/* -*- 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 "RotatedBuffer.h" #include // for int32_t #include // for max #include "BasicImplData.h" // for BasicImplData #include "BasicLayersImpl.h" // for ToData #include "BufferUnrotate.h" // for BufferUnrotate #include "GeckoProfiler.h" // for PROFILER_LABEL #include "Layers.h" // for ThebesLayer, Layer, etc #include "gfxPlatform.h" // for gfxPlatform #include "gfxUtils.h" // for gfxUtils #include "mozilla/ArrayUtils.h" // for ArrayLength #include "mozilla/gfx/BasePoint.h" // for BasePoint #include "mozilla/gfx/BaseRect.h" // for BaseRect #include "mozilla/gfx/BaseSize.h" // for BaseSize #include "mozilla/gfx/Matrix.h" // for Matrix #include "mozilla/gfx/Point.h" // for Point, IntPoint #include "mozilla/gfx/Rect.h" // for Rect, IntRect #include "mozilla/gfx/Types.h" // for ExtendMode::ExtendMode::CLAMP, etc #include "mozilla/layers/ShadowLayers.h" // for ShadowableLayer #include "mozilla/layers/TextureClient.h" // for DeprecatedTextureClient #include "nsSize.h" // for nsIntSize #include "gfx2DGlue.h" namespace mozilla { using namespace gfx; namespace layers { nsIntRect RotatedBuffer::GetQuadrantRectangle(XSide aXSide, YSide aYSide) const { // quadrantTranslation is the amount we translate the top-left // of the quadrant by to get coordinates relative to the layer nsIntPoint quadrantTranslation = -mBufferRotation; quadrantTranslation.x += aXSide == LEFT ? mBufferRect.width : 0; quadrantTranslation.y += aYSide == TOP ? mBufferRect.height : 0; return mBufferRect + quadrantTranslation; } Rect RotatedBuffer::GetSourceRectangle(XSide aXSide, YSide aYSide) const { Rect result; if (aXSide == LEFT) { result.x = 0; result.width = mBufferRotation.x; } else { result.x = mBufferRotation.x; result.width = mBufferRect.width - mBufferRotation.x; } if (aYSide == TOP) { result.y = 0; result.height = mBufferRotation.y; } else { result.y = mBufferRotation.y; result.height = mBufferRect.height - mBufferRotation.y; } return result; } /** * @param aXSide LEFT means we draw from the left side of the buffer (which * is drawn on the right side of mBufferRect). RIGHT means we draw from * the right side of the buffer (which is drawn on the left side of * mBufferRect). * @param aYSide TOP means we draw from the top side of the buffer (which * is drawn on the bottom side of mBufferRect). BOTTOM means we draw from * the bottom side of the buffer (which is drawn on the top side of * mBufferRect). */ void RotatedBuffer::DrawBufferQuadrant(gfx::DrawTarget* aTarget, XSide aXSide, YSide aYSide, ContextSource aSource, float aOpacity, gfx::CompositionOp aOperator, gfx::SourceSurface* aMask, const gfx::Matrix* aMaskTransform) const { // The rectangle that we're going to fill. Basically we're going to // render the buffer at mBufferRect + quadrantTranslation to get the // pixels in the right place, but we're only going to paint within // mBufferRect nsIntRect quadrantRect = GetQuadrantRectangle(aXSide, aYSide); nsIntRect fillRect; if (!fillRect.IntersectRect(mBufferRect, quadrantRect)) return; gfx::Point quadrantTranslation(quadrantRect.x, quadrantRect.y); MOZ_ASSERT(aOperator == CompositionOp::OP_OVER || aOperator == CompositionOp::OP_SOURCE); // direct2d is