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chromium / chromium / src / 02faece41524f0c7e6a982635a8088c4cadf946b / . / ui / compositor / layer_animator.cc
blob: dd727a6c549458e3e9abbc326ec85aa7de2b0d98 [file] [log] [blame]
// Copyright (c) 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 "ui/compositor/layer_animator.h"
#include "base/debug/trace_event.h"
#include "base/logging.h"
#include "base/memory/scoped_ptr.h"
#include "cc/animation/animation_id_provider.h"
#include "cc/output/begin_frame_args.h"
#include "ui/compositor/compositor.h"
#include "ui/compositor/layer.h"
#include "ui/compositor/layer_animation_delegate.h"
#include "ui/compositor/layer_animation_observer.h"
#include "ui/compositor/layer_animation_sequence.h"
#include "ui/gfx/animation/animation_container.h"
#include "ui/gfx/frame_time.h"
#define SAFE_INVOKE_VOID(function, running_anim, ...) \
if (running_anim.is_sequence_alive()) \
function(running_anim.sequence(), ##__VA_ARGS__)
#define SAFE_INVOKE_BOOL(function, running_anim) \
((running_anim.is_sequence_alive()) \
? function(running_anim.sequence()) \
: false)
#define SAFE_INVOKE_PTR(function, running_anim) \
((running_anim.is_sequence_alive()) \
? function(running_anim.sequence()) \
: NULL)
namespace ui {
class LayerAnimator;
namespace {
const int kDefaultTransitionDurationMs = 120;
const int kTimerIntervalMs = 10;
// Returns the AnimationContainer we're added to.
gfx::AnimationContainer* GetAnimationContainer() {
static gfx::AnimationContainer* container = NULL;
if (!container) {
container = new gfx::AnimationContainer();
container->AddRef();
}
return container;
}
} // namespace
// LayerAnimator public --------------------------------------------------------
LayerAnimator::LayerAnimator(base::TimeDelta transition_duration)
: delegate_(NULL),
preemption_strategy_(IMMEDIATELY_SET_NEW_TARGET),
transition_duration_(transition_duration),
tween_type_(gfx::Tween::LINEAR),
is_started_(false),
disable_timer_for_test_(false),
adding_animations_(false) {
}
LayerAnimator::~LayerAnimator() {
for (size_t i = 0; i < running_animations_.size(); ++i) {
if (running_animations_[i].is_sequence_alive())
running_animations_[i].sequence()->OnAnimatorDestroyed();
}
ClearAnimationsInternal();
delegate_ = NULL;
}
// static
LayerAnimator* LayerAnimator::CreateDefaultAnimator() {
return new LayerAnimator(base::TimeDelta::FromMilliseconds(0));
}
// static
LayerAnimator* LayerAnimator::CreateImplicitAnimator() {
return new LayerAnimator(
base::TimeDelta::FromMilliseconds(kDefaultTransitionDurationMs));
}
// This macro provides the implementation for the setter and getter (well,
// the getter of the target value) for an animated property. For example,
// it is used for the implementations of SetTransform and GetTargetTransform.
// It is worth noting that SetFoo avoids invoking the usual animation machinery
// if the transition duration is zero -- in this case we just set the property
// on the layer animation delegate immediately.
#define ANIMATED_PROPERTY(type, property, name, member_type, member) \
void LayerAnimator::Set##name(type value) { \
base::TimeDelta duration = GetTransitionDuration(); \
if (duration == base::TimeDelta() && delegate() && \
(preemption_strategy_ != ENQUEUE_NEW_ANIMATION)) { \
StopAnimatingProperty(LayerAnimationElement::property); \
delegate()->Set##name##FromAnimation(value); \
return; \
} \
scoped_ptr<LayerAnimationElement> element( \
LayerAnimationElement::Create##name##Element(value, duration)); \
element->set_tween_type(tween_type_); \
StartAnimation(new LayerAnimationSequence(element.release())); \
} \
\
member_type LayerAnimator::GetTarget##name() const { \
LayerAnimationElement::TargetValue target(delegate()); \
GetTargetValue(&target); \
return target.member; \
}
ANIMATED_PROPERTY(
const gfx::Transform&, TRANSFORM, Transform, gfx::Transform, transform);
ANIMATED_PROPERTY(const gfx::Rect&, BOUNDS, Bounds, gfx::Rect, bounds);
ANIMATED_PROPERTY(float, OPACITY, Opacity, float, opacity);
ANIMATED_PROPERTY(bool, VISIBILITY, Visibility, bool, visibility);
ANIMATED_PROPERTY(float, BRIGHTNESS, Brightness, float, brightness);
ANIMATED_PROPERTY(float, GRAYSCALE, Grayscale, float, grayscale);
ANIMATED_PROPERTY(SkColor, COLOR, Color, SkColor, color);
void LayerAnimator::SetDelegate(LayerAnimationDelegate* delegate) {
delegate_ = delegate;
}
void LayerAnimator::StartAnimation(LayerAnimationSequence* animation) {
scoped_refptr<LayerAnimator> retain(this);
OnScheduled(animation);
if (!StartSequenceImmediately(animation)) {
// Attempt to preempt a running animation.
