Confetti (plural) vs confetto (singular)
Confetti is a high-performance, easily-configurable particle system library that can animate any set of objects through space. You can specify your starting conditions and physical conditions (e.g. X and Y acceleration, boundaries, etc.), and let the confetti library take care of the rest.
Add the confetti dependency to your build.gradle
.
compile 'com.github.jinatonic.confetti:confetti:1.0.0'
The only thing you need to get confetti on your screen is a parent view to host the ConfettiView
and thus the confetti animation. From this point on, this parent view is referred to as container
.
You can generate pre-configured confetti from CommonConfetti
. You only need to provide it with
the parent container
, a ConfettiSource
, and an array of possible colors for the confetti.
The default confetti shapes are circle, triangle, and square.
CommonConfetti.rainingConfetti(container, new int[] { Color.BLACK })
.infinite();
First, we need to define what our individual confetto
is through the ConfettoGenerator
. Each call of generateConfetto
must generate a brand new
Confetto
object (the ConfettiManager
will recycle the generated confetto as needed so you
might see fewer and fewer calls to generateConfetto
as the animation goes on). We pass in a
Random
into generateConfetto
in case you want to randomly generate a confetto from a list
of possible confetti.
A simple ConfettoGenerator
might look like this:
final List<Bitmap> allPossibleConfetti = constructBitmapsForConfetti();
// Alternatively, we provide some helper methods inside `Utils` to generate square, circle,
// and triangle bitmaps.
// Utils.generateConfettiBitmaps(new int[] { Color.BLACK }, 20 /* size */);
final int numConfetti = allPossibleConfetti.size();
final ConfettoGenerator confettoGenerator = new ConfettoGenerator() {
@Override
public Confetto generateConfetto(Random random) {
final Bitmap bitmap = allPossibleConfetti.get(random.nextInt(numConfetti));
return new BitmapConfetto(bitmap);
}
}
Once we have our ConfettoGenerator
, we'll need to define a ConfettiSource
from which confetti
will appear out of. This source can be any arbitrary point or line.
final int containerMiddleX = container.getWidth() / 2;
final int containerMiddleY = container.getHeight() / 2;
final ConfettiSource confettiSource = new ConfettiSource(containerMiddleX, containerMiddleY);
Now you are ready! construct your ConfettiManager
, configure the animation to your liking, and
then call animate()
!
new ConfettiManager(context, confettoGenerator, confettiSource, container)
.setEmissionDuration(1000)
.setEmissionRate(100)
.setVelocityX(20, 10)
.setVelocityY(100)
.setRotationalVelocity(180, 180)
.animate();
The animate()
call will create and configure the various Confetto
objects on demand,
create a new ConfettiView
, initialize the proper states for all of the components, attach the
view to the container
and start the animation. The ConfettiView
will auto-detach itself once
all of the confetti have terminated and are off the screen.
For more sample usage of the library, please check out the confetti-sample app that's included in this project.
The ConfettiManager
is easily configurable. For simplicity's sake, all of the velocity and
acceleration attributes are in pixels per second or pixels per second^2, whereas all of the raw
time attributes (such as ttl
and emissionDuration
) are in milliseconds.
You will notice that most of the setters for the physical attributes (e.g. velocity, acceleration, rotation) can take in either one argument for the actual value or two arguments. The second argument allows you to specify a random deviation if you want to randomize the behavior among all of the generated confetto.
For example:
confettiManager.setVelocityX(200f, 50f);
The generated confetto will have an initial X velocity of anywhere between 200 - 50
or 150
and
200 + 50
or 250
, eventually distributed.
enableFadeOut(Interpolator fadeOutInterpolator)
is another interesting method. You can specify
that fade out occurs as a confetto nears its boundary (either reaching the physical boundary
specified in bound
(this is either the entirety of container
or set in setBound
) or reaching
ttl
). The interpolator essentially takes in a value between 0 and 1 (0 means that the confetto
is at its source, 1 means the confetto is at its bound) and outputs an alpha value between 0 and 1
(0 is transparent and 1 is opaque). This way, we allow you to have the full power of specifying
how the fade out occurs.
Or, if you are lazy, you can just use Utils.getDefaultAlphaInterpolator()
.
If you call confettiManager.setTouchEnabled(true)
, you can allow the user to touch and drag
the confetti that are on the screen. When the user let go of the confetti, the confetti will
start at that location with the user initiated velocity and the pre-configured acceleration
and resume animation from there.
It's very easy to define a custom Confetto
(see BitmapConfetto
). You simply need to extend
from the Confetto
class and implement drawInternal
. The function will provide you with a
Canvas
to draw on as well as a work Matrix
and Paint
so you don't have to allocate objects
in the draw path. You then need to essentially draw your confetto however you want onto the canvas
using the specified x
, y
, and rotation
.
The cool part is that you can interpret rotation
however you want. Instead of an angle in degrees,
you can choose to interpret rotation where each degree corresponds to a new shape or new image.
This way, you can achieve some cool animation effects as the confetti flow through the screen.
If you have a handle on the ConfettiManager
, you can actually very easily change the configuration
mid-animation for more unique experiences. For example:
confettiManager.setEmissionRate(100)
.animate();
new Handler().postDelayed(new Runnable() {
@Override public void run() {
confettiManager.setEmissionRate(20);
}
}, 3000);
The above snippet will configure the initial emission rate to be 100 confetti per second and start the animation. After 3 seconds, it will reduce the emission rate to 20 confetti per second. This applies to all attributes (e.g. changing velocity or acceleration based on some outside condition).
- Add more samples and pre-configured confetti into
CommonConfetti
.
Copyright 2016 Robinhood Markets, Inc.
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.
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limitations under the License.