Animations overview

The animation system in Flutter is based on typed Animation objects. Widgets can either incorporate these animations in their build functions directly by reading their current value and listening to their state changes or they can use the animations as the basis of more elaborate animations that they pass along to other widgets.

Animation

The primary building block of the animation system is the Animation class. An animation represents a value of a specific type that can change over the lifetime of the animation. Most widgets that perform an animation receive an Animation object as a parameter, from which they read the current value of the animation and to which they listen for changes to that value.

addListener

Whenever the animation’s value changes, the animation notifies all the listeners added with addListener. Typically, a State object that listens to an animation calls setState on itself in its listener callback to notify the widget system that it needs to rebuild with the new value of the animation.

This pattern is so common that there are two widgets that help widgets rebuild when animations change value: AnimatedWidget and AnimatedBuilder. The first, AnimatedWidget, is most useful for stateless animated widgets. To use AnimatedWidget, simply subclass it and implement the build function. The second, AnimatedBuilder, is useful for more complex widgets that wish to include an animation as part of a larger build function. To use AnimatedBuilder, simply construct the widget and pass it a builder function.

addStatusListener

Animations also provide an AnimationStatus, which indicates how the animation will evolve over time. Whenever the animation’s status changes, the animation notifies all the listeners added with addStatusListener. Typically, animations start out in the dismissed status, which means they’re at the beginning of their range. For example, animations that progress from 0.0 to 1.0 will be dismissed when their value is 0.0. An animation might then run forward (from 0.0 to 1.0) or perhaps in reverse (from 1.0 to 0.0). Eventually, if the animation reaches the end of its range (1.0), the animation reaches the completed status.

Animation­Controller

To create an animation, first create an AnimationController. As well as being an animation itself, an AnimationController lets you control the animation. For example, you can tell the controller to play the animation forward or stop the animation. You can also fling animations, which uses a physical simulation, such as a spring, to drive the animation.

Once you’ve created an animation controller, you can start building other animations based on it. For example, you can create a ReverseAnimation that mirrors the original animation but runs in the opposite direction (from 1.0 to 0.0). Similarly, you can create a CurvedAnimation whose value is adjusted by a Curve.

Tweens

To animate beyond the 0.0 to 1.0 interval, you can use a Tween<T>, which interpolates between its begin and end values. Many types have specific Tween subclasses that provide type-specific interpolation. For example, ColorTween interpolates between colors and RectTween interpolates between rects. You can define your own interpolations by creating your own subclass of Tween and overriding its lerp function.

By itself, a tween just defines how to interpolate between two values. To get a concrete value for the current frame of an animation, you also need an animation to determine the current state. There are two ways to combine a tween with an animation to get a concrete value:

1. You can evaluate the tween at the current value of an animation. This approach is most useful for widgets that are already listening to the animation and hence rebuilding whenever the animation changes value.

2. You can animate the tween based on the animation. Rather than returning a single value, the animate function returns a new Animation that incorporates the tween. This approach is most useful when you want to give the newly created animation to another widget, which can then read the current value that incorporates the tween as well as listen for changes to the value.

Architecture

Animations are actually built from a number of core building blocks.

Scheduler

The SchedulerBinding is a singleton class that exposes the Flutter scheduling primitives.

For this discussion, the key primitive is the frame callbacks. Each time a frame needs to be shown on the screen, Flutter’s engine triggers a “begin frame” callback that the scheduler multiplexes to all the listeners registered using scheduleFrameCallback(). All these callbacks are given the official time stamp of the frame, in the form of a Duration from some arbitrary epoch. Since all the callbacks have the same time, any animations triggered from these callbacks will appear to be exactly synchronised even if they take a few milliseconds to be executed.

Tickers

The Ticker class hooks into the scheduler’s scheduleFrameCallback() mechanism to invoke a callback every tick.

A Ticker can be started and stopped. When started, it returns a Future that will resolve when it is stopped.

Each tick, the Ticker provides the callback with the duration since the first tick after it was started.

