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// 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/layers/delegated_renderer_layer_impl.h"
#include <algorithm>
#include <utility>
#include "base/bind.h"
#include "base/hash_tables.h"
#include "cc/base/math_util.h"
#include "cc/layers/append_quads_data.h"
#include "cc/layers/quad_sink.h"
#include "cc/layers/render_pass_sink.h"
#include "cc/output/delegated_frame_data.h"
#include "cc/quads/render_pass_draw_quad.h"
#include "cc/quads/solid_color_draw_quad.h"
#include "cc/trees/layer_tree_impl.h"
namespace cc {
DelegatedRendererLayerImpl::DelegatedRendererLayerImpl(
LayerTreeImpl* tree_impl, int id)
: LayerImpl(tree_impl, id),
have_render_passes_to_push_(false),
child_id_(0),
own_child_id_(false) {
}
DelegatedRendererLayerImpl::~DelegatedRendererLayerImpl() {
ClearRenderPasses();
ClearChildId();
}
bool DelegatedRendererLayerImpl::HasDelegatedContent() const {
return !render_passes_in_draw_order_.empty();
}
bool DelegatedRendererLayerImpl::HasContributingDelegatedRenderPasses() const {
// The root RenderPass for the layer is merged with its target
// RenderPass in each frame. So we only have extra RenderPasses
// to merge when we have a non-root RenderPass present.
return render_passes_in_draw_order_.size() > 1;
}
static ResourceProvider::ResourceId ResourceRemapHelper(
bool* invalid_frame,
const ResourceProvider::ResourceIdMap& child_to_parent_map,
ResourceProvider::ResourceIdSet *remapped_resources,
ResourceProvider::ResourceId id) {
ResourceProvider::ResourceIdMap::const_iterator it =
child_to_parent_map.find(id);
if (it == child_to_parent_map.end()) {
*invalid_frame = true;
return 0;
}
DCHECK_EQ(it->first, id);
ResourceProvider::ResourceId remapped_id = it->second;
remapped_resources->insert(remapped_id);
return remapped_id;
}
void DelegatedRendererLayerImpl::PushPropertiesTo(LayerImpl* layer) {
LayerImpl::PushPropertiesTo(layer);
DelegatedRendererLayerImpl* delegated_layer =
static_cast<DelegatedRendererLayerImpl*>(layer);
// If we have a new child_id to give to the active layer, it should
// have already deleted its old child_id.
DCHECK(delegated_layer->child_id_ == 0 ||
delegated_layer->child_id_ == child_id_);
delegated_layer->child_id_ = child_id_;
delegated_layer->own_child_id_ = true;
own_child_id_ = false;
delegated_layer->SetDisplaySize(display_size_);
if (have_render_passes_to_push_) {
// This passes ownership of the render passes to the active tree.
delegated_layer->SetRenderPasses(&render_passes_in_draw_order_);
DCHECK(render_passes_in_draw_order_.empty());
have_render_passes_to_push_ = false;
}
// This is just a copy for testing since we keep the data on the pending layer
// for returning resources to the child for now.
delegated_layer->resources_ = resources_;
}
void DelegatedRendererLayerImpl::SetFrameData(
scoped_ptr<DelegatedFrameData> frame_data,
gfx::RectF damage_in_frame,
TransferableResourceArray* resources_for_ack) {
CreateChildIdIfNeeded();
DCHECK(child_id_);
ResourceProvider* resource_provider = layer_tree_impl()->resource_provider();
const ResourceProvider::ResourceIdMap& resource_map =
resource_provider->GetChildToParentMap(child_id_);
if (frame_data) {
// A frame with an empty root render pass is invalid.
DCHECK(frame_data->render_pass_list.empty() ||
!frame_data->render_pass_list.back()->output_rect.IsEmpty());
// Display size is already set so we can compute what the damage rect
// will be in layer space.
if (!frame_data->render_pass_list.empty()) {
RenderPass* new_root_pass = frame_data->render_pass_list.back();
gfx::RectF damage_in_layer = MathUtil::MapClippedRect(
DelegatedFrameToLayerSpaceTransform(
new_root_pass->output_rect.size()),
damage_in_frame);
set_update_rect(gfx::UnionRects(update_rect(), damage_in_layer));
}
resource_provider->ReceiveFromChild(child_id_, frame_data->resource_list);
bool invalid_frame = false;
ResourceProvider::ResourceIdSet used_resources;
DrawQuad::ResourceIteratorCallback remap_resources_to_parent_callback =
base::Bind(&ResourceRemapHelper,
&invalid_frame,
resource_map,
&used_resources);
for (size_t i = 0; i < frame_data->render_pass_list.size(); ++i) {
RenderPass* pass = frame_data->render_pass_list[i];
for (size_t j = 0; j < pass->quad_list.size(); ++j) {
DrawQuad* quad = pass->quad_list[j];
quad->IterateResources(remap_resources_to_parent_callback);
}
}
if (!invalid_frame) {
// Save the remapped quads on the layer. This steals the quads and render
// passes from the frame_data.
