| // Copyright 2012 The Chromium Authors. All rights reserved. |
| // Use of this source code is governed by a BSD-style license that can be |
| // found in the LICENSE file. |
| |
| #include "cc/resources/picture_layer_tiling.h" |
| |
| #include <algorithm> |
| #include <cmath> |
| #include <limits> |
| |
| #include "base/debug/trace_event.h" |
| #include "cc/base/math_util.h" |
| #include "ui/gfx/point_conversions.h" |
| #include "ui/gfx/rect_conversions.h" |
| #include "ui/gfx/safe_integer_conversions.h" |
| #include "ui/gfx/size_conversions.h" |
| |
| namespace cc { |
| |
| scoped_ptr<PictureLayerTiling> PictureLayerTiling::Create( |
| float contents_scale, |
| gfx::Size layer_bounds, |
| PictureLayerTilingClient* client) { |
| return make_scoped_ptr(new PictureLayerTiling(contents_scale, |
| layer_bounds, |
| client)); |
| } |
| |
| PictureLayerTiling::PictureLayerTiling(float contents_scale, |
| gfx::Size layer_bounds, |
| PictureLayerTilingClient* client) |
| : contents_scale_(contents_scale), |
| layer_bounds_(layer_bounds), |
| resolution_(NON_IDEAL_RESOLUTION), |
| client_(client), |
| tiling_data_(gfx::Size(), gfx::Size(), true), |
| last_impl_frame_time_in_seconds_(0.0) { |
| gfx::Size content_bounds = |
| gfx::ToCeiledSize(gfx::ScaleSize(layer_bounds, contents_scale)); |
| gfx::Size tile_size = client_->CalculateTileSize(content_bounds); |
| |
| DCHECK(!gfx::ToFlooredSize( |
| gfx::ScaleSize(layer_bounds, contents_scale)).IsEmpty()) << |
| "Tiling created with scale too small as contents become empty." << |
| " Layer bounds: " << layer_bounds.ToString() << |
| " Contents scale: " << contents_scale; |
| |
| tiling_data_.SetTotalSize(content_bounds); |
| tiling_data_.SetMaxTextureSize(tile_size); |
| } |
| |
| PictureLayerTiling::~PictureLayerTiling() { |
| } |
| |
| void PictureLayerTiling::SetClient(PictureLayerTilingClient* client) { |
| client_ = client; |
| } |
| |
| gfx::Rect PictureLayerTiling::ContentRect() const { |
| return gfx::Rect(tiling_data_.total_size()); |
| } |
| |
| gfx::SizeF PictureLayerTiling::ContentSizeF() const { |
| return gfx::ScaleSize(layer_bounds_, contents_scale_); |
| } |
| |
| Tile* PictureLayerTiling::TileAt(int i, int j) const { |
| TileMap::const_iterator iter = tiles_.find(TileMapKey(i, j)); |
| if (iter == tiles_.end()) |
| return NULL; |
| return iter->second.get(); |
| } |
| |
| void PictureLayerTiling::CreateTile(int i, |
| int j, |
| const PictureLayerTiling* twin_tiling) { |
| TileMapKey key(i, j); |
| DCHECK(tiles_.find(key) == tiles_.end()); |
| |
| gfx::Rect paint_rect = tiling_data_.TileBoundsWithBorder(i, j); |
| gfx::Rect tile_rect = paint_rect; |
| tile_rect.set_size(tiling_data_.max_texture_size()); |
| |
| // Check our twin for a valid tile. |
| if (twin_tiling && |
| tiling_data_.max_texture_size() == |
| twin_tiling->tiling_data_.max_texture_size()) { |
| if (Tile* candidate_tile = twin_tiling->TileAt(i, j)) { |
| gfx::Rect rect = |
| gfx::ScaleToEnclosingRect(paint_rect, 1.0f / contents_scale_); |
| if (!client_->GetInvalidation()->Intersects(rect)) { |
| tiles_[key] = candidate_tile; |
| return; |
| } |
| } |
| } |
| |
| // Create a new tile because our twin didn't have a valid one. |
| scoped_refptr<Tile> tile = client_->CreateTile(this, tile_rect); |
| if (tile.get()) |
| tiles_[key] = tile; |
| } |
| |
| Region PictureLayerTiling::OpaqueRegionInContentRect( |
| gfx::Rect content_rect) const { |
| Region opaque_region; |
