cc/animation/animation.h - chromium/src - Git at Google

 // 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.

 #ifndef CC_ANIMATION_ANIMATION_H_
 #define CC_ANIMATION_ANIMATION_H_

 #include "base/basictypes.h"
 #include "base/memory/scoped_ptr.h"
 #include "base/time/time.h"
 #include "cc/base/cc_export.h"

 namespace cc {

 class AnimationCurve;

 // An Animation contains all the state required to play an AnimationCurve.
 // Specifically, the affected property, the run state (paused, finished, etc.),
 // loop count, last pause time, and the total time spent paused.
 class CC_EXPORT Animation {
  public:
   // Animations begin in the 'WAITING_FOR_TARGET_AVAILABILITY' state. An
   // Animation waiting for target availibility will run as soon as its target
   // property is free (and all the animations animating with it are also able to
   // run). When this time arrives, the controller will move the animation into
   // the STARTING state, and then into the RUNNING state. RUNNING animations may
   // toggle between RUNNING and PAUSED, and may be stopped by moving into either
   // the ABORTED or FINISHED states. A FINISHED animation was allowed to run to
   // completion, but an ABORTED animation was not.
   enum RunState {
     WAITING_FOR_TARGET_AVAILABILITY = 0,
     WAITING_FOR_DELETION,
     STARTING,
     RUNNING,
     PAUSED,
     FINISHED,
     ABORTED,
     // This sentinel must be last.
     LAST_RUN_STATE = ABORTED
   };

   enum TargetProperty {
     TRANSFORM = 0,
     OPACITY,
     FILTER,
     SCROLL_OFFSET,
     BACKGROUND_COLOR,
     // This sentinel must be last.
     LAST_TARGET_PROPERTY = BACKGROUND_COLOR
   };

   enum Direction {
     DIRECTION_NORMAL,
     DIRECTION_REVERSE,
     DIRECTION_ALTERNATE,
     DIRECTION_ALTERNATE_REVERSE
   };

   enum FillMode {
     FILL_MODE_NONE,
     FILL_MODE_FORWARDS,
     FILL_MODE_BACKWARDS,
     FILL_MODE_BOTH
   };

   static scoped_ptr<Animation> Create(scoped_ptr<AnimationCurve> curve,
                                       int animation_id,
                                       int group_id,
                                       TargetProperty target_property);

   virtual ~Animation();

   int id() const { return id_; }
   int group() const { return group_; }
   TargetProperty target_property() const { return target_property_; }

   RunState run_state() const { return run_state_; }
   void SetRunState(RunState run_state, base::TimeTicks monotonic_time);

   // This is the number of times that the animation will play. If this
   // value is zero the animation will not play. If it is negative, then
   // the animation will loop indefinitely.
   double iterations() const { return iterations_; }
   void set_iterations(double n) { iterations_ = n; }

   double iteration_start() const { return iteration_start_; }
   void set_iteration_start(double iteration_start) {
     iteration_start_ = iteration_start;
   }

   base::TimeTicks start_time() const { return start_time_; }

   void set_start_time(base::TimeTicks monotonic_time) {
     start_time_ = monotonic_time;
   }
   bool has_set_start_time() const { return !start_time_.is_null(); }

   base::TimeDelta time_offset() const { return time_offset_; }
   void set_time_offset(base::TimeDelta monotonic_time) {
     time_offset_ = monotonic_time;
   }

   void Suspend(base::TimeTicks monotonic_time);
   void Resume(base::TimeTicks monotonic_time);

   Direction direction() { return direction_; }
   void set_direction(Direction direction) { direction_ = direction; }

   FillMode fill_mode() { return fill_mode_; }
   void set_fill_mode(FillMode fill_mode) { fill_mode_ = fill_mode; }

   double playback_rate() { return playback_rate_; }
   void set_playback_rate(double playback_rate) {
     playback_rate_ = playback_rate;
   }

   bool IsFinishedAt(base::TimeTicks monotonic_time) const;
   bool is_finished() const {
     return run_state_ == FINISHED || run_state_ == ABORTED ||
            run_state_ == WAITING_FOR_DELETION;
   }

   bool InEffect(base::TimeTicks monotonic_time) const;

   AnimationCurve* curve() { return curve_.get(); }
   const AnimationCurve* curve() const { return curve_.get(); }