switch (preemption_strategy_) {
case IMMEDIATELY_SET_NEW_TARGET:
ImmediatelySetNewTarget(animation);
break;
case IMMEDIATELY_ANIMATE_TO_NEW_TARGET:
ImmediatelyAnimateToNewTarget(animation);
break;
case ENQUEUE_NEW_ANIMATION:
EnqueueNewAnimation(animation);
break;
case REPLACE_QUEUED_ANIMATIONS:
ReplaceQueuedAnimations(animation);
break;
case BLEND_WITH_CURRENT_ANIMATION: {
// TODO(vollick) Add support for blended sequences and use them here.
NOTIMPLEMENTED();
break;
}
}
}
FinishAnyAnimationWithZeroDuration();
UpdateAnimationState();
}
void LayerAnimator::ScheduleAnimation(LayerAnimationSequence* animation) {
scoped_refptr<LayerAnimator> retain(this);
OnScheduled(animation);
if (is_animating()) {
animation_queue_.push_back(make_linked_ptr(animation));
ProcessQueue();
} else {
StartSequenceImmediately(animation);
}
UpdateAnimationState();
}
void LayerAnimator::StartTogether(
const std::vector<LayerAnimationSequence*>& animations) {
scoped_refptr<LayerAnimator> retain(this);
if (preemption_strategy_ == IMMEDIATELY_SET_NEW_TARGET) {
std::vector<LayerAnimationSequence*>::const_iterator iter;
for (iter = animations.begin(); iter != animations.end(); ++iter) {
StartAnimation(*iter);
}
return;
}
adding_animations_ = true;
if (!is_animating()) {
if (GetAnimationContainer()->is_running())
last_step_time_ = GetAnimationContainer()->last_tick_time();
else
last_step_time_ = gfx::FrameTime::Now();
}
// Collect all the affected properties.
LayerAnimationElement::AnimatableProperties animated_properties;
std::vector<LayerAnimationSequence*>::const_iterator iter;
for (iter = animations.begin(); iter != animations.end(); ++iter) {
animated_properties.insert((*iter)->properties().begin(),
(*iter)->properties().end());
}
// Starting a zero duration pause that affects all the animated properties
// will prevent any of the sequences from animating until there are no
// running animations that affect any of these properties, as well as
// handle preemption strategy.
StartAnimation(new LayerAnimationSequence(
LayerAnimationElement::CreatePauseElement(animated_properties,
base::TimeDelta())));
bool wait_for_group_start = false;
for (iter = animations.begin(); iter != animations.end(); ++iter)
wait_for_group_start |= (*iter)->IsFirstElementThreaded();
int group_id = cc::AnimationIdProvider::NextGroupId();
// These animations (provided they don't animate any common properties) will
// now animate together if trivially scheduled.
for (iter = animations.begin(); iter != animations.end(); ++iter) {
(*iter)->set_animation_group_id(group_id);
(*iter)->set_waiting_for_group_start(wait_for_group_start);
ScheduleAnimation(*iter);
}
adding_animations_ = false;
UpdateAnimationState();
}
void LayerAnimator::ScheduleTogether(
const std::vector<LayerAnimationSequence*>& animations) {
scoped_refptr<LayerAnimator> retain(this);
// Collect all the affected properties.
