Since we're using JavaScript to control <canvas>
elements, it's also very easy to make (interactive) animations. In this chapter we will take a look at how to do some basic animations.
Probably the biggest limitation is, that once a shape gets drawn, it stays that way. If we need to move it we have to redraw it and everything that was drawn before it. It takes a lot of time to redraw complex frames and the performance depends highly on the speed of the computer it's running on.
These are the steps you need to take to draw a frame:
- Clear the canvas Unless the shapes you'll be drawing fill the complete canvas (for instance a backdrop image), you need to clear any shapes that have been drawn previously. The easiest way to do this is using the
clearRect()
method.
- Save the canvas state If you're changing any setting (such as styles, transformations, etc.) which affect the canvas state and you want to make sure the original state is used each time a frame is drawn, you need to save that original state.
- Draw animated shapes The step where you do the actual frame rendering.
- Restore the canvas state If you've saved the state, restore it before drawing a new frame.
Shapes are drawn to the canvas by using the canvas methods directly or by calling custom functions. In normal circumstances, we only see these results appear on the canvas when the script finishes executing. For instance, it isn't possible to do an animation from within a for
loop.
That means we need a way to execute our drawing functions over a period of time. There are two ways to control an animation like this.
First there's the setInterval()
, setTimeout()
, and window.requestAnimationFrame()
functions, which can be used to call a specific function over a set period of time.
-
setInterval()
-
Starts repeatedly executing the function specified by function
every delay
milliseconds.
-
setTimeout()
-
Executes the function specified by function
in delay
milliseconds.
-
requestAnimationFrame(callback)
-
Tells the browser that you wish to perform an animation and requests that the browser call a specified function to update an animation before the next repaint.
If you don't want any user interaction you can use the setInterval()
function which repeatedly executes the supplied code. If we wanted to make a game, we could use keyboard or mouse events to control the animation and use setTimeout()
. By setting EventListener
s, we catch any user interaction and execute our animation functions.
Note: In the examples below, we'll use the window.requestAnimationFrame()
method to control the animation. The requestAnimationFrame
method provides a smoother and more efficient way for animating by calling the animation frame when the system is ready to paint the frame. The number of callbacks is usually 60 times per second and may be reduced to a lower rate when running in background tabs. For more information about the animation loop, especially for games, see the article Anatomy of a video game in our Game development zone.
This example animates a small model of our solar system.
<canvas id="canvas" width="300" height="300"></canvas>
var sun = new Image();
var moon = new Image();
var earth = new Image();
function init() {
sun.src = 'canvas_sun.png';
moon.src = 'canvas_moon.png';
earth.src = 'canvas_earth.png';
window.requestAnimationFrame(draw);
}
function draw() {
var ctx = document.getElementById('canvas').getContext('2d');
ctx.globalCompositeOperation = 'destination-over';
ctx.clearRect(0, 0, 300, 300);
ctx.fillStyle = 'rgba(0, 0, 0, 0.4)';
ctx.strokeStyle = 'rgba(0, 153, 255, 0.4)';
ctx.save();
ctx.translate(150, 150);
var time = new Date();
ctx.rotate(((2 * Math.PI) / 60) * time.getSeconds() + ((2 * Math.PI) / 60000) * time.getMilliseconds());
ctx.translate(105, 0);
ctx.fillRect(0, -12, 40, 24);
ctx.drawImage(earth, -12, -12);
ctx.save();
ctx.rotate(((2 * Math.PI) / 6) * time.getSeconds() + ((2 * Math.PI) / 6000) * time.getMilliseconds());
ctx.translate(0, 28.5);
ctx.drawImage(moon, -3.5, -3.5);
ctx.restore();
ctx.restore();
ctx.beginPath();
ctx.arc(150, 150, 105, 0, Math.PI * 2, false);
ctx.stroke();
ctx.drawImage(sun, 0, 0, 300, 300);
window.requestAnimationFrame(draw);
}
init();
This example draws an animated clock, showing your current time.
<canvas id="canvas" width="150" height="150"></canvas>
function clock() {
var now = new Date();
var ctx = document.getElementById('canvas').getContext('2d');
ctx.save();
ctx.clearRect(0, 0, 150, 150);
ctx.translate(75, 75);
ctx.scale(0.4, 0.4);
ctx.rotate(-Math.PI / 2);
ctx.strokeStyle = 'black';
ctx.fillStyle = 'white';
ctx.lineWidth = 8;
ctx.lineCap = 'round';
ctx.save();
for (var i = 0; i < 12; i++) {
ctx.beginPath();
ctx.rotate(Math.PI / 6);
ctx.moveTo(100, 0);
ctx.lineTo(120, 0);
ctx.stroke();
}
ctx.restore();
ctx.save();
ctx.lineWidth = 5;
for (i = 0; i < 60; i++) {
if (i % 5!= 0) {
ctx.beginPath();
ctx.moveTo(117, 0);
ctx.lineTo(120, 0);
ctx.stroke();
}
ctx.rotate(Math.PI / 30);
}
ctx.restore();
var sec = now.getSeconds();
var min = now.getMinutes();
var hr = now.getHours();
hr = hr >= 12 ? hr - 12 : hr;
ctx.fillStyle = 'black';
ctx.save();
ctx.rotate(hr * (Math.PI / 6) + (Math.PI / 360) * min + (Math.PI / 21600) *sec);
ctx.lineWidth = 14;
ctx.beginPath();
ctx.moveTo(-20, 0);
ctx.lineTo(80, 0);
ctx.stroke();
ctx.restore();
ctx.save();
ctx.rotate((Math.PI / 30) * min + (Math.PI / 1800) * sec);
ctx.lineWidth = 10;
ctx.beginPath();
ctx.moveTo(-28, 0);
ctx.lineTo(112, 0);
ctx.stroke();
ctx.restore();
ctx.save();
ctx.rotate(sec * Math.PI / 30);
ctx.strokeStyle = '#D40000';
ctx.fillStyle = '#D40000';
ctx.lineWidth = 6;
ctx.beginPath();
ctx.moveTo(-30, 0);
ctx.lineTo(83, 0);
ctx.stroke();
ctx.beginPath();
ctx.arc(0, 0, 10, 0, Math.PI * 2, true);
ctx.fill();
ctx.beginPath();
ctx.arc(95, 0, 10, 0, Math.PI * 2, true);
ctx.stroke();
ctx.fillStyle = 'rgba(0, 0, 0, 0)';
ctx.arc(0, 0, 3, 0, Math.PI * 2, true);
ctx.fill();
ctx.restore();
ctx.beginPath();
ctx.lineWidth = 14;
ctx.strokeStyle = '#325FA2';
ctx.arc(0, 0, 142, 0, Math.PI * 2, true);
ctx.stroke();
ctx.restore();
window.requestAnimationFrame(clock);
}
window.requestAnimationFrame(clock);
In this example, a panorama is scrolled left-to-right. We're using an image of Yosemite National Park we took from Wikipedia, but you could use any image that's larger than the canvas.
