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// Copyright 2015 Google Inc. All Rights Reserved.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
#ifndef COBALT_RENDER_TREE_ANIMATIONS_ANIMATION_LIST_H_
#define COBALT_RENDER_TREE_ANIMATIONS_ANIMATION_LIST_H_
#include <list>
#include "base/bind.h"
#include "base/callback.h"
#include "base/memory/ref_counted.h"
#include "base/time.h"
#include "cobalt/render_tree/movable.h"
namespace cobalt {
namespace render_tree {
namespace animations {
// An animation list is simply that, a list of animations. Its usefulness over
// a raw std::list or std::vector is that it is a ref counted object and also
// guaranteed to be immutable (and thus, must be created by the associated
// builder object). The property of being an immutable reference counted object
// allows this object to safely persist while being shared between multiple
// threads.
template <typename T>
class Animation {
public:
// An Animation<T>::Function represents a single animation that can be applied
// on any render_tree::Node object of the specified template type argument.
//
// As an example, one could create an animation that linearly interpolates
// between two color values on a TextNode object by first definining the
// animation function (assuming ColorRGBA has operator*() defined):
//
// void InterpolateTextColor(
// ColorRGBA final_color, base::TimeDelta duration,
// TextNode::Builder* text_node, base::TimeDelta time_elapsed) {
// if (time_elapsed < duration) {
// double progress = time_elapsed.InSecondsF() / duration.InSecondsF();
// text_node->color =
// text_node->color * (1 - progress) + final_color * progress;
// } else {
// text_node->color = final_color;
// }
// }
//
// You can then use base::Bind to package this function into a base::Callback
// that matches the Animation<T>::Function signature:
//
// AnimationList<TextNode>::Builder animation_list_builder;
// animation_list_builder.push_back(
// base::Bind(&InterpolateTextColor,
// ColorRGBA(0.0f, 1.0f, 0.0f),
// base::TimeDelta::FromSeconds(1)));
//
// You can now create an AnimationList object from the AnimationList::Builder
// and ultimately add that to a AnimateNode::Builder object so that it can be
// mapped to a specific TextNode that it should be applied to.
typedef base::Callback<void(typename T::Builder*, base::TimeDelta)> Function;
typedef base::Callback<void(typename T::Builder*)> TimeIndependentFunction;
// Helper function to convert from time independent function to a time
// dependent function.
static void CallTimeIndependentFunction(
const TimeIndependentFunction& time_independent_function,
typename T::Builder* builder, base::TimeDelta time) {
UNREFERENCED_PARAMETER(time);
time_independent_function.Run(builder);
}
};
// The AnimationListBase is used so that we can acquire a non-template handle
// to an AnimationList, which helps reduce code required in node_animation.h by
// letting us collect animation lists in a single collection, at the cost of
// needing to type cast in a few places.
class AnimationListBase : public base::RefCountedThreadSafe<AnimationListBase> {
public:
virtual base::TimeDelta GetExpiry() const = 0;
virtual base::TimeDelta GetDependsOnTimeExpiry() const = 0;
protected:
virtual ~AnimationListBase() {}
friend class base::RefCountedThreadSafe<AnimationListBase>;
};
// Since animation functions are templated on a specific render tree Node type,
// so must AnimationLists.
template <typename T>
class AnimationList : public AnimationListBase {
public:
// The actual data structure used internally to store the list of animations.
// The decision to use a std::list here instead of say, an std::vector, is
// because it is anticipated that AnimationLists will commonly have only
// 1 element in them, since std::list does not make an attempt to reserve
// capacity in advance, it can save on memory in these instances.
typedef std::list<typename Animation<T>::Function> InternalList;
// An object that provides a means to setting up a list before constructing
// the immutable AnimationList.
struct Builder {
DECLARE_AS_MOVABLE(Builder);
Builder() : expiry(base::TimeDelta::Max()),
depends_on_time_expiry(base::TimeDelta::Max()) {}
explicit Builder(Moved moved) { animations.swap(moved->animations); }
explicit Builder(const typename Animation<T>::Function& single_animation,
base::TimeDelta expiry)
: expiry(expiry), depends_on_time_expiry(expiry) {
animations.push_back(single_animation);
}
explicit Builder(
const typename Animation<T>::TimeIndependentFunction& single_animation,
base::TimeDelta expiry)
: expiry(expiry),
// Since this animation is time independent, we mark its
// time-dependent expiration to be already expired.
depends_on_time_expiry(-base::TimeDelta::Max()) {
// Transform from a time independent function to a time dependent
// function, since we store all functions as time dependent functions.
animations.push_back(base::Bind(Animation<T>::CallTimeIndependentFunction,
single_animation));
}
InternalList animations;
// When do the animations expire? base::TimeDelta::Max() implies that they
// never expire.
base::TimeDelta expiry;
// Similar to |expiry|, but only set for animations that depend on the
// time parameter passed into their animation callback functions.
// Optimizations can be performed for animations that don't depend on this.
base::TimeDelta depends_on_time_expiry;
};
explicit AnimationList(typename Builder::Moved builder) : data_(builder) {}
// Convenience constructor to allow for easy construction of AnimationLists
// containing a single Animation. |expiry| indicates the time at which the
// animation ceases, or base::TimeDelta::Max() if that never occurs.
explicit AnimationList(
const typename Animation<T>::Function& single_animation,
base::TimeDelta expiry)
: data_(single_animation, expiry) {}
explicit AnimationList(
const typename Animation<T>::TimeIndependentFunction& single_animation,
base::TimeDelta expiry)
: data_(single_animation, expiry) {}
const Builder& data() const { return data_; }
base::TimeDelta GetExpiry() const OVERRIDE { return data_.expiry; }
base::TimeDelta GetDependsOnTimeExpiry() const OVERRIDE {
return data_.depends_on_time_expiry;
}
private:
~AnimationList() OVERRIDE {}
const Builder data_;
friend class AnimationListBase;
};
} // namespace animations
} // namespace render_tree
} // namespace cobalt
#endif // COBALT_RENDER_TREE_ANIMATIONS_ANIMATION_LIST_H_