/* 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 "ClientTiledThebesLayer.h" #include "FrameMetrics.h" // for FrameMetrics #include "Units.h" // for ScreenIntRect, CSSPoint, etc #include "UnitTransforms.h" // for TransformTo #include "ClientLayerManager.h" // for ClientLayerManager, etc #include "gfx3DMatrix.h" // for gfx3DMatrix #include "gfxPlatform.h" // for gfxPlatform #include "gfxPrefs.h" // for gfxPrefs #include "gfxRect.h" // for gfxRect #include "mozilla/Assertions.h" // for MOZ_ASSERT, etc #include "mozilla/gfx/BaseSize.h" // for BaseSize #include "mozilla/gfx/Rect.h" // for Rect, RectTyped #include "mozilla/layers/LayersMessages.h" #include "mozilla/mozalloc.h" // for operator delete, etc #include "nsISupportsImpl.h" // for MOZ_COUNT_CTOR, etc #include "nsRect.h" // for nsIntRect namespace mozilla { namespace layers { ClientTiledThebesLayer::ClientTiledThebesLayer(ClientLayerManager* const aManager) : ThebesLayer(aManager, static_cast(MOZ_THIS_IN_INITIALIZER_LIST())) , mContentClient() { MOZ_COUNT_CTOR(ClientTiledThebesLayer); mPaintData.mLastScrollOffset = ParentLayerPoint(0, 0); mPaintData.mFirstPaint = true; } ClientTiledThebesLayer::~ClientTiledThebesLayer() { MOZ_COUNT_DTOR(ClientTiledThebesLayer); } void ClientTiledThebesLayer::ClearCachedResources() { if (mContentClient) { mContentClient->ClearCachedResources(); } } void ClientTiledThebesLayer::FillSpecificAttributes(SpecificLayerAttributes& aAttrs) { aAttrs = ThebesLayerAttributes(GetValidRegion()); } static LayoutDeviceRect ApplyParentLayerToLayoutTransform(const gfx3DMatrix& aTransform, const ParentLayerRect& aParentLayerRect) { return TransformTo(aTransform, aParentLayerRect); } void ClientTiledThebesLayer::BeginPaint() { if (ClientManager()->IsRepeatTransaction()) { return; } mPaintData.mLowPrecisionPaintCount = 0; mPaintData.mPaintFinished = false; mPaintData.mCompositionBounds.SetEmpty(); mPaintData.mCriticalDisplayPort.SetEmpty(); if (!GetBaseTransform().Is2DIntegerTranslation()) { // Give up if the layer is transformed. The code below assumes that there // is no transform set, and not making that assumption would cause huge // complication to handle a quite rare case. // // FIXME The intention is to bail out of this function when there's a CSS // transform set on the layer, but unfortunately there's no way to // distinguish transforms due to scrolling from transforms due to // CSS transforms. // // Because of this, there may be unintended behaviour when setting // 2d CSS translations on the children of scrollable displayport // layers. return; } // Get the metrics of the nearest scrollable layer and the nearest layer // with a displayport. ContainerLayer* displayPortParent = nullptr; ContainerLayer* scrollParent = nullptr; for (ContainerLayer* parent = GetParent(); parent; parent = parent->GetParent()) { const FrameMetrics& metrics = parent->GetFrameMetrics(); if (!scrollParent && metrics.GetScrollId() != FrameMetrics::NULL_SCROLL_ID) { scrollParent = parent; } if (!metrics.mDisplayPort.IsEmpty()) { displayPortParent = parent; // Any layer that has a displayport must be scrollable, so we can break // here. break; } } if (!displayPortParent || !scrollParent) { // No displayport or scroll parent, so we can't do progressive rendering. // Just set the composition bounds to empty and return. #if defined(MOZ_WIDGET_ANDROID) || defined(MOZ_B2G) // Both Android and b2g are guaranteed to have a displayport set, so this // should never happen. NS_WARNING("Tiled Thebes layer with no scrollable container parent"); #endif return; } // Note, not handling transformed layers lets us assume that LayoutDevice // space of the scroll parent layer is the same as LayoutDevice space of // this layer. const FrameMetrics& scrollMetrics = scrollParent->GetFrameMetrics(); const FrameMetrics& displayportMetrics = displayPortParent->GetFrameMetrics(); // Calculate the transform required to convert ParentLayer space of our // display port parent to LayoutDevice space of this layer. gfx::Matrix4x4 transform = scrollParent->GetTransform(); ContainerLayer* displayPortParentParent = displayPortParent->GetParent() ? displayPortParent->GetParent()->GetParent() : nullptr; for (ContainerLayer* parent = scrollParent->GetParent(); parent != displayPortParentParent; parent = parent->GetParent()) { transform = transform * parent->GetTransform(); } gfx3DMatrix