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1b95e41dd6
The tiles backend passes raw pointers to transfer tiled buffers between the main thread and the compositor. This patch changes that to use shared memory and tile descriptors instead, as well as changing the memory management slightly to facilitate that.
463 lines
18 KiB
C++
463 lines
18 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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#ifndef GFX_TILEDLAYERBUFFER_H
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#define GFX_TILEDLAYERBUFFER_H
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#define TILEDLAYERBUFFER_TILE_SIZE 256
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#ifdef MOZ_ANDROID_OMTC
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// This needs to go away as we enabled tiled
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// layers everywhere.
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#define FORCE_BASICTILEDTHEBESLAYER
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#endif
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// Debug defines
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//#define GFX_TILEDLAYER_DEBUG_OVERLAY
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//#define GFX_TILEDLAYER_PREF_WARNINGS
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#include <stdint.h> // for uint16_t, uint32_t
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#include <sys/types.h> // for int32_t
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#include "nsDebug.h" // for NS_ABORT_IF_FALSE
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#include "nsPoint.h" // for nsIntPoint
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#include "nsRect.h" // for nsIntRect
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#include "nsRegion.h" // for nsIntRegion
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#include "nsTArray.h" // for nsTArray
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namespace mozilla {
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namespace layers {
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// An abstract implementation of a tile buffer. This code covers the logic of
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// moving and reusing tiles and leaves the validation up to the implementor. To
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// avoid the overhead of virtual dispatch, we employ the curiously recurring
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// template pattern.
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//
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// Tiles are aligned to a grid with one of the grid points at (0,0) and other
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// grid points spaced evenly in the x- and y-directions by GetTileLength()
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// multiplied by mResolution. GetScaledTileLength() provides convenience for
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// accessing these values.
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//
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// This tile buffer stores a valid region, which defines the areas that have
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// up-to-date content. The contents of tiles within this region will be reused
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// from paint to paint. It also stores the region that was modified in the last
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// paint operation; this is useful when one tiled layer buffer shadows another
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// (as in an off-main-thread-compositing scenario), so that the shadow tiled
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// layer buffer can correctly reflect the updates of the master layer buffer.
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//
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// The associated Tile may be of any type as long as the derived class can
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// validate and return tiles of that type. Tiles will be frequently copied, so
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// the tile type should be a reference or some other type with an efficient
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// copy constructor.
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//
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// It is required that the derived class specify the base class as a friend. It
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// must also implement the following public method:
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//
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// Tile GetPlaceholderTile() const;
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//
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// Returns a temporary placeholder tile used as a marker. This placeholder tile
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// must never be returned by validateTile and must be == to every instance
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// of a placeholder tile.
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//
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// Additionally, it must implement the following protected methods:
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//
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// Tile ValidateTile(Tile aTile, const nsIntPoint& aTileOrigin,
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// const nsIntRegion& aDirtyRect);
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//
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// Validates the dirtyRect. The returned Tile will replace the tile.
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//
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// void ReleaseTile(Tile aTile);
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//
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// Destroys the given tile.
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//
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// void SwapTiles(Tile& aTileA, Tile& aTileB);
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//
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// Swaps two tiles.
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//
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// The contents of the tile buffer will be rendered at the resolution specified
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// in mResolution, which can be altered with SetResolution. The resolution
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// should always be a factor of the tile length, to avoid tiles covering
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// non-integer amounts of pixels.
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template<typename Derived, typename Tile>
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class TiledLayerBuffer
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{
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public:
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TiledLayerBuffer()
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: mRetainedWidth(0)
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, mRetainedHeight(0)
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, mResolution(1)
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{}
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~TiledLayerBuffer() {}
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// Given a tile origin aligned to a multiple of GetScaledTileLength,
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// return the tile that describes that region.
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// NOTE: To get the valid area of that tile you must intersect
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// (aTileOrigin.x, aTileOrigin.y,
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// GetScaledTileLength(), GetScaledTileLength())
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// and GetValidRegion() to get the area of the tile that is valid.