SetRenderPasses(&frame_data->render_pass_list);
resources_.swap(used_resources);
have_render_passes_to_push_ = true;
}
}
ResourceProvider::ResourceIdArray unused_resources;
for (ResourceProvider::ResourceIdMap::const_iterator it =
resource_map.begin();
it != resource_map.end();
++it) {
bool resource_is_in_current_frame = resources_.count(it->second) > 0;
bool resource_is_in_use = resource_provider->InUseByConsumer(it->second);
if (!resource_is_in_current_frame && !resource_is_in_use)
unused_resources.push_back(it->second);
}
resource_provider->PrepareSendToChild(
child_id_, unused_resources, resources_for_ack);
}
void DelegatedRendererLayerImpl::SetDisplaySize(gfx::Size size) {
if (display_size_ == size)
return;
display_size_ = size;
NoteLayerPropertyChanged();
}
void DelegatedRendererLayerImpl::SetRenderPasses(
ScopedPtrVector<RenderPass>* render_passes_in_draw_order) {
gfx::RectF old_root_damage;
if (!render_passes_in_draw_order_.empty())
old_root_damage = render_passes_in_draw_order_.back()->damage_rect;
ClearRenderPasses();
for (size_t i = 0; i < render_passes_in_draw_order->size(); ++i) {
ScopedPtrVector<RenderPass>::iterator to_take =
render_passes_in_draw_order->begin() + i;
render_passes_index_by_id_.insert(
std::pair<RenderPass::Id, int>((*to_take)->id, i));
scoped_ptr<RenderPass> taken_render_pass =
render_passes_in_draw_order->take(to_take);
render_passes_in_draw_order_.push_back(taken_render_pass.Pass());
}
if (!render_passes_in_draw_order_.empty())
render_passes_in_draw_order_.back()->damage_rect.Union(old_root_damage);
// Give back an empty array instead of nulls.
render_passes_in_draw_order->clear();
}
void DelegatedRendererLayerImpl::ClearRenderPasses() {
// FIXME: Release the resources back to the nested compositor.
render_passes_index_by_id_.clear();
render_passes_in_draw_order_.clear();
}
scoped_ptr<LayerImpl> DelegatedRendererLayerImpl::CreateLayerImpl(
LayerTreeImpl* tree_impl) {
return DelegatedRendererLayerImpl::Create(
tree_impl, id()).PassAs<LayerImpl>();
}
void DelegatedRendererLayerImpl::DidLoseOutputSurface() {
ClearRenderPasses();
ClearChildId();
}
gfx::Transform DelegatedRendererLayerImpl::DelegatedFrameToLayerSpaceTransform(
gfx::Size frame_size) const {
gfx::Size display_size = display_size_.IsEmpty() ? bounds() : display_size_;
gfx::Transform delegated_frame_to_layer_space_transform;
delegated_frame_to_layer_space_transform.Scale(
static_cast<double>(display_size.width()) / frame_size.width(),
static_cast<double>(display_size.height()) / frame_size.height());
return delegated_frame_to_layer_space_transform;
}
static inline int IndexToId(int index) { return index + 1; }
static inline int IdToIndex(int id) { return id - 1; }
RenderPass::Id DelegatedRendererLayerImpl::FirstContributingRenderPassId()
const {
return RenderPass::Id(id(), IndexToId(0));
}
RenderPass::Id DelegatedRendererLayerImpl::NextContributingRenderPassId(
RenderPass::Id previous) const {
return RenderPass::Id(previous.layer_id, previous.index + 1);
}
RenderPass::Id DelegatedRendererLayerImpl::ConvertDelegatedRenderPassId(
RenderPass::Id delegated_render_pass_id) const {
base::hash_map<RenderPass::Id, int>::const_iterator found =
render_passes_index_by_id_.find(delegated_render_pass_id);
DCHECK(found != render_passes_index_by_id_.end());
unsigned delegated_render_pass_index = found->second;
return RenderPass::Id(id(), IndexToId(delegated_render_pass_index));
}
void DelegatedRendererLayerImpl::AppendContributingRenderPasses(
RenderPassSink* render_pass_sink) {
DCHECK(HasContributingDelegatedRenderPasses());
for (size_t i = 0; i < render_passes_in_draw_order_.size() - 1; ++i) {
RenderPass::Id output_render_pass_id =
ConvertDelegatedRenderPassId(render_passes_in_draw_order_[i]->id);
// Don't clash with the RenderPass we generate if we own a RenderSurface.