   // If this is true, even if the animation is running, it will not be tickable
   // until it is given a start time. This is true for animations running on the
   // main thread.
   bool needs_synchronized_start_time() const {
     return needs_synchronized_start_time_;
   }
   void set_needs_synchronized_start_time(bool needs_synchronized_start_time) {
     needs_synchronized_start_time_ = needs_synchronized_start_time;
   }

   // This is true for animations running on the main thread when the FINISHED
   // event sent by the corresponding impl animation has been received.
   bool received_finished_event() const {
     return received_finished_event_;
   }
   void set_received_finished_event(bool received_finished_event) {
     received_finished_event_ = received_finished_event;
   }

   // Takes the given absolute time, and using the start time and the number
   // of iterations, returns the relative time in the current iteration.
   base::TimeDelta TrimTimeToCurrentIteration(
       base::TimeTicks monotonic_time) const;

   scoped_ptr<Animation> CloneAndInitialize(RunState initial_run_state) const;

   void set_is_controlling_instance_for_test(bool is_controlling_instance) {
     is_controlling_instance_ = is_controlling_instance;
   }
   bool is_controlling_instance() const { return is_controlling_instance_; }

   void PushPropertiesTo(Animation* other) const;

   void set_is_impl_only(bool is_impl_only) { is_impl_only_ = is_impl_only; }
   bool is_impl_only() const { return is_impl_only_; }

   void set_affects_active_observers(bool affects_active_observers) {
     affects_active_observers_ = affects_active_observers;
   }
   bool affects_active_observers() const { return affects_active_observers_; }

   void set_affects_pending_observers(bool affects_pending_observers) {
     affects_pending_observers_ = affects_pending_observers;
   }
   bool affects_pending_observers() const { return affects_pending_observers_; }

  private:
   Animation(scoped_ptr<AnimationCurve> curve,
             int animation_id,
             int group_id,
             TargetProperty target_property);

   base::TimeDelta ConvertToActiveTime(base::TimeTicks monotonic_time) const;

   scoped_ptr<AnimationCurve> curve_;

   // IDs must be unique.
   int id_;

   // Animations that must be run together are called 'grouped' and have the same
   // group id. Grouped animations are guaranteed to start at the same time and
   // no other animations may animate any of the group's target properties until
   // all animations in the group have finished animating.
   int group_;

   TargetProperty target_property_;
   RunState run_state_;
   double iterations_;
   double iteration_start_;
   base::TimeTicks start_time_;
   Direction direction_;
   double playback_rate_;
   FillMode fill_mode_;

   // The time offset effectively pushes the start of the animation back in time.
   // This is used for resuming paused animations -- an animation is added with a
   // non-zero time offset, causing the animation to skip ahead to the desired
   // point in time.
   base::TimeDelta time_offset_;

   bool needs_synchronized_start_time_;
   bool received_finished_event_;

   // When an animation is suspended, it behaves as if it is paused and it also
   // ignores all run state changes until it is resumed. This is used for testing
   // purposes.
   bool suspended_;

   // These are used in TrimTimeToCurrentIteration to account for time
   // spent while paused. This is not included in AnimationState since it
   // there is absolutely no need for clients of this controller to know
   // about these values.
   base::TimeTicks pause_time_;
   base::TimeDelta total_paused_time_;

   // Animations lead dual lives. An active animation will be conceptually owned
   // by two controllers, one on the impl thread and one on the main. In reality,
   // there will be two separate Animation instances for the same animation. They
   // will have the same group id and the same target property (these two values
   // uniquely identify an animation). The instance on the impl thread is the
   // instance that ultimately controls the values of the animating layer and so
   // we will refer to it as the 'controlling instance'.
   bool is_controlling_instance_;

   bool is_impl_only_;

   // When pushed from a main-thread controller to a compositor-thread
   // controller, an animation will initially only affect pending observers
   // (corresponding to layers in the pending tree). Animations that only
   // affect pending observers are able to reach the STARTING state and tick
   // pending observers, but cannot proceed any further and do not tick active
   // observers. After activation, such animations affect both kinds of observers
   // and are able to proceed past the STARTING state. When the removal of
   // an animation is pushed from a main-thread controller to a
   // compositor-thread controller, this initially only makes the animation
   // stop affecting pending observers. After activation, such animations no
   // longer affect any observers, and are deleted.
   bool affects_active_observers_;
   bool affects_pending_observers_;

   DISALLOW_COPY_AND_ASSIGN(Animation);
 };

 }  // namespace cc

 #endif  // CC_ANIMATION_ANIMATION_H_
	// 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.