LayerAnimationElement::AnimatableProperties animated_properties;
std::vector<LayerAnimationSequence*>::const_iterator iter;
for (iter = animations.begin(); iter != animations.end(); ++iter) {
animated_properties.insert((*iter)->properties().begin(),
(*iter)->properties().end());
}
// Scheduling a zero duration pause that affects all the animated properties
// will prevent any of the sequences from animating until there are no
// running animations that affect any of these properties.
ScheduleAnimation(new LayerAnimationSequence(
LayerAnimationElement::CreatePauseElement(animated_properties,
base::TimeDelta())));
bool wait_for_group_start = false;
for (iter = animations.begin(); iter != animations.end(); ++iter)
wait_for_group_start |= (*iter)->IsFirstElementThreaded();
int group_id = cc::AnimationIdProvider::NextGroupId();
// These animations (provided they don't animate any common properties) will
// now animate together if trivially scheduled.
for (iter = animations.begin(); iter != animations.end(); ++iter) {
(*iter)->set_animation_group_id(group_id);
(*iter)->set_waiting_for_group_start(wait_for_group_start);
ScheduleAnimation(*iter);
}
UpdateAnimationState();
}
void LayerAnimator::SchedulePauseForProperties(
base::TimeDelta duration,
LayerAnimationElement::AnimatableProperty property,
...) {
ui::LayerAnimationElement::AnimatableProperties properties_to_pause;
va_list marker;
va_start(marker, property);
for (int p = static_cast<int>(property); p != -1; p = va_arg(marker, int)) {
properties_to_pause.insert(
static_cast<LayerAnimationElement::AnimatableProperty>(p));
}
va_end(marker);
ScheduleAnimation(new ui::LayerAnimationSequence(
ui::LayerAnimationElement::CreatePauseElement(
properties_to_pause, duration)));
}
bool LayerAnimator::IsAnimatingProperty(
LayerAnimationElement::AnimatableProperty property) const {
for (AnimationQueue::const_iterator queue_iter = animation_queue_.begin();
queue_iter != animation_queue_.end(); ++queue_iter) {
if ((*queue_iter)->properties().find(property) !=
(*queue_iter)->properties().end()) {
return true;
}
}
return false;
}
void LayerAnimator::StopAnimatingProperty(
LayerAnimationElement::AnimatableProperty property) {
scoped_refptr<LayerAnimator> retain(this);
while (true) {
// GetRunningAnimation purges deleted animations before searching, so we are
// guaranteed to find a live animation if any is returned at all.
RunningAnimation* running = GetRunningAnimation(property);
if (!running)
break;
// As was mentioned above, this sequence must be alive.
DCHECK(running->is_sequence_alive());
FinishAnimation(running->sequence(), false);
}
}
void LayerAnimator::AddObserver(LayerAnimationObserver* observer) {
if (!observers_.HasObserver(observer))
observers_.AddObserver(observer);
}
void LayerAnimator::RemoveObserver(LayerAnimationObserver* observer) {
observers_.RemoveObserver(observer);
// Remove the observer from all sequences as well.
for (AnimationQueue::iterator queue_iter = animation_queue_.begin();
queue_iter != animation_queue_.end(); ++queue_iter) {
(*queue_iter)->RemoveObserver(observer);
}
}
void LayerAnimator::OnThreadedAnimationStarted(
const cc::AnimationEvent& event) {
LayerAnimationElement::AnimatableProperty property =
LayerAnimationElement::ToAnimatableProperty(event.target_property);
RunningAnimation* running = GetRunningAnimation(property);
if (!running)
return;
DCHECK(running->is_sequence_alive());
if (running->sequence()->animation_group_id() != event.group_id)
return;
running->sequence()->OnThreadedAnimationStarted(event);
if (!running->sequence()->waiting_for_group_start())
return;
base::TimeTicks start_time = base::TimeTicks::FromInternalValue(
event.monotonic_time * base::Time::kMicrosecondsPerSecond);
running->sequence()->set_waiting_for_group_start(false);
// The call to GetRunningAnimation made above already purged deleted
// animations, so we are guaranteed that all the animations we iterate
// over now are alive.
for (RunningAnimations::iterator iter = running_animations_.begin();
iter != running_animations_.end(); ++iter) {
// Ensure that each sequence is only Started once, regardless of the
// number of sequences in the group that have threaded first elements.