DCHECK_GT(output_render_pass_id.index, 0);
render_pass_sink->AppendRenderPass(
render_passes_in_draw_order_[i]->Copy(output_render_pass_id));
}
}
void DelegatedRendererLayerImpl::AppendQuads(
QuadSink* quad_sink,
AppendQuadsData* append_quads_data) {
AppendRainbowDebugBorder(quad_sink, append_quads_data);
if (render_passes_in_draw_order_.empty())
return;
RenderPass::Id target_render_pass_id = append_quads_data->render_pass_id;
const RenderPass* root_delegated_render_pass =
render_passes_in_draw_order_.back();
DCHECK(root_delegated_render_pass->output_rect.origin().IsOrigin());
gfx::Size frame_size = root_delegated_render_pass->output_rect.size();
// If the index of the EenderPassId is 0, then it is a RenderPass generated
// for a layer in this compositor, not the delegated renderer. Then we want to
// merge our root RenderPass with the target RenderPass. Otherwise, it is some
// RenderPass which we added from the delegated renderer.
bool should_merge_root_render_pass_with_target = !target_render_pass_id.index;
if (should_merge_root_render_pass_with_target) {
// Verify that the RenderPass we are appending to is created our
// render_target.
DCHECK(target_render_pass_id.layer_id == render_target()->id());
AppendRenderPassQuads(
quad_sink, append_quads_data, root_delegated_render_pass, frame_size);
} else {
// Verify that the RenderPass we are appending to was created by us.
DCHECK(target_render_pass_id.layer_id == id());
int render_pass_index = IdToIndex(target_render_pass_id.index);
const RenderPass* delegated_render_pass =
render_passes_in_draw_order_[render_pass_index];
AppendRenderPassQuads(
quad_sink, append_quads_data, delegated_render_pass, frame_size);
}
}
void DelegatedRendererLayerImpl::AppendRainbowDebugBorder(
QuadSink* quad_sink,
AppendQuadsData* append_quads_data) {
if (!ShowDebugBorders())
return;
SharedQuadState* shared_quad_state =
quad_sink->UseSharedQuadState(CreateSharedQuadState());
SkColor color;
float border_width;
GetDebugBorderProperties(&color, &border_width);
SkColor colors[] = {
0x80ff0000, // Red.
0x80ffa500, // Orange.
0x80ffff00, // Yellow.
0x80008000, // Green.
0x800000ff, // Blue.
0x80ee82ee, // Violet.
};
const int kNumColors = arraysize(colors);
const int kStripeWidth = 300;
const int kStripeHeight = 300;
for (size_t i = 0; ; ++i) {
// For horizontal lines.
int x = kStripeWidth * i;
int width = std::min(kStripeWidth, content_bounds().width() - x - 1);
// For vertical lines.
