Keyframes is a combination of (1) an ExtendScript script that extracts image animation data from an After Effects file and (2) a corresponding rendering library for Android and iOS. Keyframes can be used to export and render high quality, vector based animations with complex shape and path curves, all with minimal file footprint.
For a detailed list of constraints for developing animations to use with the Keyframes library, please refer to the Keyframes After Effects Guidelines.
Use of the extraction script requires an installation of Adobe After Effects as well as Adobe ExtendScript Toolkit. If Keyframes JSON files are already available, only the corresponding iOS and Android libraries are needed.
For detailed steps on running the ExtendScript script on your AE comp, please refer to the instructions detailed here.
Keyframes is available on CocoaPods. Add the following to your Podfile:
target 'MyApp' do
pod "keyframes"
end
Quit Xcode completely before running
pod install
in the project directory in terminal.
Keyframes is also available through Carthage.
Add the following to your Cartfile to get the latest release branch:
github "facebookincubator/Keyframes"
Or, to get the master branch:
github "facebookincubator/Keyframes" "master"
Run
> carthage update
In Xcode, on your application targets’ "General" settings tab, in the "Linked Frameworks and Libraries" section, drag and drop the framework from the Carthage/Build
folder.
Use the provided deserializers on the generated JSON blob from the Image Data Extraction step to create a KFVector
model object. If your JSON blob lives in the assets directory, this might look like:
NSString *filePath = [[NSBundle bundleForClass:[self class]] pathForResource:@"asset_name" ofType:@"json" inDirectory:nil];
NSData *data = [NSData dataWithContentsOfFile:filePath];
NSDictionary *vectorDictionary = [NSJSONSerialization JSONObjectWithData:data options:kNilOptions error:nil];
KFVector *vector = KFVectorFromDictionary(vectorDictionary);
Then a KFVectorLayer
can be created using this KFVector
, KFVectorLayer
can be used as normal CALayer
.
KFVectorLayer *layer = [KFVectorLayer layer];
// Set a non-zero layer frame before setting the KFVector is required.
layer.frame = $AnyNonZeroCGRect$;
layer.faceModel = vector;
If you don't want the control of animation and prefer a UIView
, KFVectorView
can also be created using KFVector
.
KFVectorView *view = [[KFVectorView alloc] initWithFrame:$AnyNonZeroCGRect$ faceVector:vector];
Use startAnimation
, pauseAnimation
, resumeAnimation
and seekToProgress
on KFVectorLayer
to control the animation.
// Animation will start from beginning.
[layer startAnimation];
// Pause the animation at current progress.
[layer pauseAnimation];
// Resume the animation from where we paused last time.
[layer resumeAnimation];
// Seek to a given progress in range [0, 1]
[layer seekToProgress:0.5]; // seek to the mid point of the animation
Download the latest JARs or grab via Gradle:
compile 'com.facebook.keyframes:keyframes:1.0'
or Maven:
<dependency>
<groupId>com.facebook.keyframes</groupId>
<artifactId>keyframes</artifactId>
<version>1.0</version>
</dependency>
Use the provided deserializers on the generated JSON blob from the Image Data Extraction step to create a KFImage
model object. If your JSON blob lives in the assets directory, this might look like:
InputStream stream = getResources().getAssets().open("asset_name");
KFImage kfImage = KFImageDeserializer.deserialize(stream);
A KeyframesDrawable object can be created now using this KFImage
, and this drawable can be used as a normal drawable. It is highly recommended to use the software layer on any views displaying Keyframes animations.
KeyframesDrawable kfDrawable = new KeyframesDrawableBuilder().withImage(kfImage).build();
ImageView imageView = (ImageView) findViewById(R.id.some_image_view);
imageView.setLayerType(View.LAYER_TYPE_SOFTWARE, null);
imageView.setImageDrawable(kfDrawable);
imageView.setImageAlpha(0);
Use the start and stop animations on the drawable when appropriate to begin playback of the animation or end it after the end of the current loop.