if (((*iter).sequence()->animation_group_id() == event.group_id) &&
!(*iter).sequence()->IsFirstElementThreaded() &&
(*iter).sequence()->waiting_for_group_start()) {
(*iter).sequence()->set_start_time(start_time);
(*iter).sequence()->set_waiting_for_group_start(false);
(*iter).sequence()->Start(delegate());
}
}
}
// LayerAnimator protected -----------------------------------------------------
void LayerAnimator::ProgressAnimation(LayerAnimationSequence* sequence,
base::TimeTicks now) {
if (!delegate() || sequence->waiting_for_group_start())
return;
sequence->Progress(now, delegate());
}
void LayerAnimator::ProgressAnimationToEnd(LayerAnimationSequence* sequence) {
if (!delegate())
return;
sequence->ProgressToEnd(delegate());
}
bool LayerAnimator::HasAnimation(LayerAnimationSequence* sequence) const {
for (AnimationQueue::const_iterator queue_iter = animation_queue_.begin();
queue_iter != animation_queue_.end(); ++queue_iter) {
if ((*queue_iter).get() == sequence)
return true;
}
return false;
}
// LayerAnimator private -------------------------------------------------------
void LayerAnimator::Step(base::TimeTicks now) {
TRACE_EVENT0("ui", "LayerAnimator::Step");
scoped_refptr<LayerAnimator> retain(this);
last_step_time_ = now;
PurgeDeletedAnimations();
// We need to make a copy of the running animations because progressing them
// and finishing them may indirectly affect the collection of running
// animations.
RunningAnimations running_animations_copy = running_animations_;
for (size_t i = 0; i < running_animations_copy.size(); ++i) {
if (!SAFE_INVOKE_BOOL(HasAnimation, running_animations_copy[i]))
continue;
if (running_animations_copy[i].sequence()->IsFinished(now)) {
SAFE_INVOKE_VOID(FinishAnimation, running_animations_copy[i], false);
} else {
SAFE_INVOKE_VOID(ProgressAnimation, running_animations_copy[i], now);
}
}
}
void LayerAnimator::SetStartTime(base::TimeTicks start_time) {
// Do nothing.
}
base::TimeDelta LayerAnimator::GetTimerInterval() const {
return base::TimeDelta::FromMilliseconds(kTimerIntervalMs);
}
void LayerAnimator::StopAnimatingInternal(bool abort) {
scoped_refptr<LayerAnimator> retain(this);
while (is_animating()) {
// We're going to attempt to finish the first running animation. Let's
// ensure that it's valid.
PurgeDeletedAnimations();
// If we've purged all running animations, attempt to start one up.
if (running_animations_.empty())
ProcessQueue();
DCHECK(!running_animations_.empty());
// Still no luck, let's just bail and clear all animations.
if (running_animations_.empty()) {
ClearAnimationsInternal();
break;
}
SAFE_INVOKE_VOID(FinishAnimation, running_animations_[0], abort);
}
}
void LayerAnimator::UpdateAnimationState() {
if (disable_timer_for_test_)
return;
const bool should_start = is_animating();
if (should_start && !is_started_)
GetAnimationContainer()->Start(this);
else if (!should_start && is_started_)
GetAnimationContainer()->Stop(this);
is_started_ = should_start;
}
LayerAnimationSequence* LayerAnimator::RemoveAnimation(
LayerAnimationSequence* sequence) {
linked_ptr<LayerAnimationSequence> to_return;
bool is_running = false;
// First remove from running animations
for (RunningAnimations::iterator iter = running_animations_.begin();
iter != running_animations_.end(); ++iter) {
if ((*iter).sequence() == sequence) {
running_animations_.erase(iter);
is_running = true;
break;
}
}
// Then remove from the queue
for (AnimationQueue::iterator queue_iter = animation_queue_.begin();
queue_iter != animation_queue_.end(); ++queue_iter) {
if ((*queue_iter) == sequence) {
to_return = *queue_iter;
animation_queue_.erase(queue_iter);
break;
}
}
if (!to_return.get() ||
!to_return->waiting_for_group_start() ||
!to_return->IsFirstElementThreaded())
return to_return.release();
// The removed sequence may have been responsible for making other sequences
// wait for a group start. If no other sequences in the group have a
// threaded first element, the group no longer needs the additional wait.