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Tile GetTile(const nsIntPoint& aTileOrigin) const;
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// Given a tile x, y relative to the top left of the layer, this function
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// will return the tile for
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// (x*GetScaledTileLength(), y*GetScaledTileLength(),
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// GetScaledTileLength(), GetScaledTileLength())
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Tile GetTile(int x, int y) const;
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// This operates the same as GetTile(aTileOrigin), but will also replace the
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// specified tile with the placeholder tile. This does not call ReleaseTile
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// on the removed tile.
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bool RemoveTile(const nsIntPoint& aTileOrigin, Tile& aRemovedTile);
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// This operates the same as GetTile(x, y), but will also replace the
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// specified tile with the placeholder tile. This does not call ReleaseTile
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// on the removed tile.
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bool RemoveTile(int x, int y, Tile& aRemovedTile);
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uint16_t GetTileLength() const { return TILEDLAYERBUFFER_TILE_SIZE; }
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#ifdef MOZ_WIDGET_ANDROID
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MOZ_NEVER_INLINE // bug 881018 causes wrong results when GetScaledTileLength is inlined
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#endif
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uint32_t GetScaledTileLength() const { return TILEDLAYERBUFFER_TILE_SIZE / mResolution; }
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unsigned int GetTileCount() const { return mRetainedTiles.Length(); }
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const nsIntRegion& GetValidRegion() const { return mValidRegion; }
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const nsIntRegion& GetPaintedRegion() const { return mPaintedRegion; }
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void ClearPaintedRegion() { mPaintedRegion.SetEmpty(); }
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// Given a position i, this function returns the position inside the current tile.
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int GetTileStart(int i) const {
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return (i >= 0) ? (i % GetScaledTileLength())
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: ((GetScaledTileLength() - (-i % GetScaledTileLength())) %
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GetScaledTileLength());
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}
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// Rounds the given coordinate down to the nearest tile boundary.
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int RoundDownToTileEdge(int aX) const { return aX - GetTileStart(aX); }
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// Get and set draw scaling. mResolution affects the resolution at which the
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// contents of the buffer are drawn. mResolution has no effect on the
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// coordinate space of the valid region, but does affect the size of an
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// individual tile's rect in relation to the valid region.
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// Setting the resolution will invalidate the buffer.
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float GetResolution() const { return mResolution; }
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void SetResolution(float aResolution) {
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if (mResolution == aResolution) {
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return;
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}
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Update(nsIntRegion(), nsIntRegion());
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mResolution = aResolution;
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}
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bool IsLowPrecision() const { return mResolution < 1; }
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typedef Tile* Iterator;
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Iterator TilesBegin() { return mRetainedTiles.Elements(); }
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Iterator TilesEnd() { return mRetainedTiles.Elements() + mRetainedTiles.Length(); }
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protected:
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// The implementor should call Update() to change
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// the new valid region. This implementation will call
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// validateTile on each tile that is dirty, which is left
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// to the implementor.
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void Update(const nsIntRegion& aNewValidRegion, const nsIntRegion& aPaintRegion);
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nsIntRegion mValidRegion;
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nsIntRegion mPaintedRegion;
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/**
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* mRetainedTiles is a rectangular buffer of mRetainedWidth x mRetainedHeight
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* stored as column major with the same origin as mValidRegion.GetBounds().
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* Any tile that does not intersect mValidRegion is a PlaceholderTile.
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* Only the region intersecting with mValidRegion should be read from a tile,
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* another other region is assumed to be uninitialized. The contents of the
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* tiles is scaled by mResolution.
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*/
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nsTArray<Tile> mRetainedTiles;
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int mRetainedWidth; // in tiles
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int mRetainedHeight; // in tiles
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float mResolution;
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private:
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const Derived& AsDerived() const { return *static_cast<const Derived*>(this); }
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Derived& AsDerived() { return *static_cast<Derived*>(this); }
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bool IsPlaceholder(Tile aTile) const { return aTile == AsDerived().GetPlaceholderTile(); }
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};
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class BasicTiledLayerBuffer;
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class SurfaceDescriptorTiles;
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class ISurfaceAllocator;
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// Shadow layers may implement this interface in order to be notified when a
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// tiled layer buffer is updated.