| // TODO(enne): implement me |
| return opaque_region; |
| } |
| |
| void PictureLayerTiling::SetCanUseLCDText(bool can_use_lcd_text) { |
| for (TileMap::iterator it = tiles_.begin(); it != tiles_.end(); ++it) |
| it->second->set_can_use_lcd_text(can_use_lcd_text); |
| } |
| |
| void PictureLayerTiling::CreateMissingTilesInLiveTilesRect() { |
| const PictureLayerTiling* twin_tiling = client_->GetTwinTiling(this); |
| for (TilingData::Iterator iter(&tiling_data_, live_tiles_rect_); iter; |
| ++iter) { |
| TileMapKey key = iter.index(); |
| TileMap::iterator find = tiles_.find(key); |
| if (find != tiles_.end()) |
| continue; |
| CreateTile(key.first, key.second, twin_tiling); |
| } |
| } |
| |
| void PictureLayerTiling::SetLayerBounds(gfx::Size layer_bounds) { |
| if (layer_bounds_ == layer_bounds) |
| return; |
| |
| DCHECK(!layer_bounds.IsEmpty()); |
| |
| gfx::Size old_layer_bounds = layer_bounds_; |
| layer_bounds_ = layer_bounds; |
| gfx::Size old_content_bounds = tiling_data_.total_size(); |
| gfx::Size content_bounds = |
| gfx::ToCeiledSize(gfx::ScaleSize(layer_bounds_, contents_scale_)); |
| |
| gfx::Size tile_size = client_->CalculateTileSize(content_bounds); |
| if (tile_size != tiling_data_.max_texture_size()) { |
| tiling_data_.SetTotalSize(content_bounds); |
| tiling_data_.SetMaxTextureSize(tile_size); |
| Reset(); |
| return; |
| } |
| |
| // Any tiles outside our new bounds are invalid and should be dropped. |
| gfx::Rect bounded_live_tiles_rect(live_tiles_rect_); |
| bounded_live_tiles_rect.Intersect(gfx::Rect(content_bounds)); |
| SetLiveTilesRect(bounded_live_tiles_rect); |
| tiling_data_.SetTotalSize(content_bounds); |
| |
| // Create tiles for newly exposed areas. |
| Region layer_region((gfx::Rect(layer_bounds_))); |
| layer_region.Subtract(gfx::Rect(old_layer_bounds)); |
| Invalidate(layer_region); |
| } |
| |
| void PictureLayerTiling::Invalidate(const Region& layer_region) { |
| std::vector<TileMapKey> new_tile_keys; |
| for (Region::Iterator iter(layer_region); iter.has_rect(); iter.next()) { |
| gfx::Rect layer_rect = iter.rect(); |
| gfx::Rect content_rect = |
| gfx::ScaleToEnclosingRect(layer_rect, contents_scale_); |
| content_rect.Intersect(live_tiles_rect_); |
| if (content_rect.IsEmpty()) |
| continue; |
| for (TilingData::Iterator iter(&tiling_data_, content_rect); iter; ++iter) { |
| TileMapKey key(iter.index()); |
| TileMap::iterator find = tiles_.find(key); |
| if (find == tiles_.end()) |
| continue; |
| tiles_.erase(find); |
| new_tile_keys.push_back(key); |
| } |
| } |
| |
| const PictureLayerTiling* twin_tiling = client_->GetTwinTiling(this); |
| for (size_t i = 0; i < new_tile_keys.size(); ++i) |
| CreateTile(new_tile_keys[i].first, new_tile_keys[i].second, twin_tiling); |
| } |
| |
| PictureLayerTiling::CoverageIterator::CoverageIterator() |
| : tiling_(NULL), |
| current_tile_(NULL), |
| tile_i_(0), |
| tile_j_(0), |
| left_(0), |
| top_(0), |
| right_(-1), |
| bottom_(-1) { |
| } |
| |
| PictureLayerTiling::CoverageIterator::CoverageIterator( |
| const PictureLayerTiling* tiling, |
| float dest_scale, |
| gfx::Rect dest_rect) |
| : tiling_(tiling), |
| dest_rect_(dest_rect), |
| dest_to_content_scale_(0), |
| current_tile_(NULL), |
| tile_i_(0), |
| tile_j_(0), |
| left_(0), |
| top_(0), |
| right_(-1), |
| bottom_(-1) { |
| DCHECK(tiling_); |
| if (dest_rect_.IsEmpty()) |
| return; |
| |
| dest_to_content_scale_ = tiling_->contents_scale_ / dest_scale; |