much slower when using OP_SOURCE so use OP_OVER and // (maybe) a clear instead. Normally we need to draw in a single operation // (to avoid flickering) but direct2d is ok since it defers rendering. // We should try abstract this logic in a helper when we have other use // cases. if (aTarget->GetType() == BackendType::DIRECT2D && aOperator == CompositionOp::OP_SOURCE) { aOperator = CompositionOp::OP_OVER; if (mDTBuffer->GetFormat() == SurfaceFormat::B8G8R8A8) { aTarget->ClearRect(ToRect(fillRect)); } } RefPtr snapshot; if (aSource == BUFFER_BLACK) { snapshot = mDTBuffer->Snapshot(); } else { MOZ_ASSERT(aSource == BUFFER_WHITE); snapshot = mDTBufferOnWhite->Snapshot(); } if (aOperator == CompositionOp::OP_SOURCE) { // OP_SOURCE is unbounded in Azure, and we really don't want that behaviour here. // We also can't do a ClearRect+FillRect since we need the drawing to happen // as an atomic operation (to prevent flickering). aTarget->PushClipRect(gfx::Rect(fillRect.x, fillRect.y, fillRect.width, fillRect.height)); } if (aMask) { // Transform from user -> buffer space. Matrix transform; transform.Translate(quadrantTranslation.x, quadrantTranslation.y); #ifdef MOZ_GFX_OPTIMIZE_MOBILE SurfacePattern source(snapshot, ExtendMode::CLAMP, transform, Filter::POINT); #else SurfacePattern source(snapshot, ExtendMode::CLAMP, transform); #endif Matrix oldTransform = aTarget->GetTransform(); aTarget->SetTransform(*aMaskTransform); aTarget->MaskSurface(source, aMask, Point(0, 0), DrawOptions(aOpacity, aOperator)); aTarget->SetTransform(oldTransform); } else { #ifdef MOZ_GFX_OPTIMIZE_MOBILE DrawSurfaceOptions options(Filter::POINT); #else DrawSurfaceOptions options; #endif aTarget->DrawSurface(snapshot, ToRect(fillRect), GetSourceRectangle(aXSide, aYSide), options, DrawOptions(aOpacity, aOperator)); } if (aOperator == CompositionOp::OP_SOURCE) { aTarget->PopClip(); } } void RotatedBuffer::DrawBufferWithRotation(gfx::DrawTarget *aTarget, ContextSource aSource, float aOpacity, gfx::CompositionOp aOperator, gfx::SourceSurface* aMask, const gfx::Matrix* aMaskTransform) const { PROFILER_LABEL("RotatedBuffer", "DrawBufferWithRotation"); // See above, in Azure Repeat should always be a safe, even faster choice // though! Particularly on D2D Repeat should be a lot faster, need to look // into that. TODO[Bas] DrawBufferQuadrant(aTarget, LEFT, TOP, aSource, aOpacity, aOperator, aMask, aMaskTransform); DrawBufferQuadrant(aTarget, RIGHT, TOP, aSource, aOpacity, aOperator, aMask, aMaskTransform); DrawBufferQuadrant(aTarget, LEFT, BOTTOM, aSource, aOpacity, aOperator, aMask, aMaskTransform); DrawBufferQuadrant(aTarget, RIGHT, BOTTOM, aSource, aOpacity, aOperator,aMask, aMaskTransform); } /* static */ bool RotatedContentBuffer::IsClippingCheap(DrawTarget* aTarget, const nsIntRegion& aRegion) { // Assume clipping is cheap if the draw target just has an integer // translation, and the visible region is simple. return !aTarget->GetTransform().HasNonIntegerTranslation() && aRegion.GetNumRects() <= 1; } void RotatedContentBuffer::DrawTo(ThebesLayer* aLayer, DrawTarget* aTarget, float aOpacity, CompositionOp aOp, gfxASurface* aMask, const Matrix* aMaskTransform) { if (!EnsureBuffer()) { return; } bool clipped = false; // If the entire buffer is valid, we can just draw the whole thing, // no need to clip. But we'll still clip if clipping is cheap --- // that might let us copy a smaller region of the buffer. // Also clip to the visible region if we're told to. if (!aLayer->GetValidRegion().Contains(BufferRect()) || (ToData(aLayer)->GetClipToVisibleRegion() && !aLayer->GetVisibleRegion().Contains(BufferRect())) || IsClippingCheap(aTarget, aLayer->GetEffectiveVisibleRegion())) { // We don't want to draw invalid stuff, so we need to clip. Might as // well clip to the smallest area possible --- the visible region. // Bug 599189 if there is a non-integer-translation transform in aTarget, // we might sample pixels outside GetEffectiveVisibleRegion(), which is wrong // and may cause gray lines. gfxUtils::ClipToRegionSnapped(aTarget, aLayer->GetEffectiveVisibleRegion()); clipped = true; } RefPtr mask; if (aMask) { mask = gfxPlatform::GetPlatform()->GetSourceSurfaceForSurface(aTarget, aMask); } Matrix maskTransform; if (aMaskTransform) { maskTransform = *aMaskTransform; } DrawBufferWithRotation(aTarget, BUFFER_BLACK, aOpacity, aOp, mask, &maskTransform); if (clipped) { aTarget->PopClip(); } } DrawTarget* RotatedContentBuffer::BorrowDrawTargetForQuadrantUpdate(const nsIntRect& aBounds, ContextSource aSource) { if (!EnsureBuffer()) { return nullptr; } MOZ_ASSERT(!mLoanedDrawTarget, "draw target has been borrowed and not returned"); if (aSource == BUFFER_BOTH && HaveBufferOnWhite()) { if (!EnsureBufferOnWhite()) { return nullptr; } MOZ_ASSERT(mDTBuffer && mDTBufferOnWhite); mLoanedDrawTarget = Factory::CreateDualDrawTarget(mDTBuffer, mDTBufferOnWhite); } else if (aSource == BUFFER_WHITE) { if (!EnsureBufferOnWhite()) { return nullptr; } mLoanedDrawTarget = mDTBufferOnWhite; } else { // BUFFER_BLACK, or BUFFER_BOTH with a single buffer. mLoanedDrawTarget = mDTBuffer; } // Figure out which quadrant to draw in int32_t xBoundary = mBufferRect.XMost() - mBufferRotation.x; int32_t yBoundary = mBufferRect.YMost() - mBufferRotation.y; XSide sideX = aBounds.XMost() <= xBoundary ? RIGHT : LEFT; YSide sideY = aBounds.YMost() <= yBoundary ? BOTTOM : TOP; nsIntRect quadrantRect = GetQuadrantRectangle(sideX, sideY); NS_ASSERTION(quadrantRect.Contains(aBounds), "Messed up quadrants"); mLoanedTransform = mLoanedDrawTarget->GetTransform(); mLoanedTransform.Translate(-quadrantRect.x, -quadrantRect.y); mLoanedDrawTarget->SetTransform(mLoanedTransform); mLoanedTransform.Translate(quadrantRect.x, quadrantRect.y); return mLoanedDrawTarget; } void BorrowDrawTarget::ReturnDrawTarget(gfx::DrawTarget*& aReturned) { MOZ_ASSERT(aReturned == mLoanedDrawTarget); mLoanedDrawTarget->SetTransform(mLoanedTransform); mLoanedDrawTarget = nullptr; aReturned = nullptr; } gfxContentType RotatedContentBuffer::BufferContentType() { if (mDeprecatedBufferProvider) { return mDeprecatedBufferProvider->GetContentType(); } if (mBufferProvider || mDTBuffer) { SurfaceFormat format; if (mBufferProvider) { format = mBufferProvider->AsTextureClientDrawTarget()->GetFormat(); } else if (mDTBuffer) { format = mDTBuffer->GetFormat(); } return ContentForFormat(format); } return gfxContentType::SENTINEL; } bool RotatedContentBuffer::BufferSizeOkFor(const