/* -*- Mode: C++; tab-width: 20; 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 "DrawTargetCairo.h" #include "SourceSurfaceCairo.h" #include "PathCairo.h" #include "HelpersCairo.h" #include "ScaledFontBase.h" #include "cairo.h" #include #include "Blur.h" #include "Logging.h" #include "Tools.h" #ifdef CAIRO_HAS_QUARTZ_SURFACE #include "cairo-quartz.h" #include #endif #ifdef CAIRO_HAS_XLIB_SURFACE #include "cairo-xlib.h" #endif #include namespace mozilla { namespace gfx { namespace { // An RAII class to prepare to draw a context and optional path. Saves and // restores the context on construction/destruction. class AutoPrepareForDrawing { public: AutoPrepareForDrawing(DrawTargetCairo* dt, cairo_t* ctx) : mCtx(ctx) { dt->PrepareForDrawing(ctx); cairo_save(mCtx); } AutoPrepareForDrawing(DrawTargetCairo* dt, cairo_t* ctx, const Path* path) : mCtx(ctx) { dt->PrepareForDrawing(ctx, path); cairo_save(mCtx); } ~AutoPrepareForDrawing() { cairo_restore(mCtx); } private: cairo_t* mCtx; }; } // end anonymous namespace static bool GetCairoSurfaceSize(cairo_surface_t* surface, IntSize& size) { switch (cairo_surface_get_type(surface)) { case CAIRO_SURFACE_TYPE_IMAGE: { size.width = cairo_image_surface_get_width(surface); size.height = cairo_image_surface_get_height(surface); return true; } #ifdef CAIRO_HAS_XLIB_SURFACE case CAIRO_SURFACE_TYPE_XLIB: { size.width = cairo_xlib_surface_get_width(surface); size.height = cairo_xlib_surface_get_height(surface); return true; } #endif #ifdef CAIRO_HAS_QUARTZ_SURFACE case CAIRO_SURFACE_TYPE_QUARTZ: { CGContextRef cgc = cairo_quartz_surface_get_cg_context(surface); // It's valid to call these CGBitmapContext functions on non-bitmap // contexts; they'll just return 0 in that case. size.width = CGBitmapContextGetWidth(cgc); size.height = CGBitmapContextGetWidth(cgc); return true; } #endif default: return false; } } static bool PatternIsCompatible(const Pattern& aPattern) { switch (aPattern.GetType()) { case PATTERN_LINEAR_GRADIENT: { const LinearGradientPattern& pattern = static_cast(aPattern); return pattern.mStops->GetBackendType() == BACKEND_CAIRO; } case PATTERN_RADIAL_GRADIENT: { const RadialGradientPattern& pattern = static_cast(aPattern); return pattern.mStops->GetBackendType() == BACKEND_CAIRO; } default: return true; } } static cairo_user_data_key_t surfaceDataKey; void ReleaseData(void* aData) { static_cast(aData)->Release(); } /** * Returns cairo surface for the given SourceSurface. * If possible, it will use the cairo_surface associated with aSurface, * otherwise, it will create a new cairo_surface. * In either case, the caller must call cairo_surface_destroy on the * result when it is done with it. */ cairo_surface_t* GetCairoSurfaceForSourceSurface(SourceSurface *aSurface) { if (aSurface->GetType() == SURFACE_CAIRO) { cairo_surface_t* surf = static_cast(aSurface)->GetSurface(); cairo_surface_reference(surf); return surf; } if (aSurface->GetType() == SURFACE_CAIRO_IMAGE) { cairo_surface_t* surf = static_cast(aSurface)->GetSurface(); cairo_surface_reference(surf); return surf; } RefPtr data = aSurface->GetDataSurface(); if (!data) { return nullptr; } cairo_surface_t* surf = cairo_image_surface_create_for_data(data->GetData(), GfxFormatToCairoFormat(data->GetFormat()), data->GetSize().width, data->GetSize().height, data->Stride()); cairo_surface_set_user_data(surf, &surfaceDataKey, data.forget().drop(), ReleaseData); return surf; } // Never returns nullptr. As such, you must always pass in Cairo-compatible // patterns, most notably gradients with a GradientStopCairo. // The pattern returned must have cairo_pattern_destroy() called on it by the // caller. // As the cairo_pattern_t