| // This is the maximum size that the dest rect can be, given the content size. |
| gfx::Size dest_content_size = gfx::ToCeiledSize(gfx::ScaleSize( |
| tiling_->ContentRect().size(), |
| 1 / dest_to_content_scale_, |
| 1 / dest_to_content_scale_)); |
| |
| gfx::Rect content_rect = |
| gfx::ScaleToEnclosingRect(dest_rect_, |
| dest_to_content_scale_, |
| dest_to_content_scale_); |
| // IndexFromSrcCoord clamps to valid tile ranges, so it's necessary to |
| // check for non-intersection first. |
| content_rect.Intersect(gfx::Rect(tiling_->tiling_data_.total_size())); |
| if (content_rect.IsEmpty()) |
| return; |
| |
| left_ = tiling_->tiling_data_.TileXIndexFromSrcCoord(content_rect.x()); |
| top_ = tiling_->tiling_data_.TileYIndexFromSrcCoord(content_rect.y()); |
| right_ = tiling_->tiling_data_.TileXIndexFromSrcCoord( |
| content_rect.right() - 1); |
| bottom_ = tiling_->tiling_data_.TileYIndexFromSrcCoord( |
| content_rect.bottom() - 1); |
| |
| tile_i_ = left_ - 1; |
| tile_j_ = top_; |
| ++(*this); |
| } |
| |
| PictureLayerTiling::CoverageIterator::~CoverageIterator() { |
| } |
| |
| PictureLayerTiling::CoverageIterator& |
| PictureLayerTiling::CoverageIterator::operator++() { |
| if (tile_j_ > bottom_) |
| return *this; |
| |
| bool first_time = tile_i_ < left_; |
| bool new_row = false; |
| tile_i_++; |
| if (tile_i_ > right_) { |
| tile_i_ = left_; |
| tile_j_++; |
| new_row = true; |
| if (tile_j_ > bottom_) { |
| current_tile_ = NULL; |
| return *this; |
| } |
| } |
| |
| current_tile_ = tiling_->TileAt(tile_i_, tile_j_); |
| |
| // Calculate the current geometry rect. Due to floating point rounding |
| // and ToEnclosingRect, tiles might overlap in destination space on the |
| // edges. |
| gfx::Rect last_geometry_rect = current_geometry_rect_; |
| |
| gfx::Rect content_rect = tiling_->tiling_data_.TileBounds(tile_i_, tile_j_); |
| |
| current_geometry_rect_ = |
| gfx::ScaleToEnclosingRect(content_rect, |
| 1 / dest_to_content_scale_, |
| 1 / dest_to_content_scale_); |
| |
| current_geometry_rect_.Intersect(dest_rect_); |
| |
| if (first_time) |
| return *this; |
| |
| // Iteration happens left->right, top->bottom. Running off the bottom-right |
| // edge is handled by the intersection above with dest_rect_. Here we make |
| // sure that the new current geometry rect doesn't overlap with the last. |
| int min_left; |
| int min_top; |
| if (new_row) { |
| min_left = dest_rect_.x(); |
| min_top = last_geometry_rect.bottom(); |
| } else { |
| min_left = last_geometry_rect.right(); |
| min_top = last_geometry_rect.y(); |
| } |
| |
| int inset_left = std::max(0, min_left - current_geometry_rect_.x()); |
| int inset_top = std::max(0, min_top - current_geometry_rect_.y()); |
| current_geometry_rect_.Inset(inset_left, inset_top, 0, 0); |
| |
| if (!new_row) { |
| DCHECK_EQ(last_geometry_rect.right(), current_geometry_rect_.x()); |
| DCHECK_EQ(last_geometry_rect.bottom(), current_geometry_rect_.bottom()); |
| DCHECK_EQ(last_geometry_rect.y(), current_geometry_rect_.y()); |
| } |
| |
| return *this; |
| } |
| |
| gfx::Rect PictureLayerTiling::CoverageIterator::geometry_rect() const { |
| return current_geometry_rect_; |
| } |
| |
| gfx::Rect |
| PictureLayerTiling::CoverageIterator::full_tile_geometry_rect() const { |
| gfx::Rect rect = tiling_->tiling_data_.TileBoundsWithBorder(tile_i_, tile_j_); |
| rect.set_size(tiling_->tiling_data_.max_texture_size()); |