bool is_wait_still_needed = false;
int group_id = to_return->animation_group_id();
for (AnimationQueue::iterator queue_iter = animation_queue_.begin();
queue_iter != animation_queue_.end(); ++queue_iter) {
if (((*queue_iter)->animation_group_id() == group_id) &&
(*queue_iter)->IsFirstElementThreaded()) {
is_wait_still_needed = true;
break;
}
}
if (is_wait_still_needed)
return to_return.release();
for (AnimationQueue::iterator queue_iter = animation_queue_.begin();
queue_iter != animation_queue_.end(); ++queue_iter) {
if ((*queue_iter)->animation_group_id() == group_id &&
(*queue_iter)->waiting_for_group_start()) {
(*queue_iter)->set_waiting_for_group_start(false);
if (is_running) {
(*queue_iter)->set_start_time(last_step_time_);
(*queue_iter)->Start(delegate());
}
}
}
return to_return.release();
}
void LayerAnimator::FinishAnimation(
LayerAnimationSequence* sequence, bool abort) {
scoped_refptr<LayerAnimator> retain(this);
scoped_ptr<LayerAnimationSequence> removed(RemoveAnimation(sequence));
if (abort)
sequence->Abort(delegate());
else
ProgressAnimationToEnd(sequence);
ProcessQueue();
UpdateAnimationState();
}
void LayerAnimator::FinishAnyAnimationWithZeroDuration() {
scoped_refptr<LayerAnimator> retain(this);
// Special case: if we've started a 0 duration animation, just finish it now
// and get rid of it. We need to make a copy because Progress may indirectly
// cause new animations to start running.
RunningAnimations running_animations_copy = running_animations_;
for (size_t i = 0; i < running_animations_copy.size(); ++i) {
if (!SAFE_INVOKE_BOOL(HasAnimation, running_animations_copy[i]))
continue;
if (running_animations_copy[i].sequence()->IsFinished(
running_animations_copy[i].sequence()->start_time())) {
SAFE_INVOKE_VOID(ProgressAnimationToEnd, running_animations_copy[i]);
scoped_ptr<LayerAnimationSequence> removed(
SAFE_INVOKE_PTR(RemoveAnimation, running_animations_copy[i]));
}
}
ProcessQueue();
UpdateAnimationState();
}
void LayerAnimator::ClearAnimations() {
scoped_refptr<LayerAnimator> retain(this);
ClearAnimationsInternal();
}
LayerAnimator::RunningAnimation* LayerAnimator::GetRunningAnimation(
LayerAnimationElement::AnimatableProperty property) {
PurgeDeletedAnimations();
for (RunningAnimations::iterator iter = running_animations_.begin();
iter != running_animations_.end(); ++iter) {
if ((*iter).sequence()->properties().find(property) !=
(*iter).sequence()->properties().end())
return &(*iter);
}
return NULL;
}
void LayerAnimator::AddToQueueIfNotPresent(LayerAnimationSequence* animation) {
// If we don't have the animation in the queue yet, add it.
bool found_sequence = false;
for (AnimationQueue::iterator queue_iter = animation_queue_.begin();
queue_iter != animation_queue_.end(); ++queue_iter) {
if ((*queue_iter) == animation) {
found_sequence = true;
break;
}
}
if (!found_sequence)
animation_queue_.push_front(make_linked_ptr(animation));
}
void LayerAnimator::RemoveAllAnimationsWithACommonProperty(
LayerAnimationSequence* sequence, bool abort) {
// For all the running animations, if they animate the same property,
// progress them to the end and remove them. Note, Aborting or Progressing
// animations may affect the collection of running animations, so we need to
// operate on a copy.
RunningAnimations running_animations_copy = running_animations_;
for (size_t i = 0; i < running_animations_copy.size(); ++i) {
if (!SAFE_INVOKE_BOOL(HasAnimation, running_animations_copy[i]))
continue;
if (running_animations_copy[i].sequence()->HasConflictingProperty(
sequence->properties())) {
scoped_ptr<LayerAnimationSequence> removed(
SAFE_INVOKE_PTR(RemoveAnimation, running_animations_copy[i]));
if (abort)
running_animations_copy[i].sequence()->Abort(delegate());
else
SAFE_INVOKE_VOID(ProgressAnimationToEnd, running_animations_copy[i]);
}
}
// Same for the queued animations that haven't been started. Again, we'll
// need to operate on a copy.