	#ifndef CC_ANIMATION_ANIMATION_H_
	#define CC_ANIMATION_ANIMATION_H_

	#include "base/basictypes.h"
	#include "base/memory/scoped_ptr.h"
	#include "base/time/time.h"
	#include "cc/base/cc_export.h"

	namespace cc {

	class AnimationCurve;

	// An Animation contains all the state required to play an AnimationCurve.
	// Specifically, the affected property, the run state (paused, finished, etc.),
	// loop count, last pause time, and the total time spent paused.
	class CC_EXPORT Animation {
	public:
	// Animations begin in the 'WAITING_FOR_TARGET_AVAILABILITY' state. An
	// Animation waiting for target availibility will run as soon as its target
	// property is free (and all the animations animating with it are also able to
	// run). When this time arrives, the controller will move the animation into
	// the STARTING state, and then into the RUNNING state. RUNNING animations may
	// toggle between RUNNING and PAUSED, and may be stopped by moving into either
	// the ABORTED or FINISHED states. A FINISHED animation was allowed to run to
	// completion, but an ABORTED animation was not.
	enum RunState {
	WAITING_FOR_TARGET_AVAILABILITY = 0,
	WAITING_FOR_DELETION,
	STARTING,
	RUNNING,
	PAUSED,
	FINISHED,
	ABORTED,
	// This sentinel must be last.
	LAST_RUN_STATE = ABORTED
	};

	enum TargetProperty {
	TRANSFORM = 0,
	OPACITY,
	FILTER,
	SCROLL_OFFSET,
	BACKGROUND_COLOR,
	// This sentinel must be last.
	LAST_TARGET_PROPERTY = BACKGROUND_COLOR
	};

	enum Direction {
	DIRECTION_NORMAL,
	DIRECTION_REVERSE,
	DIRECTION_ALTERNATE,
	DIRECTION_ALTERNATE_REVERSE
	};

	enum FillMode {
	FILL_MODE_NONE,
	FILL_MODE_FORWARDS,
	FILL_MODE_BACKWARDS,
	FILL_MODE_BOTH
	};

	static scoped_ptr<Animation> Create(scoped_ptr<AnimationCurve> curve,
	int animation_id,
	int group_id,
	TargetProperty target_property);

	virtual ~Animation();

	int id() const { return id_; }
	int group() const { return group_; }
	TargetProperty target_property() const { return target_property_; }

	RunState run_state() const { return run_state_; }
	void SetRunState(RunState run_state, base::TimeTicks monotonic_time);

	// This is the number of times that the animation will play. If this
	// value is zero the animation will not play. If it is negative, then
	// the animation will loop indefinitely.
	double iterations() const { return iterations_; }
	void set_iterations(double n) { iterations_ = n; }

	double iteration_start() const { return iteration_start_; }
	void set_iteration_start(double iteration_start) {
	iteration_start_ = iteration_start;
	}

	base::TimeTicks start_time() const { return start_time_; }

	void set_start_time(base::TimeTicks monotonic_time) {
	start_time_ = monotonic_time;
	}
	bool has_set_start_time() const { return !start_time_.is_null(); }

	base::TimeDelta time_offset() const { return time_offset_; }
	void set_time_offset(base::TimeDelta monotonic_time) {
	time_offset_ = monotonic_time;
	}

	void Suspend(base::TimeTicks monotonic_time);
	void Resume(base::TimeTicks monotonic_time);

	Direction direction() { return direction_; }
	void set_direction(Direction direction) { direction_ = direction; }

	FillMode fill_mode() { return fill_mode_; }
	void set_fill_mode(FillMode fill_mode) { fill_mode_ = fill_mode; }

	double playback_rate() { return playback_rate_; }
	void set_playback_rate(double playback_rate) {
	playback_rate_ = playback_rate;
	}

	bool IsFinishedAt(base::TimeTicks monotonic_time) const;
	bool is_finished() const {
	return run_state_ == FINISHED \|\| run_state_ == ABORTED \|\|
	run_state_ == WAITING_FOR_DELETION;
	}

	bool InEffect(base::TimeTicks monotonic_time) const;

	AnimationCurve* curve() { return curve_.get(); }
	const AnimationCurve* curve() const { return curve_.get(); }