| return rect; |
| } |
| |
| gfx::RectF PictureLayerTiling::CoverageIterator::texture_rect() const { |
| gfx::PointF tex_origin = |
| tiling_->tiling_data_.TileBoundsWithBorder(tile_i_, tile_j_).origin(); |
| |
| // Convert from dest space => content space => texture space. |
| gfx::RectF texture_rect(current_geometry_rect_); |
| texture_rect.Scale(dest_to_content_scale_, |
| dest_to_content_scale_); |
| texture_rect.Offset(-tex_origin.OffsetFromOrigin()); |
| texture_rect.Intersect(tiling_->ContentRect()); |
| |
| return texture_rect; |
| } |
| |
| gfx::Size PictureLayerTiling::CoverageIterator::texture_size() const { |
| return tiling_->tiling_data_.max_texture_size(); |
| } |
| |
| void PictureLayerTiling::Reset() { |
| live_tiles_rect_ = gfx::Rect(); |
| tiles_.clear(); |
| } |
| |
| void PictureLayerTiling::UpdateTilePriorities( |
| WhichTree tree, |
| gfx::Size device_viewport, |
| gfx::Rect viewport_in_layer_space, |
| gfx::Rect visible_layer_rect, |
| gfx::Size last_layer_bounds, |
| gfx::Size current_layer_bounds, |
| float last_layer_contents_scale, |
| float current_layer_contents_scale, |
| const gfx::Transform& last_screen_transform, |
| const gfx::Transform& current_screen_transform, |
| double current_frame_time_in_seconds, |
| size_t max_tiles_for_interest_area) { |
| if (!NeedsUpdateForFrameAtTime(current_frame_time_in_seconds)) { |
| // This should never be zero for the purposes of has_ever_been_updated(). |
| DCHECK_NE(current_frame_time_in_seconds, 0.0); |
| return; |
| } |
| if (ContentRect().IsEmpty()) { |
| last_impl_frame_time_in_seconds_ = current_frame_time_in_seconds; |
| return; |
| } |
| |
| gfx::Rect viewport_in_content_space = |
| gfx::ScaleToEnclosingRect(viewport_in_layer_space, contents_scale_); |
| gfx::Rect visible_content_rect = |
| gfx::ScaleToEnclosingRect(visible_layer_rect, contents_scale_); |
| |
| gfx::Size tile_size = tiling_data_.max_texture_size(); |
| int64 interest_rect_area = |
| max_tiles_for_interest_area * tile_size.width() * tile_size.height(); |
| |
| gfx::Rect starting_rect = visible_content_rect.IsEmpty() |
| ? viewport_in_content_space |
| : visible_content_rect; |
| gfx::Rect interest_rect = ExpandRectEquallyToAreaBoundedBy( |
| starting_rect, |
| interest_rect_area, |
| ContentRect(), |
| &expansion_cache_); |
| DCHECK(interest_rect.IsEmpty() || |
| ContentRect().Contains(interest_rect)); |
| |
| SetLiveTilesRect(interest_rect); |
| |
| double time_delta = 0; |
| if (last_impl_frame_time_in_seconds_ != 0.0 && |
| last_layer_bounds == current_layer_bounds) { |
| time_delta = |
| current_frame_time_in_seconds - last_impl_frame_time_in_seconds_; |
| } |
| |
| gfx::RectF view_rect(device_viewport); |
| float current_scale = current_layer_contents_scale / contents_scale_; |
| float last_scale = last_layer_contents_scale / contents_scale_; |
| |
| // Fast path tile priority calculation when both transforms are translations. |
| if (last_screen_transform.IsApproximatelyIdentityOrTranslation( |
| std::numeric_limits<float>::epsilon()) && |
| current_screen_transform.IsApproximatelyIdentityOrTranslation( |
| std::numeric_limits<float>::epsilon())) { |
| gfx::Vector2dF current_offset( |
| current_screen_transform.matrix().get(0, 3), |
| current_screen_transform.matrix().get(1, 3)); |
| gfx::Vector2dF last_offset( |
| last_screen_transform.matrix().get(0, 3), |
| last_screen_transform.matrix().get(1, 3)); |
| |