std::vector<base::WeakPtr<LayerAnimationSequence> > sequences;
for (AnimationQueue::iterator queue_iter = animation_queue_.begin();
queue_iter != animation_queue_.end(); ++queue_iter)
sequences.push_back((*queue_iter)->AsWeakPtr());
for (size_t i = 0; i < sequences.size(); ++i) {
if (!sequences[i].get() || !HasAnimation(sequences[i].get()))
continue;
if (sequences[i]->HasConflictingProperty(sequence->properties())) {
scoped_ptr<LayerAnimationSequence> removed(
RemoveAnimation(sequences[i].get()));
if (abort)
sequences[i]->Abort(delegate());
else
ProgressAnimationToEnd(sequences[i].get());
}
}
}
void LayerAnimator::ImmediatelySetNewTarget(LayerAnimationSequence* sequence) {
// Need to detect if our sequence gets destroyed.
base::WeakPtr<LayerAnimationSequence> weak_sequence_ptr =
sequence->AsWeakPtr();
const bool abort = false;
RemoveAllAnimationsWithACommonProperty(sequence, abort);
if (!weak_sequence_ptr.get())
return;
LayerAnimationSequence* removed = RemoveAnimation(sequence);
DCHECK(removed == NULL || removed == sequence);
if (!weak_sequence_ptr.get())
return;
ProgressAnimationToEnd(sequence);
if (!weak_sequence_ptr.get())
return;
delete sequence;
}
void LayerAnimator::ImmediatelyAnimateToNewTarget(
LayerAnimationSequence* sequence) {
// Need to detect if our sequence gets destroyed.
base::WeakPtr<LayerAnimationSequence> weak_sequence_ptr =
sequence->AsWeakPtr();
const bool abort = true;
RemoveAllAnimationsWithACommonProperty(sequence, abort);
if (!weak_sequence_ptr.get())
return;
AddToQueueIfNotPresent(sequence);
if (!weak_sequence_ptr.get())
return;
StartSequenceImmediately(sequence);
}
void LayerAnimator::EnqueueNewAnimation(LayerAnimationSequence* sequence) {
// It is assumed that if there was no conflicting animation, we would
// not have been called. No need to check for a collision; just
// add to the queue.
animation_queue_.push_back(make_linked_ptr(sequence));
ProcessQueue();
}
void LayerAnimator::ReplaceQueuedAnimations(LayerAnimationSequence* sequence) {
// Need to detect if our sequence gets destroyed.
base::WeakPtr<LayerAnimationSequence> weak_sequence_ptr =
sequence->AsWeakPtr();
// Remove all animations that aren't running. Note: at each iteration i is
// incremented or an element is removed from the queue, so
// animation_queue_.size() - i is always decreasing and we are always making
// progress towards the loop terminating.
for (size_t i = 0; i < animation_queue_.size();) {
if (!weak_sequence_ptr.get())
break;
PurgeDeletedAnimations();
bool is_running = false;
for (RunningAnimations::const_iterator iter = running_animations_.begin();
iter != running_animations_.end(); ++iter) {
if ((*iter).sequence() == animation_queue_[i].get()) {
is_running = true;
break;
}
}
if (!is_running)
delete RemoveAnimation(animation_queue_[i].get());
else
++i;
}
animation_queue_.push_back(make_linked_ptr(sequence));
ProcessQueue();
}
void LayerAnimator::ProcessQueue() {
bool started_sequence = false;
do {
started_sequence = false;
// Build a list of all currently animated properties.
LayerAnimationElement::AnimatableProperties animated;
for (RunningAnimations::const_iterator iter = running_animations_.begin();
iter != running_animations_.end(); ++iter) {
if (!(*iter).is_sequence_alive())
continue;
animated.insert((*iter).sequence()->properties().begin(),
(*iter).sequence()->properties().end());
}
// Try to find an animation that doesn't conflict with an animated
// property or a property that will be animated before it. Note: starting
// the animation may indirectly cause more animations to be started, so we
// need to operate on a copy.
