mirror of
https://gitlab.winehq.org/wine/wine-gecko.git
synced 2024-09-13 09:24:08 -07:00
387 lines
16 KiB
C++
387 lines
16 KiB
C++
/* This Source Code Form is subject to the terms of the Mozilla Public
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* License, v. 2.0. If a copy of the MPL was not distributed with this file,
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* You can obtain one at http://mozilla.org/MPL/2.0/. */
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#include "ReusableTileStoreOGL.h"
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#include "GLContext.h"
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namespace mozilla {
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namespace layers {
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ReusableTileStoreOGL::~ReusableTileStoreOGL()
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{
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if (mTiles.Length() == 0)
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return;
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mContext->MakeCurrent();
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for (uint32_t i = 0; i < mTiles.Length(); i++)
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mContext->fDeleteTextures(1, &mTiles[i]->mTexture.mTextureHandle);
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mTiles.Clear();
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}
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void
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ReusableTileStoreOGL::InvalidateTiles(TiledThebesLayerOGL* aLayer,
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const nsIntRegion& aValidRegion,
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const gfxSize& aResolution)
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{
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#ifdef GFX_TILEDLAYER_PREF_WARNINGS
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printf_stderr("Invalidating reused tiles\n");
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#endif
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// XXX We use GetTransform instead of GetEffectiveTransform in this function
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// as we want the transform of the shadowable layers and not that of the
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// shadow layers, which may have been modified due to async scrolling/
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// zooming.
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gfx3DMatrix transform = aLayer->GetTransform();
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// Find out the area of the nearest display-port to invalidate retained
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// tiles.
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gfxRect displayPort;
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gfxSize parentResolution = aResolution;
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for (ContainerLayer* parent = aLayer->GetParent(); parent; parent = parent->GetParent()) {
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const FrameMetrics& metrics = parent->GetFrameMetrics();
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if (displayPort.IsEmpty()) {
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if (!metrics.mDisplayPort.IsEmpty()) {
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// We use the bounds to cut down on complication/computation time.
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// This will be incorrect when the transform involves rotation, but
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// it'd be quite hard to retain invalid tiles correctly in this
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// situation anyway.
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displayPort = gfxRect(metrics.mDisplayPort.x,
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metrics.mDisplayPort.y,
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metrics.mDisplayPort.width,
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metrics.mDisplayPort.height);
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displayPort.ScaleRoundOut(parentResolution.width, parentResolution.height);
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}
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parentResolution.width /= metrics.mResolution.width;
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parentResolution.height /= metrics.mResolution.height;
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}
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if (parent->UseIntermediateSurface()) {
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transform.PreMultiply(parent->GetTransform());
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}
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}
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// If no display port was found, use the widget size from the layer manager.
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if (displayPort.IsEmpty()) {
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LayerManagerOGL* manager = static_cast<LayerManagerOGL*>(aLayer->Manager());
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const nsIntSize& widgetSize = manager->GetWidgetSize();
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displayPort.width = widgetSize.width;
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displayPort.height = widgetSize.height;
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}
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// Transform the display port into layer space.
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displayPort = transform.Inverse().TransformBounds(displayPort);
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// Iterate over existing harvested tiles and release any that are contained
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// within the new valid region, the display-port or the widget area. The
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// assumption is that anything within this area should be valid, so there's
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// no need to keep invalid tiles there.
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mContext->MakeCurrent();
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const nsIntRegion& visibleRegion = aLayer->GetEffectiveVisibleRegion();
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for (uint32_t i = 0; i < mTiles.Length();) {
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ReusableTiledTextureOGL* tile = mTiles[i];
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nsIntRegion tileRegion = tile->mTileRegion;
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if (tile->mResolution != aResolution) {
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tileRegion.ScaleRoundOut(tile->mResolution.width / aResolution.width,
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tile->mResolution.height / aResolution.height);
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}
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// Check if the tile region is contained within the new valid region.
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nsIntRect tileRect;
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bool release = false;
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bool forceKeep = false;
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if (aValidRegion.Contains(tile->mTileRegion)) {
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release = true;
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} else if (visibleRegion.Contains(tile->mTileRegion)) {
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forceKeep = true;
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} else {
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tileRect = tile->mTileRegion.GetBounds();
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}
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// Keep tiles that are within the visible region but outside of the valid
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// region, this signifies area that is in a progressive update and will
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// shortly be refreshed.
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if (forceKeep) {
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i++;
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continue;
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}
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// If the tile region wasn't contained within the valid region, check if
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// it intersects with the currently rendered region.