int y = kStripeHeight * i;
int height = std::min(kStripeHeight, content_bounds().height() - y - 1);
gfx::Rect top(x, 0, width, border_width);
gfx::Rect bottom(x,
content_bounds().height() - border_width,
width,
border_width);
gfx::Rect left(0, y, border_width, height);
gfx::Rect right(content_bounds().width() - border_width,
y,
border_width,
height);
if (top.IsEmpty() && left.IsEmpty())
break;
if (!top.IsEmpty()) {
scoped_ptr<SolidColorDrawQuad> top_quad = SolidColorDrawQuad::Create();
top_quad->SetNew(shared_quad_state, top, colors[i % kNumColors], false);
quad_sink->Append(top_quad.PassAs<DrawQuad>(), append_quads_data);
scoped_ptr<SolidColorDrawQuad> bottom_quad = SolidColorDrawQuad::Create();
bottom_quad->SetNew(shared_quad_state,
bottom,
colors[kNumColors - 1 - (i % kNumColors)],
false);
quad_sink->Append(bottom_quad.PassAs<DrawQuad>(), append_quads_data);
}
if (!left.IsEmpty()) {
scoped_ptr<SolidColorDrawQuad> left_quad = SolidColorDrawQuad::Create();
left_quad->SetNew(shared_quad_state,
left,
colors[kNumColors - 1 - (i % kNumColors)],
false);
quad_sink->Append(left_quad.PassAs<DrawQuad>(), append_quads_data);
scoped_ptr<SolidColorDrawQuad> right_quad = SolidColorDrawQuad::Create();
right_quad->SetNew(
shared_quad_state, right, colors[i % kNumColors], false);
quad_sink->Append(right_quad.PassAs<DrawQuad>(), append_quads_data);
}
}
}
void DelegatedRendererLayerImpl::AppendRenderPassQuads(
QuadSink* quad_sink,
AppendQuadsData* append_quads_data,
const RenderPass* delegated_render_pass,
gfx::Size frame_size) const {
const SharedQuadState* delegated_shared_quad_state = NULL;
SharedQuadState* output_shared_quad_state = NULL;
for (size_t i = 0; i < delegated_render_pass->quad_list.size(); ++i) {
const DrawQuad* delegated_quad = delegated_render_pass->quad_list[i];
if (delegated_quad->shared_quad_state != delegated_shared_quad_state) {
delegated_shared_quad_state = delegated_quad->shared_quad_state;
output_shared_quad_state = quad_sink->UseSharedQuadState(
delegated_shared_quad_state->Copy());
bool is_root_delegated_render_pass =
delegated_render_pass == render_passes_in_draw_order_.back();
if (is_root_delegated_render_pass) {
// Don't allow areas inside the bounds that are empty.
DCHECK(display_size_.IsEmpty() ||
gfx::Rect(display_size_).Contains(gfx::Rect(bounds())));
gfx::Transform delegated_frame_to_target_transform =
draw_transform() * DelegatedFrameToLayerSpaceTransform(frame_size);
output_shared_quad_state->content_to_target_transform.ConcatTransform(
delegated_frame_to_target_transform);
if (render_target() == this) {
DCHECK(!is_clipped());
DCHECK(render_surface());
output_shared_quad_state->clip_rect = MathUtil::MapClippedRect(
delegated_frame_to_target_transform,
output_shared_quad_state->clip_rect);
} else {
gfx::Rect clip_rect = drawable_content_rect();
if (output_shared_quad_state->is_clipped) {
clip_rect.Intersect(MathUtil::MapClippedRect(
delegated_frame_to_target_transform,
output_shared_quad_state->clip_rect));
}
output_shared_quad_state->clip_rect = clip_rect;
output_shared_quad_state->is_clipped = true;
}
output_shared_quad_state->opacity *= draw_opacity();
}
}
DCHECK(output_shared_quad_state);
scoped_ptr<DrawQuad> output_quad;
if (delegated_quad->material != DrawQuad::RENDER_PASS) {
output_quad = delegated_quad->Copy(output_shared_quad_state);
} else {
RenderPass::Id delegated_contributing_render_pass_id =
RenderPassDrawQuad::MaterialCast(delegated_quad)->render_pass_id;
RenderPass::Id output_contributing_render_pass_id =
ConvertDelegatedRenderPassId(delegated_contributing_render_pass_id);
DCHECK(output_contributing_render_pass_id !=
append_quads_data->render_pass_id);
output_quad = RenderPassDrawQuad::MaterialCast(delegated_quad)->Copy(
output_shared_quad_state,
output_contributing_render_pass_id).PassAs<DrawQuad>();
}
DCHECK(output_quad.get());
quad_sink->Append(output_quad.Pass(), append_quads_data);
}
}
const char* DelegatedRendererLayerImpl::LayerTypeAsString() const {
return "cc::DelegatedRendererLayerImpl";
}
void DelegatedRendererLayerImpl::CreateChildIdIfNeeded() {
if (child_id_)
return;
ResourceProvider* resource_provider = layer_tree_impl()->resource_provider();
child_id_ = resource_provider->CreateChild();
own_child_id_ = true;
}
void DelegatedRendererLayerImpl::ClearChildId() {
if (!child_id_)
return;
if (own_child_id_) {
ResourceProvider* provider = layer_tree_impl()->resource_provider();
provider->DestroyChild(child_id_);
}
child_id_ = 0;
}
} // namespace cc
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