std::vector<base::WeakPtr<LayerAnimationSequence> > sequences;
for (AnimationQueue::iterator queue_iter = animation_queue_.begin();
queue_iter != animation_queue_.end(); ++queue_iter)
sequences.push_back((*queue_iter)->AsWeakPtr());
for (size_t i = 0; i < sequences.size(); ++i) {
if (!sequences[i].get() || !HasAnimation(sequences[i].get()))
continue;
if (!sequences[i]->HasConflictingProperty(animated)) {
StartSequenceImmediately(sequences[i].get());
started_sequence = true;
break;
}
// Animation couldn't be started. Add its properties to the collection so
// that we don't start a conflicting animation. For example, if our queue
// has the elements { {T,B}, {B} } (that is, an element that animates both
// the transform and the bounds followed by an element that animates the
// bounds), and we're currently animating the transform, we can't start
// the first element because it animates the transform, too. We cannot
// start the second element, either, because the first element animates
// bounds too, and needs to go first.
animated.insert(sequences[i]->properties().begin(),
sequences[i]->properties().end());
}
// If we started a sequence, try again. We may be able to start several.
} while (started_sequence);
}
bool LayerAnimator::StartSequenceImmediately(LayerAnimationSequence* sequence) {
PurgeDeletedAnimations();
// Ensure that no one is animating one of the sequence's properties already.
for (RunningAnimations::const_iterator iter = running_animations_.begin();
iter != running_animations_.end(); ++iter) {
if ((*iter).sequence()->HasConflictingProperty(sequence->properties()))
return false;
}
// All clear, actually start the sequence. Note: base::TimeTicks::Now has
// a resolution that can be as bad as 15ms. If this causes glitches in the
// animations, this can be switched to HighResNow() (animation uses Now()
// internally).
// All LayerAnimators share the same AnimationContainer. Use the
// last_tick_time() from there to ensure animations started during the same
// event complete at the same time.
base::TimeTicks start_time;
if (is_animating() || adding_animations_)
start_time = last_step_time_;
else if (GetAnimationContainer()->is_running())
start_time = GetAnimationContainer()->last_tick_time();
else
start_time = gfx::FrameTime::Now();
if (!sequence->animation_group_id())
sequence->set_animation_group_id(cc::AnimationIdProvider::NextGroupId());
if (!sequence->waiting_for_group_start() ||
sequence->IsFirstElementThreaded()) {
sequence->set_start_time(start_time);
sequence->Start(delegate());
}
running_animations_.push_back(
RunningAnimation(sequence->AsWeakPtr()));
// Need to keep a reference to the animation.
AddToQueueIfNotPresent(sequence);
// Ensure that animations get stepped at their start time.
Step(start_time);
return true;
}
void LayerAnimator::GetTargetValue(
LayerAnimationElement::TargetValue* target) const {
for (AnimationQueue::const_iterator iter = animation_queue_.begin();
iter != animation_queue_.end(); ++iter) {
(*iter)->GetTargetValue(target);
}
}
void LayerAnimator::OnScheduled(LayerAnimationSequence* sequence) {
if (observers_.might_have_observers()) {
ObserverListBase<LayerAnimationObserver>::Iterator it(observers_);
LayerAnimationObserver* obs;
while ((obs = it.GetNext()) != NULL) {
sequence->AddObserver(obs);
}
}
sequence->OnScheduled();
}
base::TimeDelta LayerAnimator::GetTransitionDuration() const {
return transition_duration_;
}
void LayerAnimator::ClearAnimationsInternal() {
PurgeDeletedAnimations();
// Abort should never affect the set of running animations, but just in case
// clients are badly behaved, we will use a copy of the running animations.
RunningAnimations running_animations_copy = running_animations_;
for (size_t i = 0; i < running_animations_copy.size(); ++i) {
if (!SAFE_INVOKE_BOOL(HasAnimation, running_animations_copy[i]))
continue;
scoped_ptr<LayerAnimationSequence> removed(
RemoveAnimation(running_animations_copy[i].sequence()));
if (removed.get())
removed->Abort(delegate());
}
// This *should* have cleared the list of running animations.
DCHECK(running_animations_.empty());
running_animations_.clear();
animation_queue_.clear();
UpdateAnimationState();
}
void LayerAnimator::PurgeDeletedAnimations() {
for (size_t i = 0; i < running_animations_.size();) {
if (!running_animations_[i].is_sequence_alive())
running_animations_.erase(running_animations_.begin() + i);
else
i++;
}
}
LayerAnimator::RunningAnimation::RunningAnimation(
const base::WeakPtr<LayerAnimationSequence>& sequence)
: sequence_(sequence) {
}
LayerAnimator::RunningAnimation::~RunningAnimation() { }
} // namespace ui