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class TiledLayerComposer
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{
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public:
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/**
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* Update the current retained layer with the updated layer data.
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* It is expected that the tiles described by aTiledDescriptor are all in the
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* ReadLock state, so that the locks can be adopted when recreating a
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* BasicTiledLayerBuffer locally. This lock will be retained until the buffer
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* has completed uploading.
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*/
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virtual void PaintedTiledLayerBuffer(ISurfaceAllocator* aAllocator,
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const SurfaceDescriptorTiles& aTiledDescriptor) = 0;
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/**
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* If some part of the buffer is being rendered at a lower precision, this
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* returns that region. If it is not, an empty region will be returned.
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*/
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virtual const nsIntRegion& GetValidLowPrecisionRegion() const = 0;
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};
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// Normal integer division truncates towards zero,
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// we instead want to floor to hangle negative numbers.
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static inline int floor_div(int a, int b)
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{
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int rem = a % b;
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int div = a/b;
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if (rem == 0) {
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return div;
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} else {
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// If the signs are different substract 1.
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int sub;
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sub = a ^ b;
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// The results of this shift is either 0 or -1.
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sub >>= 8*sizeof(int)-1;
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return div+sub;
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}
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}
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template<typename Derived, typename Tile> Tile
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TiledLayerBuffer<Derived, Tile>::GetTile(const nsIntPoint& aTileOrigin) const
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{
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// TODO Cache firstTileOriginX/firstTileOriginY
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// Find the tile x/y of the first tile and the target tile relative to the (0, 0)
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// origin, the difference is the tile x/y relative to the start of the tile buffer.
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int firstTileX = floor_div(mValidRegion.GetBounds().x, GetScaledTileLength());
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int firstTileY = floor_div(mValidRegion.GetBounds().y, GetScaledTileLength());
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return GetTile(floor_div(aTileOrigin.x, GetScaledTileLength()) - firstTileX,
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floor_div(aTileOrigin.y, GetScaledTileLength()) - firstTileY);
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}
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template<typename Derived, typename Tile> Tile
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TiledLayerBuffer<Derived, Tile>::GetTile(int x, int y) const
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{
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int index = x * mRetainedHeight + y;
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return mRetainedTiles.SafeElementAt(index, AsDerived().GetPlaceholderTile());
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}
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template<typename Derived, typename Tile> bool
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TiledLayerBuffer<Derived, Tile>::RemoveTile(const nsIntPoint& aTileOrigin,
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Tile& aRemovedTile)
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{
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int firstTileX = floor_div(mValidRegion.GetBounds().x, GetScaledTileLength());
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int firstTileY = floor_div(mValidRegion.GetBounds().y, GetScaledTileLength());
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return RemoveTile(floor_div(aTileOrigin.x, GetScaledTileLength()) - firstTileX,
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floor_div(aTileOrigin.y, GetScaledTileLength()) - firstTileY,
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aRemovedTile);
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}
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template<typename Derived, typename Tile> bool
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TiledLayerBuffer<Derived, Tile>::RemoveTile(int x, int y, Tile& aRemovedTile)
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{
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int index = x * mRetainedHeight + y;
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const Tile& tileToRemove = mRetainedTiles.SafeElementAt(index, AsDerived().GetPlaceholderTile());
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if (!IsPlaceholder(tileToRemove)) {
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aRemovedTile = tileToRemove;
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mRetainedTiles[index] = AsDerived().GetPlaceholderTile();
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return true;
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}
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return false;
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}
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template<typename Derived, typename Tile> void
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TiledLayerBuffer<Derived, Tile>::Update(const nsIntRegion& aNewValidRegion,
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const nsIntRegion& aPaintRegion)
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{
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nsTArray<Tile> newRetainedTiles;
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nsTArray<Tile>& oldRetainedTiles = mRetainedTiles;
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const nsIntRect oldBound = mValidRegion.GetBounds();
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const nsIntRect newBound = aNewValidRegion.GetBounds();
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const nsIntPoint oldBufferOrigin(RoundDownToTileEdge(oldBound.x),
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RoundDownToTileEdge(oldBound.y));
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const nsIntPoint newBufferOrigin(RoundDownToTileEdge(newBound.x),
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RoundDownToTileEdge(newBound.y));
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const nsIntRegion& oldValidRegion = mValidRegion;
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const nsIntRegion& newValidRegion = aNewValidRegion;
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const int oldRetainedHeight = mRetainedHeight;
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// Pass 1: Recycle valid content from the old buffer
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// Recycle tiles from the old buffer that contain valid regions.
