Core Animation in Xamarin.iOS
This article examines the Core Animation framework, showing how it enables high performance, fluid animations in UIKit, as well as how to use it directly for lower-level animation control.
iOS includes Core Animation to provide animation support for views in your application. All of the ultra-smooth animations in iOS such as scrolling of tables and swiping between different views perform as well as they do because they rely on Core Animation internally.
The Core Animation and Core Graphics frameworks can work together to create beautiful, animated 2D graphics. In fact Core Animation can even transform 2D graphics in 3D space, creating amazing, cinematic experiences. However, to create true 3D graphics, you would need to use something like OpenGL ES, or for games turn to an API such as MonoGame, although 3D is beyond the scope of this article.
Core Animation
iOS uses the Core Animation framework to create animation effects such as transitioning between views, sliding menus and scrolling effects to name a few. There are two ways to work with animation:
- Via UIKit, which includes view-based animations as well as animated transitions between controllers.
- Via Core Animation, which layers directly, allowing for finer-grained control.
Using UIKit Animation
UIKit provides several features that make it easy to add animation to an application. Although it uses Core Animation internally, it abstracts it away so you work only with views and controllers.
This section discusses UIKit animation features including:
- Transitions between controllers
- Transitions between views
- View property animation
View Controller Transitions
UIViewController
provides built-in support for transitioning between view controllers through the PresentViewController
method. When using PresentViewController
, the transition to the second controller can optionally be animated.
For example, consider an application with two controllers, where touching a button in the first controller calls PresentViewController
to display a second controller. To control what transition animation is used to show the second controller, simply set its ModalTransitionStyle
property as shown below:
SecondViewController vc2 = new SecondViewController {
ModalTransitionStyle = UIModalTransitionStyle.PartialCurl
};
In this case a PartialCurl
animation is used, although several others are available, including:
CoverVertical
– Slides up from the bottom of the screenCrossDissolve
– The old view fades out & the new view fades inFlipHorizontal
- A horizontal right-to-left flip. On dismissal the transition flips left-to-right.
To animate the transition, pass true
as the second argument to PresentViewController
:
PresentViewController (vc2, true, null);
The following screenshot shows what the transition looks like for the PartialCurl
case:
View Transitions
In addition to transitions between controllers, UIKit also supports animating transitions between views to swap one view for another.
For example, say you had a controller with UIImageView
, where tapping on the image should display a second UIImageView
. To animate the image view’s superview to transition to the second image view is as simple as calling UIView.Transition
, passing it the toView
and fromView
as shown below:
UIView.Transition (
fromView: view1,
toView: view2,
duration: 2,
options: UIViewAnimationOptions.TransitionFlipFromTop |
UIViewAnimationOptions.CurveEaseInOut,
completion: () => { Console.WriteLine ("transition complete"); });
UIView.Transition
also takes a duration
parameter that controls how long the animation runs, as well as options
to specify things such as the animation to use and the easing function. Additionally, you can specify a completion handler that will be called when the animation completes.
The screenshot below show the animated transition between the image views when TransitionFlipFromTop
is used:
View Property Animations
UIKit supports animating a variety of properties on the UIView
class for free, including:
- Frame
- Bounds
- Center
- Alpha
- Transform
- Color
These animations happen implicitly by specifying property changes in an NSAction
delegate passed to the static UIView.Animate
method. For example, the following code animates the center point of a UIImageView
:
pt = imgView.Center;
UIView.Animate (
duration: 2,
delay: 0,
options: UIViewAnimationOptions.CurveEaseInOut |
UIViewAnimationOptions.Autoreverse,
animation: () => {
imgView.Center = new CGPoint (View.Bounds.GetMaxX ()
- imgView.Frame.Width / 2, pt.Y);},
completion: () => {
imgView.Center = pt; }
);
This results in an image animating back and forth across the top of the screen, as shown below:
As with the Transition
method, Animate
allows the duration to be set, along with the easing function. This example also used the UIViewAnimationOptions.Autoreverse
option, which causes the animation to animate from the value back to the initial one. However, the code also sets the Center
back to its initial value in a completion handler. While an animation is interpolating property values over time, the actual model value of the property is always the final value that has been set. In this example, the value is a point near the right side of the superview. Without setting the Center
to the initial point, which is where the animation completes due to the Autoreverse
being set, the image would snap back to the right side after the animation completes, as shown below:
Using Core Animation
UIView
animations allow a lot of capability and should be used if possible due to the ease of implementation. As mentioned earlier, UIView animations use the Core Animation framework. However, some things cannot be done with UIView
animations, such as animating additional properties that cannot be animated with a view, or interpolating along a non-linear path. In such cases where you need finer control, Core Animation can be used directly as well.