nsIntSize& aSize) { return (aSize == mBufferRect.Size() || (SizedToVisibleBounds != mBufferSizePolicy && aSize < mBufferRect.Size())); } bool RotatedContentBuffer::EnsureBuffer() { NS_ASSERTION(!mLoanedDrawTarget, "Loaned draw target must be returned"); if (!mDTBuffer) { if (mDeprecatedBufferProvider) { mDTBuffer = mDeprecatedBufferProvider->LockDrawTarget(); } else if (mBufferProvider) { mDTBuffer = mBufferProvider->AsTextureClientDrawTarget()->GetAsDrawTarget(); } } NS_WARN_IF_FALSE(mDTBuffer, "no buffer"); return !!mDTBuffer; } bool RotatedContentBuffer::EnsureBufferOnWhite() { NS_ASSERTION(!mLoanedDrawTarget, "Loaned draw target must be returned"); if (!mDTBufferOnWhite) { if (mDeprecatedBufferProviderOnWhite) { mDTBufferOnWhite = mDeprecatedBufferProviderOnWhite->LockDrawTarget(); } else if (mBufferProviderOnWhite) { mDTBufferOnWhite = mBufferProviderOnWhite->AsTextureClientDrawTarget()->GetAsDrawTarget(); } } NS_WARN_IF_FALSE(mDTBufferOnWhite, "no buffer"); return mDTBufferOnWhite; } bool RotatedContentBuffer::HaveBuffer() const { return mDTBuffer || mDeprecatedBufferProvider || mBufferProvider; } bool RotatedContentBuffer::HaveBufferOnWhite() const { return mDTBufferOnWhite || mDeprecatedBufferProviderOnWhite || mBufferProviderOnWhite; } static void WrapRotationAxis(int32_t* aRotationPoint, int32_t aSize) { if (*aRotationPoint < 0) { *aRotationPoint += aSize; } else if (*aRotationPoint >= aSize) { *aRotationPoint -= aSize; } } static nsIntRect ComputeBufferRect(const nsIntRect& aRequestedRect) { nsIntRect rect(aRequestedRect); // Set a minimum width to guarantee a minimum size of buffers we // allocate (and work around problems on some platforms with smaller // dimensions). 64 is the magic number needed to work around the // rendering glitch, and guarantees image rows can be SIMD'd for // even r5g6b5 surfaces pretty much everywhere. rect.width = std::max(aRequestedRect.width, 64); #ifdef MOZ_WIDGET_GONK // Set a minumum height to guarantee a minumum height of buffers we // allocate. Some GL implementations fail to render gralloc textures // with a height 9px-16px. It happens on Adreno 200. Adreno 320 does not // have this problem. 32 is choosed as alignment of gralloc buffers. // See Bug 873937. // Increase the height only when the requested height is more than 0. // See Bug 895976. // XXX it might be better to disable it on the gpu that does not have // the height problem. if (rect.height > 0) { rect.height = std::max(aRequestedRect.height, 32); } #endif return rect; } void RotatedContentBuffer::FlushBuffers() { if (mDTBuffer) { mDTBuffer->Flush(); } if (mDTBufferOnWhite) { mDTBufferOnWhite->Flush(); } } RotatedContentBuffer::PaintState RotatedContentBuffer::BeginPaint(ThebesLayer* aLayer, uint32_t aFlags) { PaintState result; // We need to disable rotation if we're going to be resampled when // drawing, because we might sample across the rotation boundary. bool canHaveRotation = gfxPlatform::BufferRotationEnabled() && !