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if (!release) {
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if (displayPort.Contains(tileRegion.GetBounds())) {
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release = true;
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}
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}
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if (release) {
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#if GFX_TILEDLAYER_PREF_WARNINGS
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nsIntRect tileBounds = tile->mTileRegion.GetBounds();
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printf_stderr("Releasing obsolete reused tile at %d,%d, x%f\n",
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tileBounds.x, tileBounds.y, tile->mResolution.width);
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#endif
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mContext->fDeleteTextures(1, &tile->mTexture.mTextureHandle);
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mTiles.RemoveElementAt(i);
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continue;
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}
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i++;
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}
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}
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void
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ReusableTileStoreOGL::HarvestTiles(TiledThebesLayerOGL* aLayer,
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TiledLayerBufferOGL* aVideoMemoryTiledBuffer,
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const nsIntRegion& aOldValidRegion,
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const nsIntRegion& aNewValidRegion,
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const gfxSize& aOldResolution,
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const gfxSize& aNewResolution)
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{
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NS_ASSERTION(aVideoMemoryTiledBuffer->GetResolution() == 1.0f,
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"ReusableTileStoreOGL cannot harvest scaled tiles!");
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gfxSize scaleFactor = gfxSize(aNewResolution.width / aOldResolution.width,
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aNewResolution.height / aOldResolution.height);
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#ifdef GFX_TILEDLAYER_PREF_WARNINGS
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printf_stderr("Seeing if there are any tiles we can reuse\n");
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#endif
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// Iterate over the tiles and decide which ones we're going to harvest.
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// We harvest any tile that is entirely outside of the visible region, or
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// any tile that is partially outside of the visible region and whose
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// resolution has changed.
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// XXX Tile iteration needs to be abstracted, or have some utility functions
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// to make it simpler.
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uint16_t tileSize = aVideoMemoryTiledBuffer->GetTileLength();
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nsIntRect validBounds = aOldValidRegion.GetBounds();
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nsIntRegion visibleRegion = aLayer->GetEffectiveVisibleRegion();
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for (int x = validBounds.x; x < validBounds.XMost();) {
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int w = tileSize - aVideoMemoryTiledBuffer->GetTileStart(x);
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if (x + w > validBounds.x + validBounds.width)
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w = validBounds.x + validBounds.width - x;
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for (int y = validBounds.y; y < validBounds.YMost();) {
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int h = tileSize - aVideoMemoryTiledBuffer->GetTileStart(y);
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if (y + h > validBounds.y + validBounds.height)
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h = validBounds.y + validBounds.height - y;
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// If the new valid region doesn't contain this tile region,
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// harvest the tile.
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nsIntRegion tileRegion;
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tileRegion.And(aOldValidRegion, nsIntRect(x, y, w, h));
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nsIntRegion intersectingRegion;
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bool retainTile = false;
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if (fabs(aNewResolution.width - aOldResolution.width) > 1e-6) {
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// Reconcile resolution changes.
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// If the resolution changes, we know the backing layer will have been
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// invalidated, so retain tiles that are partially encompassed by the
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// new valid area, instead of just tiles that don't intersect at all.
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nsIntRegion transformedTileRegion(tileRegion);
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transformedTileRegion.ScaleRoundOut(scaleFactor.width, scaleFactor.height);
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if (!visibleRegion.Contains(transformedTileRegion))
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retainTile = true;
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} else if (intersectingRegion.And(tileRegion, visibleRegion).IsEmpty()) {
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retainTile = true;
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}
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if (retainTile) {
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TiledTexture removedTile;
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if (aVideoMemoryTiledBuffer->RemoveTile(nsIntPoint(x, y), removedTile)) {
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ReusableTiledTextureOGL* reusedTile =
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new ReusableTiledTextureOGL(removedTile, nsIntPoint(x, y), tileRegion,
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tileSize, aOldResolution);
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mTiles.AppendElement(reusedTile);
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#ifdef GFX_TILEDLAYER_PREF_WARNINGS
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bool replacedATile = false;
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#endif
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// Remove any tile that is superseded by this new tile.
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// (same resolution, same area)
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for (uint32_t i = 0; i < mTiles.Length() - 1; i++) {
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// XXX Perhaps we should check the region instead of the origin
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// so a partial tile doesn't replace a full older tile?