returned may depend on the Pattern passed in, the // lifetime of the cairo_pattern_t returned must not exceed the lifetime of the // Pattern passed in. static cairo_pattern_t* GfxPatternToCairoPattern(const Pattern& aPattern, Float aAlpha) { cairo_pattern_t* pat; switch (aPattern.GetType()) { case PATTERN_COLOR: { Color color = static_cast(aPattern).mColor; pat = cairo_pattern_create_rgba(color.r, color.g, color.b, color.a * aAlpha); break; } case PATTERN_SURFACE: { const SurfacePattern& pattern = static_cast(aPattern); cairo_surface_t* surf = GetCairoSurfaceForSourceSurface(pattern.mSurface); pat = cairo_pattern_create_for_surface(surf); cairo_pattern_set_filter(pat, GfxFilterToCairoFilter(pattern.mFilter)); cairo_pattern_set_extend(pat, GfxExtendToCairoExtend(pattern.mExtendMode)); cairo_surface_destroy(surf); break; } case PATTERN_LINEAR_GRADIENT: { const LinearGradientPattern& pattern = static_cast(aPattern); pat = cairo_pattern_create_linear(pattern.mBegin.x, pattern.mBegin.y, pattern.mEnd.x, pattern.mEnd.y); MOZ_ASSERT(pattern.mStops->GetBackendType() == BACKEND_CAIRO); const std::vector& stops = static_cast(pattern.mStops.get())->GetStops(); for (size_t i = 0; i < stops.size(); ++i) { const GradientStop& stop = stops[i]; cairo_pattern_add_color_stop_rgba(pat, stop.offset, stop.color.r, stop.color.g, stop.color.b, stop.color.a); } break; } case PATTERN_RADIAL_GRADIENT: { const RadialGradientPattern& pattern = static_cast(aPattern); pat = cairo_pattern_create_radial(pattern.mCenter1.x, pattern.mCenter1.y, pattern.mRadius1, pattern.mCenter2.x, pattern.mCenter2.y, pattern.mRadius2); const std::vector& stops = static_cast(pattern.mStops.get())->GetStops(); for (size_t i = 0; i < stops.size(); ++i) { const GradientStop& stop = stops[i]; cairo_pattern_add_color_stop_rgba(pat, stop.offset, stop.color.r, stop.color.g, stop.color.b, stop.color.a); } break; } default: { // We should support all pattern types! MOZ_ASSERT(false); } } return pat; } /** * Returns true iff the the given operator should affect areas of the * destination where the source is transparent. Among other things, this * implies that a fully transparent source would still affect the canvas. */ static bool OperatorAffectsUncoveredAreas(CompositionOp op) { return op == OP_IN || op == OP_OUT || op == OP_DEST_IN || op == OP_DEST_ATOP || op == OP_DEST_OUT; } static bool NeedIntermediateSurface(const Pattern& aPattern, const DrawOptions& aOptions) { // We pre-multiply colours' alpha by the global alpha, so we don't need to // use an intermediate surface for them. if (aPattern.GetType() == PATTERN_COLOR) return false; if (aOptions.mAlpha == 1.0) return false; return true; } DrawTargetCairo::DrawTargetCairo() : mContext(nullptr) { } DrawTargetCairo::~DrawTargetCairo() { MarkSnapshotsIndependent(); if (mPathObserver) { mPathObserver->ForgetDrawTarget(); } cairo_destroy(mContext); if (mSurface) { cairo_surface_destroy(mSurface); } } IntSize DrawTargetCairo::GetSize() { return mSize; } TemporaryRef DrawTargetCairo::Snapshot() { IntSize size = GetSize(); cairo_content_t content = cairo_surface_get_content(mSurface); RefPtr surf = new SourceSurfaceCairo(mSurface, size, CairoContentToGfxFormat(content), this); AppendSnapshot(surf); return surf; } void DrawTargetCairo::Flush() { cairo_surface_t* surf = cairo_get_target(mContext); cairo_surface_flush(surf); } void DrawTargetCairo::PrepareForDrawing(cairo_t* aContext, const Path* aPath /* = nullptr */) { WillChange(aPath); } void DrawTargetCairo::DrawSurface(SourceSurface *aSurface, const Rect &aDest, const Rect &aSource, const DrawSurfaceOptions &aSurfOptions, const DrawOptions &aOptions) { AutoPrepareForDrawing