layoutDeviceToScrollParentLayer; gfx::To3DMatrix(transform, layoutDeviceToScrollParentLayer); layoutDeviceToScrollParentLayer.ScalePost(scrollMetrics.mCumulativeResolution.scale, scrollMetrics.mCumulativeResolution.scale, 1.f); mPaintData.mTransformParentLayerToLayoutDevice = layoutDeviceToScrollParentLayer.Inverse(); // Compute the critical display port of the display port layer in // LayoutDevice space of this layer. ParentLayerRect criticalDisplayPort = (displayportMetrics.mCriticalDisplayPort + displayportMetrics.GetScrollOffset()) * displayportMetrics.GetZoomToParent(); mPaintData.mCriticalDisplayPort = LayoutDeviceIntRect::ToUntyped(RoundedOut( ApplyParentLayerToLayoutTransform(mPaintData.mTransformParentLayerToLayoutDevice, criticalDisplayPort))); // Compute the viewport of the display port layer in LayoutDevice space of // this layer. ParentLayerRect viewport = (displayportMetrics.mViewport + displayportMetrics.GetScrollOffset()) * displayportMetrics.GetZoomToParent(); mPaintData.mViewport = ApplyParentLayerToLayoutTransform( mPaintData.mTransformParentLayerToLayoutDevice, viewport); // Store the scroll parent resolution. Because this is Gecko-side, before any // async transforms have occurred, we can use the zoom for this. mPaintData.mResolution = displayportMetrics.GetZoomToParent(); // Store the parent composition bounds in LayoutDevice units. // This is actually in LayoutDevice units of the scrollParent's parent layer, // but because there is no transform, we can assume that these are the same. mPaintData.mCompositionBounds = scrollMetrics.mCompositionBounds / scrollMetrics.GetParentResolution(); // Calculate the scroll offset since the last transaction mPaintData.mScrollOffset = displayportMetrics.GetScrollOffset() * displayportMetrics.GetZoomToParent(); } void ClientTiledThebesLayer::EndPaint(bool aFinish) { if (!aFinish && !mPaintData.mPaintFinished) { return; } mPaintData.mLastScrollOffset = mPaintData.mScrollOffset; mPaintData.mPaintFinished = true; mPaintData.mFirstPaint = false; } void ClientTiledThebesLayer::RenderLayer() { LayerManager::DrawThebesLayerCallback callback = ClientManager()->GetThebesLayerCallback(); void *data = ClientManager()->GetThebesLayerCallbackData(); if (!callback) { ClientManager()->SetTransactionIncomplete(); return; } if (!mContentClient) { mContentClient = new TiledContentClient(this, ClientManager()); mContentClient->Connect(); ClientManager()->AsShadowForwarder()->Attach(mContentClient, this); MOZ_ASSERT(mContentClient->GetForwarder()); } if (mContentClient->mTiledBuffer.HasFormatChanged()) { mValidRegion = nsIntRegion(); } nsIntRegion invalidRegion = mVisibleRegion; invalidRegion.Sub(invalidRegion, mValidRegion); if (invalidRegion.IsEmpty()) { EndPaint(true); return; } // Only paint the mask layer on the first transaction. if (GetMaskLayer() && !ClientManager()->IsRepeatTransaction()) { ToClientLayer(GetMaskLayer())->RenderLayer(); } bool isFixed = GetIsFixedPosition() || GetParent()->GetIsFixedPosition(); // Fast path for no progressive updates, no low-precision updates and no // critical display-port set, or no display-port set, or this is a fixed // position layer/contained in a fixed position layer const FrameMetrics& parentMetrics = GetParent()->GetFrameMetrics(); if ((!gfxPrefs::UseProgressiveTilePainting() && !gfxPrefs::UseLowPrecisionBuffer() && parentMetrics.mCriticalDisplayPort.IsEmpty()) || parentMetrics.mDisplayPort.IsEmpty() || isFixed) { mValidRegion = mVisibleRegion; NS_ASSERTION(!ClientManager()->IsRepeatTransaction(), "Didn't paint our mask layer"); mContentClient->mTiledBuffer.PaintThebes(mValidRegion, invalidRegion, callback, data); ClientManager()->Hold(this); mContentClient->UseTiledLayerBuffer(TiledContentClient::TILED_BUFFER); return; } // Calculate everything we need to perform the paint. BeginPaint(); if (mPaintData.mPaintFinished) { return; } // Make sure that tiles that fall outside of the visible region are // discarded on the first update. if (!ClientManager()->IsRepeatTransaction()) { mValidRegion.And(mValidRegion, mVisibleRegion); if (!mPaintData.mCriticalDisplayPort.IsEmpty()) { // Make sure that tiles that fall outside of the critical displayport are // discarded on the first update. mValidRegion.And(mValidRegion, mPaintData.mCriticalDisplayPort); } } nsIntRegion lowPrecisionInvalidRegion; if (!mPaintData.mCriticalDisplayPort.IsEmpty()) { if (gfxPrefs::UseLowPrecisionBuffer()) { // Calculate the invalid region for the low precision buffer lowPrecisionInvalidRegion.Sub(mVisibleRegion, mLowPrecisionValidRegion); // Remove