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if (aVideoMemoryTiledBuffer->RoundDownToTileEdge(mTiles[i]->mTileOrigin.x) == aVideoMemoryTiledBuffer->RoundDownToTileEdge(x) &&
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aVideoMemoryTiledBuffer->RoundDownToTileEdge(mTiles[i]->mTileOrigin.y) == aVideoMemoryTiledBuffer->RoundDownToTileEdge(y) &&
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abs(mTiles[i]->mResolution.width - aOldResolution.width) < 1e-5) {
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mContext->fDeleteTextures(1, &mTiles[i]->mTexture.mTextureHandle);
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mTiles.RemoveElementAt(i);
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#ifdef GFX_TILEDLAYER_PREF_WARNINGS
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replacedATile = true;
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#endif
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// There should only be one similar tile
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break;
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}
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}
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#ifdef GFX_TILEDLAYER_PREF_WARNINGS
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if (replacedATile) {
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printf_stderr("Replaced tile at %d,%d, x%f for reuse\n", x, y, aOldResolution.width);
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} else {
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printf_stderr("New tile at %d,%d, x%f for reuse\n", x, y, aOldResolution.width);
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}
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#endif
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}
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#ifdef GFX_TILEDLAYER_PREF_WARNINGS
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else
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printf_stderr("Failed to retain tile for reuse\n");
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#endif
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}
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y += h;
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}
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x += w;
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}
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// Make sure we don't hold onto tiles that may cause visible rendering glitches
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InvalidateTiles(aLayer, aNewValidRegion, aNewResolution);
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// Calculate the maximum number of tiles we should have. We base this on the
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// number of tiles it would take to cover the visible region.
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uint32_t maxTiles = 0;
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while (!visibleRegion.IsEmpty()) {
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nsIntRegionRectIterator it(visibleRegion);
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const nsIntRect* rect = it.Next();
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nsIntRect tileRect;
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tileRect.x = aVideoMemoryTiledBuffer->RoundDownToTileEdge(rect->x);
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tileRect.y = aVideoMemoryTiledBuffer->RoundDownToTileEdge(rect->y);
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tileRect.width = aVideoMemoryTiledBuffer->RoundDownToTileEdge(rect->XMost() + tileSize - 1) - tileRect.x;
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tileRect.height = aVideoMemoryTiledBuffer->RoundDownToTileEdge(rect->YMost() + tileSize - 1) - tileRect.y;
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visibleRegion.Sub(visibleRegion, tileRect);
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maxTiles += (tileRect.width / tileSize) * (tileRect.height / tileSize);
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}
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maxTiles *= mSizeLimit;
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// Now prune our reused tile store of its oldest tiles if it gets too large.
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while (mTiles.Length() > maxTiles) {
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#if GFX_TILEDLAYER_PREF_WARNINGS
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nsIntRect tileBounds = mTiles[0]->mTileRegion.GetBounds();
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printf_stderr("Releasing old reused tile at %d,%d, x%f\n",
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tileBounds.x, tileBounds.y, mTiles[0]->mResolution.width);
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#endif
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mContext->fDeleteTextures(1, &mTiles[0]->mTexture.mTextureHandle);
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mTiles.RemoveElementAt(0);
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}
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#if GFX_TILEDLAYER_PREF_WARNINGS
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printf_stderr("Retained %d tiles\n", mTiles.Length());
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#endif
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}
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void
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ReusableTileStoreOGL::DrawTiles(TiledThebesLayerOGL* aLayer,
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const nsIntRegion& aValidRegion,
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const gfxSize& aResolution,
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const gfx3DMatrix& aTransform,
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const nsIntPoint& aRenderOffset,
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Layer* aMaskLayer)
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{
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// Walk up the tree, looking for a display-port - if we find one, we know
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// that this layer represents a content node and we can use its first
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// scrollable child, in conjunction with its content area and viewport offset
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// to establish the screen coordinates to which the content area will be
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// rendered.
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gfxRect compositionBounds;
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ContainerLayer* scrollableLayer = nullptr;
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for (ContainerLayer* parent = aLayer->GetParent(); parent; parent = parent->GetParent()) {
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const FrameMetrics& parentMetrics = parent->GetFrameMetrics();
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if (parentMetrics.IsScrollable())
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scrollableLayer = parent;
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if (!parentMetrics.mDisplayPort.IsEmpty() && scrollableLayer) {
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// Get the composition bounds, so as not to waste rendering time.
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compositionBounds = gfxRect(parentMetrics.mCompositionBounds);
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// Calculate the scale transform applied to the root layer to determine
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// the content resolution.