prep(this, mContext); float sx = aSource.Width() / aDest.Width(); float sy = aSource.Height() / aDest.Height(); cairo_matrix_t src_mat; cairo_matrix_init_translate(&src_mat, aSource.X(), aSource.Y()); cairo_matrix_scale(&src_mat, sx, sy); cairo_surface_t* surf = GetCairoSurfaceForSourceSurface(aSurface); cairo_pattern_t* pat = cairo_pattern_create_for_surface(surf); cairo_surface_destroy(surf); cairo_pattern_set_matrix(pat, &src_mat); cairo_pattern_set_filter(pat, GfxFilterToCairoFilter(aSurfOptions.mFilter)); cairo_pattern_set_extend(pat, CAIRO_EXTEND_PAD); cairo_translate(mContext, aDest.X(), aDest.Y()); if (OperatorAffectsUncoveredAreas(aOptions.mCompositionOp) || aOptions.mCompositionOp == OP_SOURCE) { cairo_push_group(mContext); cairo_new_path(mContext); cairo_rectangle(mContext, 0, 0, aDest.Width(), aDest.Height()); cairo_set_source(mContext, pat); cairo_fill(mContext); cairo_pop_group_to_source(mContext); } else { cairo_new_path(mContext); cairo_rectangle(mContext, 0, 0, aDest.Width(), aDest.Height()); cairo_clip(mContext); cairo_set_source(mContext, pat); } cairo_set_operator(mContext, GfxOpToCairoOp(aOptions.mCompositionOp)); cairo_paint_with_alpha(mContext, aOptions.mAlpha); cairo_pattern_destroy(pat); } void DrawTargetCairo::DrawSurfaceWithShadow(SourceSurface *aSurface, const Point &aDest, const Color &aColor, const Point &aOffset, Float aSigma, CompositionOp aOperator) { if (aSurface->GetType() != SURFACE_CAIRO) { return; } WillChange(); Float width = aSurface->GetSize().width; Float height = aSurface->GetSize().height; Rect extents(0, 0, width, height); AlphaBoxBlur blur(extents, IntSize(0, 0), AlphaBoxBlur::CalculateBlurRadius(Point(aSigma, aSigma)), nullptr, nullptr); if (!blur.GetData()) { return; } IntSize blursize = blur.GetSize(); cairo_surface_t* blursurf = cairo_image_surface_create_for_data(blur.GetData(), CAIRO_FORMAT_A8, blursize.width, blursize.height, blur.GetStride()); ClearSurfaceForUnboundedSource(aOperator); // Draw the source surface into the surface we're going to blur. SourceSurfaceCairo* source = static_cast(aSurface); cairo_surface_t* surf = source->GetSurface(); cairo_pattern_t* pat = cairo_pattern_create_for_surface(surf); cairo_pattern_set_extend(pat, CAIRO_EXTEND_PAD); cairo_t* ctx = cairo_create(blursurf); cairo_set_source(ctx, pat); IntRect blurrect = blur.GetRect(); cairo_new_path(ctx); cairo_rectangle(ctx, blurrect.x, blurrect.y, blurrect.width, blurrect.height); cairo_clip(ctx); cairo_paint(ctx); cairo_destroy(ctx); // Blur the result, then use that blurred result as a mask to draw the shadow // colour to the surface. blur.Blur(); cairo_save(mContext); cairo_set_operator(mContext, GfxOpToCairoOp(aOperator)); cairo_identity_matrix(mContext); cairo_translate(mContext, aDest.x, aDest.y); if (OperatorAffectsUncoveredAreas(aOperator) || aOperator == OP_SOURCE){ cairo_push_group(mContext); cairo_set_source_rgba(mContext, aColor.r, aColor.g, aColor.b, aColor.a); cairo_mask_surface(mContext, blursurf, aOffset.x, aOffset.y); cairo_pop_group_to_source(mContext); cairo_paint(mContext); // Now that the shadow has been drawn, we can draw the surface on top. cairo_push_group(mContext); cairo_new_path(mContext); cairo_rectangle(mContext, 0, 0, width, height); cairo_set_source(mContext, pat); cairo_fill(mContext); cairo_pop_group_to_source(mContext); } else { cairo_set_source_rgba(mContext, aColor.r, aColor.g, aColor.b, aColor.a); cairo_mask_surface(mContext, blursurf, aOffset.x, aOffset.y); // Now that the shadow has been drawn, we can draw the surface on top. cairo_set_source(mContext, pat); cairo_new_path(mContext); cairo_rectangle(mContext, 0, 