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// Insert placeholders tiles if we have no valid area for that tile
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// which we will allocate in pass 2.
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// TODO: Add a tile pool to reduce new allocation
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int tileX = 0;
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int tileY = 0;
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// Iterate over the new drawing bounds in steps of tiles.
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for (int32_t x = newBound.x; x < newBound.XMost(); tileX++) {
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// Compute tileRect(x,y,width,height) in layer space coordinate
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// giving us the rect of the tile that hits the newBounds.
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int width = GetScaledTileLength() - GetTileStart(x);
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if (x + width > newBound.XMost()) {
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width = newBound.x + newBound.width - x;
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}
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tileY = 0;
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for (int32_t y = newBound.y; y < newBound.YMost(); tileY++) {
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int height = GetScaledTileLength() - GetTileStart(y);
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if (y + height > newBound.y + newBound.height) {
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height = newBound.y + newBound.height - y;
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}
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const nsIntRect tileRect(x,y,width,height);
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if (oldValidRegion.Intersects(tileRect) && newValidRegion.Intersects(tileRect)) {
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// This old tiles contains some valid area so move it to the new tile
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// buffer. Replace the tile in the old buffer with a placeholder
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// to leave the old buffer index unaffected.
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int tileX = floor_div(x - oldBufferOrigin.x, GetScaledTileLength());
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int tileY = floor_div(y - oldBufferOrigin.y, GetScaledTileLength());
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int index = tileX * oldRetainedHeight + tileY;
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// The tile may have been removed, skip over it in this case.
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if (IsPlaceholder(oldRetainedTiles.
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SafeElementAt(index, AsDerived().GetPlaceholderTile()))) {
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newRetainedTiles.AppendElement(AsDerived().GetPlaceholderTile());
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} else {
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Tile tileWithPartialValidContent = oldRetainedTiles[index];
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newRetainedTiles.AppendElement(tileWithPartialValidContent);
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oldRetainedTiles[index] = AsDerived().GetPlaceholderTile();
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}
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} else {
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// This tile is either:
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// 1) Outside the new valid region and will simply be an empty
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// placeholder forever.
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// 2) The old buffer didn't have any data for this tile. We postpone
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// the allocation of this tile after we've reused any tile with
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// valid content because then we know we can safely recycle
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// with taking from a tile that has recyclable content.
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newRetainedTiles.AppendElement(AsDerived().GetPlaceholderTile());
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}
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y += height;
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}
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x += width;
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}
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// Keep track of the number of horizontal/vertical tiles
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// in the buffer so that we can easily look up a tile.
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mRetainedWidth = tileX;
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mRetainedHeight = tileY;
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NS_ABORT_IF_FALSE(aNewValidRegion.Contains(aPaintRegion), "Painting a region outside the visible region");
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#ifdef DEBUG
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nsIntRegion oldAndPainted(oldValidRegion);
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oldAndPainted.Or(oldAndPainted, aPaintRegion);
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#endif
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NS_ABORT_IF_FALSE(oldAndPainted.Contains(newValidRegion), "newValidRegion has not been fully painted");
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nsIntRegion regionToPaint(aPaintRegion);
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// Pass 2: Validate
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// We know at this point that any tile in the new buffer that had valid content
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// from the previous buffer is placed correctly in the new buffer.
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// We know that any tile in the old buffer that isn't a place holder is
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// of no use and can be recycled.
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// We also know that any place holder tile in the new buffer must be
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// allocated.