The HTML includes the <canvas>
in which the image is scrolled. Note that the width and height specified here must match the values of the CanvasXZSize
and CanvasYSize
variables in the JavaScript code.
<canvas id="canvas" width="800" height="200"></canvas>
var img = new Image();
img.src = 'capitan_meadows_yosemite_national_park.jpg';
var CanvasXSize = 800;
var CanvasYSize = 200;
var speed = 30;
var scale = 1.05;
var y = -4.5;
var dx = 0.75;
var imgW;
var imgH;
var x = 0;
var clearX;
var clearY;
var ctx;
img.onload = function() {
imgW = img.width * scale;
imgH = img.height * scale;
if (imgW > CanvasXSize) {
x = CanvasXSize - imgW;
}
if (imgW > CanvasXSize) {
clearX = imgW;
} else {
clearX = CanvasXSize;
}
if (imgH > CanvasYSize) {
clearY = imgH;
} else {
clearY = CanvasYSize;
}
ctx = document.getElementById('canvas').getContext('2d');
return setInterval(draw, speed);
}
function draw() {
ctx.clearRect(0, 0, clearX, clearY);
if (imgW <= CanvasXSize) {
if (x > CanvasXSize) {
x = -imgW + x;
}
if (x > 0) {
ctx.drawImage(img, -imgW + x, y, imgW, imgH);
}
if (x - imgW > 0) {
ctx.drawImage(img, -imgW * 2 + x, y, imgW, imgH);
}
}
else {
if (x > (CanvasXSize)) {
x = CanvasXSize - imgW;
}
if (x > (CanvasXSize-imgW)) {
ctx.drawImage(img, x - imgW + 1, y, imgW, imgH);
}
}
ctx.drawImage(img, x, y,imgW, imgH);
x += dx;
}
<canvas id="cw"></canvas>
#cw {
position: fixed;
z-index: -1;
}
body {
margin: 0;
padding: 0;
background-color: rgba(0, 0, 0, 0.05);
}
const canvas = document.getElementById("cw");
const context = canvas.getContext("2d");
context.globalAlpha = 0.5;
const cursor = {
x: innerWidth / 2,
y: innerHeight / 2,
};
let particlesArray = [];
generateParticles(101);
setSize();
anim();
addEventListener("mousemove", (e) => {
cursor.x = e.clientX;
cursor.y = e.clientY;
});
addEventListener(
"touchmove",
(e) => {
e.preventDefault();
cursor.x = e.touches[0].clientX;
cursor.y = e.touches[0].clientY;
},
{ passive: false }
);
addEventListener("resize", () => setSize());
function generateParticles(amount) {
for (let i = 0; i < amount; i++) {
particlesArray[i] = new Particle(
innerWidth / 2,
innerHeight / 2,
4,
generateColor(),
0.02
);
}
}
function generateColor() {
let hexSet = "0123456789ABCDEF";
let finalHexString = "#";
for (let i = 0; i < 6; i++) {
finalHexString += hexSet[Math.ceil(Math.random() * 15)];
}
return finalHexString;
}
function setSize() {
canvas.height = innerHeight;
canvas.width = innerWidth;
}
function Particle(x, y, particleTrailWidth, strokeColor, rotateSpeed) {
this.x = x;
this.y = y;
this.particleTrailWidth = particleTrailWidth;
this.strokeColor = strokeColor;
this.theta = Math.random() * Math.PI * 2;
this.rotateSpeed = rotateSpeed;
this.t = Math.random() * 150;
this.rotate = () => {
const ls = {
x: this.x,
y: this.y,
};
this.theta += this.rotateSpeed;
this.x = cursor.x + Math.cos(this.theta) * this.t;
this.y = cursor.y + Math.sin(this.theta) * this.t;
context.beginPath();
context.lineWidth = this.particleTrailWidth;
context.strokeStyle = this.strokeColor;
context.moveTo(ls.x, ls.y);
context.lineTo(this.x, this.y);
context.stroke();
};
}
function anim() {
requestAnimationFrame(anim);
context.fillStyle = "rgba(0,0,0,0.05)";
context.fillRect(0, 0, canvas.width, canvas.height);
particlesArray.forEach((particle) => particle.rotate());
}