0, width, height); cairo_clip(mContext); } cairo_paint(mContext); cairo_restore(mContext); cairo_pattern_destroy(pat); cairo_surface_destroy(blursurf); } void DrawTargetCairo::DrawPattern(const Pattern& aPattern, const StrokeOptions& aStrokeOptions, const DrawOptions& aOptions, DrawPatternType aDrawType) { if (!PatternIsCompatible(aPattern)) { return; } cairo_pattern_t* pat = GfxPatternToCairoPattern(aPattern, aOptions.mAlpha); cairo_set_source(mContext, pat); if (NeedIntermediateSurface(aPattern, aOptions) || OperatorAffectsUncoveredAreas(aOptions.mCompositionOp)) { cairo_push_group_with_content(mContext, CAIRO_CONTENT_COLOR_ALPHA); ClearSurfaceForUnboundedSource(aOptions.mCompositionOp); // Don't want operators to be applied twice cairo_set_operator(mContext, CAIRO_OPERATOR_OVER); if (aDrawType == DRAW_STROKE) { SetCairoStrokeOptions(mContext, aStrokeOptions); cairo_stroke_preserve(mContext); } else { cairo_fill_preserve(mContext); } cairo_pop_group_to_source(mContext); // Now draw the content using the desired operator cairo_set_operator(mContext, GfxOpToCairoOp(aOptions.mCompositionOp)); cairo_paint_with_alpha(mContext, aOptions.mAlpha); } else { ClearSurfaceForUnboundedSource(aOptions.mCompositionOp); cairo_set_operator(mContext, GfxOpToCairoOp(aOptions.mCompositionOp)); if (aDrawType == DRAW_STROKE) { SetCairoStrokeOptions(mContext, aStrokeOptions); cairo_stroke_preserve(mContext); } else { cairo_fill_preserve(mContext); } } cairo_pattern_destroy(pat); } void DrawTargetCairo::FillRect(const Rect &aRect, const Pattern &aPattern, const DrawOptions &aOptions) { AutoPrepareForDrawing prep(this, mContext); cairo_new_path(mContext); cairo_rectangle(mContext, aRect.x, aRect.y, aRect.Width(), aRect.Height()); DrawPattern(aPattern, StrokeOptions(), aOptions, DRAW_FILL); } void DrawTargetCairo::CopySurface(SourceSurface *aSurface, const IntRect &aSource, const IntPoint &aDest) { AutoPrepareForDrawing prep(this, mContext); if (!aSurface || aSurface->GetType() != SURFACE_CAIRO) { gfxWarning() << "Unsupported surface type specified"; return; } cairo_surface_t* surf = static_cast(aSurface)->GetSurface(); cairo_identity_matrix(mContext); cairo_set_source_surface(mContext, surf, aDest.x - aSource.x, aDest.y - aSource.y); cairo_set_operator(mContext, CAIRO_OPERATOR_SOURCE); cairo_reset_clip(mContext); cairo_new_path(mContext); cairo_rectangle(mContext, aDest.x, aDest.y, aSource.width, aSource.height); cairo_fill(mContext); } void DrawTargetCairo::ClearRect(const Rect& aRect) { AutoPrepareForDrawing prep(this, mContext); cairo_new_path(mContext); cairo_set_operator(mContext, CAIRO_OPERATOR_CLEAR); cairo_rectangle(mContext, aRect.X(), aRect.Y(), aRect.Width(), aRect.Height()); cairo_fill(mContext); } void DrawTargetCairo::StrokeRect(const Rect &aRect, const Pattern &aPattern, const StrokeOptions &aStrokeOptions /* = StrokeOptions() */, const DrawOptions &aOptions /* = DrawOptions() */) { AutoPrepareForDrawing prep(this, mContext); cairo_new_path(mContext); cairo_rectangle(mContext, aRect.x, aRect.y, aRect.Width(), aRect.Height()); DrawPattern(aPattern, aStrokeOptions, aOptions, DRAW_STROKE); } void DrawTargetCairo::StrokeLine(const Point &aStart, const Point &aEnd, const Pattern &aPattern, const StrokeOptions &aStrokeOptions /* = StrokeOptions() */, const DrawOptions &aOptions /* = DrawOptions() */) { AutoPrepareForDrawing prep(this, mContext); cairo_new_path(mContext); cairo_move_to(mContext, aStart.x, aStart.y); cairo_line_to(mContext, aEnd.x, aEnd.y); DrawPattern(aPattern, aStrokeOptions, aOptions, DRAW_STROKE); } void DrawTargetCairo::Stroke(const Path *aPath, const Pattern &aPattern, const StrokeOptions &aStrokeOptions /* = StrokeOptions() */, const