the valid region from the low precision valid region (we don't // validate this part of the low precision buffer). lowPrecisionInvalidRegion.Sub(lowPrecisionInvalidRegion, mValidRegion); } // Clip the invalid region to the critical display-port invalidRegion.And(invalidRegion, mPaintData.mCriticalDisplayPort); if (invalidRegion.IsEmpty() && lowPrecisionInvalidRegion.IsEmpty()) { EndPaint(true); return; } } if (!invalidRegion.IsEmpty() && mPaintData.mLowPrecisionPaintCount == 0) { bool updatedBuffer = false; // Only draw progressively when the resolution is unchanged. if (gfxPrefs::UseProgressiveTilePainting() && !ClientManager()->HasShadowTarget() && mContentClient->mTiledBuffer.GetFrameResolution() == mPaintData.mResolution) { // Store the old valid region, then clear it before painting. // We clip the old valid region to the visible region, as it only gets // used to decide stale content (currently valid and previously visible) nsIntRegion oldValidRegion = mContentClient->mTiledBuffer.GetValidRegion(); oldValidRegion.And(oldValidRegion, mVisibleRegion); if (!mPaintData.mCriticalDisplayPort.IsEmpty()) { oldValidRegion.And(oldValidRegion, mPaintData.mCriticalDisplayPort); } updatedBuffer = mContentClient->mTiledBuffer.ProgressiveUpdate(mValidRegion, invalidRegion, oldValidRegion, &mPaintData, callback, data); } else { updatedBuffer = true; mValidRegion = mVisibleRegion; if (!mPaintData.mCriticalDisplayPort.IsEmpty()) { mValidRegion.And(mValidRegion, mPaintData.mCriticalDisplayPort); } mContentClient->mTiledBuffer.SetFrameResolution(mPaintData.mResolution); mContentClient->mTiledBuffer.PaintThebes(mValidRegion, invalidRegion, callback, data); } if (updatedBuffer) { ClientManager()->Hold(this); mContentClient->UseTiledLayerBuffer(TiledContentClient::TILED_BUFFER); // If there are low precision updates, mark the paint as unfinished and // request a repeat transaction. if (!lowPrecisionInvalidRegion.IsEmpty() && mPaintData.mPaintFinished) { ClientManager()->SetRepeatTransaction(); mPaintData.mLowPrecisionPaintCount = 1; mPaintData.mPaintFinished = false; } // Return so that low precision updates aren't performed in the same // transaction as high-precision updates. EndPaint(false); return; } } // Render the low precision buffer, if there's area to invalidate and the // visible region is larger than the critical display port. bool updatedLowPrecision = false; if (!lowPrecisionInvalidRegion.IsEmpty() && !nsIntRegion(mPaintData.mCriticalDisplayPort).Contains(mVisibleRegion)) { nsIntRegion oldValidRegion = mContentClient->mLowPrecisionTiledBuffer.GetValidRegion(); oldValidRegion.And(oldValidRegion, mVisibleRegion); // If the frame resolution or format have changed, invalidate the buffer if (mContentClient->mLowPrecisionTiledBuffer.GetFrameResolution() != mPaintData.mResolution || mContentClient->mLowPrecisionTiledBuffer.HasFormatChanged()) { if (!mLowPrecisionValidRegion.IsEmpty()) { updatedLowPrecision = true; } oldValidRegion.SetEmpty(); mLowPrecisionValidRegion.SetEmpty(); mContentClient->mLowPrecisionTiledBuffer.SetFrameResolution(mPaintData.mResolution); lowPrecisionInvalidRegion = mVisibleRegion; } // Invalidate previously valid content that is no longer visible if (mPaintData.mLowPrecisionPaintCount == 1) { mLowPrecisionValidRegion.And(mLowPrecisionValidRegion, mVisibleRegion); } mPaintData.mLowPrecisionPaintCount++; // Remove the valid high-precision region from the invalid low-precision // region. We don't want to spend time drawing things twice. lowPrecisionInvalidRegion.Sub(lowPrecisionInvalidRegion, mValidRegion); if (!lowPrecisionInvalidRegion.IsEmpty()) { updatedLowPrecision = mContentClient->mLowPrecisionTiledBuffer .ProgressiveUpdate(mLowPrecisionValidRegion, lowPrecisionInvalidRegion, oldValidRegion, &mPaintData, callback, data); } } else if (!mLowPrecisionValidRegion.IsEmpty()) { // Clear the low precision tiled buffer updatedLowPrecision = true; mLowPrecisionValidRegion.SetEmpty(); mContentClient->mLowPrecisionTiledBuffer.PaintThebes(mLowPrecisionValidRegion, mLowPrecisionValidRegion, callback, data); } // We send a Painted callback if we clear the valid region of the low // precision buffer, so that the shadow buffer's valid region can be updated // and the associated resources can be freed. if (updatedLowPrecision) { ClientManager()->Hold(this); mContentClient->UseTiledLayerBuffer(TiledContentClient::LOW_PRECISION_TILED_BUFFER); } EndPaint(false); } } // mozilla } // layers