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Layer* rootLayer = aLayer->Manager()->GetRoot();
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const gfx3DMatrix& rootTransform = rootLayer->GetTransform();
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float scaleX = rootTransform.GetXScale();
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float scaleY = rootTransform.GetYScale();
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// Get the content document bounds, in screen-space.
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const FrameMetrics& metrics = scrollableLayer->GetFrameMetrics();
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const nsIntSize& contentSize = metrics.mContentRect.Size();
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gfx::Point scrollOffset =
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gfx::Point((metrics.mScrollOffset.x * metrics.LayersPixelsPerCSSPixel().width) / scaleX,
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(metrics.mScrollOffset.y * metrics.LayersPixelsPerCSSPixel().height) / scaleY);
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const nsIntPoint& contentOrigin = metrics.mContentRect.TopLeft() -
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nsIntPoint(NS_lround(scrollOffset.x), NS_lround(scrollOffset.y));
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gfxRect contentRect = gfxRect(contentOrigin.x, contentOrigin.y,
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contentSize.width, contentSize.height);
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gfxRect contentBounds = scrollableLayer->GetEffectiveTransform().
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TransformBounds(contentRect);
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// Clip the composition bounds to the content bounds
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compositionBounds.IntersectRect(compositionBounds, contentBounds);
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break;
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}
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}
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// Render old tiles to fill in gaps we haven't had the time to render yet.
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// Simultaneously reorder tiles in LRU order.
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nsTArray< nsAutoPtr<ReusableTiledTextureOGL> > reorderedTiles(mTiles.Length());
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for (uint32_t i = 0, lastOldTile = 0; i < mTiles.Length(); i++) {
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ReusableTiledTextureOGL* tile = mTiles[i];
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// Work out the scaling factor in case of resolution differences.
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gfxSize scaleFactor = gfxSize(aResolution.width / tile->mResolution.width,
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aResolution.height / tile->mResolution.height);
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// Reconcile the resolution difference by adjusting the transform.
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gfx3DMatrix transform = aTransform;
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if (aResolution != tile->mResolution)
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transform.Scale(scaleFactor.width, scaleFactor.height, 1);
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gfx3DMatrix inverseTransform = transform.Inverse();
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// Subtract the layer's valid region from the tile region.
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nsIntRegion transformedValidRegion(aValidRegion);
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if (aResolution != tile->mResolution)
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transformedValidRegion.ScaleRoundOut(1.0f/scaleFactor.width,
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1.0f/scaleFactor.height);
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nsIntRegion tileRegion;
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tileRegion.Sub(tile->mTileRegion, transformedValidRegion);
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// Intersect the tile region with the composition bounds.
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if (!compositionBounds.IsEmpty()) {
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// Transform the composition bounds from screen space to layer space.
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gfxRect transformedCompositionBounds = inverseTransform.TransformBounds(compositionBounds);
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tileRegion.And(tileRegion, nsIntRect(transformedCompositionBounds.x,
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transformedCompositionBounds.y,
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transformedCompositionBounds.width,
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transformedCompositionBounds.height));
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}
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// If the tile region is empty, skip drawing.
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if (tileRegion.IsEmpty()) {
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reorderedTiles.InsertElementAt(lastOldTile++, mTiles[i].forget());
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continue;
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}
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reorderedTiles.AppendElement(mTiles[i].forget());
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// XXX If we have multiple tiles covering the same area, we will
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// end up with rendering artifacts if the aLayer isn't opaque.
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int32_t tileStartX;
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int32_t tileStartY;
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if (tile->mTileOrigin.x >= 0) {
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tileStartX = tile->mTileOrigin.x % tile->mTileSize;
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} else {
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tileStartX = (tile->mTileSize - (-tile->mTileOrigin.x % tile->mTileSize)) % tile->mTileSize;
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}
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if (tile->mTileOrigin.y >= 0) {
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tileStartY = tile->mTileOrigin.y % tile->mTileSize;
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} else {
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tileStartY = (tile->mTileSize - (-tile->mTileOrigin.y % tile->mTileSize)) % tile->mTileSize;
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}
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nsIntPoint tileOffset(tile->mTileOrigin.x - tileStartX, tile->mTileOrigin.y - tileStartY);
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nsIntSize textureSize(tile->mTileSize, tile->mTileSize);
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aLayer->RenderTile(tile->mTexture, transform, aRenderOffset, tileRegion, tileOffset, textureSize, aMaskLayer);
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}
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mTiles.SwapElements(reorderedTiles);
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}
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} // mozilla
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} // layers
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