	// If this is true, even if the animation is running, it will not be tickable
	// until it is given a start time. This is true for animations running on the
	// main thread.
	bool needs_synchronized_start_time() const {
	return needs_synchronized_start_time_;
	}
	void set_needs_synchronized_start_time(bool needs_synchronized_start_time) {
	needs_synchronized_start_time_ = needs_synchronized_start_time;
	}

	// This is true for animations running on the main thread when the FINISHED
	// event sent by the corresponding impl animation has been received.
	bool received_finished_event() const {
	return received_finished_event_;
	}
	void set_received_finished_event(bool received_finished_event) {
	received_finished_event_ = received_finished_event;
	}

	// Takes the given absolute time, and using the start time and the number
	// of iterations, returns the relative time in the current iteration.
	base::TimeDelta TrimTimeToCurrentIteration(
	base::TimeTicks monotonic_time) const;

	scoped_ptr<Animation> CloneAndInitialize(RunState initial_run_state) const;

	void set_is_controlling_instance_for_test(bool is_controlling_instance) {
	is_controlling_instance_ = is_controlling_instance;
	}
	bool is_controlling_instance() const { return is_controlling_instance_; }

	void PushPropertiesTo(Animation* other) const;

	void set_is_impl_only(bool is_impl_only) { is_impl_only_ = is_impl_only; }
	bool is_impl_only() const { return is_impl_only_; }

	void set_affects_active_observers(bool affects_active_observers) {
	affects_active_observers_ = affects_active_observers;
	}
	bool affects_active_observers() const { return affects_active_observers_; }

	void set_affects_pending_observers(bool affects_pending_observers) {
	affects_pending_observers_ = affects_pending_observers;
	}
	bool affects_pending_observers() const { return affects_pending_observers_; }

	private:
	Animation(scoped_ptr<AnimationCurve> curve,
	int animation_id,
	int group_id,
	TargetProperty target_property);

	base::TimeDelta ConvertToActiveTime(base::TimeTicks monotonic_time) const;

	scoped_ptr<AnimationCurve> curve_;

	// IDs must be unique.
	int id_;

	// Animations that must be run together are called 'grouped' and have the same
	// group id. Grouped animations are guaranteed to start at the same time and
	// no other animations may animate any of the group's target properties until
	// all animations in the group have finished animating.
	int group_;

	TargetProperty target_property_;
	RunState run_state_;
	double iterations_;
	double iteration_start_;
	base::TimeTicks start_time_;
	Direction direction_;
	double playback_rate_;
	FillMode fill_mode_;

	// The time offset effectively pushes the start of the animation back in time.
	// This is used for resuming paused animations -- an animation is added with a
	// non-zero time offset, causing the animation to skip ahead to the desired
	// point in time.
	base::TimeDelta time_offset_;

	bool needs_synchronized_start_time_;
	bool received_finished_event_;

	// When an animation is suspended, it behaves as if it is paused and it also
	// ignores all run state changes until it is resumed. This is used for testing
	// purposes.
	bool suspended_;

	// These are used in TrimTimeToCurrentIteration to account for time
	// spent while paused. This is not included in AnimationState since it
	// there is absolutely no need for clients of this controller to know
	// about these values.
	base::TimeTicks pause_time_;
	base::TimeDelta total_paused_time_;

	// Animations lead dual lives. An active animation will be conceptually owned
	// by two controllers, one on the impl thread and one on the main. In reality,
	// there will be two separate Animation instances for the same animation. They
	// will have the same group id and the same target property (these two values
	// uniquely identify an animation). The instance on the impl thread is the
	// instance that ultimately controls the values of the animating layer and so
	// we will refer to it as the 'controlling instance'.
	bool is_controlling_instance_;

	bool is_impl_only_;

	// When pushed from a main-thread controller to a compositor-thread
	// controller, an animation will initially only affect pending observers
	// (corresponding to layers in the pending tree). Animations that only
	// affect pending observers are able to reach the STARTING state and tick
	// pending observers, but cannot proceed any further and do not tick active
	// observers. After activation, such animations affect both kinds of observers
	// and are able to proceed past the STARTING state. When the removal of
	// an animation is pushed from a main-thread controller to a
	// compositor-thread controller, this initially only makes the animation
	// stop affecting pending observers. After activation, such animations no
	// longer affect any observers, and are deleted.
	bool affects_active_observers_;
	bool affects_pending_observers_;

	DISALLOW_COPY_AND_ASSIGN(Animation);
	};

	} // namespace cc

	#endif // CC_ANIMATION_ANIMATION_H_