| for (TilingData::Iterator iter(&tiling_data_, interest_rect); |
| iter; ++iter) { |
| TileMap::iterator find = tiles_.find(iter.index()); |
| if (find == tiles_.end()) |
| continue; |
| Tile* tile = find->second.get(); |
| |
| gfx::Rect tile_bounds = |
| tiling_data_.TileBounds(iter.index_x(), iter.index_y()); |
| gfx::RectF current_screen_rect = gfx::ScaleRect( |
| tile_bounds, |
| current_scale, |
| current_scale) + current_offset; |
| gfx::RectF last_screen_rect = gfx::ScaleRect( |
| tile_bounds, |
| last_scale, |
| last_scale) + last_offset; |
| |
| float distance_to_visible_in_pixels = |
| current_screen_rect.ManhattanInternalDistance(view_rect); |
| |
| float time_to_visible_in_seconds = |
| TilePriority::TimeForBoundsToIntersect( |
| last_screen_rect, current_screen_rect, time_delta, view_rect); |
| TilePriority priority( |
| resolution_, |
| time_to_visible_in_seconds, |
| distance_to_visible_in_pixels); |
| tile->SetPriority(tree, priority); |
| } |
| } else if (!last_screen_transform.HasPerspective() && |
| !current_screen_transform.HasPerspective()) { |
| // Secondary fast path that can be applied for any affine transforms. |
| |
| // Initialize the necessary geometry in screen space, so that we can |
| // iterate over tiles in screen space without needing a costly transform |
| // mapping for each tile. |
| |
| // Apply screen space transform to the local origin point (0, 0); only the |
| // translation component is needed and can be initialized directly. |
| gfx::Point current_screen_space_origin( |
| current_screen_transform.matrix().get(0, 3), |
| current_screen_transform.matrix().get(1, 3)); |
| |
| gfx::Point last_screen_space_origin( |
| last_screen_transform.matrix().get(0, 3), |
| last_screen_transform.matrix().get(1, 3)); |
| |
| float current_tile_width = tiling_data_.TileSizeX(0) * current_scale; |
| float last_tile_width = tiling_data_.TileSizeX(0) * last_scale; |
| float current_tile_height = tiling_data_.TileSizeY(0) * current_scale; |
| float last_tile_height = tiling_data_.TileSizeY(0) * last_scale; |
| |
| // Apply screen space transform to local basis vectors (tile_width, 0) and |
| // (0, tile_height); the math simplifies and can be initialized directly. |
| gfx::Vector2dF current_horizontal( |
| current_screen_transform.matrix().get(0, 0) * current_tile_width, |
| current_screen_transform.matrix().get(1, 0) * current_tile_width); |
| gfx::Vector2dF current_vertical( |
| current_screen_transform.matrix().get(0, 1) * current_tile_height, |
| current_screen_transform.matrix().get(1, 1) * current_tile_height); |
| |
| gfx::Vector2dF last_horizontal( |
| last_screen_transform.matrix().get(0, 0) * last_tile_width, |
| last_screen_transform.matrix().get(1, 0) * last_tile_width); |
| gfx::Vector2dF last_vertical( |
| last_screen_transform.matrix().get(0, 1) * last_tile_height, |
| last_screen_transform.matrix().get(1, 1) * last_tile_height); |
| |
| for (TilingData::Iterator iter(&tiling_data_, interest_rect); |
| iter; ++iter) { |
| TileMap::iterator find = tiles_.find(iter.index()); |
| if (find == tiles_.end()) |
| continue; |
| |
| Tile* tile = find->second.get(); |
| |
| int i = iter.index_x(); |
| int j = iter.index_y(); |
| gfx::PointF current_tile_origin = current_screen_space_origin + |
| ScaleVector2d(current_horizontal, i) + |
| ScaleVector2d(current_vertical, j); |
| gfx::PointF last_tile_origin = last_screen_space_origin + |
| ScaleVector2d(last_horizontal, i) + |
