include "mozilla/TimeStamp.h" #include "mozilla/UniquePtr.h" #include "mozilla/unused.h" #include "nsCCUncollectableMarker.h" #include "nsWrapperCacheInlines.h" #include "mozilla/dom/CanvasRenderingContext2DBinding.h" #include "mozilla/dom/CanvasPath.h" #include "mozilla/dom/HTMLImageElement.h" #include "mozilla/dom/HTMLVideoElement.h" #include "mozilla/dom/SVGMatrix.h" #include "mozilla/dom/TextMetrics.h" #include "mozilla/dom/SVGMatrix.h" #include "mozilla/FloatingPoint.h" #include "nsGlobalWindow.h" #include "GLContext.h" #include "GLContextProvider.h" #include "SVGContentUtils.h" #include "SVGImageContext.h" #include "nsIScreenManager.h" #include "nsFilterInstance.h" #include "nsSVGLength2.h" #include "nsDeviceContext.h" #include "nsFontMetrics.h" #include "Units.h" #include "CanvasUtils.h" #undef free // apparently defined by some windows header, clashing with a free() // method in SkTypes.h #include "SkiaGLGlue.h" #ifdef USE_SKIA #include "SurfaceTypes.h" #include "GLBlitHelper.h" #endif using mozilla::gl::GLContext; using mozilla::gl::SkiaGLGlue; using mozilla::gl::GLContextProvider; #ifdef XP_WIN #include "gfxWindowsPlatform.h" #endif #ifdef MOZ_WIDGET_GONK #include "mozilla/layers/ShadowLayers.h" #endif // windows.h (included by chromium code) defines this, in its infinite wisdom #undef DrawText using namespace mozilla; using namespace mozilla::CanvasUtils; using namespace mozilla::css; using namespace mozilla::gfx; using namespace mozilla::image; using namespace mozilla::ipc; using namespace mozilla::layers; namespace mozilla { namespace dom { // Cap sigma to avoid overly large temp surfaces. const Float SIGMA_MAX = 100; /* Memory reporter stuff */ static int64_t gCanvasAzureMemoryUsed = 0; // This is KIND_OTHER because it's not always clear where in memory the pixels // of a canvas are stored. Furthermore, this memory will be tracked by the // underlying surface implementations. See bug 655638 for details. class Canvas2dPixelsReporter final : public nsIMemoryReporter { ~Canvas2dPixelsReporter() {} public: NS_DECL_ISUPPORTS NS_IMETHOD CollectReports(nsIHandleReportCallback* aHandleReport, nsISupports* aData, bool aAnonymize) override { return MOZ_COLLECT_REPORT( "canvas-2d-pixels", KIND_OTHER, UNITS_BYTES, gCanvasAzureMemoryUsed, "Memory used by 2D canvases. Each canvas requires " "(width * height * 4) bytes."); } }; NS_IMPL_ISUPPORTS(Canvas2dPixelsReporter, nsIMemoryReporter) class CanvasRadialGradient : public CanvasGradient { public: CanvasRadialGradient(CanvasRenderingContext2D* aContext, const Point &aBeginOrigin, Float aBeginRadius, const Point &aEndOrigin, Float aEndRadius) : CanvasGradient(aContext, Type::RADIAL) , mCenter1(aBeginOrigin) , mCenter2(aEndOrigin) , mRadius1(aBeginRadius) , mRadius2(aEndRadius) { } Point mCenter1; Point mCenter2; Float mRadius1; Float mRadius2; }; class CanvasLinearGradient : public CanvasGradient { public: CanvasLinearGradient(CanvasRenderingContext2D* aContext, const Point &aBegin, const Point &aEnd) : CanvasGradient(aContext, Type::LINEAR) , mBegin(aBegin) , mEnd(aEnd) { } protected: friend class CanvasGeneralPattern; // Beginning of linear gradient. Point mBegin; // End of linear gradient. Point mEnd; }; // This class is named 'GeneralCanvasPattern' instead of just // 'GeneralPattern' to keep Windows PGO builds from confusing the // GeneralPattern class in gfxContext.cpp with this one. class CanvasGeneralPattern { public: typedef CanvasRenderingContext2D::Style Style; typedef CanvasRenderingContext2D::ContextState ContextState; Pattern& ForStyle(CanvasRenderingContext2D *aCtx, Style aStyle, DrawTarget *aRT) { // This should only be called once or the mPattern destructor will // not be executed. NS_ASSERTION(!mPattern.GetPattern(), "ForStyle() should only be called once on CanvasGeneralPattern!"); const ContextState &state = aCtx->CurrentState(); if (state.StyleIsColor(aStyle)) { mPattern.InitColorPattern(ToDeviceColor(state.colorStyles[aStyle])); } else if (state.gradientStyles[aStyle] && state.gradientStyles[aStyle]->GetType() == CanvasGradient::Type::LINEAR) { CanvasLinearGradient *gradient = static_cast(state.gradientStyles[aStyle].get()); mPattern.InitLinearGradientPattern(gradient->mBegin, gradient->mEnd, gradient->GetGradientStopsForTarget(aRT)); } else if (state.gradientStyles[aStyle] && state.gradientStyles[aStyle]->GetType() == CanvasGradient::Type::RADIAL) { CanvasRadialGradient *gradient = static_cast(state.gradientStyles[aStyle].get()); mPattern.InitRadialGradientPattern(gradient->mCenter1, gradient->mCenter2, gradient->mRadius1, gradient->mRadius2, gradient->GetGradientStopsForTarget(aRT)); } else if (state.patternStyles[aStyle]) { if (aCtx->mCanvasElement) { CanvasUtils::DoDrawImageSecurityCheck(aCtx->mCanvasElement, state.patternStyles[aStyle]->mPrincipal, state.patternStyles[aStyle]->mForceWriteOnly, state.patternStyles[aStyle]->mCORSUsed); } ExtendMode mode; if (state.patternStyles[aStyle]->mRepeat == CanvasPattern::RepeatMode::NOREPEAT) { mode = ExtendMode::CLAMP; } else { mode = ExtendMode::REPEAT; } mPattern.InitSurfacePattern(state.patternStyles[aStyle]->mSurface, mode, state.patternStyles[aStyle]->mTransform); } return *mPattern.GetPattern(); } GeneralPattern mPattern; }; /* This is an RAII based class that can be used as a drawtarget for * operations that need to have a filter applied to their results. * All coordinates passed to the constructor are in device space. */ class AdjustedTargetForFilter { public: typedef CanvasRenderingContext2D::ContextState ContextState; AdjustedTargetForFilter(CanvasRenderingContext2D *ctx, DrawTarget *aFinalTarget, const gfx::IntPoint& aFilterSpaceToTargetOffset, const gfx::IntRect& aPreFilterBounds, const gfx::IntRect& aPostFilterBounds, gfx::CompositionOp aCompositionOp) : mCtx(nullptr) , mCompositionOp(aCompositionOp) { mCtx = ctx; mFinalTarget = aFinalTarget; mPostFilterBounds = aPostFilterBounds; mOffset = aFilterSpaceToTargetOffset; nsIntRegion sourceGraphicNeededRegion; nsIntRegion fillPaintNeededRegion; nsIntRegion strokePaintNeededRegion; FilterSupport::ComputeSourceNeededRegions( ctx->CurrentState().filter, mPostFilterBounds, sourceGraphicNeededRegion, fillPaintNeededRegion, strokePaintNeededRegion); mSourceGraphicRect = sourceGraphicNeededRegion.GetBounds(); mFillPaintRect = fillPaintNeededRegion.GetBounds(); mStrokePaintRect = strokePaintNeededRegion.GetBounds(); mSourceGraphicRect = mSourceGraphicRect.Intersect(aPreFilterBounds); if (mSourceGraphicRect.IsEmpty()) { // The filter might not make any use of the source graphic. We need to // create a DrawTarget that we can return from DT() anyway, so we'll // just use a 1x1-sized one. mSourceGraphicRect.SizeTo(1, 1); } mTarget = mFinalTarget->CreateSimilarDrawTarget(mSourceGraphicRect.Size(), SurfaceFormat::B8G8R8A8); if (!mTarget) { // XXX - Deal with the situation where our temp size is too big to // fit in a texture (bug 1066622). mTarget = mFinalTarget; mCtx = nullptr; mFinalTarget = nullptr; return; } mTarget->SetTransform( mFinalTarget->GetTransform().PostTranslate(-mSourceGraphicRect.TopLeft() + mOffset)); } // Return a SourceSurface that contains the FillPaint or StrokePaint source. already_AddRefed DoSourcePaint(gfx::IntRect& aRect, CanvasRenderingContext2D::Style aStyle) { if (aRect.IsEmpty()) { return nullptr; } RefPtr dt = mFinalTarget->CreateSimilarDrawTarget(aRect.Size(), SurfaceFormat::B8G8R8A8); if (!dt) { aRect.SetEmpty(); return nullptr; } Matrix transform = mFinalTarget->GetTransform().PostTranslate(-aRect.TopLeft() + mOffset); dt->SetTransform(transform); if (transform.Invert()) { gfx::Rect dtBounds(0, 0, aRect.width, aRect.height); gfx::Rect fillRect = transform.TransformBounds(dtBounds); dt->FillRect(fillRect, CanvasGeneralPattern().ForStyle(mCtx, aStyle, dt)); } return dt->Snapshot(); } ~AdjustedTargetForFilter() { if (!mCtx) { return; } RefPtr snapshot = mTarget->Snapshot(); RefPtr fillPaint = DoSourcePaint(mFillPaintRect, CanvasRenderingContext2D::Style::FILL); RefPtr strokePaint = DoSourcePaint(mStrokePaintRect, CanvasRenderingContext2D::Style::STROKE); AutoRestoreTransform autoRestoreTransform(mFinalTarget); mFinalTarget->SetTransform(Matrix()); gfx::FilterSupport::RenderFilterDescription( mFinalTarget, mCtx->CurrentState().filter, gfx::Rect(mPostFilterBounds), snapshot, mSourceGraphicRect, fillPaint, mFillPaintRect, strokePaint, mStrokePaintRect, mCtx->CurrentState().filterAdditionalImages, mPostFilterBounds.TopLeft() - mOffset, DrawOptions(1.0f, mCompositionOp)); } DrawTarget* DT() { return mTarget; } private: RefPtr mTarget; RefPtr mFinalTarget; CanvasRenderingContext2D *mCtx; gfx::IntRect mSourceGraphicRect; gfx::IntRect mFillPaintRect; gfx::IntRect mStrokePaintRect; gfx::IntRect mPostFilterBounds; gfx::IntPoint mOffset; gfx::CompositionOp mCompositionOp; }; /* This is an RAII based class that can be used as a drawtarget for * operations that need to have a shadow applied to their results. * All coordinates passed to the constructor are in device space. */ class AdjustedTargetForShadow { public: typedef CanvasRenderingContext2D::ContextState ContextState; AdjustedTargetForShadow(CanvasRenderingContext2D *ctx, DrawTarget *aFinalTarget, const gfx::Rect& aBounds, gfx::CompositionOp aCompositionOp) : mCtx(nullptr) , mCompositionOp(aCompositionOp) { mCtx = ctx; mFinalTarget = aFinalTarget; const ContextState &state = mCtx->CurrentState(); mSigma = state.ShadowBlurSigma(); gfx::Rect bounds = aBounds; int32_t blurRadius = state.ShadowBlurRadius(); // We actually include the bounds of the shadow blur, this makes it // easier to execute the actual blur on hardware, and shouldn't affect // the amount of pixels that need to be touched. bounds.Inflate(blurRadius); bounds.RoundOut(); bounds.ToIntRect(&mTempRect); mTarget = mFinalTarget->CreateShadowDrawTarget(mTempRect.Size(), SurfaceFormat::B8G8R8A8, mSigma); if (!mTarget) { // XXX - Deal with the situation where our temp size is too big to // fit in a texture (bug 1066622). mTarget = mFinalTarget; mCtx = nullptr; mFinalTarget = nullptr; } else { mTarget->SetTransform( mFinalTarget->GetTransform().PostTranslate(-mTempRect.TopLeft())); } } ~AdjustedTargetForShadow() { if (!mCtx) { return; } RefPtr snapshot = mTarget->Snapshot(); mFinalTarget->DrawSurfaceWithShadow(snapshot, mTempRect.TopLeft(), Color::FromABGR(mCtx->CurrentState().shadowColor), mCtx->CurrentState().shadowOffset, mSigma, mCompositionOp); } DrawTarget* DT() { return mTarget; } gfx::IntPoint OffsetToFinalDT() { return mTempRect.TopLeft(); } private: RefPtr mTarget; RefPtr mFinalTarget; CanvasRenderingContext2D *mCtx; Float mSigma; gfx::IntRect mTempRect; gfx::CompositionOp mCompositionOp; }; /* This is an RAII based class that can be used as a drawtarget for * operations that need a shadow or a filter drawn. It will automatically * provide a temporary target when needed, and if so blend it back with a * shadow, filter, or both. * If both a shadow and a filter are needed, the filter is applied first, * and the shadow is applied to the filtered results. * * aBounds specifies the bounds of the drawing operation that will be * drawn to the target, it is given in device space! If this is nullptr the * drawing operation will be assumed to cover the whole canvas. */ class AdjustedTarget { public: typedef CanvasRenderingContext2D::ContextState ContextState; explicit AdjustedTarget(CanvasRenderingContext2D* ctx, const gfx::Rect *aBounds = nullptr) { mTarget = ctx->mTarget; // All rects in this function are in the device space of ctx->mTarget. // In order to keep our temporary surfaces as small as possible, we first // calculate what their maximum required bounds would need to be if we // were to fill the whole canvas. Everything outside those bounds we don't // need to render. gfx::Rect r(0, 0, ctx->mWidth, ctx->mHeight); gfx::Rect maxSourceNeededBoundsForShadow = MaxSourceNeededBoundsForShadow(r, ctx); gfx::Rect maxSourceNeededBoundsForFilter = MaxSourceNeededBoundsForFilter(maxSourceNeededBoundsForShadow, ctx); gfx::Rect bounds = maxSourceNeededBoundsForFilter; if (aBounds) { bounds = bounds.Intersect(*aBounds); } gfx::Rect boundsAfterFilter = BoundsAfterFilter(bounds, ctx); mozilla::gfx::CompositionOp op = ctx->CurrentState().op; gfx::IntPoint offsetToFinalDT; // First set up the shadow draw target, because the shadow goes outside. // It applies to the post-filter results, if both a filter and a shadow // are used. if (ctx->NeedToDrawShadow()) { mShadowTarget = MakeUnique( ctx, mTarget, boundsAfterFilter, op); mTarget = mShadowTarget->DT(); offsetToFinalDT = mShadowTarget->OffsetToFinalDT(); // If we also have a filter, the filter needs to be drawn with OP_OVER // because shadow drawing already applies op on the result. op = gfx::CompositionOp::OP_OVER; } // Now set up the filter draw target. if (ctx->NeedToApplyFilter()) { bounds.RoundOut(); gfx::IntRect intBounds; if (!bounds.ToIntRect(&intBounds)) { return; } mFilterTarget = MakeUnique( ctx, mTarget, offsetToFinalDT, intBounds, gfx::RoundedToInt(boundsAfterFilter), op); mTarget = mFilterTarget->DT(); } } ~AdjustedTarget() { // The order in which the targets are finalized is important. // Filters are inside, any shadow applies to the post-filter results. mFilterTarget.reset(); mShadowTarget.reset(); } operator DrawTarget*() { return mTarget; } DrawTarget* operator->() MOZ_NO_ADDREF_RELEASE_ON_RETURN { return mTarget; } private: gfx::Rect MaxSourceNeededBoundsForFilter(const gfx::Rect& aDestBounds, CanvasRenderingContext2D *ctx) { if (!ctx->NeedToApplyFilter()) { return aDestBounds; } nsIntRegion sourceGraphicNeededRegion; nsIntRegion fillPaintNeededRegion; nsIntRegion strokePaintNeededRegion; FilterSupport::ComputeSourceNeededRegions( ctx->CurrentState().filter, gfx::RoundedToInt(aDestBounds), sourceGraphicNeededRegion, fillPaintNeededRegion, strokePaintNeededRegion); return gfx::Rect(sourceGraphicNeededRegion.GetBounds()); } gfx::Rect MaxSourceNeededBoundsForShadow(const gfx::Rect& aDestBounds, CanvasRenderingContext2D *ctx) { if (!ctx->NeedToDrawShadow()) { return aDestBounds; } const ContextState &state = ctx->CurrentState(); gfx::Rect sourceBounds = aDestBounds - state.shadowOffset; sourceBounds.Inflate(state.ShadowBlurRadius()); // Union the shadow source with the original rect because we're going to // draw both. return sourceBounds.Union(aDestBounds); } gfx::Rect BoundsAfterFilter(const gfx::Rect& aBounds, CanvasRenderingContext2D *ctx) { if (!ctx->NeedToApplyFilter()) { return aBounds; } gfx::Rect bounds(aBounds); bounds.RoundOut(); gfx::IntRect intBounds; if (!bounds.ToIntRect(&intBounds)) { return gfx::Rect(); } nsIntRegion extents = gfx::FilterSupport::ComputePostFilterExtents(ctx->CurrentState().filter, intBounds); return gfx::Rect(extents.GetBounds()); } RefPtr mTarget; UniquePtr mShadowTarget; UniquePtr mFilterTarget; }; void CanvasPattern::SetTransform(SVGMatrix& aMatrix) { mTransform = ToMatrix(aMatrix.GetMatrix()); } void CanvasGradient::AddColorStop(float offset, const nsAString& colorstr, ErrorResult& rv) { if (offset < 0.0 || offset > 1.0) { rv.Throw(NS_ERROR_DOM_INDEX_SIZE_ERR); return; } nsCSSValue value; nsCSSParser parser; if (!parser.ParseColorString(colorstr, nullptr, 0, value)) { rv.Throw(NS_ERROR_DOM_SYNTAX_ERR); return; } nscolor color; nsCOMPtr presShell = mContext ? mContext->GetPresShell() : nullptr; if (!nsRuleNode::ComputeColor(value, presShell ? presShell->GetPresContext() : nullptr, nullptr, color)) { rv.Throw(NS_ERROR_DOM_SYNTAX_ERR); return; } mStops = nullptr; GradientStop newStop; newStop.offset = offset; newStop.color = Color::FromABGR(color); mRawStops.AppendElement(newStop); } NS_IMPL_CYCLE_COLLECTION_ROOT_NATIVE(CanvasGradient, AddRef) NS_IMPL_CYCLE_COLLECTION_UNROOT_NATIVE(CanvasGradient, Release) NS_IMPL_CYCLE_COLLECTION_WRAPPERCACHE(CanvasGradient, mContext) NS_IMPL_CYCLE_COLLECTION_ROOT_NATIVE(CanvasPattern, AddRef) NS_IMPL_CYCLE_COLLECTION_UNROOT_NATIVE(CanvasPattern, Release) NS_IMPL_CYCLE_COLLECTION_WRAPPERCACHE(CanvasPattern, mContext) class CanvasDrawObserver { public: explicit CanvasDrawObserver(CanvasRenderingContext2D* aCanvasContext); // Only enumerate draw calls that could affect the heuristic enum DrawCallType { PutImageData, GetImageData, DrawImage }; // This is the one that we call on relevant draw calls and count // GPU vs. CPU preferrable calls... void DidDrawCall(DrawCallType aType); // When this returns true, the observer is done making the decisions. // Right now, we expect to get rid of the observer after the FrameEnd // returns true, though the decision could eventually change if the // function calls shift. If we change to monitor the functions called // and make decisions to change more than once, we would probably want // FrameEnd to reset the timer and counters as it returns true. bool FrameEnd(); private: // These values will be picked up from preferences: int32_t mMinFramesBeforeDecision; float mMinSecondsBeforeDecision; int32_t mMinCallsBeforeDecision; CanvasRenderingContext2D* mCanvasContext; int32_t mSoftwarePreferredCalls; int32_t mGPUPreferredCalls; int32_t mFramesRendered; TimeStamp mCreationTime; }; // We are not checking for the validity of the preference values. For example, // negative values will have an effect of a quick exit, so no harm done. CanvasDrawObserver::CanvasDrawObserver(CanvasRenderingContext2D* aCanvasContext) : mMinFramesBeforeDecision(gfxPrefs::CanvasAutoAccelerateMinFrames()) , mMinSecondsBeforeDecision(gfxPrefs::CanvasAutoAccelerateMinSeconds()) , mMinCallsBeforeDecision(gfxPrefs::CanvasAutoAccelerateMinCalls()) , mCanvasContext(aCanvasContext) , mSoftwarePreferredCalls(0) , mGPUPreferredCalls(0) , mFramesRendered(0) , mCreationTime(TimeStamp::NowLoRes()) {} void CanvasDrawObserver::DidDrawCall(DrawCallType aType) { switch (aType) { case PutImageData: case GetImageData: if (mGPUPreferredCalls == 0 && mSoftwarePreferredCalls == 0) { mCreationTime = TimeStamp::NowLoRes(); } mSoftwarePreferredCalls++; break; case DrawImage: if (mGPUPreferredCalls == 0 && mSoftwarePreferredCalls == 0) { mCreationTime = TimeStamp::NowLoRes(); } mGPUPreferredCalls++; break; } } // If we return true, the observer is done making the decisions... bool CanvasDrawObserver::FrameEnd() { mFramesRendered++; // We log the first mMinFramesBeforeDecision frames of any // canvas object then make a call to determine whether it should // be GPU or CPU backed if ((mFramesRendered >= mMinFramesBeforeDecision) || ((TimeStamp::NowLoRes() - mCreationTime).ToSeconds()) > mMinSecondsBeforeDecision) { // If we don't have enough data, don't bother changing... if (mGPUPreferredCalls > mMinCallsBeforeDecision || mSoftwarePreferredCalls > mMinCallsBeforeDecision) { if (mGPUPreferredCalls >= mSoftwarePreferredCalls) { mCanvasContext->SwitchRenderingMode(CanvasRenderingContext2D::RenderingMode::OpenGLBackendMode); } else { mCanvasContext->SwitchRenderingMode(CanvasRenderingContext2D::RenderingMode::SoftwareBackendMode); } } // If we ever redesign this class to constantly monitor the functions // and keep making decisions, we would probably want to reset the counters // and the timers here... return true; } return false; } class CanvasRenderingContext2DUserData : public LayerUserData { public: explicit CanvasRenderingContext2DUserData(CanvasRenderingContext2D *aContext) : mContext(aContext) { aContext->mUserDatas.AppendElement(this); } ~CanvasRenderingContext2DUserData() { if (mContext) { mContext->mUserDatas.RemoveElement(this); } } static void PreTransactionCallback(void* aData) { CanvasRenderingContext2DUserData* self = static_cast(aData); CanvasRenderingContext2D* context = self->mContext; if (!context || !context->mTarget) return; // Since SkiaGL default to store drawing command until flush // We will have to flush it before present. context->mTarget->Flush(); context->ReturnTarget(); } static void DidTransactionCallback(void* aData) { CanvasRenderingContext2DUserData* self = static_cast(aData); if (self->mContext) { self->mContext->MarkContextClean(); if (self->mContext->mDrawObserver) { if (self->mContext->mDrawObserver->FrameEnd()) { // Note that this call deletes and nulls out mDrawObserver: self->mContext->RemoveDrawObserver(); } } } } bool IsForContext(CanvasRenderingContext2D *aContext) { return mContext == aContext; } void Forget() { mContext = nullptr; } private: CanvasRenderingContext2D *mContext; }; NS_IMPL_CYCLE_COLLECTING_ADDREF(CanvasRenderingContext2D) NS_IMPL_CYCLE_COLLECTING_RELEASE(CanvasRenderingContext2D) NS_IMPL_CYCLE_COLLECTION_CLASS(CanvasRenderingContext2D) NS_IMPL_CYCLE_COLLECTION_UNLINK_BEGIN(CanvasRenderingContext2D) // Make sure we remove ourselves from the list of demotable contexts (raw pointers), // since we're logically destructed at this point. CanvasRenderingContext2D::RemoveDemotableContext(tmp); NS_IMPL_CYCLE_COLLECTION_UNLINK(mCanvasElement) for (uint32_t i = 0; i < tmp->mStyleStack.Length(); i++) { ImplCycleCollectionUnlink(tmp->mStyleStack[i].patternStyles[Style::STROKE]); ImplCycleCollectionUnlink(tmp->mStyleStack[i].patternStyles[Style::FILL]); ImplCycleCollectionUnlink(tmp->mStyleStack[i].gradientStyles[Style::STROKE]); ImplCycleCollectionUnlink(tmp->mStyleStack[i].gradientStyles[Style::FILL]); } for (size_t x = 0 ; x < tmp->mHitRegionsOptions.Length(); x++) { RegionInfo& info = tmp->mHitRegionsOptions[x]; if (info.mElement) { ImplCycleCollectionUnlink(info.mElement); } } NS_IMPL_CYCLE_COLLECTION_UNLINK_PRESERVED_WRAPPER NS_IMPL_CYCLE_COLLECTION_UNLINK_END NS_IMPL_CYCLE_COLLECTION_TRAVERSE_BEGIN(CanvasRenderingContext2D) NS_IMPL_CYCLE_COLLECTION_TRAVERSE(mCanvasElement) for (uint32_t i = 0; i < tmp->mStyleStack.Length(); i++) { ImplCycleCollectionTraverse(cb, tmp->mStyleStack[i].patternStyles[Style::STROKE], "Stroke CanvasPattern"); ImplCycleCollectionTraverse(cb, tmp->mStyleStack[i].patternStyles[Style::FILL], "Fill CanvasPattern"); ImplCycleCollectionTraverse(cb, tmp->mStyleStack[i].gradientStyles[Style::STROKE], "Stroke CanvasGradient"); ImplCycleCollectionTraverse(cb, tmp->mStyleStack[i].gradientStyles[Style::FILL], "Fill CanvasGradient"); } for (size_t x = 0 ; x < tmp->mHitRegionsOptions.Length(); x++) { RegionInfo& info = tmp->mHitRegionsOptions[x]; if (info.mElement) { ImplCycleCollectionTraverse(cb, info.mElement, "Hit region fallback element"); } } NS_IMPL_CYCLE_COLLECTION_TRAVERSE_SCRIPT_OBJECTS NS_IMPL_CYCLE_COLLECTION_TRAVERSE_END NS_IMPL_CYCLE_COLLECTION_TRACE_WRAPPERCACHE(CanvasRenderingContext2D) NS_IMPL_CYCLE_COLLECTION_CAN_SKIP_BEGIN(CanvasRenderingContext2D) if (nsCCUncollectableMarker::sGeneration && tmp->IsBlack()) { dom::Element* canvasElement = tmp->mCanvasElement; if (canvasElement) { if (canvasElement->IsPurple()) { canvasElement->RemovePurple(); } dom::Element::MarkNodeChildren(canvasElement); } return true; } NS_IMPL_CYCLE_COLLECTION_CAN_SKIP_END NS_IMPL_CYCLE_COLLECTION_CAN_SKIP_IN_CC_BEGIN(CanvasRenderingContext2D) return nsCCUncollectableMarker::sGeneration && tmp->IsBlack(); NS_IMPL_CYCLE_COLLECTION_CAN_SKIP_IN_CC_END NS_IMPL_CYCLE_COLLECTION_CAN_SKIP_THIS_BEGIN(CanvasRenderingContext2D) return nsCCUncollectableMarker::sGeneration && tmp->IsBlack(); NS_IMPL_CYCLE_COLLECTION_CAN_SKIP_THIS_END NS_INTERFACE_MAP_BEGIN_CYCLE_COLLECTION(CanvasRenderingContext2D) NS_WRAPPERCACHE_INTERFACE_MAP_ENTRY NS_INTERFACE_MAP_ENTRY(nsICanvasRenderingContextInternal) NS_INTERFACE_MAP_ENTRY(nsISupports) NS_INTERFACE_MAP_END /** ** CanvasRenderingContext2D impl **/ // Initialize our static variables. uint32_t CanvasRenderingContext2D::sNumLivingContexts = 0; DrawTarget* CanvasRenderingContext2D::sErrorTarget = nullptr; CanvasRenderingContext2D::CanvasRenderingContext2D() : mRenderingMode(RenderingMode::OpenGLBackendMode) #ifdef USE_SKIA_GPU , mVideoTexture(0) #endif // these are the default values from the Canvas spec , mWidth(0), mHeight(0) , mZero(false), mOpaque(false) , mResetLayer(true) , mIPC(false) , mIsSkiaGL(false) , mDrawObserver(nullptr) , mIsEntireFrameInvalid(false) , mPredictManyRedrawCalls(false) , mIsCapturedFrameInvalid(false) , mPathTransformWillUpdate(false) , mInvalidateCount(0) { sNumLivingContexts++; // The default is to use OpenGL mode if (!gfxPlatform::GetPlatform()->UseAcceleratedSkiaCanvas()) { mRenderingMode = RenderingMode::SoftwareBackendMode; } if (gfxPlatform::GetPlatform()->HaveChoiceOfHWAndSWCanvas()) { mDrawObserver = new CanvasDrawObserver(this); } } CanvasRenderingContext2D::~CanvasRenderingContext2D() { RemoveDrawObserver(); RemovePostRefreshObserver(); Reset(); // Drop references from all CanvasRenderingContext2DUserData to this context for (uint32_t i = 0; i < mUserDatas.Length(); ++i) { mUserDatas[i]->Forget(); } sNumLivingContexts--; if (!sNumLivingContexts) { NS_IF_RELEASE(sErrorTarget); } #ifdef USE_SKIA_GPU if (mVideoTexture) { MOZ_ASSERT(gfxPlatform::GetPlatform()->GetSkiaGLGlue(), "null SkiaGLGlue"); gfxPlatform::GetPlatform()->GetSkiaGLGlue()->GetGLContext()->MakeCurrent(); gfxPlatform::GetPlatform()->GetSkiaGLGlue()->GetGLContext()->fDeleteTextures(1, &mVideoTexture); } #endif RemoveDemotableContext(this); } JSObject* CanvasRenderingContext2D::WrapObject(JSContext *cx, JS::Handle aGivenProto) { return CanvasRenderingContext2DBinding::Wrap(cx, this, aGivenProto); } bool CanvasRenderingContext2D::ParseColor(const nsAString& aString, nscolor* aColor) { nsIDocument* document = mCanvasElement ? mCanvasElement->OwnerDoc() : nullptr; // Pass the CSS Loader object to the parser, to allow parser error // reports to include the outer window ID. nsCSSParser parser(document ? document->CSSLoader() : nullptr); nsCSSValue value; if (!parser.ParseColorString(aString, nullptr, 0, value)) { return false; } if (value.IsNumericColorUnit()) { // if we already have a color we can just use it directly *aColor = value.GetColorValue(); } else { // otherwise resolve it nsCOMPtr presShell = GetPresShell(); nsRefPtr parentContext; if (mCanvasElement && mCanvasElement->IsInDoc()) { // Inherit from the canvas element. parentContext = nsComputedDOMStyle::GetStyleContextForElement( mCanvasElement, nullptr, presShell); } unused << nsRuleNode::ComputeColor( value, presShell ? presShell->GetPresContext() : nullptr, parentContext, *aColor); } return true; } nsresult CanvasRenderingContext2D::Reset() { if (mCanvasElement) { mCanvasElement->InvalidateCanvas(); } // only do this for non-docshell created contexts, // since those are the ones that we created a surface for if (mTarget && IsTargetValid() && !mDocShell) { gCanvasAzureMemoryUsed -= mWidth * mHeight * 4; } ReturnTarget(); mTarget = nullptr; mBufferProvider = nullptr; // reset hit regions mHitRegionsOptions.ClearAndRetainStorage(); // Since the target changes the backing texture will change, and this will // no longer be valid. mIsEntireFrameInvalid = false; mPredictManyRedrawCalls = false; mIsCapturedFrameInvalid = false; return NS_OK; } void CanvasRenderingContext2D::SetStyleFromString(const nsAString& str, Style whichStyle) { MOZ_ASSERT(!str.IsVoid()); nscolor color; if (!ParseColor(str, &color)) { return; } CurrentState().SetColorStyle(whichStyle, color); } void CanvasRenderingContext2D::GetStyleAsUnion(OwningStringOrCanvasGradientOrCanvasPattern& aValue, Style aWhichStyle) { const ContextState &state = CurrentState(); if (state.patternStyles[aWhichStyle]) { aValue.SetAsCanvasPattern() = state.patternStyles[aWhichStyle]; } else if (state.gradientStyles[aWhichStyle]) { aValue.SetAsCanvasGradient() = state.gradientStyles[aWhichStyle]; } else { StyleColorToString(state.colorStyles[aWhichStyle], aValue.SetAsString()); } } // static void CanvasRenderingContext2D::StyleColorToString(const nscolor& aColor, nsAString& aStr) { // We can't reuse the normal CSS color stringification code, // because the spec calls for a different algorithm for canvas. if (NS_GET_A(aColor) == 255) { CopyUTF8toUTF16(nsPrintfCString("#%02x%02x%02x", NS_GET_R(aColor), NS_GET_G(aColor), NS_GET_B(aColor)), aStr); } else { CopyUTF8toUTF16(nsPrintfCString("rgba(%d, %d, %d, ", NS_GET_R(aColor), NS_GET_G(aColor), NS_GET_B(aColor)), aStr); aStr.AppendFloat(nsStyleUtil::ColorComponentToFloat(NS_GET_A(aColor))); aStr.Append(')'); } } nsresult CanvasRenderingContext2D::Redraw() { mIsCapturedFrameInvalid = true; if (mIsEntireFrameInvalid) { return NS_OK; } mIsEntireFrameInvalid = true; if (!mCanvasElement) { NS_ASSERTION(mDocShell, "Redraw with no canvas element or docshell!"); return NS_OK; } nsSVGEffects::InvalidateDirectRenderingObservers(mCanvasElement); mCanvasElement->InvalidateCanvasContent(nullptr); return NS_OK; } void CanvasRenderingContext2D::Redraw(const gfx::Rect &r) { mIsCapturedFrameInvalid = true; ++mInvalidateCount; if (mIsEntireFrameInvalid) { return; } if (mPredictManyRedrawCalls || mInvalidateCount > kCanvasMaxInvalidateCount) { Redraw(); return; } if (!mCanvasElement) { NS_ASSERTION(mDocShell, "Redraw with no canvas element or docshell!"); return; } nsSVGEffects::InvalidateDirectRenderingObservers(mCanvasElement); mCanvasElement->InvalidateCanvasContent(&r); } void CanvasRenderingContext2D::DidRefresh() { if (IsTargetValid() && SkiaGLTex()) { SkiaGLGlue* glue = gfxPlatform::GetPlatform()->GetSkiaGLGlue(); MOZ_ASSERT(glue); auto gl = glue->GetGLContext(); gl->FlushIfHeavyGLCallsSinceLastFlush(); } } void CanvasRenderingContext2D::RedrawUser(const gfxRect& r) { mIsCapturedFrameInvalid = true; if (mIsEntireFrameInvalid) { ++mInvalidateCount; return; } gfx::Rect newr = mTarget->GetTransform().TransformBounds(ToRect(r)); Redraw(newr); } bool CanvasRenderingContext2D::SwitchRenderingMode(RenderingMode aRenderingMode) { if (!IsTargetValid() || mRenderingMode == aRenderingMode) { return false; } #ifdef USE_SKIA_GPU if (mRenderingMode == RenderingMode::OpenGLBackendMode) { if (mVideoTexture) { gfxPlatform::GetPlatform()->GetSkiaGLGlue()->GetGLContext()->MakeCurrent(); gfxPlatform::GetPlatform()->GetSkiaGLGlue()->GetGLContext()->fDeleteTextures(1, &mVideoTexture); } mCurrentVideoSize.width = 0; mCurrentVideoSize.height = 0; } #endif RefPtr snapshot; Matrix transform; if (mTarget) { snapshot = mTarget->Snapshot(); transform = mTarget->GetTransform(); } else { MOZ_ASSERT(mBufferProvider); // When mBufferProvider is true but we have no mTarget, our current state's // transform is always valid. See ReturnTarget(). transform = CurrentState().transform; snapshot = mBufferProvider->GetSnapshot(); } mTarget = nullptr; mBufferProvider = nullptr; mResetLayer = true; // Recreate target using the new rendering mode RenderingMode attemptedMode = EnsureTarget(aRenderingMode); if (!IsTargetValid()) return false; // We succeeded, so update mRenderingMode to reflect reality mRenderingMode = attemptedMode; // Restore the content from the old DrawTarget gfx::Rect r(0, 0, mWidth, mHeight); mTarget->DrawSurface(snapshot, r, r); // Restore the clips and transform for (uint32_t i = 0; i < CurrentState().clipsPushed.size(); i++) { mTarget->PushClip(CurrentState().clipsPushed[i]); } mTarget->SetTransform(transform); return true; } void CanvasRenderingContext2D::Demote() { if (SwitchRenderingMode(RenderingMode::SoftwareBackendMode)) { RemoveDemotableContext(this); } } std::vector& CanvasRenderingContext2D::DemotableContexts() { // This is a list of raw pointers to cycle-collected objects. We need to ensure // that we remove elements from it during UNLINK (which can happen considerably before // the actual destructor) since the object is logically destroyed at that point // and will be in an inconsistant state. static std::vector contexts; return contexts; } void CanvasRenderingContext2D::DemoteOldestContextIfNecessary() { const size_t kMaxContexts = 64; std::vector& contexts = DemotableContexts(); if (contexts.size() < kMaxContexts) return; CanvasRenderingContext2D* oldest = contexts.front(); if (oldest->SwitchRenderingMode(RenderingMode::SoftwareBackendMode)) { RemoveDemotableContext(oldest); } } void CanvasRenderingContext2D::AddDemotableContext(CanvasRenderingContext2D* context) { std::vector::iterator iter = std::find(DemotableContexts().begin(), DemotableContexts().end(), context); if (iter != DemotableContexts().end()) return; DemotableContexts().push_back(context); } void CanvasRenderingContext2D::RemoveDemotableContext(CanvasRenderingContext2D* context) { std::vector::iterator iter = std::find(DemotableContexts().begin(), DemotableContexts().end(), context); if (iter != DemotableContexts().end()) DemotableContexts().erase(iter); } bool CanvasRenderingContext2D::CheckSizeForSkiaGL(IntSize size) { MOZ_ASSERT(NS_IsMainThread()); int minsize = Preferences::GetInt("gfx.canvas.min-size-for-skia-gl", 128); if (size.width < minsize || size.height < minsize) { return false; } // Maximum pref allows 3 different options: // 0 means unlimited size // > 0 means use value as an absolute threshold // < 0 means use the number of screen pixels as a threshold int maxsize = Preferences::GetInt("gfx.canvas.max-size-for-skia-gl", 0); // unlimited max size if (!maxsize) { return true; } // absolute max size threshold if (maxsize > 0) { return size.width <= maxsize && size.height <= maxsize; } // Cache the number of pixels on the primary screen static int32_t gScreenPixels = -1; if (gScreenPixels < 0) { // Default to historical mobile screen size of 980x480, like FishIEtank. // In addition, allow skia use up to this size even if the screen is smaller. // A lot content expects this size to work well. // See Bug 999841 if (gfxPlatform::GetPlatform()->HasEnoughTotalSystemMemoryForSkiaGL()) { gScreenPixels = 980 * 480; } nsCOMPtr screenManager = do_GetService("@mozilla.org/gfx/screenmanager;1"); if (screenManager) { nsCOMPtr primaryScreen; screenManager->GetPrimaryScreen(getter_AddRefs(primaryScreen)); if (primaryScreen) { int32_t x, y, width, height; primaryScreen->GetRect(&x, &y, &width, &height); gScreenPixels = std::max(gScreenPixels, width * height); } } } // Just always use a scale of 1.0. It can be changed if a lot of contents need it. static double gDefaultScale = 1.0; double scale = gDefaultScale > 0 ? gDefaultScale : 1.0; int32_t threshold = ceil(scale * scale * gScreenPixels); // screen size acts as max threshold return threshold < 0 || (size.width * size.height) <= threshold; } CanvasRenderingContext2D::RenderingMode CanvasRenderingContext2D::EnsureTarget(RenderingMode aRenderingMode) { // This would make no sense, so make sure we don't get ourselves in a mess MOZ_ASSERT(mRenderingMode != RenderingMode::DefaultBackendMode); RenderingMode mode = (aRenderingMode == RenderingMode::DefaultBackendMode) ? mRenderingMode : aRenderingMode; if (mTarget && mode == mRenderingMode) { return mRenderingMode; } if (mBufferProvider && mode == mRenderingMode) { mTarget = mBufferProvider->GetDT(IntRect(IntPoint(), IntSize(mWidth, mHeight))); if (mTarget) { return mRenderingMode; } else { mBufferProvider = nullptr; } } mIsSkiaGL = false; // Check that the dimensions are sane IntSize size(mWidth, mHeight); if (size.width <= gfxPrefs::MaxCanvasSize() && size.height <= gfxPrefs::MaxCanvasSize() && size.width >= 0 && size.height >= 0) { SurfaceFormat format = GetSurfaceFormat(); nsIDocument* ownerDoc = nullptr; if (mCanvasElement) { ownerDoc = mCanvasElement->OwnerDoc(); } nsRefPtr layerManager = nullptr; if (ownerDoc) { layerManager = nsContentUtils::PersistentLayerManagerForDocument(ownerDoc); } if (layerManager) { if (mode == RenderingMode::OpenGLBackendMode && gfxPlatform::GetPlatform()->UseAcceleratedSkiaCanvas() && CheckSizeForSkiaGL(size)) { DemoteOldestContextIfNecessary(); mBufferProvider = nullptr; #if USE_SKIA_GPU SkiaGLGlue* glue = gfxPlatform::GetPlatform()->GetSkiaGLGlue(); if (glue && glue->GetGrContext() && glue->GetGLContext()) { mTarget = Factory::CreateDrawTargetSkiaWithGrContext(glue->GetGrContext(), size, format); if (mTarget) { AddDemotableContext(this); mBufferProvider = new PersistentBufferProviderBasic(mTarget); mIsSkiaGL = true; } else { printf_stderr("Failed to create a SkiaGL DrawTarget, falling back to software\n"); mode = RenderingMode::SoftwareBackendMode; } } #endif } if (!mBufferProvider) { mBufferProvider = layerManager->CreatePersistentBufferProvider(size, format); } } if (mBufferProvider) { mTarget = mBufferProvider->GetDT(IntRect(IntPoint(), IntSize(mWidth, mHeight))); } else if (!mTarget) { mTarget = gfxPlatform::GetPlatform()->CreateOffscreenCanvasDrawTarget(size, format); mode = RenderingMode::SoftwareBackendMode; } } if (mTarget) { static bool registered = false; if (!registered) { registered = true; RegisterStrongMemoryReporter(new Canvas2dPixelsReporter()); } gCanvasAzureMemoryUsed += mWidth * mHeight * 4; JSContext* context = nsContentUtils::GetCurrentJSContext(); if (context) { JS_updateMallocCounter(context, mWidth * mHeight * 4); } mTarget->ClearRect(gfx::Rect(Point(0, 0), Size(mWidth, mHeight))); if (mTarget->GetBackendType() == gfx::BackendType::CAIRO) { // Cairo doesn't play well with huge clips. When given a very big clip it // will try to allocate big mask surface without taking the target // size into account which can cause OOM. See bug 1034593. // This limits the clip extents to the size of the canvas. // A fix in Cairo would probably be preferable, but requires somewhat // invasive changes. mTarget->PushClipRect(gfx::Rect(Point(0, 0), Size(mWidth, mHeight))); } // Force a full layer transaction since we didn't have a layer before // and now we might need one. if (mCanvasElement) { mCanvasElement->InvalidateCanvas(); } // Calling Redraw() tells our invalidation machinery that the entire // canvas is already invalid, which can speed up future drawing. Redraw(); } else { EnsureErrorTarget(); mTarget = sErrorTarget; } return mode; } int32_t CanvasRenderingContext2D::GetWidth() const { return mWidth; } int32_t