// Starts a loop that progresses animation from the beginning and invalidates the drawable.
kfDrawable.startAnimation();
// Pause the animation at current progress.
kfDrawable.pauseAnimation();
// Resume the animation from where we paused last time.
kfDrawable.resumeAnimation();
// Stops the animation.
kfDrawable.stopAnimation();
// Stops the animation when the current animation ends.
kfDrawable.stopAnimationAtLoopEnd();
// Starts the animation and plays it once. Will stop at the end
kfDrawable.playOnce();
Existing implementations for mobile frameworks:
Framework | Platform | Author | Link |
---|---|---|---|
React Native (imperative api) | Android/IOS | Tomas Roos | https://github.com/ptomasroos/react-native-keyframes/ |
Appcelerator Titanium | iOS | Hans Knoechel | https://github.com/hansemannn/ti.keyframes |
Appcelerator Titanium | Android | Michael Gangolf | https://github.com/m1ga/ti.keyframes |
React Native | Android/iOS | Underscope | https://github.com/underscopeio/react-native-facebook-keyframes |
NativeScript | Android/IOS | Eddy Verbruggen | https://github.com/EddyVerbruggen/nativescript-keyframes |
An Image
in Keyframes consists of a number of important fields, which together, describe an animated and scalable image. At the top level, an image contains information about how to scale (canvas_size
) an image, as well as how to play back an animation at the correct speed (frame_rate
, frame_count
). The animation itself is not bound to the discrete frame_rate
that the image was extracted at, as the Keyframes rendering library supports fractional frames. In addition to these global parameters of an Image
, an Image
also contains a number of Feature
s, which describe different shapes to be drawn, as well as Animation Group
s, which describe transforms that can be applied to multiple Feature
s or even other Animation Group
s at once.
Let's break down this simple image of a star against a circle scaling up and down. The animation was exported at 24FPS, and the frame number is shown in the top left corner as well as the scale of the star on the bottom.
Let's slow that down a bit, frame by frame.
A Feature
is any independent visual object of the image. Most important, it includes shape drawing commands, presented very similary to SVG type commands, which describe the Feature
's shape at any given time. A Feature
may belong to a larger Animation Group
, as well as contain features specific animations of its own, including a specialized STROKE_WIDTH
animation. The shape of a Feature
can also change over time, using the same Keyframe
and Interpolator
pattern described below.
A shape is any list of line drawing commands, which strung together, describe a continuous line or closed shape that can be filled or stroked. The commands are given as a series of Move
, Line
, Quadratic
, and Cubic
commands, one after another.
Here are the important shapes for the above image, along with vertices (squares) and control points (circles), if relevant.
The Keyframes rendering library includes support for the common matrix based transform operations, SCALE
, ROTATE
, and TRANSLATE
. For Feature
s specifically, an additional non-matrix STROKE_WIDTH
is available. Animation
s may belong to specific Feature
s, or as part of a larger Animation Group
.
The values of a transform of an animation and how they change during the playback of an animation are determined by two key fields, Keyframe
s and Timing Curves
. Using the combination of the two fields, we can calculate back a value for a transform at any specified time in the animation.
Keyframes are specific frames in the animation that have specific target values. For example, in scaling a shape up and back down over 10 frames, we will want to start and end at 100% scale at the 0th and 10th frame, and hit our max scale of 150% on the 7th frame. In this example, our key frames for the SCALE
transform for this shape would be [0, 7, 10]
with the values [100%, 150%, 100%
respectively.
Timing Curves describe the pace with which a transform changes between each keyframe. Each timing curve is modeled as a cubic bezier curve from point [0, 0]
to [1, 1]
, where the X value is the progression in time from the origin keyframe to the destination keyframe, and the Y value describes the amount of change in the value at a given time: origValue + (destValue - origValue) * Y
.
For our scaling star image, the graph of scale change over time looks like this, with vertices and timing curve in/out values shown.
With these fields from an Image
object, as well as a progress value, we can build back all of the shapes of the Image
at a given time, as well as any transformations to apply to the shapes, and draw back the Image
at that frame. Because the animations are driven by flexible timing_curves
, a Keyframes Image
is not limited to discrete integer frames for playback, but it is important to note that all progress values are given in relation to the frame count. This means a 10 frame animation accepts all values in the range [0..10]
.
See CONTRIBUTING.md
for how to help us by improving this library!