Layers
When working with Core Animation, animation happens via layers, which are of type CALayer
. A layer is conceptually similar to a view in that there is a layer hierarchy, much like there is a view hierarchy. Actually, layers back views, with the view adding support for user interaction. You can access the layer of any view via the view’s Layer
property. In fact, the context used in Draw
method of UIView
is actually created from the layer. Internally, the layer backing a UIView
has its delegate set to the view itself, which is what calls Draw
. So when drawing to a UIView
, you are actually drawing to its layer.
Layer animations can be either implicit or explicit. Implicit animations are declarative. You simply declare what layer properties should change and the animation just works. Explicit animations on the other hand are created via an animation class that is added to a layer. Explicit animations allow addition control over how an animation is created. The following sections delve into implicit and explicit animations in greater depth.
Implicit Animations
One way to animate the properties of a layer is via an implicit animation. UIView
animations create implicit animations. However, you can create implicit animations directly against a layer as well.
For example, the following code sets a layer’s Contents
from an image, sets a border width and color, and adds the layer as a sublayer of the view’s layer:
public override void ViewDidLoad ()
{
base.ViewDidLoad ();
layer = new CALayer ();
layer.Bounds = new CGRect (0, 0, 50, 50);
layer.Position = new CGPoint (50, 50);
layer.Contents = UIImage.FromFile ("monkey2.png").CGImage;
layer.ContentsGravity = CALayer.GravityResize;
layer.BorderWidth = 1.5f;
layer.BorderColor = UIColor.Green.CGColor;
View.Layer.AddSublayer (layer);
}
To add an implicit animation for the layer, simply wrap property changes in a CATransaction
. This allows animating properties that would not be animatable with a view animation, such as the BorderWidth
and BorderColor
as shown below:
public override void ViewDidAppear (bool animated)
{
base.ViewDidAppear (animated);
CATransaction.Begin ();
CATransaction.AnimationDuration = 10;
layer.Position = new CGPoint (50, 400);
layer.BorderWidth = 5.0f;
layer.BorderColor = UIColor.Red.CGColor;
CATransaction.Commit ();
}
This code also animates the layer’s Position
, which is the location of the layer’s anchor point measured from the upper left of the superlayer’s coordinates. The anchor point of a layer is a normalized point within the layer’s coordinate system.
The following figure shows the position and anchor point:
When the example is run, the Position
, BorderWidth
and BorderColor
animate as shown in the following screenshots:
Explicit Animations
In addition to implicit animations, Core Animation includes a variety of classes that inherit from CAAnimation
that let you encapsulate animations that are then explicitly added to a layer. These allow finer-grained control over animations, such as modifying the start value of an animation, grouping animations and specifying keyframes to allow non-linear paths.
The following code shows an example of an explicit animation using a CAKeyframeAnimation
for the layer shown earlier (in the Implicit Animation section):
public override void ViewDidAppear (bool animated)
{
base.ViewDidAppear (animated);
// get the initial value to start the animation from
CGPoint fromPt = layer.Position;
/* set the position to coincide with the final animation value
to prevent it from snapping back to the starting position
after the animation completes*/
layer.Position = new CGPoint (200, 300);
// create a path for the animation to follow
CGPath path = new CGPath ();
path.AddLines (new CGPoint[] { fromPt, new CGPoint (50, 300), new CGPoint (200, 50), new CGPoint (200, 300) });
// create a keyframe animation for the position using the path
CAKeyFrameAnimation animPosition = (CAKeyFrameAnimation)CAKeyFrameAnimation.FromKeyPath ("position");
animPosition.Path = path;
animPosition.Duration = 2;
// add the animation to the layer.
/* the "position" key is used to overwrite the implicit animation created
when the layer positino is set above*/
layer.AddAnimation (animPosition, "position");
}
This code changes the Position
of the layer by creating a path that is then used to define a keyframe animation. Notice that the layer’s Position
is set to the final value of the Position
from the animation. Without this, the layer would abruptly return to its Position
before the animation because the animation only changes the presentation value and not the actual model value. By setting the model value to the final value from the animation, the layer stay in place at the end of the animation.
The following screenshots show the layer containing the image animating through the specified path:
Summary
In this article we looked at the animation capabilities provided via the Core Animation frameworks. We examined Core Animation, showing both how it powers animations in UIKit, and how it can be used directly for lower-level animation control.