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tileX = 0;
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#ifdef GFX_TILEDLAYER_PREF_WARNINGS
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printf_stderr("Update %i, %i, %i, %i\n", newBound.x, newBound.y, newBound.width, newBound.height);
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#endif
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for (int x = newBound.x; x < newBound.x + newBound.width; tileX++) {
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// Compute tileRect(x,y,width,height) in layer space coordinate
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// giving us the rect of the tile that hits the newBounds.
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int tileStartX = RoundDownToTileEdge(x);
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int width = GetScaledTileLength() - GetTileStart(x);
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if (x + width > newBound.XMost())
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width = newBound.XMost() - x;
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tileY = 0;
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for (int y = newBound.y; y < newBound.y + newBound.height; tileY++) {
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int tileStartY = RoundDownToTileEdge(y);
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int height = GetScaledTileLength() - GetTileStart(y);
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if (y + height > newBound.YMost()) {
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height = newBound.YMost() - y;
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}
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const nsIntRect tileRect(x, y, width, height);
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nsIntRegion tileDrawRegion;
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tileDrawRegion.And(tileRect, regionToPaint);
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if (tileDrawRegion.IsEmpty()) {
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// We have a tile but it doesn't hit the draw region
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// because we can reuse all of the content from the
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// previous buffer.
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#ifdef DEBUG
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int currTileX = floor_div(x - newBufferOrigin.x, GetScaledTileLength());
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int currTileY = floor_div(y - newBufferOrigin.y, GetScaledTileLength());
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int index = currTileX * mRetainedHeight + currTileY;
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NS_ABORT_IF_FALSE(!newValidRegion.Intersects(tileRect) ||
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!IsPlaceholder(newRetainedTiles.
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SafeElementAt(index, AsDerived().GetPlaceholderTile())),
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"If we don't draw a tile we shouldn't have a placeholder there.");
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#endif
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y += height;
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continue;
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}
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int tileX = floor_div(x - newBufferOrigin.x, GetScaledTileLength());
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int tileY = floor_div(y - newBufferOrigin.y, GetScaledTileLength());
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int index = tileX * mRetainedHeight + tileY;
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NS_ABORT_IF_FALSE(index >= 0 &&
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static_cast<unsigned>(index) < newRetainedTiles.Length(),
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"index out of range");
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Tile newTile = newRetainedTiles[index];
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while (IsPlaceholder(newTile) && oldRetainedTiles.Length() > 0) {
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AsDerived().SwapTiles(newTile, oldRetainedTiles[oldRetainedTiles.Length()-1]);
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oldRetainedTiles.RemoveElementAt(oldRetainedTiles.Length()-1);
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}
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// We've done our best effort to recycle a tile but it can be null
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// in which case it's up to the derived class's ValidateTile()
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// implementation to allocate a new tile before drawing
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nsIntPoint tileOrigin(tileStartX, tileStartY);
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newTile = AsDerived().ValidateTile(newTile, nsIntPoint(tileStartX, tileStartY),
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tileDrawRegion);
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NS_ABORT_IF_FALSE(!IsPlaceholder(newTile), "index out of range");
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#ifdef GFX_TILEDLAYER_PREF_WARNINGS
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printf_stderr("Store Validate tile %i, %i -> %i\n", tileStartX, tileStartY, index);
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#endif
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newRetainedTiles[index] = newTile;
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y += height;
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}
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x += width;
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}
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// Throw away any tiles we didn't recycle
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// TODO: Add a tile pool
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while (oldRetainedTiles.Length() > 0) {
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|
Tile oldTile = oldRetainedTiles[oldRetainedTiles.Length()-1];
|
|
oldRetainedTiles.RemoveElementAt(oldRetainedTiles.Length()-1);
|
|
AsDerived().ReleaseTile(oldTile);
|
|
}
|
|
|
|
mRetainedTiles = newRetainedTiles;
|
|
mValidRegion = aNewValidRegion;
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|
mPaintedRegion.Or(mPaintedRegion, aPaintRegion);
|
|
}
|
|
|
|
} // layers
|
|
} // mozilla
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|
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#endif // GFX_TILEDLAYERBUFFER_H
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