CanvasRenderingContext2D::GetHeight() const { return mHeight; } NS_IMETHODIMP CanvasRenderingContext2D::SetDimensions(int32_t width, int32_t height) { ClearTarget(); // Zero sized surfaces can cause problems. mZero = false; if (height == 0) { height = 1; mZero = true; } if (width == 0) { width = 1; mZero = true; } mWidth = width; mHeight = height; return NS_OK; } void CanvasRenderingContext2D::ClearTarget() { Reset(); mResetLayer = true; // set up the initial canvas defaults mStyleStack.Clear(); mPathBuilder = nullptr; mPath = nullptr; mDSPathBuilder = nullptr; ContextState *state = mStyleStack.AppendElement(); state->globalAlpha = 1.0; state->colorStyles[Style::FILL] = NS_RGB(0,0,0); state->colorStyles[Style::STROKE] = NS_RGB(0,0,0); state->shadowColor = NS_RGBA(0,0,0,0); // For vertical writing-mode, unless text-orientation is sideways, // we'll modify the initial value of textBaseline to 'middle'. nsRefPtr canvasStyle; if (mCanvasElement && mCanvasElement->IsInDoc()) { nsCOMPtr presShell = GetPresShell(); if (presShell) { canvasStyle = nsComputedDOMStyle::GetStyleContextForElement(mCanvasElement, nullptr, presShell); if (canvasStyle) { WritingMode wm(canvasStyle); if (wm.IsVertical() && !wm.IsSideways()) { state->textBaseline = TextBaseline::MIDDLE; } } } } } void CanvasRenderingContext2D::ReturnTarget() { if (mTarget && mBufferProvider) { CurrentState().transform = mTarget->GetTransform(); DrawTarget* oldDT = mTarget; mTarget = nullptr; mBufferProvider->ReturnAndUseDT(oldDT); } } NS_IMETHODIMP CanvasRenderingContext2D::InitializeWithSurface(nsIDocShell *shell, gfxASurface *surface, int32_t width, int32_t height) { RemovePostRefreshObserver(); mDocShell = shell; AddPostRefreshObserverIfNecessary(); SetDimensions(width, height); mTarget = gfxPlatform::GetPlatform()-> CreateDrawTargetForSurface(surface, IntSize(width, height)); if (!mTarget) { EnsureErrorTarget(); mTarget = sErrorTarget; } if (mTarget->GetBackendType() == gfx::BackendType::CAIRO) { // Cf comment in EnsureTarget mTarget->PushClipRect(gfx::Rect(Point(0, 0), Size(mWidth, mHeight))); } return NS_OK; } NS_IMETHODIMP CanvasRenderingContext2D::SetIsOpaque(bool isOpaque) { if (isOpaque != mOpaque) { mOpaque = isOpaque; ClearTarget(); } return NS_OK; } NS_IMETHODIMP CanvasRenderingContext2D::SetIsIPC(bool isIPC) { if (isIPC != mIPC) { mIPC = isIPC; ClearTarget(); } return NS_OK; } NS_IMETHODIMP CanvasRenderingContext2D::SetContextOptions(JSContext* aCx, JS::Handle aOptions) { if (aOptions.isNullOrUndefined()) { return NS_OK; } // This shouldn't be called before drawing starts, so there should be no drawtarget yet MOZ_ASSERT(!mTarget); ContextAttributes2D attributes; NS_ENSURE_TRUE(attributes.Init(aCx, aOptions), NS_ERROR_UNEXPECTED); if (Preferences::GetBool("gfx.canvas.willReadFrequently.enable", false)) { // Use software when there is going to be a lot of readback if (attributes.mWillReadFrequently) { // We want to lock into software, so remove the observer that // may potentially change that... RemoveDrawObserver(); mRenderingMode = RenderingMode::SoftwareBackendMode; } } if (!attributes.mAlpha) { SetIsOpaque(true); } return NS_OK; } void CanvasRenderingContext2D::GetImageBuffer(uint8_t** aImageBuffer, int32_t* aFormat) { *aImageBuffer = nullptr; *aFormat = 0; EnsureTarget(); RefPtr snapshot = mTarget->Snapshot(); if (!snapshot) { return; } RefPtr data = snapshot->GetDataSurface(); if (!data || data->GetSize() != IntSize(mWidth, mHeight)) { return; } *aImageBuffer = SurfaceToPackedBGRA(data); *aFormat = imgIEncoder::INPUT_FORMAT_HOSTARGB; } nsString CanvasRenderingContext2D::GetHitRegion(const mozilla::gfx::Point& aPoint) { for (size_t x = 0 ; x < mHitRegionsOptions.Length(); x++) { RegionInfo& info = mHitRegionsOptions[x]; if (info.mPath->ContainsPoint(aPoint, Matrix())) { return info.mId; } } return nsString(); } NS_IMETHODIMP CanvasRenderingContext2D::GetInputStream(const char *aMimeType, const char16_t *aEncoderOptions, nsIInputStream **aStream) { nsCString enccid("@mozilla.org/image/encoder;2?type="); enccid += aMimeType; nsCOMPtr encoder = do_CreateInstance(enccid.get()); if (!encoder) { return NS_ERROR_FAILURE; } nsAutoArrayPtr imageBuffer; int32_t format = 0; GetImageBuffer(getter_Transfers(imageBuffer), &format); if (!imageBuffer) { return NS_ERROR_FAILURE; } return ImageEncoder::GetInputStream(mWidth, mHeight, imageBuffer, format, encoder, aEncoderOptions, aStream); } SurfaceFormat CanvasRenderingContext2D::GetSurfaceFormat() const { return mOpaque ? SurfaceFormat::B8G8R8X8 : SurfaceFormat::B8G8R8A8; } // // state // void CanvasRenderingContext2D::Save() { EnsureTarget(); mStyleStack[mStyleStack.Length() - 1].transform = mTarget->GetTransform(); mStyleStack.SetCapacity(mStyleStack.Length() + 1); mStyleStack.AppendElement(CurrentState()); } void CanvasRenderingContext2D::Restore() { if (mStyleStack.Length() - 1 == 0) return; TransformWillUpdate(); for (uint32_t i = 0; i < CurrentState().clipsPushed.size(); i++) { mTarget->PopClip(); } mStyleStack.RemoveElementAt(mStyleStack.Length() - 1); mTarget->SetTransform(CurrentState().transform); } // // transformations // void CanvasRenderingContext2D::Scale(double x, double y, ErrorResult& error) { TransformWillUpdate(); if (!IsTargetValid()) { error.Throw(NS_ERROR_FAILURE); return; } Matrix newMatrix = mTarget->GetTransform(); newMatrix.PreScale(x, y); if (!newMatrix.IsFinite()) { return; } mTarget->SetTransform(newMatrix); } void CanvasRenderingContext2D::Rotate(double angle, ErrorResult& error) { TransformWillUpdate(); if (!IsTargetValid()) { error.Throw(NS_ERROR_FAILURE); return; } Matrix newMatrix = Matrix::Rotation(angle) * mTarget->GetTransform(); if (!newMatrix.IsFinite()) { return; } mTarget->SetTransform(newMatrix); } void CanvasRenderingContext2D::Translate(double x, double y, ErrorResult& error) { TransformWillUpdate(); if (!IsTargetValid()) { error.Throw(NS_ERROR_FAILURE); return; } Matrix newMatrix = mTarget->GetTransform(); newMatrix.PreTranslate(x, y); if (!newMatrix.IsFinite()) { return; } mTarget->SetTransform(newMatrix); } void CanvasRenderingContext2D::Transform(double m11, double m12, double m21, double m22, double dx, double dy, ErrorResult& error) { TransformWillUpdate(); if (!IsTargetValid()) { error.Throw(NS_ERROR_FAILURE); return; } Matrix newMatrix(m11, m12, m21, m22, dx, dy); newMatrix *= mTarget->GetTransform(); if (!newMatrix.IsFinite()) { return; } mTarget->SetTransform(newMatrix); } void CanvasRenderingContext2D::SetTransform(double m11, double m12, double m21, double m22, double dx, double dy, ErrorResult& error) { TransformWillUpdate(); if (!IsTargetValid()) { error.Throw(NS_ERROR_FAILURE); return; } Matrix matrix(m11, m12, m21, m22, dx, dy); if (!matrix.IsFinite()) { return; } mTarget->SetTransform(matrix); } void CanvasRenderingContext2D::ResetTransform(ErrorResult& error) { SetTransform(1.0, 0.0, 0.0, 1.0, 0.0, 0.0, error); } static void MatrixToJSObject(JSContext* cx, const Matrix& matrix, JS::MutableHandle result, ErrorResult& error) { double elts[6] = { matrix._11, matrix._12, matrix._21, matrix._22, matrix._31, matrix._32 }; // XXX Should we enter GetWrapper()'s compartment? JS::Rooted val(cx); if (!ToJSValue(cx, elts, &val)) { error.Throw(NS_ERROR_OUT_OF_MEMORY); } else { result.set(&val.toObject()); } } static bool ObjectToMatrix(JSContext* cx, JS::Handle obj, Matrix& matrix, ErrorResult& error) { uint32_t length; if (!JS_GetArrayLength(cx, obj, &length) || length != 6) { // Not an array-like thing or wrong size error.Throw(NS_ERROR_INVALID_ARG); return false; } Float* elts[] = { &matrix._11, &matrix._12, &matrix._21, &matrix._22, &matrix._31, &matrix._32 }; for (uint32_t i = 0; i < 6; ++i) { JS::Rooted elt(cx); double d; if (!JS_GetElement(cx, obj, i, &elt)) { error.Throw(NS_ERROR_FAILURE); return false; } if (!CoerceDouble(elt, &d)) { error.Throw(NS_ERROR_INVALID_ARG); return false; } if (!FloatValidate(d)) { // This is weird, but it's the behavior of SetTransform() return false; } *elts[i] = Float(d); } return true; } void CanvasRenderingContext2D::SetMozCurrentTransform(JSContext* cx, JS::Handle currentTransform, ErrorResult& error) { EnsureTarget(); if (!IsTargetValid()) { error.Throw(NS_ERROR_FAILURE); return; } Matrix newCTM; if (ObjectToMatrix(cx, currentTransform, newCTM, error)) { mTarget->SetTransform(newCTM); } } void CanvasRenderingContext2D::GetMozCurrentTransform(JSContext* cx, JS::MutableHandle result, ErrorResult& error) const { MatrixToJSObject(cx, mTarget ? mTarget->GetTransform() : Matrix(), result, error); } void CanvasRenderingContext2D::SetMozCurrentTransformInverse(JSContext* cx, JS::Handle currentTransform, ErrorResult& error) { EnsureTarget(); if (!IsTargetValid()) { error.Throw(NS_ERROR_FAILURE); return; } Matrix newCTMInverse; if (ObjectToMatrix(cx, currentTransform, newCTMInverse, error)) { // XXX ERRMSG we need to report an error to developers here! (bug 329026) if (newCTMInverse.Invert()) { mTarget->SetTransform(newCTMInverse); } } } void CanvasRenderingContext2D::GetMozCurrentTransformInverse(JSContext* cx, JS::MutableHandle result, ErrorResult& error) const { if (!mTarget) { MatrixToJSObject(cx, Matrix(), result, error); return; } Matrix ctm = mTarget->GetTransform(); if (!ctm.Invert()) { double NaN = JS_GetNaNValue(cx).toDouble(); ctm = Matrix(NaN, NaN, NaN, NaN, NaN, NaN); } MatrixToJSObject(cx, ctm, result, error); } // // colors // void CanvasRenderingContext2D::SetStyleFromUnion(const StringOrCanvasGradientOrCanvasPattern& value, Style whichStyle) { if (value.IsString()) { SetStyleFromString(value.GetAsString(), whichStyle); return; } if (value.IsCanvasGradient()) { SetStyleFromGradient(value.GetAsCanvasGradient(), whichStyle); return; } if (value.IsCanvasPattern()) { SetStyleFromPattern(value.GetAsCanvasPattern(), whichStyle); return; } MOZ_ASSERT_UNREACHABLE("Invalid union value"); } void CanvasRenderingContext2D::SetFillRule(const nsAString& aString) { FillRule rule; if (aString.EqualsLiteral("evenodd")) rule = FillRule::FILL_EVEN_ODD; else if (aString.EqualsLiteral("nonzero")) rule = FillRule::FILL_WINDING; else return; CurrentState().fillRule = rule; } void CanvasRenderingContext2D::GetFillRule(nsAString& aString) { switch (CurrentState().fillRule) { case FillRule::FILL_WINDING: aString.AssignLiteral("nonzero"); break; case FillRule::FILL_EVEN_ODD: aString.AssignLiteral("evenodd"); break; } } // // gradients and patterns // already_AddRefed CanvasRenderingContext2D::CreateLinearGradient(double x0, double y0, double x1, double y1) { nsRefPtr grad = new CanvasLinearGradient(this, Point(x0, y0), Point(x1, y1)); return grad.forget(); } already_AddRefed CanvasRenderingContext2D::CreateRadialGradient(double x0, double y0, double r0, double x1, double y1, double r1, ErrorResult& aError) { if (r0 < 0.0 || r1 < 0.0) { aError.Throw(NS_ERROR_DOM_INDEX_SIZE_ERR); return nullptr; } nsRefPtr grad = new CanvasRadialGradient(this, Point(x0, y0), r0, Point(x1, y1), r1); return grad.forget(); } already_AddRefed CanvasRenderingContext2D::CreatePattern(const CanvasImageSource& source, const nsAString& repeat, ErrorResult& error) { CanvasPattern::RepeatMode repeatMode = CanvasPattern::RepeatMode::NOREPEAT; if (repeat.IsEmpty() || repeat.EqualsLiteral("repeat")) { repeatMode = CanvasPattern::RepeatMode::REPEAT; } else if (repeat.EqualsLiteral("repeat-x")) { repeatMode = CanvasPattern::RepeatMode::REPEATX; } else if (repeat.EqualsLiteral("repeat-y")) { repeatMode = CanvasPattern::RepeatMode::REPEATY; } else if (repeat.EqualsLiteral("no-repeat")) { repeatMode = CanvasPattern::RepeatMode::NOREPEAT; } else { error.Throw(NS_ERROR_DOM_SYNTAX_ERR); return nullptr; } Element* htmlElement; if (source.IsHTMLCanvasElement()) { HTMLCanvasElement* canvas = &source.GetAsHTMLCanvasElement(); htmlElement = canvas; nsIntSize size = canvas->GetSize(); if (size.width == 0 || size.height == 0) { error.Throw(NS_ERROR_DOM_INVALID_STATE_ERR); return nullptr; } // Special case for Canvas, which could be an Azure canvas! nsICanvasRenderingContextInternal *srcCanvas = canvas->GetContextAtIndex(0); if (srcCanvas) { // This might not be an Azure canvas! RefPtr srcSurf = srcCanvas->GetSurfaceSnapshot(); nsRefPtr pat = new CanvasPattern(this, srcSurf, repeatMode, htmlElement->NodePrincipal(), canvas->IsWriteOnly(), false); return pat.forget(); } } else if (source.IsHTMLImageElement()) { HTMLImageElement* img = &source.GetAsHTMLImageElement(); if (img->IntrinsicState().HasState(NS_EVENT_STATE_BROKEN)) { error.Throw(NS_ERROR_DOM_INVALID_STATE_ERR); return nullptr; } htmlElement = img; } else if (source.IsHTMLVideoElement()) { htmlElement = &source.GetAsHTMLVideoElement(); } else { // Special case for ImageBitmap ImageBitmap& imgBitmap = source.GetAsImageBitmap(); EnsureTarget(); RefPtr srcSurf = imgBitmap.PrepareForDrawTarget(mTarget); // An ImageBitmap never taints others so we set principalForSecurityCheck to // nullptr and set CORSUsed to true for passing the security check in // CanvasUtils::DoDrawImageSecurityCheck(). nsRefPtr pat = new CanvasPattern(this, srcSurf, repeatMode, nullptr, false, true); return pat.forget(); } EnsureTarget(); // The canvas spec says that createPattern should use the first frame // of animated images nsLayoutUtils::SurfaceFromElementResult res = nsLayoutUtils::SurfaceFromElement(htmlElement, nsLayoutUtils::SFE_WANT_FIRST_FRAME, mTarget); if (!res.mSourceSurface) { error.Throw(NS_ERROR_NOT_AVAILABLE); return nullptr; } nsRefPtr pat = new CanvasPattern(this, res.mSourceSurface, repeatMode, res.mPrincipal, res.mIsWriteOnly, res.mCORSUsed); return pat.forget(); } // // shadows // void CanvasRenderingContext2D::SetShadowColor(const nsAString& shadowColor) { nscolor color; if (!ParseColor(shadowColor, &color)) { return; } CurrentState().shadowColor = color; } // // filters // static already_AddRefed CreateStyleRule(nsINode* aNode, const nsCSSProperty aProp1, const nsAString& aValue1, bool* aChanged1, const nsCSSProperty aProp2, const nsAString& aValue2, bool* aChanged2, ErrorResult& error) { nsRefPtr rule; nsIPrincipal* principal = aNode->NodePrincipal(); nsIDocument* document = aNode->OwnerDoc(); nsIURI* docURL = document->GetDocumentURI(); nsIURI* baseURL = document->GetDocBaseURI(); // Pass the CSS Loader object to the parser, to allow parser error reports // to include the outer window ID. nsCSSParser parser(document->CSSLoader()); error = parser.ParseStyleAttribute(EmptyString(), docURL, baseURL, principal, getter_AddRefs(rule)); if (error.Failed()) { return nullptr; } if (aProp1 != eCSSProperty_UNKNOWN) { parser.ParseProperty(aProp1, aValue1, docURL, baseURL, principal, rule->GetDeclaration(), aChanged1, false); } if (aProp2 != eCSSProperty_UNKNOWN) { parser.ParseProperty(aProp2, aValue2, docURL, baseURL, principal, rule->GetDeclaration(), aChanged2, false); } rule->RuleMatched(); return rule.forget(); } static already_AddRefed CreateFontStyleRule(const nsAString& aFont, nsINode* aNode, bool* aOutFontChanged, ErrorResult& error) { bool lineHeightChanged; return CreateStyleRule(aNode, eCSSProperty_font, aFont, aOutFontChanged, eCSSProperty_line_height, NS_LITERAL_STRING("normal"), &lineHeightChanged, error); } static already_AddRefed GetFontParentStyleContext(Element* aElement, nsIPresShell* presShell, ErrorResult& error) { if (aElement && aElement->IsInDoc()) { // Inherit from the canvas element. nsRefPtr result = nsComputedDOMStyle::GetStyleContextForElement(aElement, nullptr, presShell); if (!result) { error.Throw(NS_ERROR_FAILURE); return nullptr; } return result.forget(); } // otherwise inherit from default (10px sans-serif) bool changed; nsRefPtr parentRule = CreateFontStyleRule(NS_LITERAL_STRING("10px sans-serif"), presShell->GetDocument(), &changed, error); if (error.Failed()) { return nullptr; } nsTArray> parentRules; parentRules.AppendElement(parentRule); nsRefPtr result = presShell->StyleSet()->ResolveStyleForRules(nullptr, parentRules); if (!result) { error.Throw(NS_ERROR_FAILURE); return nullptr; } return result.forget(); } static bool PropertyIsInheritOrInitial(StyleRule* aRule, const nsCSSProperty aProperty) { css::Declaration* declaration = aRule->GetDeclaration(); // We know the declaration is not !important, so we can use // GetNormalBlock(). const nsCSSValue* filterVal = declaration->GetNormalBlock()->ValueFor(aProperty); return (!filterVal || (filterVal->GetUnit() == eCSSUnit_Unset || filterVal->GetUnit() == eCSSUnit_Inherit || filterVal->GetUnit() == eCSSUnit_Initial)); } static already_AddRefed GetFontStyleContext(Element* aElement, const nsAString& aFont, nsIPresShell* presShell, nsAString& aOutUsedFont, ErrorResult& error) { bool fontParsedSuccessfully = false; nsRefPtr rule = CreateFontStyleRule(aFont, presShell->GetDocument(), &fontParsedSuccessfully, error); if (error.Failed()) { return nullptr; } if (!fontParsedSuccessfully) { // We got a syntax error. The spec says this value must be ignored. return nullptr; } // In addition to unparseable values, the spec says we need to reject // 'inherit' and 'initial'. The easiest way to check for this is to look // at font-size-adjust, which the font shorthand resets to either 'none' or // '-moz-system-font'. if (PropertyIsInheritOrInitial(rule, eCSSProperty_font_size_adjust)) { return nullptr; } // have to get a parent style context for inherit-like relative // values (2em, bolder, etc.) nsRefPtr parentContext = GetFontParentStyleContext(aElement, presShell, error); if (error.Failed()) { error.Throw(NS_ERROR_FAILURE); return nullptr; } MOZ_RELEASE_ASSERT(parentContext, "GetFontParentStyleContext should have returned an error if it couldn't get a parent context."); MOZ_ASSERT(!presShell->IsDestroying(), "GetFontParentStyleContext should have returned an error if the presshell is being destroyed."); nsTArray> rules; rules.AppendElement(rule); // add a rule to prevent text zoom from affecting the style rules.AppendElement(new nsDisableTextZoomStyleRule); nsStyleSet* styleSet = presShell->StyleSet(); nsRefPtr sc = styleSet->ResolveStyleForRules(parentContext, rules); // The font getter is required to be reserialized based on what we // parsed (including having line-height removed). (Older drafts of // the spec required font sizes be converted to pixels, but that no // longer seems to be required.) rule->GetDeclaration()->GetValue(eCSSProperty_font, aOutUsedFont); return sc.forget(); } static already_AddRefed CreateFilterStyleRule(const nsAString& aFilter, nsINode* aNode, bool* aOutFilterChanged, ErrorResult& error) { bool dummy; return CreateStyleRule(aNode, eCSSProperty_filter, aFilter, aOutFilterChanged, eCSSProperty_UNKNOWN, EmptyString(), &dummy, error); } static already_AddRefed ResolveStyleForFilterRule(const nsAString& aFilterString, nsIPresShell* aPresShell, nsStyleContext* aParentContext, ErrorResult& error) { nsIDocument* document = aPresShell->GetDocument(); bool filterChanged = false; nsRefPtr rule = CreateFilterStyleRule(aFilterString, document, &filterChanged, error); if (error.Failed()) { return nullptr; } if (!filterChanged) { // Refuse to accept the filter, but do not throw an error. return nullptr; } // In addition to unparseable values, the spec says we need to reject // 'inherit' and 'initial'. if (PropertyIsInheritOrInitial(rule, eCSSProperty_filter)) { return nullptr; } nsTArray> rules; rules.AppendElement(rule); nsRefPtr sc = aPresShell->StyleSet()->ResolveStyleForRules(aParentContext, rules); return sc.forget(); } bool CanvasRenderingContext2D::ParseFilter(const nsAString& aString, nsTArray& aFilterChain, ErrorResult& error) { if (!mCanvasElement && !mDocShell) { NS_WARNING("Canvas element must be non-null or a docshell must be provided"); error.Throw(NS_ERROR_FAILURE); return false; } nsCOMPtr presShell = GetPresShell(); if (!presShell) { error.Throw(NS_ERROR_FAILURE); return false; } nsString usedFont; nsRefPtr parentContext = GetFontStyleContext(mCanvasElement, GetFont(), presShell, usedFont, error); if (!parentContext) { error.Throw(NS_ERROR_FAILURE); return false; } nsRefPtr sc = ResolveStyleForFilterRule(aString, presShell, parentContext, error); if (!sc) { return false; } aFilterChain = sc->StyleSVGReset()->mFilters; return true; } class CanvasFilterChainObserver : public nsSVGFilterChainObserver { public: CanvasFilterChainObserver(nsTArray &aFilters, Element *aCanvasElement, CanvasRenderingContext2D *aContext) : nsSVGFilterChainObserver(aFilters, aCanvasElement) , mContext(aContext) { } virtual void DoUpdate() override { // Refresh the cached FilterDescription in mContext->CurrentState().filter. // If this filter is not at the top of the state stack, we'll refresh the // wrong filter, but that's ok, because we'll refresh the right filter // when we pop the state stack in CanvasRenderingContext2D::Restore(). mContext->UpdateFilter(); } private: CanvasRenderingContext2D *mContext; }; void CanvasRenderingContext2D::SetFilter(const nsAString& filter, ErrorResult& error) { nsTArray filterChain; if (ParseFilter(filter, filterChain, error)) { CurrentState().filterString = filter; filterChain.SwapElements(CurrentState().filterChain); if (mCanvasElement) { CurrentState().filterChainObserver = new CanvasFilterChainObserver(CurrentState().filterChain, mCanvasElement, this); UpdateFilter(); } } } class CanvasUserSpaceMetrics : public UserSpaceMetricsWithSize { public: CanvasUserSpaceMetrics(const gfx::IntSize& aSize, const nsFont& aFont, nsIAtom* aFontLanguage, bool aExplicitLanguage, nsPresContext* aPresContext) : mSize(aSize) , mFont(aFont) , mFontLanguage(aFontLanguage) , mExplicitLanguage(aExplicitLanguage) , mPresContext(aPresContext) { } virtual float GetEmLength() const override { return NSAppUnitsToFloatPixels(mFont.size, nsPresContext::AppUnitsPerCSSPixel()); } virtual float GetExLength() const override { gfxTextPerfMetrics* tp = mPresContext->GetTextPerfMetrics(); nsRefPtr fontMetrics; nsDeviceContext* dc = mPresContext->DeviceContext(); dc->GetMetricsFor(mFont, mFontLanguage, mExplicitLanguage, gfxFont::eHorizontal, nullptr, tp, *getter_AddRefs(fontMetrics)); return NSAppUnitsToFloatPixels(fontMetrics->XHeight(), nsPresContext::AppUnitsPerCSSPixel()); } virtual gfx::Size GetSize() const override { return Size(mSize); } private: gfx::IntSize mSize; const nsFont& mFont; nsIAtom* mFontLanguage; bool mExplicitLanguage; nsPresContext* mPresContext; }; void CanvasRenderingContext2D::UpdateFilter() { nsCOMPtr presShell = GetPresShell(); if (!presShell || presShell->IsDestroying()) { return; } // The filter might reference an SVG filter that is declared inside this // document. Flush frames so that we'll have an nsSVGFilterFrame to work // with. presShell->FlushPendingNotifications(Flush_Frames); CurrentState().filter = nsFilterInstance::GetFilterDescription(mCanvasElement, CurrentState().filterChain, CanvasUserSpaceMetrics(IntSize(mWidth, mHeight), CurrentState().fontFont, CurrentState().fontLanguage, CurrentState().fontExplicitLanguage, presShell->GetPresContext()), gfxRect(0, 0, mWidth, mHeight), CurrentState().filterAdditionalImages); } // // rects // // bug 1074733 // The canvas spec does not forbid rects with negative w or h, so given // corners (x, y), (x+w, y), (x+w, y+h), and (x, y+h) we must generate // the appropriate rect by flipping negative dimensions. This prevents // draw targets from receiving "empty" rects later on. static void NormalizeRect(double& aX, double& aY, double& aWidth, double& aHeight) { if (aWidth < 0) { aWidth = -aWidth; aX -= aWidth; } if (aHeight < 0) { aHeight = -aHeight; aY -= aHeight; } } void CanvasRenderingContext2D::ClearRect(double x, double y, double w, double h) { NormalizeRect(x, y, w, h); EnsureTarget(); mTarget->ClearRect(gfx::Rect(x, y, w, h)); RedrawUser(gfxRect(x, y, w, h)); } void CanvasRenderingContext2D::FillRect(double x, double y, double w, double h) { const ContextState &state = CurrentState(); NormalizeRect(x, y, w, h); if (state.patternStyles[Style::FILL]) { CanvasPattern::RepeatMode repeat = state.patternStyles[Style::FILL]->mRepeat; // In the FillRect case repeat modes are easy to deal with. bool limitx = repeat == CanvasPattern::RepeatMode::NOREPEAT || repeat == CanvasPattern::RepeatMode::REPEATY; bool limity = repeat == CanvasPattern::RepeatMode::NOREPEAT || repeat == CanvasPattern::RepeatMode::REPEATX; IntSize patternSize = state.patternStyles[Style::FILL]->mSurface->GetSize(); // We always need to execute painting for non-over operators, even if // we end up with w/h = 0. if (limitx) { if (x < 0) { w += x; if (w < 0) { w = 0; } x = 0; } if (x + w > patternSize.width) { w = patternSize.width - x; if (w < 0) { w = 0; } } } if (limity) { if (y < 0) { h += y; if (h < 0) { h = 0; } y = 0; } if (y + h > patternSize.height) { h = patternSize.height - y; if (h < 0) { h = 0; } } } } gfx::Rect bounds; EnsureTarget(); if (NeedToCalculateBounds()) { bounds = gfx::Rect(x, y, w, h); bounds = mTarget->GetTransform().TransformBounds(bounds); } AdjustedTarget(this, bounds.IsEmpty() ? nullptr : &bounds)-> FillRect(gfx::Rect(x, y, w, h), CanvasGeneralPattern().ForStyle(this, Style::FILL, mTarget), DrawOptions(state.globalAlpha, UsedOperation())); RedrawUser(gfxRect(x, y, w, h)); } void CanvasRenderingContext2D::StrokeRect(double x, double y, double w, double h) { const ContextState &state = CurrentState(); gfx::Rect bounds; if (!w && !h) { return; } NormalizeRect(x, y, w, h); EnsureTarget(); if (!IsTargetValid()) { return; } if (NeedToCalculateBounds()) { bounds = gfx::Rect(x - state.lineWidth / 2.0f, y - state.lineWidth / 2.0f, w + state.lineWidth, h + state.lineWidth); bounds = mTarget->GetTransform().TransformBounds(bounds); } if (!h) { CapStyle cap = CapStyle::BUTT; if (state.lineJoin == JoinStyle::ROUND) { cap = CapStyle::ROUND; } AdjustedTarget(this, bounds.IsEmpty() ? nullptr : &bounds)-> StrokeLine(Point(x, y), Point(x + w, y), CanvasGeneralPattern().ForStyle(this, Style::STROKE, mTarget), StrokeOptions(state.lineWidth, state.lineJoin, cap, state.miterLimit, state.dash.Length(), state.dash.Elements(), state.dashOffset), DrawOptions(state.globalAlpha, UsedOperation())); return; } if (!w) { CapStyle cap = CapStyle::BUTT; if (state.lineJoin == JoinStyle::ROUND) { cap = CapStyle::ROUND; } AdjustedTarget(this, bounds.IsEmpty() ? nullptr : &bounds)-> StrokeLine(Point(x, y), Point(x, y + h), CanvasGeneralPattern().ForStyle(this, Style::STROKE, mTarget), StrokeOptions(state.lineWidth, state.lineJoin, cap, state.miterLimit, state.dash.Length(), state.dash.Elements(), state.dashOffset), DrawOptions(state.globalAlpha, UsedOperation())); return; } AdjustedTarget(this, bounds.IsEmpty() ? nullptr : &bounds)-> StrokeRect(gfx::Rect(x, y, w, h), CanvasGeneralPattern().ForStyle(this, Style::STROKE, mTarget), StrokeOptions(state.lineWidth, state.lineJoin, state.lineCap, state.miterLimit, state.dash.Length(), state.dash.Elements(), state.dashOffset), DrawOptions(state.globalAlpha, UsedOperation())); Redraw(); } // // path bits // void CanvasRenderingContext2D::BeginPath() { mPath = nullptr; mPathBuilder = nullptr; mDSPathBuilder = nullptr; mPathTransformWillUpdate = false; } void CanvasRenderingContext2D::Fill(const CanvasWindingRule& winding) { EnsureUserSpacePath(winding); if (!mPath) { return; } gfx::Rect bounds; if (NeedToCalculateBounds()) { bounds = mPath->GetBounds(mTarget->GetTransform()); } AdjustedTarget(this, bounds.IsEmpty() ? nullptr : &bounds)-> Fill(mPath, CanvasGeneralPattern().ForStyle(this, Style::FILL, mTarget), DrawOptions(CurrentState().globalAlpha, UsedOperation())); Redraw(); } void CanvasRenderingContext2D::Fill(const CanvasPath& path, const CanvasWindingRule& winding) { EnsureTarget(); RefPtr gfxpath = path.GetPath(winding, mTarget); if (!gfxpath) { return; } gfx::Rect bounds; if (NeedToCalculateBounds()) { bounds = gfxpath->GetBounds(mTarget->GetTransform()); } AdjustedTarget(this, bounds.IsEmpty() ? nullptr : &bounds)-> Fill(gfxpath, CanvasGeneralPattern().ForStyle(this, Style::FILL, mTarget), DrawOptions(CurrentState().globalAlpha, UsedOperation())); Redraw(); } void CanvasRenderingContext2D::Stroke() { EnsureUserSpacePath(); if (!mPath) { return; } const ContextState &state = CurrentState(); StrokeOptions strokeOptions(state.lineWidth, state.lineJoin, state.lineCap, state.miterLimit, state.dash.Length(), state.dash.Elements(), state.dashOffset); gfx::Rect bounds; if (NeedToCalculateBounds()) { bounds = mPath->GetStrokedBounds(strokeOptions, mTarget->GetTransform()); } AdjustedTarget(this, bounds.IsEmpty() ? nullptr : &bounds)-> Stroke(mPath, CanvasGeneralPattern().ForStyle(this, Style::STROKE, mTarget), strokeOptions, DrawOptions(state.globalAlpha, UsedOperation())); Redraw(); } void CanvasRenderingContext2D::Stroke(const CanvasPath& path) { EnsureTarget(); RefPtr gfxpath = path.GetPath(CanvasWindingRule::Nonzero, mTarget); if (!gfxpath) { return; } const ContextState &state = CurrentState(); StrokeOptions strokeOptions(state.lineWidth, state.lineJoin, state.lineCap, state.miterLimit, state.dash.Length(), state.dash.Elements(), state.dashOffset); gfx::Rect bounds; if (NeedToCalculateBounds()) { bounds = gfxpath->GetStrokedBounds(strokeOptions, mTarget->GetTransform()); } AdjustedTarget(this, bounds.IsEmpty() ? nullptr : &bounds)-> Stroke(gfxpath, CanvasGeneralPattern().ForStyle(this, Style::STROKE, mTarget), strokeOptions, DrawOptions(state.globalAlpha, UsedOperation())); Redraw(); } void CanvasRenderingContext2D::DrawFocusIfNeeded(mozilla::dom::Element& aElement, ErrorResult& aRv) { EnsureUserSpacePath(); if (!mPath) { return; } if(DrawCustomFocusRing(aElement)) { Save(); // set state to conforming focus state ContextState& state = CurrentState(); state.globalAlpha = 1.0; state.shadowBlur = 0; state.shadowOffset.x = 0; state.shadowOffset.y = 0; state.op = mozilla::gfx::CompositionOp::OP_OVER; state.lineCap = CapStyle::BUTT; state.lineJoin = mozilla::gfx::JoinStyle::MITER_OR_BEVEL; state.lineWidth = 1; CurrentState().dash.Clear(); // color and style of the rings is the same as for image maps // set the background focus color CurrentState().SetColorStyle(Style::STROKE, NS_RGBA(255, 255, 255, 255)); // draw the focus ring Stroke(); // set dashing for foreground nsTArray& dash = CurrentState().dash; for (uint32_t i = 0; i < 2; ++i) { if (!dash.AppendElement(1, fallible)) { aRv.Throw(NS_ERROR_OUT_OF_MEMORY); return; } } // set the foreground focus color CurrentState().SetColorStyle(Style::STROKE, NS_RGBA(0,0,0, 255)); // draw the focus ring Stroke(); Restore(); } } bool CanvasRenderingContext2D::DrawCustomFocusRing(mozilla::dom::Element& aElement) { EnsureUserSpacePath(); HTMLCanvasElement* canvas = GetCanvas(); if (!canvas|| !nsContentUtils::ContentIsDescendantOf(&aElement, canvas)) { return false; } nsIFocusManager* fm = nsFocusManager::GetFocusManager(); if (fm) { // check that the element i focused nsCOMPtr focusedElement; fm->GetFocusedElement(getter_AddRefs(focusedElement)); if (SameCOMIdentity(aElement.AsDOMNode(), focusedElement)) { nsPIDOMWindow *window = aElement.OwnerDoc()->GetWindow(); if (window) { return window->ShouldShowFocusRing(); } } } return false; } void CanvasRenderingContext2D::Clip(const CanvasWindingRule& winding) { EnsureUserSpacePath(winding); if (!mPath) { return; } mTarget->PushClip(mPath); CurrentState().clipsPushed.push_back(mPath); } void CanvasRenderingContext2D::Clip(const CanvasPath& path, const CanvasWindingRule& winding) { EnsureTarget(); RefPtr gfxpath = path.GetPath(winding, mTarget); if (!gfxpath) { return; } mTarget->PushClip(gfxpath); CurrentState().clipsPushed.push_back(gfxpath); } void CanvasRenderingContext2D::ArcTo(double x1, double y1, double x2, double y2, double radius, ErrorResult& error) { if (radius < 0) { error.Throw(NS_ERROR_DOM_INDEX_SIZE_ERR); return; } EnsureWritablePath(); // Current point in user space! Point p0; if (mPathBuilder) { p0 = mPathBuilder->CurrentPoint(); } else { Matrix invTransform = mTarget->GetTransform(); if (!invTransform.Invert()) { return; } p0 = invTransform * mDSPathBuilder->CurrentPoint(); } Point p1(x1, y1); Point p2(x2, y2); // Execute these calculations in double precision to avoid cumulative // rounding errors. double dir, a2, b2, c2, cosx, sinx, d, anx, any, bnx, bny, x3, y3, x4, y4, cx, cy, angle0, angle1; bool anticlockwise; if (p0 == p1 || p1 == p2 || radius == 0) { LineTo(p1.x, p1.y); return; } // Check for colinearity dir = (p2.x - p1.x) * (p0.y - p1.y) + (p2.y - p1.y) * (p1.x - p0.x); if (dir == 0) { LineTo(p1.x, p1.y); return; } // XXX - Math for this code was already available from the non-azure code // and would be well tested. Perhaps converting to bezier directly might // be more efficient longer run. a2 = (p0.x-x1)*(p0.x-x1) + (p0.y-y1)*(p0.y-y1); b2 = (x1-x2)*(x1-x2) + (y1-y2)*(y1-y2); c2 = (p0.x-x2)*(p0.x-x2) + (p0.y-y2)*(p0.y-y2); cosx = (a2+b2-c2)/(2*sqrt(a2*b2)); sinx = sqrt(1 - cosx*cosx); d = radius / ((1 - cosx) / sinx); anx = (x1-p0.x) / sqrt(a2); any = (y1-p0.y) / sqrt(a2); bnx = (x1-x2) / sqrt(b2); bny = (y1-y2) / sqrt(b2); x3 = x1 - anx*d; y3 = y1 - any*d; x4 = x1 - bnx*d; y4 = y1 - bny*d; anticlockwise = (dir < 0); cx = x3 + any*radius*(anticlockwise ? 1 : -1); cy = y3 - anx*radius*(anticlockwise ? 1 : -1); angle0 = atan2((y3-cy), (x3-cx)); angle1 = atan2((y4-cy), (x4-cx)); LineTo(x3, y3); Arc(cx, cy, radius, angle0, angle1, anticlockwise, error); } void CanvasRenderingContext2D::Arc(double x, double y, double r, double startAngle, double endAngle, bool anticlockwise, ErrorResult& error) { if (r < 0.0) { error.Throw(NS_ERROR_DOM_INDEX_SIZE_ERR); return; } EnsureWritablePath(); ArcToBezier(this, Point(x, y), Size(r, r), startAngle, endAngle, anticlockwise); } void CanvasRenderingContext2D::Rect(double x, double y, double w, double h) { EnsureWritablePath(); if (mPathBuilder) { mPathBuilder->MoveTo(Point(x, y)); mPathBuilder->LineTo(Point(x + w, y)); mPathBuilder->LineTo(Point(x + w, y + h)); mPathBuilder->LineTo(Point(x, y + h)); mPathBuilder->Close(); } else { mDSPathBuilder->MoveTo(mTarget->GetTransform() * Point(x, y)); mDSPathBuilder->LineTo(mTarget->GetTransform() * Point(x + w, y)); mDSPathBuilder->LineTo(mTarget->GetTransform() * Point(x + w, y + h)); mDSPathBuilder->LineTo(mTarget->GetTransform() * Point(x, y + h)); mDSPathBuilder->Close(); } } void CanvasRenderingContext2D::EnsureWritablePath() { EnsureTarget(); if (mDSPathBuilder) { return; } FillRule fillRule = CurrentState().fillRule; if (mPathBuilder) { if (mPathTransformWillUpdate) { mPath = mPathBuilder->Finish(); mDSPathBuilder = mPath->TransformedCopyToBuilder(mPathToDS, fillRule); mPath = nullptr; mPathBuilder = nullptr; mPathTransformWillUpdate = false; } return; } if (!mPath) { NS_ASSERTION(!mPathTransformWillUpdate, "mPathTransformWillUpdate should be false, if all paths are null"); mPathBuilder = mTarget->CreatePathBuilder(fillRule); } else if (!mPathTransformWillUpdate) { mPathBuilder = mPath->CopyToBuilder(fillRule); } else { mDSPathBuilder = mPath->TransformedCopyToBuilder(mPathToDS, fillRule); mPathTransformWillUpdate = false; mPath = nullptr; } } void CanvasRenderingContext2D::EnsureUserSpacePath(const CanvasWindingRule& winding) { FillRule fillRule = CurrentState().fillRule; if(winding == CanvasWindingRule::Evenodd) fillRule = FillRule::FILL_EVEN_ODD; EnsureTarget(); if (!mPath && !mPathBuilder && !mDSPathBuilder) { mPathBuilder = mTarget->CreatePathBuilder(fillRule); } if (mPathBuilder) { mPath = mPathBuilder->Finish(); mPathBuilder = nullptr; } if (mPath && mPathTransformWillUpdate) { mDSPathBuilder = mPath->TransformedCopyToBuilder(mPathToDS, fillRule); mPath = nullptr; mPathTransformWillUpdate = false; } if (mDSPathBuilder) { RefPtr dsPath; dsPath = mDSPathBuilder->Finish(); mDSPathBuilder = nullptr; Matrix inverse = mTarget->GetTransform(); if (!inverse.Invert()) { NS_WARNING("Could not invert transform"); return; } mPathBuilder = dsPath->TransformedCopyToBuilder(inverse, fillRule); mPath = mPathBuilder->Finish(); mPathBuilder = nullptr; } if (mPath && mPath->GetFillRule() != fillRule) { mPathBuilder = mPath->CopyToBuilder(fillRule); mPath = mPathBuilder->Finish(); mPathBuilder = nullptr; } NS_ASSERTION(mPath, "mPath should exist"); } void CanvasRenderingContext2D::TransformWillUpdate() { EnsureTarget(); // Store the matrix that would transform the current path to device // space. if (mPath || mPathBuilder) { if (!mPathTransformWillUpdate) { // If the transform has already been updated, but a device space builder // has not been created yet mPathToDS contains the right transform to // transform the current mPath into device space. // We should leave it alone. mPathToDS = mTarget->GetTransform(); } mPathTransformWillUpdate = true; } } // // text // void CanvasRenderingContext2D::SetFont(const nsAString& font, ErrorResult& error) { SetFontInternal(font, error); } bool CanvasRenderingContext2D::SetFontInternal(const nsAString& font, ErrorResult& error) { /* * If font is defined with relative units (e.g. ems) and the parent * style context changes in between calls, setting the font to the * same value as previous could result in a different computed value, * so we cannot have the optimization where we check if the new font * string is equal to the old one. */ if (!mCanvasElement && !mDocShell) { NS_WARNING("Canvas element must be non-null or a docshell must be provided"); error.Throw(NS_ERROR_FAILURE); return false; } nsCOMPtr presShell = GetPresShell(); if (!presShell) { error.Throw(NS_ERROR_FAILURE); return false; } nsString usedFont; nsRefPtr sc = GetFontStyleContext(mCanvasElement, font, presShell, usedFont, error); if (!sc) { return false; } const nsStyleFont* fontStyle = sc->StyleFont(); nsPresContext *c = presShell->GetPresContext(); // Purposely ignore the font size that respects