(aFlags & (PAINT_WILL_RESAMPLE | PAINT_NO_ROTATION)); nsIntRegion validRegion = aLayer->GetValidRegion(); bool canUseOpaqueSurface = aLayer->CanUseOpaqueSurface(); ContentType layerContentType = canUseOpaqueSurface ? gfxContentType::COLOR : gfxContentType::COLOR_ALPHA; SurfaceMode mode; nsIntRegion neededRegion; bool canReuseBuffer; nsIntRect destBufferRect; while (true) { mode = aLayer->GetSurfaceMode(); neededRegion = aLayer->GetVisibleRegion(); canReuseBuffer = HaveBuffer() && BufferSizeOkFor(neededRegion.GetBounds().Size()); result.mContentType = layerContentType; if (canReuseBuffer) { if (mBufferRect.Contains(neededRegion.GetBounds())) { // We don't need to adjust mBufferRect. destBufferRect = mBufferRect; } else if (neededRegion.GetBounds().Size() <= mBufferRect.Size()) { // The buffer's big enough but doesn't contain everything that's // going to be visible. We'll move it. destBufferRect = nsIntRect(neededRegion.GetBounds().TopLeft(), mBufferRect.Size()); } else { destBufferRect = neededRegion.GetBounds(); } } else { // We won't be reusing the buffer. Compute a new rect. destBufferRect = ComputeBufferRect(neededRegion.GetBounds()); } if (mode == SurfaceMode::SURFACE_COMPONENT_ALPHA) { #if defined(MOZ_GFX_OPTIMIZE_MOBILE) || defined(MOZ_WIDGET_GONK) mode = SurfaceMode::SURFACE_SINGLE_CHANNEL_ALPHA; #else if (!aLayer->GetParent() || !aLayer->GetParent()->SupportsComponentAlphaChildren() || !aLayer->Manager()->IsCompositingCheap() || !aLayer->AsShadowableLayer() || !aLayer->AsShadowableLayer()->HasShadow() || !gfxPlatform::ComponentAlphaEnabled()) { mode = SurfaceMode::SURFACE_SINGLE_CHANNEL_ALPHA; } else { result.mContentType = gfxContentType::COLOR; } #endif } if ((aFlags & PAINT_WILL_RESAMPLE) && (!neededRegion.GetBounds().IsEqualInterior(destBufferRect) || neededRegion.GetNumRects() > 1)) { // The area we add to neededRegion might not be painted opaquely if (mode == SurfaceMode::SURFACE_OPAQUE) { result.mContentType = gfxContentType::COLOR_ALPHA; mode = SurfaceMode::SURFACE_SINGLE_CHANNEL_ALPHA; } // We need to validate the entire buffer, to make sure that only valid // pixels are sampled neededRegion = destBufferRect; } // If we have an existing buffer, but the content type has changed or we // have transitioned into/out of component alpha, then we need to recreate it. if (HaveBuffer() && (result.mContentType != BufferContentType() || (mode == SurfaceMode::SURFACE_COMPONENT_ALPHA) != HaveBufferOnWhite())) { // We're effectively clearing the valid region, so we need to draw // the entire needed region now. result.mRegionToInvalidate = aLayer->GetValidRegion(); validRegion.SetEmpty(); Clear(); // Restart decision process with the cleared buffer. We can only go // around the loop one more iteration, since mDTBuffer is null now. continue; } break; } NS_ASSERTION(destBufferRect.Contains(neededRegion.GetBounds()), "Destination rect doesn't contain what we need to paint"); result.mRegionToDraw.Sub(neededRegion, validRegion); // Do not modify result.mRegionToDraw or result.mContentType after this call. // Do not modify mBufferRect, mBufferRotation, or mDidSelfCopy, // or call CreateBuffer before this call. FinalizeFrame(result.mRegionToDraw); if (result.mRegionToDraw.IsEmpty()) return result; nsIntRect drawBounds = result.mRegionToDraw.GetBounds(); RefPtr destDTBuffer; RefPtr destDTBufferOnWhite; uint32_t bufferFlags = canHaveRotation ? ALLOW_REPEAT : 0; if (mode == SurfaceMode::SURFACE_COMPONENT_ALPHA) { bufferFlags |= BUFFER_COMPONENT_ALPHA; } if (canReuseBuffer) { if (!EnsureBuffer()) { return result; } nsIntRect keepArea; if (keepArea.IntersectRect(destBufferRect, mBufferRect)) { // Set mBufferRotation so that the pixels currently in mDTBuffer // will still be rendered in the right place when mBufferRect // changes to destBufferRect. nsIntPoint newRotation = mBufferRotation + (destBufferRect.TopLeft() - mBufferRect.TopLeft()); WrapRotationAxis(&newRotation.x, mBufferRect.width); WrapRotationAxis(&newRotation.y, mBufferRect.height); NS_ASSERTION(nsIntRect(nsIntPoint(0,0), mBufferRect.Size()).Contains(newRotation), "newRotation out of bounds"); int32_t xBoundary = destBufferRect.XMost() - newRotation.x; int32_t yBoundary = destBufferRect.YMost() - newRotation.y; if ((drawBounds.x < xBoundary && xBoundary < drawBounds.XMost()) || (drawBounds.y < yBoundary && yBoundary < drawBounds.YMost()) || (newRotation != nsIntPoint(0,0) && !canHaveRotation)) { // The stuff we need to redraw will wrap around an edge of the // buffer, so move the pixels we can keep into a position that // lets us redraw in just one quadrant. if (mBufferRotation == nsIntPoint(0,0)) { nsIntRect srcRect(nsIntPoint(0, 0), mBufferRect.Size()); nsIntPoint dest = mBufferRect.TopLeft() - destBufferRect.TopLeft(); MOZ_ASSERT(mDTBuffer); mDTBuffer->CopyRect(IntRect(srcRect.x, srcRect.y, srcRect.width, srcRect.height), IntPoint(dest.x, dest.y)); if (mode == SurfaceMode::SURFACE_COMPONENT_ALPHA) { if (!EnsureBufferOnWhite()) { return result; } MOZ_ASSERT(mDTBufferOnWhite); mDTBufferOnWhite->CopyRect(IntRect(srcRect.x, srcRect.y, srcRect.width, srcRect.height), IntPoint(dest.x, dest.y)); } result.mDidSelfCopy = true; mDidSelfCopy = true; // Don't set destBuffer; we special-case self-copies, and // just did the necessary work above. mBufferRect = destBufferRect; } else { // With azure and a data surface perform an buffer unrotate // (SelfCopy). unsigned char* data; IntSize size; int32_t stride; SurfaceFormat format; if (mDTBuffer->LockBits(&data, &size, &stride, &format)) { uint8_t bytesPerPixel = BytesPerPixel(format); BufferUnrotate(data, size.width * bytesPerPixel, size.height, stride, newRotation.x * bytesPerPixel, newRotation.y); mDTBuffer->ReleaseBits(data); if (mode == SurfaceMode::SURFACE_COMPONENT_ALPHA) { if (!EnsureBufferOnWhite()) { return result; } MOZ_ASSERT(mDTBufferOnWhite); mDTBufferOnWhite->LockBits(&data, &size, &stride, &format); uint8_t bytesPerPixel = BytesPerPixel(format); BufferUnrotate(data, size.width * bytesPerPixel, size.height, stride, newRotation.x * bytesPerPixel, newRotation.y); mDTBufferOnWhite->ReleaseBits(data); } // Buffer unrotate moves all the pixels, note that // we self copied for SyncBackToFrontBuffer result.mDidSelfCopy = true; mDidSelfCopy = true; mBufferRect = destBufferRect; mBufferRotation = nsIntPoint(0, 0); } if (!result.mDidSelfCopy) { destBufferRect = ComputeBufferRect(neededRegion.GetBounds()); CreateBuffer(result.mContentType, destBufferRect, bufferFlags, &destDTBuffer, &destDTBufferOnWhite); if (!destDTBuffer) { return result; } } } } else { mBufferRect = destBufferRect; mBufferRotation = newRotation; } } else { // No pixels are going to be kept. The whole visible region // will be redrawn, so we don't need to copy anything, so we don't // set destBuffer. mBufferRect = destBufferRect; mBufferRotation = nsIntPoint(0,0); } } else { // The buffer's not big enough, so allocate a new one CreateBuffer(result.mContentType, destBufferRect, bufferFlags, &destDTBuffer, &destDTBufferOnWhite); if (!destDTBuffer) { return result; } } NS_ASSERTION(!