| ScaleVector2d(last_vertical, j); |
| |
| gfx::RectF current_screen_rect = gfx::QuadF( |
| current_tile_origin, |
| current_tile_origin + current_horizontal, |
| current_tile_origin + current_horizontal + current_vertical, |
| current_tile_origin + current_vertical).BoundingBox(); |
| |
| gfx::RectF last_screen_rect = gfx::QuadF( |
| last_tile_origin, |
| last_tile_origin + last_horizontal, |
| last_tile_origin + last_horizontal + last_vertical, |
| last_tile_origin + last_vertical).BoundingBox(); |
| |
| float distance_to_visible_in_pixels = |
| current_screen_rect.ManhattanInternalDistance(view_rect); |
| |
| float time_to_visible_in_seconds = |
| TilePriority::TimeForBoundsToIntersect( |
| last_screen_rect, current_screen_rect, time_delta, view_rect); |
| TilePriority priority( |
| resolution_, |
| time_to_visible_in_seconds, |
| distance_to_visible_in_pixels); |
| tile->SetPriority(tree, priority); |
| } |
| } else { |
| for (TilingData::Iterator iter(&tiling_data_, interest_rect); |
| iter; ++iter) { |
| TileMap::iterator find = tiles_.find(iter.index()); |
| if (find == tiles_.end()) |
| continue; |
| Tile* tile = find->second.get(); |
| |
| gfx::Rect tile_bounds = |
| tiling_data_.TileBounds(iter.index_x(), iter.index_y()); |
| gfx::RectF current_layer_content_rect = gfx::ScaleRect( |
| tile_bounds, |
| current_scale, |
| current_scale); |
| gfx::RectF current_screen_rect = MathUtil::MapClippedRect( |
| current_screen_transform, current_layer_content_rect); |
| gfx::RectF last_layer_content_rect = gfx::ScaleRect( |
| tile_bounds, |
| last_scale, |
| last_scale); |
| gfx::RectF last_screen_rect = MathUtil::MapClippedRect( |
| last_screen_transform, last_layer_content_rect); |
| |
| float distance_to_visible_in_pixels = |
| current_screen_rect.ManhattanInternalDistance(view_rect); |
| |
| float time_to_visible_in_seconds = |
| TilePriority::TimeForBoundsToIntersect( |
| last_screen_rect, current_screen_rect, time_delta, view_rect); |
| |
| TilePriority priority( |
| resolution_, |
| time_to_visible_in_seconds, |
| distance_to_visible_in_pixels); |
| tile->SetPriority(tree, priority); |
| } |
| } |
| |
| last_impl_frame_time_in_seconds_ = current_frame_time_in_seconds; |
| } |
| |
| void PictureLayerTiling::SetLiveTilesRect( |
| gfx::Rect new_live_tiles_rect) { |
| DCHECK(new_live_tiles_rect.IsEmpty() || |
| ContentRect().Contains(new_live_tiles_rect)); |
| if (live_tiles_rect_ == new_live_tiles_rect) |
| return; |
| |
| // Iterate to delete all tiles outside of our new live_tiles rect. |
| for (TilingData::DifferenceIterator iter(&tiling_data_, |
| live_tiles_rect_, |
| new_live_tiles_rect); |
| iter; |
| ++iter) { |
| TileMapKey key(iter.index()); |
| TileMap::iterator found = tiles_.find(key); |
| // If the tile was outside of the recorded region, it won't exist even |
| // though it was in the live rect. |
| if (found != tiles_.end()) |
| tiles_.erase(found); |
| } |
| |
| const PictureLayerTiling* twin_tiling = client_->GetTwinTiling(this); |
| |
| // Iterate to allocate new tiles for all regions with newly exposed area. |
| for (TilingData::DifferenceIterator iter(&tiling_data_, |
| new_live_tiles_rect, |
| live_tiles_rect_); |
| iter; |
| ++iter) { |
| TileMapKey key(iter.index()); |
| CreateTile(key.first, key.second, twin_tiling); |
| } |
| |
| live_tiles_rect_ = new_live_tiles_rect; |
| } |
| |
| void PictureLayerTiling::DidBecomeRecycled() { |