the user's minimum // font preference (fontStyle->mFont.size) in favor of the computed // size (fontStyle->mSize). See // https://bugzilla.mozilla.org/show_bug.cgi?id=698652. MOZ_ASSERT(!fontStyle->mAllowZoom, "expected text zoom to be disabled on this nsStyleFont"); nsFont resizedFont(fontStyle->mFont); // Create a font group working in units of CSS pixels instead of the usual // device pixels, to avoid being affected by page zoom. nsFontMetrics will // convert nsFont size in app units to device pixels for the font group, so // here we first apply to the size the equivalent of a conversion from device // pixels to CSS pixels, to adjust for the difference in expectations from // other nsFontMetrics clients. resizedFont.size = (fontStyle->mSize * c->AppUnitsPerDevPixel()) / c->AppUnitsPerCSSPixel(); nsRefPtr metrics; c->DeviceContext()->GetMetricsFor(resizedFont, fontStyle->mLanguage, fontStyle->mExplicitLanguage, gfxFont::eHorizontal, c->GetUserFontSet(), c->GetTextPerfMetrics(), *getter_AddRefs(metrics)); gfxFontGroup* newFontGroup = metrics->GetThebesFontGroup(); CurrentState().fontGroup = newFontGroup; NS_ASSERTION(CurrentState().fontGroup, "Could not get font group"); CurrentState().font = usedFont; CurrentState().fontFont = fontStyle->mFont; CurrentState().fontFont.size = fontStyle->mSize; CurrentState().fontLanguage = fontStyle->mLanguage; CurrentState().fontExplicitLanguage = fontStyle->mExplicitLanguage; return true; } void CanvasRenderingContext2D::SetTextAlign(const nsAString& ta) { if (ta.EqualsLiteral("start")) CurrentState().textAlign = TextAlign::START; else if (ta.EqualsLiteral("end")) CurrentState().textAlign = TextAlign::END; else if (ta.EqualsLiteral("left")) CurrentState().textAlign = TextAlign::LEFT; else if (ta.EqualsLiteral("right")) CurrentState().textAlign = TextAlign::RIGHT; else if (ta.EqualsLiteral("center")) CurrentState().textAlign = TextAlign::CENTER; } void CanvasRenderingContext2D::GetTextAlign(nsAString& ta) { switch (CurrentState().textAlign) { case TextAlign::START: ta.AssignLiteral("start"); break; case TextAlign::END: ta.AssignLiteral("end"); break; case TextAlign::LEFT: ta.AssignLiteral("left"); break; case TextAlign::RIGHT: ta.AssignLiteral("right"); break; case TextAlign::CENTER: ta.AssignLiteral("center"); break; } } void CanvasRenderingContext2D::SetTextBaseline(const nsAString& tb) { if (tb.EqualsLiteral("top")) CurrentState().textBaseline = TextBaseline::TOP; else if (tb.EqualsLiteral("hanging")) CurrentState().textBaseline = TextBaseline::HANGING; else if (tb.EqualsLiteral("middle")) CurrentState().textBaseline = TextBaseline::MIDDLE; else if (tb.EqualsLiteral("alphabetic")) CurrentState().textBaseline = TextBaseline::ALPHABETIC; else if (tb.EqualsLiteral("ideographic")) CurrentState().textBaseline = TextBaseline::IDEOGRAPHIC; else if (tb.EqualsLiteral("bottom")) CurrentState().textBaseline = TextBaseline::BOTTOM; } void CanvasRenderingContext2D::GetTextBaseline(nsAString& tb) { switch (CurrentState().textBaseline) { case TextBaseline::TOP: tb.AssignLiteral("top"); break; case TextBaseline::HANGING: tb.AssignLiteral("hanging"); break; case TextBaseline::MIDDLE: tb.AssignLiteral("middle"); break; case TextBaseline::ALPHABETIC: tb.AssignLiteral("alphabetic"); break; case TextBaseline::IDEOGRAPHIC: tb.AssignLiteral("ideographic"); break; case TextBaseline::BOTTOM: tb.AssignLiteral("bottom"); break; } } /* * Helper function that replaces the whitespace characters in a string * with U+0020 SPACE. The whitespace characters are defined as U+0020 SPACE, * U+0009 CHARACTER TABULATION (tab), U+000A LINE FEED (LF), U+000B LINE * TABULATION, U+000C FORM FEED (FF), and U+000D CARRIAGE RETURN (CR). * @param str The string whose whitespace characters to replace. */ static inline void TextReplaceWhitespaceCharacters(nsAutoString& str) { str.ReplaceChar("\x09\x0A\x0B\x0C\x0D", char16_t(' ')); } void CanvasRenderingContext2D::FillText(const nsAString& text, double x, double y, const Optional& maxWidth, ErrorResult& error) { error = DrawOrMeasureText(text, x, y, maxWidth, TextDrawOperation::FILL, nullptr); } void CanvasRenderingContext2D::StrokeText(const nsAString& text, double x, double y, const Optional& maxWidth, ErrorResult& error) { error = DrawOrMeasureText(text, x, y, maxWidth, TextDrawOperation::STROKE, nullptr); } TextMetrics* CanvasRenderingContext2D::MeasureText(const nsAString& rawText, ErrorResult& error) { float width; Optional maxWidth; error = DrawOrMeasureText(rawText, 0, 0, maxWidth, TextDrawOperation::MEASURE, &width); if (error.Failed()) { return nullptr; } return new TextMetrics(width); } void CanvasRenderingContext2D::AddHitRegion(const HitRegionOptions& options, ErrorResult& error) { RefPtr path; if (options.mPath) { EnsureTarget(); path = options.mPath->GetPath(CanvasWindingRule::Nonzero, mTarget); } if (!path) { // check if the path is valid EnsureUserSpacePath(CanvasWindingRule::Nonzero); path = mPath; } if(!path) { error.Throw(NS_ERROR_DOM_NOT_SUPPORTED_ERR); return; } // get the bounds of the current path. They are relative to the canvas gfx::Rect bounds(path->GetBounds(mTarget->GetTransform())); if ((bounds.width == 0) || (bounds.height == 0) || !bounds.IsFinite()) { // The specified region has no pixels. error.Throw(NS_ERROR_DOM_NOT_SUPPORTED_ERR); return; } // remove old hit region first RemoveHitRegion(options.mId); if (options.mControl) { // also remove regions with this control for (size_t x = 0; x < mHitRegionsOptions.Length(); x++) { RegionInfo& info = mHitRegionsOptions[x]; if (info.mElement == options.mControl) { mHitRegionsOptions.RemoveElementAt(x); break; } } #ifdef ACCESSIBILITY options.mControl->SetProperty(nsGkAtoms::hitregion, new bool(true), nsINode::DeleteProperty); #endif } // finally, add the region to the list RegionInfo info; info.mId = options.mId; info.mElement = options.mControl; RefPtr pathBuilder = path->TransformedCopyToBuilder(mTarget->GetTransform()); info.mPath = pathBuilder->Finish(); mHitRegionsOptions.InsertElementAt(0, info); } void CanvasRenderingContext2D::RemoveHitRegion(const nsAString& id) { if (id.Length() == 0) { return; } for (size_t x = 0; x < mHitRegionsOptions.Length(); x++) { RegionInfo& info = mHitRegionsOptions[x]; if (info.mId == id) { mHitRegionsOptions.RemoveElementAt(x); return; } } } void CanvasRenderingContext2D::ClearHitRegions() { mHitRegionsOptions.Clear(); } bool CanvasRenderingContext2D::GetHitRegionRect(Element* aElement, nsRect& aRect) { for (unsigned int x = 0; x < mHitRegionsOptions.Length(); x++) { RegionInfo& info = mHitRegionsOptions[x]; if (info.mElement == aElement) { gfx::Rect bounds(info.mPath->GetBounds()); gfxRect rect(bounds.x, bounds.y, bounds.width, bounds.height); aRect = nsLayoutUtils::RoundGfxRectToAppRect(rect, AppUnitsPerCSSPixel()); return true; } } return false; } /** * Used for nsBidiPresUtils::ProcessText */ struct MOZ_STACK_CLASS CanvasBidiProcessor : public nsBidiPresUtils::BidiProcessor { CanvasBidiProcessor() : nsBidiPresUtils::BidiProcessor() { if (Preferences::GetBool(GFX_MISSING_FONTS_NOTIFY_PREF)) { mMissingFonts = new gfxMissingFontRecorder(); } } ~CanvasBidiProcessor() { // notify front-end code if we encountered missing glyphs in any script if (mMissingFonts) { mMissingFonts->Flush(); } } typedef CanvasRenderingContext2D::ContextState ContextState; virtual void SetText(const char16_t* text, int32_t length, nsBidiDirection direction) { mFontgrp->UpdateUserFonts(); // ensure user font generation is current // adjust flags for current direction run uint32_t flags = mTextRunFlags; if (direction == NSBIDI_RTL) { flags |= gfxTextRunFactory::TEXT_IS_RTL; } else { flags &= ~gfxTextRunFactory::TEXT_IS_RTL; } mTextRun = mFontgrp->MakeTextRun(text, length, mThebes, mAppUnitsPerDevPixel, flags, mMissingFonts); } virtual nscoord GetWidth() { gfxTextRun::Metrics textRunMetrics = mTextRun->MeasureText(0, mTextRun->GetLength(), mDoMeasureBoundingBox ? gfxFont::TIGHT_INK_EXTENTS : gfxFont::LOOSE_INK_EXTENTS, mThebes, nullptr); // this only measures the height; the total width is gotten from the // the return value of ProcessText. if (mDoMeasureBoundingBox) { textRunMetrics.mBoundingBox.Scale(1.0 / mAppUnitsPerDevPixel); mBoundingBox = mBoundingBox.Union(textRunMetrics.mBoundingBox); } return NSToCoordRound(textRunMetrics.mAdvanceWidth); } virtual void DrawText(nscoord xOffset, nscoord width) { gfxPoint point = mPt; bool rtl = mTextRun->IsRightToLeft(); bool verticalRun = mTextRun->IsVertical(); bool centerBaseline = mTextRun->UseCenterBaseline(); gfxFloat& inlineCoord = verticalRun ? point.y : point.x; inlineCoord += xOffset; // offset is given in terms of left side of string if (rtl) { // Bug 581092 - don't use rounded pixel width to advance to // right-hand end of run, because this will cause different // glyph positioning for LTR vs RTL drawing of the same // glyph string on OS X and DWrite where textrun widths may // involve fractional pixels. gfxTextRun::Metrics textRunMetrics = mTextRun->MeasureText(0, mTextRun->GetLength(), mDoMeasureBoundingBox ? gfxFont::TIGHT_INK_EXTENTS : gfxFont::LOOSE_INK_EXTENTS, mThebes, nullptr); inlineCoord += textRunMetrics.mAdvanceWidth; // old code was: // point.x += width * mAppUnitsPerDevPixel; // TODO: restore this if/when we move to fractional coords // throughout the text layout process } uint32_t numRuns; const gfxTextRun::GlyphRun *runs = mTextRun->GetGlyphRuns(&numRuns); const int32_t appUnitsPerDevUnit = mAppUnitsPerDevPixel; const double devUnitsPerAppUnit = 1.0/double(appUnitsPerDevUnit); Point baselineOrigin = Point(point.x * devUnitsPerAppUnit, point.y * devUnitsPerAppUnit); float advanceSum = 0; mCtx->EnsureTarget(); for (uint32_t c = 0; c < numRuns; c++) { gfxFont *font = runs[c].mFont; bool verticalFont = runs[c].mOrientation == gfxTextRunFactory::TEXT_ORIENT_VERTICAL_UPRIGHT; const float& baselineOriginInline = verticalFont ? baselineOrigin.y : baselineOrigin.x; const float& baselineOriginBlock = verticalFont ? baselineOrigin.x : baselineOrigin.y; uint32_t endRun = 0; if (c + 1 < numRuns) { endRun = runs[c + 1].mCharacterOffset; } else { endRun = mTextRun->GetLength(); } const gfxTextRun::CompressedGlyph *glyphs = mTextRun->GetCharacterGlyphs(); RefPtr scaledFont = gfxPlatform::GetPlatform()->GetScaledFontForFont(mCtx->mTarget, font); if (!scaledFont) { // This can occur when something switched DirectWrite off. return; } AutoRestoreTransform sidewaysRestore; if (runs[c].mOrientation == gfxTextRunFactory::TEXT_ORIENT_VERTICAL_SIDEWAYS_RIGHT) { sidewaysRestore.Init(mCtx->mTarget); const gfxFont::Metrics& metrics = mTextRun->GetFontGroup()-> GetFirstValidFont()->GetMetrics(gfxFont::eHorizontal); gfx::Matrix mat = mCtx->mTarget->GetTransform().Copy(). PreTranslate(baselineOrigin). // translate origin for rotation PreRotate(gfx::Float(M_PI / 2.0)). // turn 90deg clockwise PreTranslate(-baselineOrigin); // undo the translation if (centerBaseline) { // TODO: The baseline adjustment here is kinda ad hoc; eventually // perhaps we should check for horizontal and vertical baseline data // in the font, and adjust accordingly. // (The same will be true for HTML text layout.) float offset = (metrics.emAscent - metrics.emDescent) / 2; mat = mat.PreTranslate(Point(0, offset)); // offset the (alphabetic) baseline of the // horizontally-shaped text from the (centered) // default baseline used for vertical } mCtx->mTarget->SetTransform(mat); } RefPtr renderingOptions = font->GetGlyphRenderingOptions(); GlyphBuffer buffer; std::vector glyphBuf; // TODO: // This more-or-less duplicates the code found in gfxTextRun::Draw // and the gfxFont methods that uses (Draw, DrawGlyphs, DrawOneGlyph); // it would be nice to refactor and share that code. for (uint32_t i = runs[c].mCharacterOffset; i < endRun; i++) { Glyph newGlyph; float& inlinePos = verticalFont ? newGlyph.mPosition.y : newGlyph.mPosition.x; float& blockPos = verticalFont ? newGlyph.mPosition.x : newGlyph.mPosition.y; if (glyphs[i].IsSimpleGlyph()) { newGlyph.mIndex = glyphs[i].GetSimpleGlyph(); if (rtl) { inlinePos = baselineOriginInline - advanceSum - glyphs[i].GetSimpleAdvance() * devUnitsPerAppUnit; } else { inlinePos = baselineOriginInline + advanceSum; } blockPos = baselineOriginBlock; advanceSum += glyphs[i].GetSimpleAdvance() * devUnitsPerAppUnit; glyphBuf.push_back(newGlyph); continue; } if (!glyphs[i].GetGlyphCount()) { continue; } const gfxTextRun::DetailedGlyph *d = mTextRun->GetDetailedGlyphs(i); if (glyphs[i].IsMissing()) { if (d->mAdvance > 0) { // Perhaps we should render a hexbox here, but for now // we just draw the font's .notdef glyph. (See bug 808288.) newGlyph.mIndex = 0; if (rtl) { inlinePos = baselineOriginInline - advanceSum - d->mAdvance * devUnitsPerAppUnit; } else { inlinePos = baselineOriginInline + advanceSum; } blockPos = baselineOriginBlock; advanceSum += d->mAdvance * devUnitsPerAppUnit; glyphBuf.push_back(newGlyph); } continue; } for (uint32_t c = 0; c < glyphs[i].GetGlyphCount(); c++, d++) { newGlyph.mIndex = d->mGlyphID; if (rtl) { inlinePos = baselineOriginInline - advanceSum - d->mAdvance * devUnitsPerAppUnit; } else { inlinePos = baselineOriginInline + advanceSum; } inlinePos += d->mXOffset * devUnitsPerAppUnit; blockPos = baselineOriginBlock + d->mYOffset * devUnitsPerAppUnit; glyphBuf.push_back(newGlyph); advanceSum += d->mAdvance * devUnitsPerAppUnit; } } if (!glyphBuf.size()) { // This may happen for glyph runs for a 0 size font. continue; } buffer.mGlyphs = &glyphBuf.front(); buffer.mNumGlyphs = glyphBuf.size(); Rect bounds = mCtx->mTarget->GetTransform(). TransformBounds(Rect(mBoundingBox.x, mBoundingBox.y, mBoundingBox.width, mBoundingBox.height)); if (mOp == CanvasRenderingContext2D::TextDrawOperation::FILL) { AdjustedTarget(mCtx, &bounds)-> FillGlyphs(scaledFont, buffer, CanvasGeneralPattern(). ForStyle(mCtx, CanvasRenderingContext2D::Style::FILL, mCtx->mTarget), DrawOptions(mState->globalAlpha, mCtx->UsedOperation()), renderingOptions); } else if (mOp == CanvasRenderingContext2D::TextDrawOperation::STROKE) { // stroke glyphs one at a time to avoid poor CoreGraphics performance // when stroking a path with a very large number of points buffer.mGlyphs = &glyphBuf.front(); buffer.mNumGlyphs = 1; const ContextState& state = *mState; const StrokeOptions strokeOpts(state.lineWidth, state.lineJoin, state.lineCap, state.miterLimit, state.dash.Length(), state.dash.Elements(), state.dashOffset); // We need to adjust the bounds for the adjusted target bounds.Inflate(MaxStrokeExtents(strokeOpts, mCtx->mTarget->GetTransform())); AdjustedTarget target(mCtx, &bounds); CanvasGeneralPattern cgp; const Pattern& patForStyle (cgp.ForStyle(mCtx, CanvasRenderingContext2D::Style::STROKE, mCtx->mTarget)); const DrawOptions drawOpts(state.globalAlpha, mCtx->UsedOperation()); for (unsigned i = glyphBuf.size(); i > 0; --i) { RefPtr path = scaledFont->GetPathForGlyphs(buffer, mCtx->mTarget); target->Stroke(path, patForStyle, strokeOpts, drawOpts); buffer.mGlyphs++; } } } } // current text run nsAutoPtr mTextRun; // pointer to a screen reference context used to measure text and such nsRefPtr mThebes; // Pointer to the draw target we should fill our text to CanvasRenderingContext2D *mCtx; // position of the left side of the string, alphabetic baseline gfxPoint mPt; // current font gfxFontGroup* mFontgrp; // to record any unsupported characters found in the text, // and notify front-end if it is interested nsAutoPtr mMissingFonts; // dev pixel conversion factor int32_t mAppUnitsPerDevPixel; // operation (fill or stroke) CanvasRenderingContext2D::TextDrawOperation mOp; // context state ContextState *mState; // union of bounding boxes of all runs, needed for shadows gfxRect mBoundingBox; // flags to use when creating textrun, based on CSS style uint32_t mTextRunFlags; // true iff the bounding box should be measured bool mDoMeasureBoundingBox; }; nsresult CanvasRenderingContext2D::DrawOrMeasureText(const nsAString& aRawText, float aX, float aY, const Optional& aMaxWidth, TextDrawOperation aOp, float* aWidth) { nsresult rv; // spec isn't clear on what should happen if aMaxWidth <= 0, so // treat it as an invalid argument // technically, 0 should be an invalid value as well, but 0 is the default // arg, and there is no way to tell if the default was used if (aMaxWidth.WasPassed() && aMaxWidth.Value() < 0) return NS_ERROR_INVALID_ARG; if (!mCanvasElement && !mDocShell) { NS_WARNING("Canvas element must be non-null or a docshell must be provided"); return NS_ERROR_FAILURE; } nsCOMPtr presShell = GetPresShell(); if (!presShell) return NS_ERROR_FAILURE; nsIDocument* document = presShell->GetDocument(); // replace all the whitespace characters with U+0020 SPACE nsAutoString textToDraw(aRawText); TextReplaceWhitespaceCharacters(textToDraw); // for now, default to ltr if not in doc bool isRTL = false; nsRefPtr canvasStyle; if (mCanvasElement && mCanvasElement->IsInDoc()) { // try to find the closest context canvasStyle = nsComputedDOMStyle::GetStyleContextForElement(mCanvasElement, nullptr, presShell); if (!canvasStyle) { return NS_ERROR_FAILURE; } isRTL = canvasStyle->StyleVisibility()->mDirection == NS_STYLE_DIRECTION_RTL; } else { isRTL = GET_BIDI_OPTION_DIRECTION(document->GetBidiOptions()) == IBMBIDI_TEXTDIRECTION_RTL; } gfxFontGroup* currentFontStyle = GetCurrentFontStyle(); if (!currentFontStyle) { return NS_ERROR_FAILURE; } MOZ_ASSERT(!presShell->IsDestroying(), "GetCurrentFontStyle() should have returned null if the presshell is being destroyed"); // ensure user font set is up to date currentFontStyle-> SetUserFontSet(presShell->GetPresContext()->GetUserFontSet()); if (currentFontStyle->GetStyle()->size == 0.0F) { if (aWidth) { *aWidth = 0; } return NS_OK; } const ContextState &state = CurrentState(); // This is only needed to know if we can know the drawing bounding box easily. bool doCalculateBounds = NeedToCalculateBounds(); CanvasBidiProcessor processor; // If we don't have a style context, we can't set up vertical-text flags // (for now, at least; perhaps we need new Canvas API to control this). processor.mTextRunFlags = canvasStyle ? nsLayoutUtils::GetTextRunFlagsForStyle(canvasStyle, canvasStyle->StyleFont(), canvasStyle->StyleText(), 0) : 0; GetAppUnitsValues(&processor.mAppUnitsPerDevPixel, nullptr); processor.mPt = gfxPoint(aX, aY); processor.mThebes = new gfxContext(gfxPlatform::GetPlatform()->ScreenReferenceDrawTarget()); // If we don't have a target then we don't have a transform. A target won't // be needed in the case where we're measuring the text size. This allows // to avoid creating a target if it's only being used to measure text sizes. if (mTarget) { Matrix matrix = mTarget->GetTransform(); processor.mThebes->SetMatrix(gfxMatrix(matrix._11, matrix._12, matrix._21, matrix._22, matrix._31, matrix._32)); } processor.mCtx = this; processor.mOp = aOp; processor.mBoundingBox = gfxRect(0, 0, 0, 0); processor.mDoMeasureBoundingBox = doCalculateBounds || !mIsEntireFrameInvalid; processor.mState = &CurrentState(); processor.mFontgrp = currentFontStyle; nscoord totalWidthCoord; // calls bidi algo twice since it needs the full text width and the // bounding boxes before rendering anything nsBidi bidiEngine; rv = nsBidiPresUtils::ProcessText(textToDraw.get(), textToDraw.Length(), isRTL ? NSBIDI_RTL : NSBIDI_LTR, presShell->GetPresContext(), processor, nsBidiPresUtils::MODE_MEASURE, nullptr, 0, &totalWidthCoord, &bidiEngine); if (NS_FAILED(rv)) { return rv; } float totalWidth = float(totalWidthCoord) / processor.mAppUnitsPerDevPixel; if (aWidth) { *aWidth = totalWidth; } // if only measuring, don't need to do any more work if (aOp==TextDrawOperation::MEASURE) { return NS_OK; } // offset pt.x based on text align gfxFloat anchorX; if (state.textAlign == TextAlign::CENTER) { anchorX = .5; } else if (state.textAlign == TextAlign::LEFT || (!isRTL && state.textAlign == TextAlign::START) || (isRTL && state.textAlign == TextAlign::END)) { anchorX = 0; } else { anchorX = 1; } processor.mPt.x -= anchorX * totalWidth; // offset pt.y (or pt.x, for vertical text) based on text baseline processor.mFontgrp->UpdateUserFonts(); // ensure user font generation is current const gfxFont::Metrics& fontMetrics = processor.mFontgrp->GetFirstValidFont()->GetMetrics(gfxFont::eHorizontal); gfxFloat baselineAnchor; switch (state.textBaseline) { case TextBaseline::HANGING: // fall through; best we can do with the information available case TextBaseline::TOP: baselineAnchor = fontMetrics.emAscent; break; case TextBaseline::MIDDLE: baselineAnchor = (fontMetrics.emAscent - fontMetrics.emDescent) * .5f; break; case TextBaseline::IDEOGRAPHIC: // fall through; best we can do with the information available case TextBaseline::ALPHABETIC: baselineAnchor = 0; break; case TextBaseline::BOTTOM: baselineAnchor = -fontMetrics.emDescent; break; default: MOZ_CRASH("unexpected TextBaseline"); } // We can't query the textRun directly, as it may not have been created yet; // so instead we check the flags that will be used to initialize it. uint16_t runOrientation = (processor.mTextRunFlags & gfxTextRunFactory::TEXT_ORIENT_MASK); if (runOrientation != gfxTextRunFactory::TEXT_ORIENT_HORIZONTAL) { if (runOrientation == gfxTextRunFactory::TEXT_ORIENT_VERTICAL_MIXED || runOrientation == gfxTextRunFactory::TEXT_ORIENT_VERTICAL_UPRIGHT) { // Adjust to account for mTextRun being shaped using center baseline // rather than alphabetic. baselineAnchor -= (fontMetrics.emAscent - fontMetrics.emDescent) * .5f; } processor.mPt.x -= baselineAnchor; } else { processor.mPt.y += baselineAnchor; } // correct bounding box to get it to be the correct size/position processor.mBoundingBox.width = totalWidth; processor.mBoundingBox.MoveBy(processor.mPt); processor.mPt.x *= processor.mAppUnitsPerDevPixel; processor.mPt.y *= processor.mAppUnitsPerDevPixel; EnsureTarget(); Matrix oldTransform = mTarget->GetTransform(); // if text is over aMaxWidth, then scale the text horizontally such that its // width is precisely aMaxWidth if (aMaxWidth.WasPassed() && aMaxWidth.Value() > 0 && totalWidth > aMaxWidth.Value()) { Matrix newTransform = oldTransform; // Translate so that the anchor point is at 0,0, then scale and then // translate back. newTransform.PreTranslate(aX, 0); newTransform.PreScale(aMaxWidth.Value() / totalWidth, 1); newTransform.PreTranslate(-aX, 0); /* we do this to avoid an ICE in the android compiler */ Matrix androidCompilerBug = newTransform; mTarget->SetTransform(androidCompilerBug); } // save the previous bounding box gfxRect boundingBox = processor.mBoundingBox; // don't ever need to measure the bounding box twice processor.mDoMeasureBoundingBox = false; rv = nsBidiPresUtils::ProcessText(textToDraw.get(), textToDraw.Length(), isRTL ? NSBIDI_RTL : NSBIDI_LTR, presShell->GetPresContext(), processor, nsBidiPresUtils::MODE_DRAW, nullptr, 0, nullptr, &bidiEngine); mTarget->SetTransform(oldTransform); if (aOp == CanvasRenderingContext2D::TextDrawOperation::FILL && !doCalculateBounds) { RedrawUser(boundingBox); return NS_OK; } Redraw(); return NS_OK; } gfxFontGroup *CanvasRenderingContext2D::GetCurrentFontStyle() { // use lazy initilization for the font group since it's rather expensive if (!CurrentState().fontGroup) { ErrorResult err; NS_NAMED_LITERAL_STRING(kDefaultFontStyle, "10px sans-serif"); static float kDefaultFontSize = 10.0; nsCOMPtr presShell = GetPresShell(); bool fontUpdated = SetFontInternal(kDefaultFontStyle, err); if (err.Failed() || !fontUpdated) { gfxFontStyle style; style.size = kDefaultFontSize; gfxTextPerfMetrics* tp = nullptr; if (presShell && !presShell->IsDestroying()) { tp = presShell->GetPresContext()->GetTextPerfMetrics(); } CurrentState().fontGroup = gfxPlatform::GetPlatform()->CreateFontGroup(FontFamilyList(eFamily_sans_serif), &style, tp, nullptr); if (CurrentState().fontGroup) { CurrentState().font = kDefaultFontStyle; } else { NS_ERROR("Default canvas font is invalid"); } } } return CurrentState().fontGroup; } // // line caps/joins // void CanvasRenderingContext2D::SetLineCap(const nsAString& capstyle) { CapStyle cap; if (capstyle.EqualsLiteral("butt")) { cap = CapStyle::BUTT; } else if (capstyle.EqualsLiteral("round")) { cap = CapStyle::ROUND; } else if (capstyle.EqualsLiteral("square")) { cap = CapStyle::SQUARE; } else { // XXX ERRMSG we need to report an error to developers here! (bug 329026) return; } CurrentState().lineCap = cap; } void CanvasRenderingContext2D::GetLineCap(nsAString& capstyle) { switch (CurrentState().lineCap) { case CapStyle::BUTT: capstyle.AssignLiteral("butt"); break; case CapStyle::ROUND: capstyle.AssignLiteral("round"); break; case CapStyle::SQUARE: capstyle.AssignLiteral("square"); break; } } void CanvasRenderingContext2D::SetLineJoin(const nsAString& joinstyle) { JoinStyle j; if (joinstyle.EqualsLiteral("round")) { j = JoinStyle::ROUND; } else if (joinstyle.EqualsLiteral("bevel")) { j = JoinStyle::BEVEL; } else if (joinstyle.EqualsLiteral("miter")) { j = JoinStyle::MITER_OR_BEVEL; } else { // XXX ERRMSG we need to report an error to developers here! (bug 329026) return; } CurrentState().lineJoin = j; } void CanvasRenderingContext2D::GetLineJoin(nsAString& joinstyle, ErrorResult& error) { switch (CurrentState().lineJoin) { case JoinStyle::ROUND: joinstyle.AssignLiteral("round"); break; case JoinStyle::BEVEL: joinstyle.AssignLiteral("bevel"); break; case JoinStyle::MITER_OR_BEVEL: joinstyle.AssignLiteral("miter"); break; default: error.Throw(NS_ERROR_FAILURE); } } void CanvasRenderingContext2D::SetMozDash(JSContext* cx, const JS::Value& mozDash, ErrorResult& error) { nsTArray dash; error = JSValToDashArray(cx, mozDash, dash); if (!error.Failed()) { ContextState& state = CurrentState(); state.dash = Move(dash); if (state.dash.IsEmpty()) { state.dashOffset = 0; } } } void CanvasRenderingContext2D::GetMozDash(JSContext* cx, JS::MutableHandle retval, ErrorResult& error) { DashArrayToJSVal(CurrentState().dash, cx, retval, error); } void CanvasRenderingContext2D::SetMozDashOffset(double mozDashOffset) { ContextState& state = CurrentState(); if (!state.dash.IsEmpty()) { state.dashOffset = mozDashOffset; } } void CanvasRenderingContext2D::SetLineDash(const Sequence& aSegments, ErrorResult& aRv) { nsTArray dash; for (uint32_t x = 0; x < aSegments.Length(); x++) { if (aSegments[x] < 0.0) { // Pattern elements must be finite "numbers" >= 0, with "finite" // taken care of by WebIDL return; } if (!dash.AppendElement(aSegments[x], fallible)) { aRv.Throw(NS_ERROR_OUT_OF_MEMORY); return; } } if (aSegments.Length() % 2) { // If the number of elements is odd, concatenate again for (uint32_t x = 0; x < aSegments.Length(); x++) { if (!dash.AppendElement(aSegments[x], fallible)) { aRv.Throw(NS_ERROR_OUT_OF_MEMORY); return; } } } CurrentState().dash = Move(dash); } void CanvasRenderingContext2D::GetLineDash(nsTArray& aSegments) const { const nsTArray& dash = CurrentState().dash; aSegments.Clear(); for (uint32_t x = 0; x < dash.Length(); x++) { aSegments.AppendElement(dash[x]); } } void CanvasRenderingContext2D::SetLineDashOffset(double mOffset) { CurrentState().dashOffset = mOffset; } double CanvasRenderingContext2D::LineDashOffset() const { return CurrentState().dashOffset; } bool CanvasRenderingContext2D::IsPointInPath(double x, double y, const CanvasWindingRule& winding) { if (!FloatValidate(x,y)) { return false; } EnsureUserSpacePath(winding); if (!mPath) { return false; } if (mPathTransformWillUpdate) { return mPath->ContainsPoint(Point(x, y), mPathToDS); } return mPath->ContainsPoint(Point(x, y), mTarget->GetTransform()); } bool CanvasRenderingContext2D::IsPointInPath(const CanvasPath& mPath, double x, double y, const CanvasWindingRule& mWinding) { if (!FloatValidate(x,y)) { return false; } EnsureTarget(); RefPtr tempPath = mPath.GetPath(mWinding, mTarget); return tempPath->ContainsPoint(Point(x, y), mTarget->GetTransform()); } bool CanvasRenderingContext2D::IsPointInStroke(double x, double y) { if (!FloatValidate(x,y)) { return false; } EnsureUserSpacePath(); if (!mPath) { return false; } const ContextState &state = CurrentState(); StrokeOptions strokeOptions(state.lineWidth, state.lineJoin, state.lineCap, state.miterLimit, state.dash.Length(), state.dash.Elements(), state.dashOffset); if (mPathTransformWillUpdate) { return mPath->StrokeContainsPoint(strokeOptions, Point(x, y), mPathToDS); } return mPath->StrokeContainsPoint(strokeOptions, Point(x, y), mTarget->GetTransform()); } bool CanvasRenderingContext2D::IsPointInStroke(const CanvasPath& mPath, double x, double y) { if (!FloatValidate(x,y)) { return false; } EnsureTarget(); RefPtr tempPath = mPath.GetPath(CanvasWindingRule::Nonzero, mTarget); const ContextState &state = CurrentState(); StrokeOptions strokeOptions(state.lineWidth, state.lineJoin, state.lineCap, state.miterLimit, state.dash.Length(), state.dash.Elements(), state.dashOffset); return tempPath->StrokeContainsPoint(strokeOptions, Point(x, y), mTarget->GetTransform()); } // Returns a surface that contains only the part needed to draw aSourceRect. // On entry, aSourceRect is relative to aSurface, and on return aSourceRect is // relative to the returned surface. static already_AddRefed ExtractSubrect(SourceSurface* aSurface, gfx::Rect* aSourceRect, DrawTarget* aTargetDT) { gfx::Rect roundedOutSourceRect = *aSourceRect; roundedOutSourceRect.RoundOut(); gfx::IntRect roundedOutSourceRectInt; if (!roundedOutSourceRect.ToIntRect(&roundedOutSourceRectInt)) { RefPtr surface(aSurface); return surface.forget(); } RefPtr subrectDT = aTargetDT->CreateSimilarDrawTarget(roundedOutSourceRectInt.Size(), SurfaceFormat::B8G8R8A8); if (!subrectDT) { RefPtr surface(aSurface); return surface.forget(); } *aSourceRect -= roundedOutSourceRect.TopLeft(); subrectDT->CopySurface(aSurface, roundedOutSourceRectInt, IntPoint()); return subrectDT->Snapshot(); } // Acts like nsLayoutUtils::SurfaceFromElement, but it'll attempt // to pull a SourceSurface from our cache. This allows us to avoid // reoptimizing surfaces if content and canvas backends are different. nsLayoutUtils::SurfaceFromElementResult CanvasRenderingContext2D::CachedSurfaceFromElement(Element* aElement) { nsLayoutUtils::SurfaceFromElementResult res; nsCOMPtr imageLoader = do_QueryInterface(aElement); if (!imageLoader) { return res; } nsCOMPtr imgRequest; imageLoader->GetRequest(nsIImageLoadingContent::CURRENT_REQUEST, getter_AddRefs(imgRequest)); if (!imgRequest) { return res; } uint32_t status; if (NS_FAILED(imgRequest->GetImageStatus(&status)) || !(status & imgIRequest::STATUS_LOAD_COMPLETE)) { return res; } nsCOMPtr principal; if (NS_FAILED(imgRequest->GetImagePrincipal(getter_AddRefs(principal))) || !principal) { return res; } res.mSourceSurface = CanvasImageCache::SimpleLookup(aElement); if (!res.mSourceSurface) { return res; } int32_t corsmode = imgIRequest::CORS_NONE; if (NS_SUCCEEDED(imgRequest->GetCORSMode(&corsmode))) { res.mCORSUsed = corsmode != imgIRequest::CORS_NONE; } res.mSize = res.mSourceSurface->GetSize(); res.mPrincipal = principal.forget(); res.mIsWriteOnly = false; res.mImageRequest = imgRequest.forget(); return res; } // // image // static void ClipImageDimension(double& aSourceCoord, double& aSourceSize, int32_t aImageSize, double& aDestCoord, double& aDestSize) { double scale = aDestSize / aSourceSize; if (aSourceCoord < 0.0) { double destEnd = aDestCoord + aDestSize; aDestCoord -= aSourceCoord * scale; aDestSize = destEnd - aDestCoord; aSourceSize += aSourceCoord; aSourceCoord = 0.0; } double delta = aImageSize - (aSourceCoord + aSourceSize); if (delta < 0.0) { aDestSize += delta * scale; aSourceSize = aImageSize - aSourceCoord; } } // drawImage(in HTMLImageElement image, in float dx, in float dy); // -- render image from 0,0 at dx,dy top-left coords // drawImage(in HTMLImageElement image, in float dx, in float dy, in float sw, in float sh); // -- render image from 0,0 at dx,dy top-left coords clipping it to sw,sh // drawImage(in HTMLImageElement image, in float sx, in float sy, in float sw, in float sh, in float dx, in float dy, in float dw, in float dh); // -- render the region defined by (sx,sy,sw,wh) in image-local space into the region (dx,dy,dw,dh) on the canvas // If only dx and dy are passed in then optional_argc should be 0. If only // dx, dy, dw and dh are passed in then optional_argc should be 2. The only // other valid value for optional_argc is 6 if sx, sy, sw, sh, dx, dy, dw and dh // are all passed in. void CanvasRenderingContext2D::DrawImage(const CanvasImageSource& image, double sx, double sy, double sw, double sh, double dx, double dy, double dw, double dh, uint8_t optional_argc, ErrorResult& error) { if (mDrawObserver) { mDrawObserver->DidDrawCall(CanvasDrawObserver::DrawCallType::DrawImage); } MOZ_ASSERT(optional_argc == 0 || optional_argc == 2 || optional_argc == 6); if (optional_argc == 6) { NormalizeRect(sx, sy, sw, sh); NormalizeRect(dx, dy, dw, dh); } RefPtr srcSurf; gfx::IntSize imgSize; Element* element = nullptr; EnsureTarget(); if (image.IsHTMLCanvasElement()) { HTMLCanvasElement* canvas = &image.GetAsHTMLCanvasElement(); element = canvas; nsIntSize size = canvas->GetSize(); if (size.width == 0 || size.height == 0) { error.Throw(NS_ERROR_DOM_INVALID_STATE_ERR); return; } } else if (image.IsImageBitmap()) { ImageBitmap& imageBitmap = image.GetAsImageBitmap(); srcSurf = imageBitmap.PrepareForDrawTarget(mTarget); if (!srcSurf) { return; } imgSize = gfx::IntSize(imageBitmap.Width(), imageBitmap.Height()); } else { if (image.IsHTMLImageElement()) { HTMLImageElement* img = &image.GetAsHTMLImageElement(); element = img; } else { HTMLVideoElement* video = &image.GetAsHTMLVideoElement(); element = video; } srcSurf = CanvasImageCache::Lookup(element, mCanvasElement, &imgSize); } nsLayoutUtils::DirectDrawInfo drawInfo; #ifdef USE_SKIA_GPU if (mRenderingMode == RenderingMode::OpenGLBackendMode && !srcSurf && image.IsHTMLVideoElement() && gfxPlatform::GetPlatform()->GetSkiaGLGlue()) { mozilla::gl::GLContext* gl = gfxPlatform::GetPlatform()->GetSkiaGLGlue()->GetGLContext(); HTMLVideoElement* video = &image.GetAsHTMLVideoElement(); if (!video) { return; } #ifdef MOZ_EME if (video->ContainsRestrictedContent()) { error.Throw(NS_ERROR_NOT_AVAILABLE); return; } #endif uint16_t readyState; if (NS_SUCCEEDED(video->GetReadyState(&readyState)) && readyState < nsIDOMHTMLMediaElement::HAVE_CURRENT_DATA) { // still loading, just return return; } // If it doesn't have a principal, just bail nsCOMPtr principal = video->GetCurrentPrincipal(); if (!principal) { error.Throw(NS_ERROR_NOT_AVAILABLE); return; } mozilla::layers::ImageContainer* container = video->GetImageContainer(); if (!container) { error.Throw(NS_ERROR_NOT_AVAILABLE); return; } AutoLockImage lockImage(container); layers::Image* srcImage = lockImage.GetImage(); if (!srcImage) { error.Throw(NS_ERROR_NOT_AVAILABLE); return; } gl->MakeCurrent(); if (!mVideoTexture) { gl->fGenTextures(1, &mVideoTexture); } // skiaGL expect upload on drawing, and uses texture 0 for texturing, // so we must active texture 0 and bind the texture for it. gl->fActiveTexture(LOCAL_GL_TEXTURE0); gl->fBindTexture(LOCAL_GL_TEXTURE_2D, mVideoTexture); bool dimensionsMatch = mCurrentVideoSize.width == srcImage->GetSize().width && mCurrentVideoSize.height == srcImage->GetSize().height; if (!dimensionsMatch) { // we need to allocation mCurrentVideoSize.width = srcImage->GetSize().width; mCurrentVideoSize.height = srcImage->GetSize().height; gl->fTexImage2D(LOCAL_GL_TEXTURE_2D, 0, LOCAL_GL_RGB, srcImage->GetSize().width, srcImage->GetSize().height, 0, LOCAL_GL_RGB, LOCAL_GL_UNSIGNED_SHORT_5_6_5, nullptr); gl->fTexParameteri(LOCAL_GL_TEXTURE_2D, LOCAL_GL_TEXTURE_WRAP_S, LOCAL_GL_CLAMP_TO_EDGE); gl->fTexParameteri(LOCAL_GL_TEXTURE_2D, LOCAL_GL_TEXTURE_WRAP_T, LOCAL_GL_CLAMP_TO_EDGE); gl->fTexParameteri(LOCAL_GL_TEXTURE_2D, LOCAL_GL_TEXTURE_MAG_FILTER, LOCAL_GL_LINEAR); gl->fTexParameteri(LOCAL_GL_TEXTURE_2D, LOCAL_GL_TEXTURE_MIN_FILTER, LOCAL_GL_LINEAR); } const gl::OriginPos destOrigin = gl::OriginPos::TopLeft; bool ok = gl->BlitHelper()->BlitImageToTexture(srcImage, srcImage->GetSize(), mVideoTexture, LOCAL_GL_TEXTURE_2D, destOrigin); if (ok) { NativeSurface texSurf; texSurf.mType = NativeSurfaceType::OPENGL_TEXTURE; texSurf.mFormat = SurfaceFormat::R5G6B5; texSurf.mSize.width = mCurrentVideoSize.width; texSurf.mSize.height = mCurrentVideoSize.height; texSurf.mSurface = (void*)((uintptr_t)mVideoTexture); srcSurf = mTarget->CreateSourceSurfaceFromNativeSurface(texSurf); imgSize.width = mCurrentVideoSize.width; imgSize.height = mCurrentVideoSize.height; int32_t displayWidth = video->VideoWidth(); int32_t displayHeight = video->VideoHeight(); sw *= (double)imgSize.width / (double)displayWidth; sh *= (double)imgSize.height / (double)displayHeight; } srcImage = nullptr; if (mCanvasElement) { CanvasUtils::DoDrawImageSecurityCheck(mCanvasElement, principal, false, video->GetCORSMode() != CORS_NONE); } } #endif if (!srcSurf) { // The canvas spec says that drawImage should draw the first frame // of animated images. We also don't want to rasterize vector images. uint32_t sfeFlags = nsLayoutUtils::SFE_WANT_FIRST_FRAME | nsLayoutUtils::SFE_NO_RASTERIZING_VECTORS; // The cache lookup can miss even if the image is already in the cache // if the image is coming from a different element or cached for a // different canvas. This covers the case when we miss due to caching // for a different canvas, but CanvasImageCache should be fixed if we // see misses due to different elements drawing the same image. nsLayoutUtils::SurfaceFromElementResult res = CachedSurfaceFromElement(element); if (!res.mSourceSurface) res = nsLayoutUtils::SurfaceFromElement(element, sfeFlags, mTarget); if (!res.mSourceSurface && !res.mDrawInfo.mImgContainer) { // The spec says to silently do nothing in the following cases: // - The element is still loading. // - The image is bad, but it's not in the broken state (i.e., we could // decode the headers and get the size). if (!res.mIsStillLoading && !res.mHasSize) { error.Throw(NS_ERROR_NOT_AVAILABLE); } return; } imgSize = res.mSize; // Scale sw/sh based on aspect ratio if (image.IsHTMLVideoElement()) { HTMLVideoElement* video = &image.GetAsHTMLVideoElement(); int32_t displayWidth = video->VideoWidth(); int32_t displayHeight = video->VideoHeight(); sw *= (double)imgSize.width / (double)displayWidth; sh *= (double)imgSize.height / (double)displayHeight; } if (mCanvasElement) { CanvasUtils::DoDrawImageSecurityCheck(mCanvasElement, res.mPrincipal, res.mIsWriteOnly, res.mCORSUsed); } if (res.mSourceSurface) { if (res.mImageRequest) { CanvasImageCache::NotifyDrawImage(element, mCanvasElement, res.mImageRequest, res.mSourceSurface, imgSize); } srcSurf = res.mSourceSurface; } else { drawInfo = res.mDrawInfo; } } if (optional_argc == 0) { sx = sy = 0.0; dw = sw = (double) imgSize.width; dh = sh = (double) imgSize.height; } else if (optional_argc == 2) { sx = sy = 0.0; sw = (double) imgSize.width; sh = (double) imgSize.height; } if (sw == 0.0 || sh == 0.0) { error.Throw(NS_ERROR_DOM_INDEX_SIZE_ERR); return; } ClipImageDimension(sx, sw, imgSize.width, dx, dw); ClipImageDimension(sy, sh, imgSize.height, dy, dh); if (sw <= 0.0 || sh <= 0.0 || dw <= 0.0 || dh <= 0.0) { // source and/or destination are fully clipped, so nothing is painted return; } Filter filter; if (CurrentState().imageSmoothingEnabled) filter = gfx::Filter::LINEAR; else filter = gfx::Filter::POINT; gfx::Rect bounds; if (NeedToCalculateBounds()) { bounds = gfx::Rect(dx, dy, dw, dh); bounds = mTarget->GetTransform().TransformBounds(bounds); } if (srcSurf) { gfx::Rect sourceRect(sx, sy, sw, sh); if (element == mCanvasElement) { // srcSurf is a snapshot of mTarget. If we draw to mTarget now, we'll // trigger a COW copy of the whole canvas into srcSurf. That's a huge // waste if sourceRect doesn't cover the whole canvas. // We avoid copying the whole canvas by manually copying just the part // that we need. srcSurf = ExtractSubrect(srcSurf, &sourceRect, mTarget); } AdjustedTarget(this, bounds.IsEmpty() ? nullptr : &bounds)-> DrawSurface(srcSurf, gfx::Rect(dx, dy, dw, dh), sourceRect, DrawSurfaceOptions(filter), DrawOptions(CurrentState().globalAlpha, UsedOperation())); } else { DrawDirectlyToCanvas(drawInfo, &bounds, gfx::Rect(dx, dy, dw, dh), gfx::Rect(sx, sy, sw, sh), imgSize); } RedrawUser(gfxRect(dx, dy, dw, dh)); } void CanvasRenderingContext2D::DrawDirectlyToCanvas( const nsLayoutUtils::DirectDrawInfo& image, gfx::Rect* bounds, gfx::Rect dest, gfx::Rect src, gfx::IntSize imgSize) { MOZ_ASSERT(src.width > 0 && src.height > 0, "Need positive source width and height"); gfxMatrix contextMatrix; AdjustedTarget tempTarget(this, bounds->IsEmpty() ? nullptr: bounds); // Get any existing transforms on the context, including transformations used // for context shadow. if (tempTarget) { Matrix matrix = tempTarget->GetTransform(); contextMatrix = gfxMatrix(matrix._11, matrix._12, matrix._21, matrix._22, matrix._31, matrix._32); } gfxSize contextScale(contextMatrix.ScaleFactors(true)); // Scale the dest rect to include the context scale. dest.Scale(contextScale.width, contextScale.height); // Scale the image size to the dest rect, and adjust the source rect to match. gfxSize scale(dest.width / src.width, dest.height / src.height); nsIntSize scaledImageSize(std::ceil(imgSize.width * scale.width), std::ceil(imgSize.height * scale.height)); src.Scale(scale.width, scale.height); // We're wrapping tempTarget's (our) DrawTarget here, so we need to restore // the matrix even though this is a temp gfxContext. AutoRestoreTransform autoRestoreTransform(mTarget); nsRefPtr context = new gfxContext(tempTarget); context->SetMatrix(contextMatrix. Scale(1.0 / contextScale.width, 1.0 / contextScale.height). Translate(dest.x - src.x, dest.y - src.y)); // FLAG_CLAMP is added for increased performance, since we never tile here. uint32_t modifiedFlags = image.mDrawingFlags | imgIContainer::FLAG_CLAMP; CSSIntSize sz(scaledImageSize.width, scaledImageSize.height); // XXX hmm is scaledImageSize really in CSS pixels? SVGImageContext svgContext(sz, Nothing(), CurrentState().globalAlpha); auto result = image.mImgContainer-> Draw(context, scaledImageSize, ImageRegion::Create(gfxRect(src.x, src.y, src.width, src.height)), image.mWhichFrame, Filter::GOOD, Some(svgContext), modifiedFlags); if (result != DrawResult::SUCCESS) { NS_WARNING("imgIContainer::Draw failed"); } } void CanvasRenderingContext2D::SetGlobalCompositeOperation(const nsAString& op, ErrorResult& error) { CompositionOp comp_op; #define CANVAS_OP_TO_GFX_OP(cvsop, op2d) \ if (op.EqualsLiteral(cvsop)) \ comp_op = CompositionOp::OP_##op2d; CANVAS_OP_TO_GFX_OP("copy", SOURCE) else CANVAS_OP_TO_GFX_OP("source-atop", ATOP) else CANVAS_OP_TO_GFX_OP("source-in", IN) else CANVAS_OP_TO_GFX_OP("source-out", OUT) else CANVAS_OP_TO_GFX_OP("source-over", OVER) else CANVAS_OP_TO_GFX_OP("destination-in", DEST_IN) else CANVAS_OP_TO_GFX_OP("destination-out", DEST_OUT) else CANVAS_OP_TO_GFX_OP("destination-over", DEST_OVER) else CANVAS_OP_TO_GFX_OP("destination-atop", DEST_ATOP) else CANVAS_OP_TO_GFX_OP("lighter", ADD) else CANVAS_OP_TO_GFX_OP("xor", XOR) else CANVAS_OP_TO_GFX_OP("multiply", MULTIPLY) else CANVAS_OP_TO_GFX_OP("screen", SCREEN) else CANVAS_OP_TO_GFX_OP("overlay", OVERLAY) else CANVAS_OP_TO_GFX_OP("darken", DARKEN) else CANVAS_OP_TO_GFX_OP("lighten", LIGHTEN) else CANVAS_OP_TO_GFX_OP("color-dodge", COLOR_DODGE) else CANVAS_OP_TO_GFX_OP("color-burn", COLOR_BURN) else CANVAS_OP_TO_GFX_OP("hard-light", HARD_LIGHT) else CANVAS_OP_TO_GFX_OP("soft-light", SOFT_LIGHT) else CANVAS_OP_TO_GFX_OP("difference", DIFFERENCE) else CANVAS_OP_TO_GFX_OP("exclusion", EXCLUSION) else CANVAS_OP_TO_GFX_OP("hue", HUE) else CANVAS_OP_TO_GFX_OP("saturation", SATURATION) else CANVAS_OP_TO_GFX_OP("color", COLOR) else CANVAS_OP_TO_GFX_OP("luminosity", LUMINOSITY) // XXX ERRMSG we need to report an error to developers here! (bug 329026) else return; #undef CANVAS_OP_TO_GFX_OP CurrentState().op = comp_op; } void CanvasRenderingContext2D::GetGlobalCompositeOperation(nsAString& op, ErrorResult& error) { CompositionOp comp_op = CurrentState().op; #define CANVAS_OP_TO_GFX_OP(cvsop, op2d) \ if (comp_op == CompositionOp::OP_##op2d) \ op.AssignLiteral(cvsop); CANVAS_OP_TO_GFX_OP("copy", SOURCE) else CANVAS_OP_TO_GFX_OP("destination-atop", DEST_ATOP) else CANVAS_OP_TO_GFX_OP("destination-in", DEST_IN) else CANVAS_OP_TO_GFX_OP("destination-out", DEST_OUT) else CANVAS_OP_TO_GFX_OP("destination-over", DEST_OVER) else CANVAS_OP_TO_GFX_OP("lighter", ADD) else CANVAS_OP_TO_GFX_OP("source-atop", ATOP) else CANVAS_OP_TO_GFX_OP("source-in", IN) else CANVAS_OP_TO_GFX_OP("source-out", OUT) else CANVAS_OP_TO_GFX_OP("source-over", OVER) else CANVAS_OP_TO_GFX_OP("xor", XOR) else CANVAS_OP_TO_GFX_OP("multiply", MULTIPLY) else CANVAS_OP_TO_GFX_OP("screen", SCREEN) else CANVAS_OP_TO_GFX_OP("overlay", OVERLAY) else CANVAS_OP_TO_GFX_OP("darken", DARKEN) else CANVAS_OP_TO_GFX_OP("lighten", LIGHTEN) else CANVAS_OP_TO_GFX_OP("color-dodge", COLOR_DODGE) else CANVAS_OP_TO_GFX_OP("color-burn", COLOR_BURN) else CANVAS_OP_TO_GFX_OP("hard-light", HARD_LIGHT) else CANVAS_OP_TO_GFX_OP("soft-light", SOFT_LIGHT) else CANVAS_OP_TO_GFX_OP("difference", DIFFERENCE) else CANVAS_OP_TO_GFX_OP("exclusion", EXCLUSION) else CANVAS_OP_TO_GFX_OP("hue", HUE) else CANVAS_OP_TO_GFX_OP("saturation", SATURATION) else CANVAS_OP_TO_GFX_OP("color", COLOR) else CANVAS_OP_TO_GFX_OP("luminosity", LUMINOSITY) else { error.Throw(NS_ERROR_FAILURE); } #undef CANVAS_OP_TO_GFX_OP } void CanvasRenderingContext2D::DrawWindow(nsGlobalWindow& window, double x, double y, double w, double h, const nsAString& bgColor, uint32_t flags, ErrorResult& error) { // protect against too-large surfaces that will cause allocation // or overflow issues if (!gfxASurface::CheckSurfaceSize(gfx::IntSize(int32_t(w), int32_t(h)), 0xffff)) { error.Throw(NS_ERROR_FAILURE); return; } EnsureTarget(); // We can't allow web apps to call this until we fix at least the // following potential security issues: // -- rendering cross-domain IFRAMEs and then extracting the results // -- rendering the user's theme and then extracting the results // -- rendering native anonymous content (e.g., file input paths; // scrollbars should be allowed) if (!nsContentUtils::IsCallerChrome()) { // not permitted to use DrawWindow // XXX ERRMSG we need to report an error to developers here! (bug 329026) error.Throw(NS_ERROR_DOM_SECURITY_ERR); return; } // Flush layout updates if (!(flags & nsIDOMCanvasRenderingContext2D::DRAWWINDOW_DO_NOT_FLUSH)) { nsContentUtils::FlushLayoutForTree(&window); } nsRefPtr presContext; nsIDocShell* docshell = window.GetDocShell(); if (docshell) { docshell->GetPresContext(getter_AddRefs(presContext)); } if (!presContext) { error.Throw(NS_ERROR_FAILURE); return; } nscolor backgroundColor; if (!ParseColor(bgColor, &backgroundColor)) { error.Throw(NS_ERROR_FAILURE); return; } nsRect r(nsPresContext::CSSPixelsToAppUnits((float)x), nsPresContext::CSSPixelsToAppUnits((float)y), nsPresContext::CSSPixelsToAppUnits((float)w), nsPresContext::CSSPixelsToAppUnits((float)h)); uint32_t renderDocFlags = (nsIPresShell::RENDER_IGNORE_VIEWPORT_SCROLLING | nsIPresShell::RENDER_DOCUMENT_RELATIVE); if (flags & nsIDOMCanvasRenderingContext2D::DRAWWINDOW_DRAW_CARET) { renderDocFlags |= nsIPresShell::RENDER_CARET; } if (flags & nsIDOMCanvasRenderingContext2D::DRAWWINDOW_DRAW_VIEW) { renderDocFlags &= ~(nsIPresShell::RENDER_IGNORE_VIEWPORT_SCROLLING | nsIPresShell::RENDER_DOCUMENT_RELATIVE); } if (flags & nsIDOMCanvasRenderingContext2D::DRAWWINDOW_USE_WIDGET_LAYERS) { renderDocFlags |= nsIPresShell::RENDER_USE_WIDGET_LAYERS; } if (flags & nsIDOMCanvasRenderingContext2D::DRAWWINDOW_ASYNC_DECODE_IMAGES) { renderDocFlags |= nsIPresShell::RENDER_ASYNC_DECODE_IMAGES; } if (flags & nsIDOMCanvasRenderingContext2D::DRAWWINDOW_DO_NOT_FLUSH) { renderDocFlags |= nsIPresShell::RENDER_DRAWWINDOW_NOT_FLUSHING; } // gfxContext-over-Azure may modify the DrawTarget's transform, so // save and restore it Matrix matrix = mTarget->GetTransform(); double sw = matrix._11 * w; double sh = matrix._22 * h; if (!sw || !sh) { return; } nsRefPtr thebes; RefPtr drawDT; // Rendering directly is faster and can be done if mTarget supports Azure // and does not need alpha blending. if (gfxPlatform::GetPlatform()->SupportsAzureContentForDrawTarget(mTarget) && GlobalAlpha() == 1.0f) { thebes = new gfxContext(mTarget); thebes->SetMatrix(gfxMatrix(matrix._11, matrix._12, matrix._21, matrix._22, matrix._31, matrix._32)); } else { drawDT = gfxPlatform::GetPlatform()->CreateOffscreenContentDrawTarget(IntSize(ceil(sw), ceil(sh)), SurfaceFormat::B8G8R8A8); if (!drawDT) { error.Throw(NS_ERROR_FAILURE); return; } thebes = new gfxContext(drawDT); thebes->SetMatrix(gfxMatrix::Scaling(matrix._11, matrix._22)); } nsCOMPtr shell = presContext->PresShell(); unused << shell->RenderDocument(r, renderDocFlags, backgroundColor, thebes); if (drawDT) { RefPtr snapshot = drawDT->Snapshot(); RefPtr data = snapshot->GetDataSurface(); DataSourceSurface::MappedSurface rawData; if (NS_WARN_IF(!data->Map(DataSourceSurface::READ, &rawData))) { error.Throw(NS_ERROR_FAILURE); return; } RefPtr source = mTarget->CreateSourceSurfaceFromData(rawData.mData, data->GetSize(), rawData.mStride, data->GetFormat()); data->Unmap(); if (!source) { error.Throw(NS_ERROR_FAILURE); return; } gfx::Rect destRect(0, 0, w, h); gfx::Rect sourceRect(0, 0, sw, sh); mTarget->DrawSurface(source, destRect, sourceRect, DrawSurfaceOptions(gfx::Filter::POINT), DrawOptions(GlobalAlpha(), CompositionOp::OP_OVER, AntialiasMode::NONE)); mTarget->Flush(); } else { mTarget->SetTransform(matrix); } // note that x and y are coordinates in the document that // we're drawing; x and y are drawn to 0,0 in current user // space. RedrawUser(gfxRect(0, 0, w, h)); } void CanvasRenderingContext2D::AsyncDrawXULElement(nsXULElement& elem, double x, double y, double w, double h, const nsAString& bgColor, uint32_t flags, ErrorResult& error) { // We can't allow web apps to call this until we fix at least the // following potential security issues: // -- rendering cross-domain IFRAMEs and then extracting the results // -- rendering the user's theme and then extracting the results // -- rendering native anonymous content (e.g., file input paths; // scrollbars should be allowed) if (!nsContentUtils::IsCallerChrome()) { // not permitted to use DrawWindow // XXX ERRMSG we need to report an error to developers here! (bug 329026) error.Throw(NS_ERROR_DOM_SECURITY_ERR); return; } #if 0 nsCOMPtr loaderOwner = do_QueryInterface(&elem); if (!loaderOwner) { error.Throw(NS_ERROR_FAILURE); return; } nsRefPtr frameloader = loaderOwner->GetFrameLoader(); if (!frameloader) { error.Throw(NS_ERROR_FAILURE); return; } PBrowserParent *child = frameloader->GetRemoteBrowser(); if (!child) { nsIDocShell* docShell = frameLoader->GetExistingDocShell(); if (!docShell) { error.Throw(NS_ERROR_FAILURE); return; } nsCOMPtr window = docShell->GetWindow(); if (!window) { error.Throw(NS_ERROR_FAILURE); return; } return DrawWindow(window, x, y, w, h, bgColor, flags); } // protect against too-large surfaces that will cause allocation // or overflow issues if (!gfxASurface::CheckSurfaceSize(gfx::IntSize(w, h), 0xffff)) { error.Throw(NS_ERROR_FAILURE); return; } bool flush = (flags & nsIDOMCanvasRenderingContext2D::DRAWWINDOW_DO_NOT_FLUSH) == 0; uint32_t renderDocFlags = nsIPresShell::RENDER_IGNORE_VIEWPORT_SCROLLING; if (flags & nsIDOMCanvasRenderingContext2D::DRAWWINDOW_DRAW_CARET) { renderDocFlags |= nsIPresShell::RENDER_CARET; } if (flags & nsIDOMCanvasRenderingContext2D::DRAWWINDOW_DRAW_VIEW) { renderDocFlags &= ~nsIPresShell::RENDER_IGNORE_VIEWPORT_SCROLLING; } nsRect rect(nsPresContext::CSSPixelsToAppUnits(x), nsPresContext::CSSPixelsToAppUnits(y), nsPresContext::CSSPixelsToAppUnits(w), nsPresContext::CSSPixelsToAppUnits(h)); if (mIPC) { PDocumentRendererParent *pdocrender = child->SendPDocumentRendererConstructor(rect, mThebes->CurrentMatrix(), nsString(aBGColor), renderDocFlags, flush, nsIntSize(mWidth, mHeight)); if (!pdocrender) return NS_ERROR_FAILURE; DocumentRendererParent *docrender = static_cast(pdocrender); docrender->SetCanvasContext(this, mThebes); } #endif } void CanvasRenderingContext2D::DrawWidgetAsOnScreen(nsGlobalWindow& aWindow, mozilla::ErrorResult& error) { EnsureTarget(); // This is an internal API. if (!nsContentUtils::IsCallerChrome()) { error.Throw(NS_ERROR_DOM_SECURITY_ERR); return; } nsRefPtr presContext; nsIDocShell* docshell = aWindow.GetDocShell(); if (docshell) { docshell->GetPresContext(getter_AddRefs(presContext)); } if (!presContext) { error.Throw(NS_ERROR_FAILURE); return; } nsIWidget* widget = presContext->GetRootWidget(); if (!widget) { error.Throw(NS_ERROR_FAILURE); return; } RefPtr snapshot = widget->SnapshotWidgetOnScreen(); if (!snapshot) { error.Throw(NS_ERROR_FAILURE); return; } gfx::Rect sourceRect(gfx::Point(0, 0), gfx::Size(snapshot->GetSize())); mTarget->DrawSurface(snapshot, sourceRect, sourceRect, DrawSurfaceOptions(gfx::Filter::POINT), DrawOptions(GlobalAlpha(), CompositionOp::OP_OVER, AntialiasMode::NONE)); mTarget->Flush(); RedrawUser(gfxRect(0, 0, std::min(mWidth, snapshot->GetSize().width), std::min(mHeight, snapshot->GetSize().height))); } // // device pixel getting/setting // already_AddRefed CanvasRenderingContext2D::GetImageData(JSContext* aCx, double aSx, double aSy, double aSw, double aSh, ErrorResult& error) { if (mDrawObserver) { mDrawObserver->DidDrawCall(CanvasDrawObserver::DrawCallType::GetImageData); } EnsureTarget(); if (!IsTargetValid()) { error.Throw(NS_ERROR_FAILURE); return nullptr; } if (!mCanvasElement && !mDocShell) { NS_ERROR("No canvas element and no docshell in GetImageData!!!"); error.Throw(NS_ERROR_DOM_SECURITY_ERR); return nullptr; } // Check only if we have a canvas element; if we were created with a docshell, // then it's special internal use. if (mCanvasElement && mCanvasElement->IsWriteOnly() && !nsContentUtils::IsCallerChrome()) { // XXX ERRMSG we need to report an error to developers here! (bug 329026) error.Throw(NS_ERROR_DOM_SECURITY_ERR); return nullptr; } if (!IsFinite(aSx) || !IsFinite(aSy) || !IsFinite(aSw) || !IsFinite(aSh)) { error.Throw(NS_ERROR_DOM_NOT_SUPPORTED_ERR); return nullptr; } if (!aSw || !aSh) { error.Throw(NS_ERROR_DOM_INDEX_SIZE_ERR); return nullptr; } int32_t x = JS::ToInt32(aSx); int32_t y = JS::ToInt32(aSy); int32_t wi = JS::ToInt32(aSw); int32_t hi = JS::ToInt32(aSh); // Handle negative width and height by flipping the rectangle over in the // relevant direction. uint32_t w, h; if (aSw < 0) { w = -wi; x -= w; } else { w = wi; } if (aSh < 0) { h = -hi; y -= h; } else { h = hi; } if (w == 0) { w = 1; } if (h == 0) { h = 1; } JS::Rooted array(aCx); error = GetImageDataArray(aCx, x, y, w, h, array.address()); if (error.Failed()) { return nullptr; } MOZ_ASSERT(array); nsRefPtr imageData = new ImageData(w, h, *array); return imageData.forget(); } nsresult CanvasRenderingContext2D::GetImageDataArray(JSContext* aCx, int32_t aX, int32_t aY, uint32_t aWidth, uint32_t aHeight, JSObject** aRetval) { if (mDrawObserver) { mDrawObserver->DidDrawCall(CanvasDrawObserver::DrawCallType::GetImageData); } MOZ_ASSERT(aWidth && aHeight); CheckedInt len = CheckedInt(aWidth) * aHeight * 4; if (!len.isValid()) { return NS_ERROR_DOM_INDEX_SIZE_ERR; } CheckedInt rightMost = CheckedInt(aX) + aWidth; CheckedInt bottomMost = CheckedInt(aY) + aHeight; if (!rightMost.isValid() || !bottomMost.isValid()) { return NS_ERROR_DOM_SYNTAX_ERR; } JS::Rooted darray(aCx, JS_NewUint8ClampedArray(aCx, len.value())); if (!darray) { return NS_ERROR_OUT_OF_MEMORY; } if (mZero) { *aRetval = darray; return NS_OK; } IntRect srcRect(0, 0, mWidth, mHeight); IntRect destRect(aX, aY, aWidth, aHeight); IntRect srcReadRect = srcRect.Intersect(destRect); RefPtr readback; DataSourceSurface::MappedSurface rawData; if (!srcReadRect.IsEmpty()) { RefPtr snapshot = mTarget->Snapshot(); if (snapshot) { readback = snapshot->GetDataSurface(); } if (!readback || !readback->Map(DataSourceSurface::READ, &rawData)) { return NS_ERROR_OUT_OF_MEMORY; } } IntRect dstWriteRect = srcReadRect; dstWriteRect.MoveBy(-aX, -aY); uint8_t* src; uint32_t srcStride; if (readback) { srcStride = rawData.mStride; src = rawData.mData + srcReadRect.y * srcStride + srcReadRect.x * 4; } JS::AutoCheckCannotGC nogc; uint8_t* data = JS_GetUint8ClampedArrayData(darray, nogc); if (!readback) { src = data; srcStride = aWidth * 4; } uint8_t* dst = data + dstWriteRect.y * (aWidth * 4) + dstWriteRect.x * 4; if (mOpaque) { for (int32_t j = 0; j < dstWriteRect.height; ++j) { for (int32_t i = 0; i < dstWriteRect.width; ++i) { // XXX Is there some useful swizzle MMX we can use here? #if MOZ_LITTLE_ENDIAN uint8_t b = *src++; uint8_t g = *src++; uint8_t r = *src++; src++; #else src++; uint8_t r = *src++; uint8_t g = *src++; uint8_t b = *src++; #endif *dst++ = r; *dst++ = g; *dst++ = b; *dst++ = 255; } src += srcStride - (dstWriteRect.width * 4); dst += (aWidth * 4) - (dstWriteRect.width * 4); } } else for (int32_t j = 0; j < dstWriteRect.height; ++j) { for (int32_t i = 0; i < dstWriteRect.width; ++i) { // XXX Is there some useful swizzle MMX we can use here? #if MOZ_LITTLE_ENDIAN uint8_t b = *src++; uint8_t g = *src++; uint8_t r = *src++; uint8_t a = *src++; #else uint8_t a = *src++; uint8_t r = *src++; uint8_t g = *src++; uint8_t b = *src++; #endif // Convert to non-premultiplied color *dst++ = gfxUtils::sUnpremultiplyTable[a * 256 + r]; *dst++ = gfxUtils::sUnpremultiplyTable[a * 256 + g]; *dst++ = gfxUtils::sUnpremultiplyTable[a * 256 + b]; *dst++ = a; } src += srcStride - (dstWriteRect.width * 4); dst += (aWidth * 4) - (dstWriteRect.width * 4); } if (readback) { readback->Unmap(); } *aRetval = darray; return NS_OK; } void CanvasRenderingContext2D::EnsureErrorTarget() { if (sErrorTarget) { return; } RefPtr errorTarget = gfxPlatform::GetPlatform()->CreateOffscreenCanvasDrawTarget(IntSize(1, 1), SurfaceFormat::B8G8R8A8); MOZ_ASSERT(errorTarget, "Failed to allocate the error target!"); sErrorTarget = errorTarget; NS_ADDREF(sErrorTarget); } void CanvasRenderingContext2D::FillRuleChanged() { if (mPath) { mPathBuilder = mPath->CopyToBuilder(CurrentState().fillRule); mPath = nullptr; } } void CanvasRenderingContext2D::PutImageData(ImageData& imageData, double dx, double dy, ErrorResult& error) { dom::Uint8ClampedArray arr; DebugOnly inited = arr.Init(imageData.GetDataObject()); MOZ_ASSERT(inited); error = PutImageData_explicit(JS::ToInt32(dx), JS::ToInt32(dy), imageData.Width(), imageData.Height(), &arr, false, 0, 0, 0, 0); } void CanvasRenderingContext2D::PutImageData(ImageData& imageData, double dx, double dy, double dirtyX, double dirtyY, double dirtyWidth, double dirtyHeight, ErrorResult& error) { dom::Uint8ClampedArray arr; DebugOnly inited = arr.Init(imageData.GetDataObject()); MOZ_ASSERT(inited); error = PutImageData_explicit(JS::ToInt32(dx), JS::ToInt32(dy), imageData.Width(), imageData.Height(), &arr, true, JS::ToInt32(dirtyX), JS::ToInt32(dirtyY), JS::ToInt32(dirtyWidth), JS::ToInt32(dirtyHeight)); } // void putImageData (in ImageData d, in float x, in float y); // void putImageData (in ImageData d, in double x, in double y, in double dirtyX, in double dirtyY, in double dirtyWidth, in double dirtyHeight); nsresult CanvasRenderingContext2D::PutImageData_explicit(int32_t x, int32_t y, uint32_t w, uint32_t h, dom::Uint8ClampedArray* aArray, bool hasDirtyRect, int32_t dirtyX, int32_t dirtyY, int32_t dirtyWidth, int32_t dirtyHeight) { EnsureTarget(); if (mDrawObserver) { mDrawObserver->DidDrawCall(CanvasDrawObserver::DrawCallType::PutImageData); } if (w == 0 || h == 0) { return NS_ERROR_DOM_INVALID_STATE_ERR; } IntRect dirtyRect; IntRect imageDataRect(0, 0, w, h); if (hasDirtyRect) { // fix up negative dimensions if (dirtyWidth < 0) { NS_ENSURE_TRUE(dirtyWidth != INT_MIN, NS_ERROR_DOM_INDEX_SIZE_ERR); CheckedInt32 checkedDirtyX = CheckedInt32(dirtyX) + dirtyWidth; if (!checkedDirtyX.isValid()) return NS_ERROR_DOM_INDEX_SIZE_ERR; dirtyX = checkedDirtyX.value(); dirtyWidth = -dirtyWidth; } if (dirtyHeight < 0) { NS_ENSURE_TRUE(dirtyHeight != INT_MIN, NS_ERROR_DOM_INDEX_SIZE_ERR); CheckedInt32 checkedDirtyY = CheckedInt32(dirtyY) + dirtyHeight; if (!checkedDirtyY.isValid()) return NS_ERROR_DOM_INDEX_SIZE_ERR; dirtyY = checkedDirtyY.value(); dirtyHeight = -dirtyHeight; } // bound the dirty rect within the imageData rectangle dirtyRect = imageDataRect.Intersect(IntRect(dirtyX, dirtyY, dirtyWidth, dirtyHeight)); if (dirtyRect.Width() <= 0 || dirtyRect.Height() <= 0) return NS_OK; } else { dirtyRect = imageDataRect; } dirtyRect.MoveBy(IntPoint(x, y)); dirtyRect = IntRect(0, 0, mWidth, mHeight).Intersect(dirtyRect); if (dirtyRect.Width() <= 0 || dirtyRect.Height() <= 0) { return NS_OK; } aArray->ComputeLengthAndData(); uint32_t dataLen = aArray->Length(); uint32_t len = w * h * 4; if (dataLen != len) { return NS_ERROR_DOM_INVALID_STATE_ERR; } uint32_t copyWidth = dirtyRect.Width(); uint32_t copyHeight = dirtyRect.Height(); nsRefPtr imgsurf = new gfxImageSurface(gfx::IntSize(copyWidth, copyHeight), gfxImageFormat::ARGB32, false); if (!imgsurf || imgsurf->CairoStatus()) { return NS_ERROR_FAILURE; } uint32_t copyX = dirtyRect.x - x; uint32_t copyY = dirtyRect.y - y; //uint8_t *src = aArray->Data(); uint8_t *dst = imgsurf->Data(); uint8_t* srcLine = aArray->Data() + copyY * (w * 4) + copyX * 4; #if 0 printf("PutImageData_explicit: dirty x=%d y=%d w=%d h=%d copy x=%d y=%d w=%d h=%d ext x=%d y=%d w=%d h=%d\n", dirtyRect.x, dirtyRect.y, copyWidth, copyHeight, copyX, copyY, copyWidth, copyHeight, x, y, w, h); #endif for (uint32_t j = 0; j < copyHeight; j++) { uint8_t *src = srcLine; for (uint32_t i = 0; i < copyWidth; i++) { uint8_t r = *src++; uint8_t g = *src++; uint8_t b = *src++; uint8_t a = *src++; // Convert to premultiplied color (losslessly if the input came from getImageData) #if MOZ_LITTLE_ENDIAN *dst++ = gfxUtils::sPremultiplyTable[a * 256 + b]; *dst++ = gfxUtils::sPremultiplyTable[a * 256 + g]; *dst++ = gfxUtils::sPremultiplyTable[a * 256 + r]; *dst++ = a; #else *dst++ = a; *dst++ = gfxUtils::sPremultiplyTable[a * 256 + r]; *dst++ = gfxUtils::sPremultiplyTable[a * 256 + g]; *dst++ = gfxUtils::sPremultiplyTable[a * 256 + b]; #endif } srcLine += w * 4; } EnsureTarget(); if (!IsTargetValid()) { return NS_ERROR_FAILURE; } RefPtr sourceSurface = mTarget->CreateSourceSurfaceFromData(imgsurf->Data(), IntSize(copyWidth, copyHeight), imgsurf->Stride(), SurfaceFormat::B8G8R8A8); // In certain scenarios, requesting larger than 8k image fails. Bug 803568 // covers the details of how to run into it, but the full detailed // investigation hasn't been done to determine the underlying cause. We // will just handle the failure to allocate the surface to avoid a crash. if (!sourceSurface) { return NS_ERROR_FAILURE; } mTarget->CopySurface(sourceSurface, IntRect(0, 0, dirtyRect.width, dirtyRect.height), IntPoint(dirtyRect.x, dirtyRect.y)); Redraw(gfx::Rect(dirtyRect.x, dirtyRect.y, dirtyRect.width, dirtyRect.height)); return NS_OK; } static already_AddRefed CreateImageData(JSContext* cx, CanvasRenderingContext2D* context, uint32_t w, uint32_t h, ErrorResult& error) { if (w == 0) w = 1; if (h == 0) h = 1; CheckedInt len = CheckedInt(w) * h * 4; if (!len.isValid()) { error.Throw(NS_ERROR_DOM_INDEX_SIZE_ERR); return nullptr; } // Create the fast typed array; it's initialized to 0 by default. JSObject* darray = Uint8ClampedArray::Create(cx, context, len.value()); if (!darray) { error.Throw(NS_ERROR_OUT_OF_MEMORY); return nullptr; } nsRefPtr imageData = new mozilla::dom::ImageData(w, h, *darray); return imageData.forget(); } already_AddRefed CanvasRenderingContext2D::CreateImageData(JSContext* cx, double sw, double sh, ErrorResult& error) { if (!sw || !sh) { error.Throw(NS_ERROR_DOM_INDEX_SIZE_ERR); return nullptr; } int32_t wi = JS::ToInt32(sw); int32_t hi = JS::ToInt32(sh); uint32_t w = Abs(wi); uint32_t h = Abs(hi); return mozilla::dom::CreateImageData(cx, this, w, h, error); } already_AddRefed CanvasRenderingContext2D::CreateImageData(JSContext* cx, ImageData& imagedata, ErrorResult& error) { return mozilla::dom::CreateImageData(cx, this, imagedata.Width(), imagedata.Height(), error); } static uint8_t g2DContextLayerUserData; uint32_t CanvasRenderingContext2D::SkiaGLTex() const { if (!mTarget) { return 0; } MOZ_ASSERT(IsTargetValid()); return (uint32_t)(uintptr_t)mTarget->GetNativeSurface(NativeSurfaceType::OPENGL_TEXTURE); } void CanvasRenderingContext2D::RemoveDrawObserver() { if (mDrawObserver) { delete mDrawObserver; mDrawObserver = nullptr; } } PersistentBufferProvider* CanvasRenderingContext2D::GetBufferProvider(LayerManager* aManager) { if (mBufferProvider) { return mBufferProvider; } if (!mTarget) { return nullptr; } mBufferProvider = new PersistentBufferProviderBasic(mTarget); return mBufferProvider; } already_AddRefed CanvasRenderingContext2D::GetCanvasLayer(nsDisplayListBuilder* aBuilder, CanvasLayer *aOldLayer, LayerManager *aManager) { if (mOpaque || mIsSkiaGL) { // If we're opaque then make sure we have a surface so we paint black // instead of transparent. // If we're using SkiaGL, then SkiaGLTex() below needs the target to // be accessible. EnsureTarget(); } // Don't call EnsureTarget() ... if there isn't already a surface, then // we have nothing to paint and there is no need to create a surface just // to paint nothing. Also, EnsureTarget() can cause creation of a persistent // layer manager which must NOT happen during a paint. if ((!mBufferProvider && !mTarget) || !IsTargetValid()) { // No DidTransactionCallback will be received, so mark the context clean // now so future invalidations will be dispatched. MarkContextClean(); return nullptr; } if (!mResetLayer && aOldLayer) { CanvasRenderingContext2DUserData* userData = static_cast( aOldLayer->GetUserData(&g2DContextLayerUserData)); CanvasLayer::Data data; GLuint skiaGLTex = SkiaGLTex(); if (skiaGLTex) { SkiaGLGlue* glue = gfxPlatform::GetPlatform()->GetSkiaGLGlue(); MOZ_ASSERT(glue); data.mGLContext = glue->GetGLContext(); data.mFrontbufferGLTex = skiaGLTex; } else { PersistentBufferProvider *provider = GetBufferProvider(aManager); data.mBufferProvider = provider; } if (userData && userData->IsForContext(this) && aOldLayer->IsDataValid(data)) { nsRefPtr ret = aOldLayer; return ret.forget(); } } nsRefPtr canvasLayer = aManager->CreateCanvasLayer(); if (!canvasLayer) { NS_WARNING("CreateCanvasLayer returned null!"); // No DidTransactionCallback will be received, so mark the context clean // now so future invalidations will be dispatched. MarkContextClean(); return nullptr; } CanvasRenderingContext2DUserData *userData = nullptr; // Make the layer tell us whenever a transaction finishes (including // the current transaction), so we can clear our invalidation state and // start invalidating again. We need to do this for all layers since // callers of DrawWindow may be expecting to receive normal invalidation // notifications after this paint. // The layer will be destroyed when we tear down the presentation // (at the latest), at which time this userData will be destroyed, // releasing the reference to the element. // The userData will receive DidTransactionCallbacks, which flush the // the invalidation state to indicate that the canvas is up to date. userData = new CanvasRenderingContext2DUserData(this); canvasLayer->SetDidTransactionCallback( CanvasRenderingContext2DUserData::DidTransactionCallback, userData); canvasLayer->SetUserData(&g2DContextLayerUserData, userData); CanvasLayer::Data data; data.mSize = nsIntSize(mWidth, mHeight); data.mHasAlpha = !mOpaque; canvasLayer->SetPreTransactionCallback( CanvasRenderingContext2DUserData::PreTransactionCallback, userData); GLuint skiaGLTex = SkiaGLTex(); if (skiaGLTex) { SkiaGLGlue* glue = gfxPlatform::GetPlatform()->GetSkiaGLGlue(); MOZ_ASSERT(glue); data.mGLContext = glue->GetGLContext(); data.mFrontbufferGLTex = skiaGLTex; } else { PersistentBufferProvider *provider = GetBufferProvider(aManager); data.mBufferProvider = provider; } canvasLayer->Initialize(data); uint32_t flags = mOpaque ? Layer::CONTENT_OPAQUE : 0; canvasLayer->SetContentFlags(flags); canvasLayer->Updated(); mResetLayer = false; return canvasLayer.forget(); } void CanvasRenderingContext2D::MarkContextClean() { if (mInvalidateCount > 0) { mPredictManyRedrawCalls = mInvalidateCount > kCanvasMaxInvalidateCount; } mIsEntireFrameInvalid = false; mInvalidateCount = 0; } void CanvasRenderingContext2D::MarkContextCleanForFrameCapture() { mIsCapturedFrameInvalid = false; } bool CanvasRenderingContext2D::IsContextCleanForFrameCapture() { return !mIsCapturedFrameInvalid; } bool CanvasRenderingContext2D::ShouldForceInactiveLayer(LayerManager *aManager) { return !aManager->CanUseCanvasLayerForSize(IntSize(mWidth, mHeight)); } NS_IMPL_CYCLE_COLLECTION_ROOT_NATIVE(CanvasPath, AddRef) NS_IMPL_CYCLE_COLLECTION_UNROOT_NATIVE(CanvasPath, Release) NS_IMPL_CYCLE_COLLECTION_WRAPPERCACHE(CanvasPath, mParent) CanvasPath::CanvasPath(nsISupports* aParent) : mParent(aParent) { mPathBuilder = gfxPlatform::GetPlatform()->ScreenReferenceDrawTarget()->CreatePathBuilder(); } CanvasPath::CanvasPath(nsISupports* aParent, already_AddRefed aPathBuilder) : mParent(aParent), mPathBuilder(aPathBuilder) { if (!mPathBuilder) { mPathBuilder = gfxPlatform::GetPlatform()->ScreenReferenceDrawTarget()->CreatePathBuilder(); } } JSObject* CanvasPath::WrapObject(JSContext* aCx, JS::Handle aGivenProto) { return Path2DBinding::Wrap(aCx, this, aGivenProto); } already_AddRefed CanvasPath::Constructor(const GlobalObject& aGlobal, ErrorResult& aRv) { nsRefPtr path = new CanvasPath(aGlobal.GetAsSupports()); return path.forget(); } already_AddRefed CanvasPath::Constructor(const GlobalObject& aGlobal, CanvasPath& aCanvasPath, ErrorResult& aRv) { RefPtr tempPath = aCanvasPath.GetPath(CanvasWindingRule::Nonzero, gfxPlatform::GetPlatform()->ScreenReferenceDrawTarget()); nsRefPtr path = new CanvasPath(aGlobal.GetAsSupports(), tempPath->CopyToBuilder()); return path.forget(); } already_AddRefed CanvasPath::Constructor(const GlobalObject& aGlobal, const nsAString& aPathString, ErrorResult& aRv) { RefPtr tempPath = SVGContentUtils::GetPath(aPathString); if (!tempPath) { return Constructor(aGlobal, aRv); } nsRefPtr path = new CanvasPath(aGlobal.GetAsSupports(), tempPath->CopyToBuilder()); return path.forget(); } void CanvasPath::ClosePath() { EnsurePathBuilder(); mPathBuilder->Close(); } void CanvasPath::MoveTo(double x, double y) { EnsurePathBuilder(); mPathBuilder->MoveTo(Point(ToFloat(x), ToFloat(y))); } void CanvasPath::LineTo(double x, double y) { EnsurePathBuilder(); mPathBuilder->LineTo(Point(ToFloat(x), ToFloat(y))); } void CanvasPath::QuadraticCurveTo(double cpx, double cpy, double x, double y) { EnsurePathBuilder(); mPathBuilder->QuadraticBezierTo(gfx::Point(ToFloat(cpx), ToFloat(cpy)), gfx::Point(ToFloat(x), ToFloat(y))); } void CanvasPath::BezierCurveTo(double cp1x, double cp1y, double cp2x, double cp2y, double x, double y) { BezierTo(gfx::Point(ToFloat(cp1x), ToFloat(cp1y)), gfx::Point(ToFloat(cp2x), ToFloat(cp2y)), gfx::Point(ToFloat(x), ToFloat(y))); } void CanvasPath::ArcTo(double x1, double y1, double x2, double y2, double radius, ErrorResult& error) { if (radius < 0) { error.Throw(NS_ERROR_DOM_INDEX_SIZE_ERR); return; } EnsurePathBuilder(); // Current point in user space! Point p0 = mPathBuilder->CurrentPoint(); Point p1(x1, y1); Point p2(x2, y2); // Execute these calculations in double precision to avoid cumulative // rounding errors. double dir, a2, b2, c2, cosx, sinx, d, anx, any, bnx, bny, x3, y3, x4, y4, cx, cy, angle0, angle1; bool anticlockwise; if (p0 == p1 || p1 == p2 || radius == 0) { LineTo(p1.x, p1.y); return; } // Check for colinearity dir = (p2.x - p1.x) * (p0.y - p1.y) + (p2.y - p1.y) * (p1.x - p0.x); if (dir == 0) { LineTo(p1.x, p1.y); return; } // XXX - Math for this code was already available from the non-azure code // and would be well tested. Perhaps converting to bezier directly might // be more efficient longer run. a2 = (p0.x-x1)*(p0.x-x1) + (p0.y-y1)*(p0.y-y1); b2 = (x1-x2)*(x1-x2) + (y1-y2)*(y1-y2); c2 = (p0.x-x2)*(p0.x-x2) + (p0.y-y2)*(p0.y-y2); cosx = (a2+b2-c2)/(2*sqrt(a2*b2)); sinx = sqrt(1 - cosx*cosx); d = radius / ((1 - cosx) / sinx); anx = (x1-p0.x) / sqrt(a2); any = (y1-p0.y) / sqrt(a2); bnx = (x1-x2) / sqrt(b2); bny = (y1-y2) / sqrt(b2); x3 = x1 - anx*d; y3 = y1 - any*d; x4 = x1 - bnx*d; y4 = y1 - bny*d; anticlockwise = (dir < 0); cx = x3 + any*radius*(anticlockwise ? 1 : -1); cy = y3 - anx*radius*(anticlockwise ? 1 : -1); angle0 = atan2((y3-cy), (x3-cx)); angle1 = atan2((y4-cy), (x4-cx)); LineTo(x3, y3); Arc(cx, cy, radius, angle0, angle1, anticlockwise, error); } void CanvasPath::Rect(double x, double y, double w, double h) { MoveTo(x, y); LineTo(x + w, y); LineTo(x + w, y + h); LineTo(x, y + h); ClosePath(); } void CanvasPath::Arc(double x, double y, double radius, double startAngle, double endAngle, bool anticlockwise, ErrorResult& error) { if (radius < 0.0) { error.Throw(NS_ERROR_DOM_INDEX_SIZE_ERR); return; } EnsurePathBuilder(); ArcToBezier(this, Point(x, y), Size(radius, radius), startAngle, endAngle, anticlockwise); } void CanvasPath::LineTo(const gfx::Point& aPoint) { EnsurePathBuilder(); mPathBuilder->LineTo(aPoint); } void CanvasPath::BezierTo(const gfx::Point& aCP1, const gfx::Point& aCP2, const gfx::Point& aCP3) { EnsurePathBuilder(); mPathBuilder->BezierTo(aCP1, aCP2, aCP3); } void CanvasPath::AddPath(CanvasPath& aCanvasPath, const Optional>& aMatrix) { RefPtr tempPath = aCanvasPath.GetPath(CanvasWindingRule::Nonzero, gfxPlatform::GetPlatform()->ScreenReferenceDrawTarget()); if (aMatrix.WasPassed()) { const SVGMatrix& m = aMatrix.Value(); Matrix transform(m.A(), m.B(), m.C(), m.D(), m.E(), m.F()); if (!transform.IsIdentity()) { RefPtr tempBuilder = tempPath->TransformedCopyToBuilder(transform, FillRule::FILL_WINDING); tempPath = tempBuilder->Finish(); } } EnsurePathBuilder(); // in case a path is added to itself tempPath->StreamToSink(mPathBuilder); } already_AddRefed CanvasPath::GetPath(const CanvasWindingRule& winding, const DrawTarget* aTarget) const { FillRule fillRule = FillRule::FILL_WINDING; if (winding == CanvasWindingRule::Evenodd) { fillRule = FillRule::FILL_EVEN_ODD; } if (mPath && (mPath->GetBackendType() == aTarget->GetBackendType()) && (mPath->GetFillRule() == fillRule)) { RefPtr path(mPath); return path.forget(); } if (!mPath) { // if there is no path, there must be a pathbuilder MOZ_ASSERT(mPathBuilder); mPath = mPathBuilder->Finish(); if (!mPath) { RefPtr path(mPath); return path.forget(); } mPathBuilder = nullptr; } // retarget our backend if we're used with a different backend if (mPath->GetBackendType() != aTarget->GetBackendType()) { RefPtr tmpPathBuilder = aTarget->CreatePathBuilder(fillRule); mPath->StreamToSink(tmpPathBuilder); mPath = tmpPathBuilder->Finish(); } else if (mPath->GetFillRule() != fillRule) { RefPtr tmpPathBuilder = mPath->CopyToBuilder(fillRule); mPath = tmpPathBuilder->Finish(); } RefPtr path(mPath); return path.forget(); } void CanvasPath::EnsurePathBuilder() const { if (mPathBuilder) { return; } // if there is not pathbuilder, there must be a path MOZ_ASSERT(mPath); mPathBuilder = mPath->CopyToBuilder(); mPath = nullptr; } } // namespace dom } // namespace mozilla