Because tickers always give their elapsed time relative to the first tick after they were started; tickers are all synchronised. If you start three tickers at different times between two ticks, they will all nonetheless be synchronised with the same starting time, and will subsequently tick in lockstep. Like people at a bus-stop, all the tickers wait for a regularly occurring event (the tick) to begin moving (counting time).

Simulations

The Simulation abstract class maps a relative time value (an elapsed time) to a double value, and has a notion of completion.

In principle simulations are stateless but in practice some simulations (for example, BouncingScrollSimulation and ClampingScrollSimulation) change state irreversibly when queried.

There are various concrete implementations of the Simulation class for different effects.

Animatables

The Animatable abstract class maps a double to a value of a particular type.

Animatable classes are stateless and immutable.

Tweens

The Tween<T> abstract class maps a double value nominally in the range 0.0-1.0 to a typed value (for example, a Color, or another double). It is an Animatable.

It has a notion of an output type (T), a begin value and an end value of that type, and a way to interpolate (lerp) between the begin and end values for a given input value (the double nominally in the range 0.0-1.0).

Tween classes are stateless and immutable.

Composing animatables

Passing an Animatable<double> (the parent) to an Animatable’s chain() method creates a new Animatable subclass that applies the parent’s mapping then the child’s mapping.

Curves

The Curve abstract class maps doubles nominally in the range 0.0-1.0 to doubles nominally in the range 0.0-1.0.

Curve classes are stateless and immutable.

Animations

The Animation abstract class provides a value of a given type, a concept of animation direction and animation status, and a listener interface to register callbacks that get invoked when the value or status change.

Some subclasses of Animation have values that never change (kAlwaysCompleteAnimation, kAlwaysDismissedAnimation, AlwaysStoppedAnimation); registering callbacks on these has no effect as the callbacks are never called.

The Animation<double> variant is special because it can be used to represent a double nominally in the range 0.0-1.0, which is the input expected by Curve and Tween classes, as well as some further subclasses of Animation.

Some Animation subclasses are stateless, merely forwarding listeners to their parents. Some are very stateful.

Composable animations

Most Animation subclasses take an explicit “parent” Animation<double>. They are driven by that parent.

The CurvedAnimation subclass takes an Animation<double> class (the parent) and a couple of Curve classes (the forward and reverse curves) as input, and uses the value of the parent as input to the curves to determine its output. CurvedAnimation is immutable and stateless.

The ReverseAnimation subclass takes an Animation<double> class as its parent and reverses all the values of the animation. It assumes the parent is using a value nominally in the range 0.0-1.0 and returns a value in the range 1.0-0.0. The status and direction of the parent animation are also reversed. ReverseAnimation is immutable and stateless.

The ProxyAnimation subclass takes an Animation<double> class as its parent and merely forwards the current state of that parent. However, the parent is mutable.

The TrainHoppingAnimation subclass takes two parents, and switches between them when their values cross.

Animation controllers

The AnimationController is a stateful Animation<double> that uses a Ticker to give itself life. It can be started and stopped. At each tick, it takes the time elapsed since it was started and passes it to a Simulation to obtain a value. That is then the value it reports. If the Simulation reports that at that time it has ended, then the controller stops itself.

The animation controller can be given a lower and upper bound to animate between, and a duration.

In the simple case (using forward() or reverse()), the animation controller simply does a linear interpolation from the lower bound to the upper bound (or vice versa, for the reverse direction) over the given duration.

When using repeat(), the animation controller uses a linear interpolation between the given bounds over the given duration, but does not stop.

When using animateTo(), the animation controller does a linear interpolation over the given duration from the current value to the given target. If no duration is given to the method, the default duration of the controller and the range described by the controller’s lower bound and upper bound is used to determine the velocity of the animation.

When using fling(), a Force is used to create a specific simulation which is then used to drive the controller.

When using animateWith(), the given simulation is used to drive the controller.

These methods all return the future that the Ticker provides and which will resolve when the controller next stops or changes simulation.

Attaching animatables to animations

Passing an Animation<double> (the new parent) to an Animatable’s animate() method creates a new Animation subclass that acts like the Animatable but is driven from the given parent.