(aFlags & PAINT_WILL_RESAMPLE) || destBufferRect == neededRegion.GetBounds(), "If we're resampling, we need to validate the entire buffer"); // If we have no buffered data already, then destBuffer will be a fresh buffer // and we do not need to clear it below. bool isClear = !HaveBuffer(); if (destDTBuffer) { if (!isClear && (mode != SurfaceMode::SURFACE_COMPONENT_ALPHA || HaveBufferOnWhite())) { // Copy the bits nsIntPoint offset = -destBufferRect.TopLeft(); Matrix mat; mat.Translate(offset.x, offset.y); destDTBuffer->SetTransform(mat); if (!EnsureBuffer()) { return result; } MOZ_ASSERT(mDTBuffer, "Have we got a Thebes buffer for some reason?"); DrawBufferWithRotation(destDTBuffer, BUFFER_BLACK, 1.0, CompositionOp::OP_SOURCE); destDTBuffer->SetTransform(Matrix()); if (mode == SurfaceMode::SURFACE_COMPONENT_ALPHA) { NS_ASSERTION(destDTBufferOnWhite, "Must have a white buffer!"); destDTBufferOnWhite->SetTransform(mat); if (!EnsureBufferOnWhite()) { return result; } MOZ_ASSERT(mDTBufferOnWhite, "Have we got a Thebes buffer for some reason?"); DrawBufferWithRotation(destDTBufferOnWhite, BUFFER_WHITE, 1.0, CompositionOp::OP_SOURCE); destDTBufferOnWhite->SetTransform(Matrix()); } } mDTBuffer = destDTBuffer.forget(); mDTBufferOnWhite = destDTBufferOnWhite.forget(); mBufferRect = destBufferRect; mBufferRotation = nsIntPoint(0,0); } NS_ASSERTION(canHaveRotation || mBufferRotation == nsIntPoint(0,0), "Rotation disabled, but we have nonzero rotation?"); nsIntRegion invalidate; invalidate.Sub(aLayer->GetValidRegion(), destBufferRect); result.mRegionToInvalidate.Or(result.mRegionToInvalidate, invalidate); result.mClip = DrawRegionClip::DRAW_SNAPPED; result.mMode = mode; return result; } DrawTarget* RotatedContentBuffer::BorrowDrawTargetForPainting(ThebesLayer* aLayer, const PaintState& aPaintState) { if (aPaintState.mMode == SurfaceMode::SURFACE_NONE) { return nullptr; } DrawTarget* result = BorrowDrawTargetForQuadrantUpdate(aPaintState.mRegionToDraw.GetBounds(), BUFFER_BOTH); if (aPaintState.mMode == SurfaceMode::SURFACE_COMPONENT_ALPHA) { MOZ_ASSERT(mDTBuffer && mDTBufferOnWhite); nsIntRegionRectIterator iter(aPaintState.mRegionToDraw); const nsIntRect *iterRect; while ((iterRect = iter.Next())) { mDTBuffer->FillRect(Rect(iterRect->x, iterRect->y, iterRect->width, iterRect->height), ColorPattern(Color(0.0, 0.0, 0.0, 1.0))); mDTBufferOnWhite->FillRect(Rect(iterRect->x, iterRect->y, iterRect->width, iterRect->height), ColorPattern(Color(1.0, 1.0, 1.0, 1.0))); } } else if (aPaintState.mContentType == gfxContentType::COLOR_ALPHA && HaveBuffer()) { // HaveBuffer() => we have an existing buffer that we must clear nsIntRegionRectIterator iter(aPaintState.mRegionToDraw); const nsIntRect *iterRect; while ((iterRect = iter.Next())) { result->ClearRect(Rect(iterRect->x, iterRect->y, iterRect->width, iterRect->height)); } } return result; } } }