| // DidBecomeActive below will set the active priority for tiles that are |
| // still in the tree. Calling this first on an active tiling that is becoming |
| // recycled takes care of tiles that are no longer in the active tree (eg. |
| // due to a pending invalidation). |
| for (TileMap::const_iterator it = tiles_.begin(); it != tiles_.end(); ++it) { |
| it->second->SetPriority(ACTIVE_TREE, TilePriority()); |
| } |
| } |
| |
| void PictureLayerTiling::DidBecomeActive() { |
| for (TileMap::const_iterator it = tiles_.begin(); it != tiles_.end(); ++it) { |
| it->second->SetPriority(ACTIVE_TREE, it->second->priority(PENDING_TREE)); |
| it->second->SetPriority(PENDING_TREE, TilePriority()); |
| |
| // Tile holds a ref onto a picture pile. If the tile never gets invalidated |
| // and recreated, then that picture pile ref could exist indefinitely. To |
| // prevent this, ask the client to update the pile to its own ref. This |
| // will cause PicturePileImpls and their clones to get deleted once the |
| // corresponding PictureLayerImpl and any in flight raster jobs go out of |
| // scope. |
| client_->UpdatePile(it->second.get()); |
| } |
| } |
| |
| void PictureLayerTiling::UpdateTilesToCurrentPile() { |
| for (TileMap::const_iterator it = tiles_.begin(); it != tiles_.end(); ++it) { |
| client_->UpdatePile(it->second.get()); |
| } |
| } |
| |
| scoped_ptr<base::Value> PictureLayerTiling::AsValue() const { |
| scoped_ptr<base::DictionaryValue> state(new base::DictionaryValue()); |
| state->SetInteger("num_tiles", tiles_.size()); |
| state->SetDouble("content_scale", contents_scale_); |
| state->Set("content_bounds", |
| MathUtil::AsValue(ContentRect().size()).release()); |
| return state.PassAs<base::Value>(); |
| } |
| |
| size_t PictureLayerTiling::GPUMemoryUsageInBytes() const { |
| size_t amount = 0; |
| for (TileMap::const_iterator it = tiles_.begin(); it != tiles_.end(); ++it) { |
| const Tile* tile = it->second.get(); |
| amount += tile->GPUMemoryUsageInBytes(); |
| } |
| return amount; |
| } |
| |
| PictureLayerTiling::RectExpansionCache::RectExpansionCache() |
| : previous_target(0) { |
| } |
| |
| namespace { |
| |
| // This struct represents an event at which the expending rect intersects |
| // one of its boundaries. 4 intersection events will occur during expansion. |
| struct EdgeEvent { |
| enum { BOTTOM, TOP, LEFT, RIGHT } edge; |
| int* num_edges; |
| int distance; |
| }; |
| |
| // Compute the delta to expand from edges to cover target_area. |
| int ComputeExpansionDelta(int num_x_edges, int num_y_edges, |
| int width, int height, |
| int64 target_area) { |
| // Compute coefficients for the quadratic equation: |
| // a*x^2 + b*x + c = 0 |
| int a = num_y_edges * num_x_edges; |
| int b = num_y_edges * width + num_x_edges * height; |
| int64 c = static_cast<int64>(width) * height - target_area; |
| |
| // Compute the delta for our edges using the quadratic equation. |
| return a == 0 ? -c / b : |
| (-b + static_cast<int>( |
| std::sqrt(static_cast<int64>(b) * b - 4.0 * a * c))) / (2 * a); |
| } |
| |
| } // namespace |
| |
| gfx::Rect PictureLayerTiling::ExpandRectEquallyToAreaBoundedBy( |
| gfx::Rect starting_rect, |
| int64 target_area, |
| gfx::Rect bounding_rect, |
| RectExpansionCache* cache) { |
| if (starting_rect.IsEmpty()) |
| return starting_rect; |
| |
| if (cache && |
| cache->previous_start == starting_rect && |
| cache->previous_bounds == bounding_rect && |