DrawOptions &aOptions /* = DrawOptions() */) { AutoPrepareForDrawing prep(this, mContext, aPath); if (aPath->GetBackendType() != BACKEND_CAIRO) return; PathCairo* path = const_cast(static_cast(aPath)); path->CopyPathTo(mContext, this); DrawPattern(aPattern, aStrokeOptions, aOptions, DRAW_STROKE); } void DrawTargetCairo::Fill(const Path *aPath, const Pattern &aPattern, const DrawOptions &aOptions /* = DrawOptions() */) { AutoPrepareForDrawing prep(this, mContext, aPath); if (aPath->GetBackendType() != BACKEND_CAIRO) return; PathCairo* path = const_cast(static_cast(aPath)); path->CopyPathTo(mContext, this); DrawPattern(aPattern, StrokeOptions(), aOptions, DRAW_FILL); } void DrawTargetCairo::FillGlyphs(ScaledFont *aFont, const GlyphBuffer &aBuffer, const Pattern &aPattern, const DrawOptions &aOptions, const GlyphRenderingOptions*) { AutoPrepareForDrawing prep(this, mContext); ScaledFontBase* scaledFont = static_cast(aFont); cairo_set_scaled_font(mContext, scaledFont->GetCairoScaledFont()); cairo_pattern_t* pat = GfxPatternToCairoPattern(aPattern, aOptions.mAlpha); cairo_set_source(mContext, pat); cairo_pattern_destroy(pat); // Convert our GlyphBuffer into an array of Cairo glyphs. std::vector glyphs(aBuffer.mNumGlyphs); for (uint32_t i = 0; i < aBuffer.mNumGlyphs; ++i) { glyphs[i].index = aBuffer.mGlyphs[i].mIndex; glyphs[i].x = aBuffer.mGlyphs[i].mPosition.x; glyphs[i].y = aBuffer.mGlyphs[i].mPosition.y; } cairo_show_glyphs(mContext, &glyphs[0], aBuffer.mNumGlyphs); } void DrawTargetCairo::Mask(const Pattern &aSource, const Pattern &aMask, const DrawOptions &aOptions /* = DrawOptions() */) { AutoPrepareForDrawing prep(this, mContext); // TODO } void DrawTargetCairo::PushClip(const Path *aPath) { if (aPath->GetBackendType() != BACKEND_CAIRO) { return; } WillChange(aPath); cairo_save(mContext); PathCairo* path = const_cast(static_cast(aPath)); path->CopyPathTo(mContext, this); cairo_clip_preserve(mContext); } void DrawTargetCairo::PushClipRect(const Rect& aRect) { WillChange(); cairo_save(mContext); cairo_new_path(mContext); cairo_rectangle(mContext, aRect.X(), aRect.Y(), aRect.Width(), aRect.Height()); cairo_clip_preserve(mContext); } void DrawTargetCairo::PopClip() { // save/restore does not affect the path, so no need to call WillChange() cairo_restore(mContext); } TemporaryRef DrawTargetCairo::CreatePathBuilder(FillRule aFillRule /* = FILL_WINDING */) const { RefPtr builder = new PathBuilderCairo(mContext, const_cast(this), aFillRule); // Creating a PathBuilder implicitly resets our mPathObserver, as it calls // SetPathObserver() on us. Since this guarantees our old path is saved off, // it's safe to reset the path here. cairo_new_path(mContext); return builder; } void DrawTargetCairo::ClearSurfaceForUnboundedSource(const CompositionOp &aOperator) { if (aOperator != OP_SOURCE) return; cairo_set_operator(mContext, CAIRO_OPERATOR_CLEAR); // It doesn't really matter what the source is here, since Paint // isn't bounded by the source and the mask covers the entire clip // region. cairo_paint(mContext); } TemporaryRef DrawTargetCairo::CreateGradientStops(GradientStop *aStops, uint32_t aNumStops, ExtendMode aExtendMode) const { RefPtr stops = new GradientStopsCairo(aStops, aNumStops); return stops; } /** * Copies pixel data from aData into aSurface; aData must have the dimensions * given in aSize, with a stride of aStride bytes and aPixelWidth bytes per pixel */ static void CopyDataToCairoSurface(cairo_surface_t* aSurface, unsigned char *aData, const IntSize &aSize, int32_t aStride, int32_t aPixelWidth) { unsigned char* surfData = cairo_image_surface_get_data(aSurface); for (int32_t y = 0; y < aSize.height; ++y) { memcpy(surfData + y * aSize.width * aPixelWidth, aData + y * aStride, aSize.width * aPixelWidth); } cairo_surface_mark_dirty(aSurface); } TemporaryRef DrawTargetCairo::CreateSourceSurfaceFromData(unsigned char *aData, const IntSize &aSize, int32_t aStride, SurfaceFormat aFormat) const { cairo_surface_t* surf = cairo_image_surface_create(GfxFormatToCairoFormat(aFormat), aSize.width, aSize.height); CopyDataToCairoSurface(surf, aData, aSize, aStride, BytesPerPixel(aFormat)); RefPtr source_surf = new SourceSurfaceCairo(surf, aSize, aFormat); cairo_surface_destroy(surf); return source_surf; } TemporaryRef DrawTargetCairo::OptimizeSourceSurface(SourceSurface *aSurface) const { return aSurface; } TemporaryRef DrawTargetCairo::CreateSourceSurfaceFromNativeSurface(const NativeSurface &aSurface) const { if (aSurface.mType == NATIVE_SURFACE_CAIRO_SURFACE) { IntSize size; cairo_surface_t* surf = static_cast(aSurface.mSurface); if (GetCairoSurfaceSize(surf, size)) { RefPtr source = new SourceSurfaceCairo(surf, size, aSurface.mFormat); return source; } } return nullptr; } TemporaryRef DrawTargetCairo::CreateSimilarDrawTarget(const IntSize &aSize, SurfaceFormat aFormat) const { cairo_surface_t* similar = cairo_surface_create_similar(cairo_get_target(mContext), GfxFormatToCairoContent(aFormat), aSize.width, aSize.height); if (!cairo_surface_status(similar)) { RefPtr target = new DrawTargetCairo(); target->Init(similar, aSize); return target; } return nullptr; } bool DrawTargetCairo::InitAlreadyReferenced(cairo_surface_t* aSurface, const IntSize& aSize) { mContext = cairo_create(aSurface); mSurface = aSurface; mSize = aSize; mFormat = CairoContentToGfxFormat(cairo_surface_get_content(aSurface)); return true; } bool DrawTargetCairo::Init(cairo_surface_t* aSurface, const IntSize& aSize) { cairo_surface_reference(aSurface); return InitAlreadyReferenced(aSurface, aSize); } void * DrawTargetCairo::GetNativeSurface(NativeSurfaceType aType) { if (aType == NATIVE_SURFACE_CAIRO_SURFACE) { return cairo_get_target(mContext); } return nullptr; } void DrawTargetCairo::MarkSnapshotsIndependent() { // Make a copy of the vector, since MarkIndependent implicitly modifies mSnapshots. std::vector snapshots = mSnapshots; for (std::vector::iterator iter = snapshots.begin(); iter != snapshots.end(); ++iter) { (*iter)->MarkIndependent(); } } void DrawTargetCairo::AppendSnapshot(SourceSurfaceCairo* aSnapshot) { mSnapshots.push_back(aSnapshot); } void DrawTargetCairo::RemoveSnapshot(SourceSurfaceCairo* aSnapshot) { std::vector::iterator iter = std::find(mSnapshots.begin(), mSnapshots.end(), aSnapshot); if (iter != mSnapshots.end()) { mSnapshots.erase(iter); } } void DrawTargetCairo::WillChange(const Path* aPath /* = nullptr */) { if (!mSnapshots.empty()) { for (std::vector::iterator iter = mSnapshots.begin(); iter != mSnapshots.end(); ++iter) { (*iter)->DrawTargetWillChange(); } // All snapshots will now have copied data. mSnapshots.clear(); } if (mPathObserver && (!aPath || !mPathObserver->ContainsPath(aPath))) { mPathObserver->PathWillChange(); mPathObserver = nullptr; } } void DrawTargetCairo::SetPathObserver(CairoPathContext* aPathObserver) { if (mPathObserver && mPathObserver != aPathObserver) { mPathObserver->PathWillChange(); } mPathObserver = aPathObserver; } void DrawTargetCairo::SetTransform(const Matrix& aTransform) { // We're about to logically change our transformation. Our current path will // need to change, because Cairo stores paths in device space. if (mPathObserver) { mPathObserver->MatrixWillChange(aTransform); } mTransform = aTransform; cairo_matrix_t mat; GfxMatrixToCairoMatrix(mTransform, mat); cairo_set_matrix(mContext, &mat); } } }