| cache->previous_target == target_area) |
| return cache->previous_result; |
| |
| if (cache) { |
| cache->previous_start = starting_rect; |
| cache->previous_bounds = bounding_rect; |
| cache->previous_target = target_area; |
| } |
| |
| DCHECK(!bounding_rect.IsEmpty()); |
| DCHECK_GT(target_area, 0); |
| |
| // Expand the starting rect to cover target_area, if it is smaller than it. |
| int delta = ComputeExpansionDelta( |
| 2, 2, starting_rect.width(), starting_rect.height(), target_area); |
| gfx::Rect expanded_starting_rect = starting_rect; |
| if (delta > 0) |
| expanded_starting_rect.Inset(-delta, -delta); |
| |
| gfx::Rect rect = IntersectRects(expanded_starting_rect, bounding_rect); |
| if (rect.IsEmpty()) { |
| // The starting_rect and bounding_rect are far away. |
| if (cache) |
| cache->previous_result = rect; |
| return rect; |
| } |
| if (delta >= 0 && rect == expanded_starting_rect) { |
| // The starting rect already covers the entire bounding_rect and isn't too |
| // large for the target_area. |
| if (cache) |
| cache->previous_result = rect; |
| return rect; |
| } |
| |
| // Continue to expand/shrink rect to let it cover target_area. |
| |
| // These values will be updated by the loop and uses as the output. |
| int origin_x = rect.x(); |
| int origin_y = rect.y(); |
| int width = rect.width(); |
| int height = rect.height(); |
| |
| // In the beginning we will consider 2 edges in each dimension. |
| int num_y_edges = 2; |
| int num_x_edges = 2; |
| |
| // Create an event list. |
| EdgeEvent events[] = { |
| { EdgeEvent::BOTTOM, &num_y_edges, rect.y() - bounding_rect.y() }, |
| { EdgeEvent::TOP, &num_y_edges, bounding_rect.bottom() - rect.bottom() }, |
| { EdgeEvent::LEFT, &num_x_edges, rect.x() - bounding_rect.x() }, |
| { EdgeEvent::RIGHT, &num_x_edges, bounding_rect.right() - rect.right() } |
| }; |
| |
| // Sort the events by distance (closest first). |
| if (events[0].distance > events[1].distance) std::swap(events[0], events[1]); |
| if (events[2].distance > events[3].distance) std::swap(events[2], events[3]); |
| if (events[0].distance > events[2].distance) std::swap(events[0], events[2]); |
| if (events[1].distance > events[3].distance) std::swap(events[1], events[3]); |
| if (events[1].distance > events[2].distance) std::swap(events[1], events[2]); |
| |
| for (int event_index = 0; event_index < 4; event_index++) { |
| const EdgeEvent& event = events[event_index]; |
| |
| int delta = ComputeExpansionDelta( |
| num_x_edges, num_y_edges, width, height, target_area); |
| |
| // Clamp delta to our event distance. |
| if (delta > event.distance) |
| delta = event.distance; |
| |
| // Adjust the edge count for this kind of edge. |
| --*event.num_edges; |
| |
| // Apply the delta to the edges and edge events. |
| for (int i = event_index; i < 4; i++) { |
| switch (events[i].edge) { |
| case EdgeEvent::BOTTOM: |
| origin_y -= delta; |
| height += delta; |
| break; |
| case EdgeEvent::TOP: |
| height += delta; |
| break; |
| case EdgeEvent::LEFT: |
| origin_x -= delta; |
| width += delta; |
| break; |
| case EdgeEvent::RIGHT: |
| width += delta; |
| break; |
| } |
| events[i].distance -= delta; |
| } |
| |
| // If our delta is less then our event distance, we're done. |
| if (delta < event.distance) |
| break; |
| } |
| |
| gfx::Rect result(origin_x, origin_y, width, height); |
| if (cache) |
| cache->previous_result = result; |
| return result; |
| } |
| |
| } // namespace cc |