This article was written by Alvin Ourrad and Richard Davey. Freshly updated for Phaser 2.0! Welcome to the our first tutorial on Making a Game with Phaser. Here we will learn how to create a small game involving a player running and jumping around platforms collecting stars. While going through this process we'll explain some of the core features of the framework.
var game = new Phaser.Game(800, 600, Phaser.AUTO, '', { preload: preload, create: create, update: update }); function preload() { } function create() { } function update() { }Line 1 is where you bring Phaser to life by creating an instance of a Phaser.Game object and assigning it to a local variable called 'game'. Calling it 'game' is a common practice, but not a requirement, and this is what you will find in the Phaser examples. The first two parameters are the width and the height of the canvas element that Phaser will create. In this case 800 x 600 pixels. Your game world can be any size you like, but this is the resolution the game will display in. The third parameter can be either Phaser.CANVAS, Phaser.WEBGL, or Phaser.AUTO. This is the rendering context that you want to use. The recommended parameter is Phaser.AUTO which automatically tries to use WebGL, but if the browser or device doesn't support it it'll fall back to Canvas. The fourth parameter is an empty string, this is the id of the DOM element in which you would like to insert the canvas element that Phaser creates. As we've left it blank it will simply be appended to the body. The final parameter is an object containing four references to Phasers essential functions. Their use is thoroughly explained here. Note that this object isn't required - Phaser supports a full State system allowing you to break your code into much cleaner single objects. But for a simple Getting Started guide such as this we'll use this approach as it allows for faster prototyping.
function preload() { game.load.image('sky', 'assets/sky.png'); game.load.image('ground', 'assets/platform.png'); game.load.image('star', 'assets/star.png'); game.load.spritesheet('dude', 'assets/dude.png', 32, 48); }This will load in 4 assets: 3 images and a sprite sheet. It may appear obvious to some of you, but I would like to point out the first parameter, also known as the asset key. This string is a link to the loaded asset and is what you'll use in your code when creating sprites. You're free to use any valid JavaScript string as the key.
game.add.sprite(0, 0, 'star');If you bring up the page in a browser you should now see a black game screen with a single star sprite in the top left corner: The order in which items are rendered in the display matches the order in which you create them. So if you wish to place a background behind the star sprite you would need to ensure that it was added as a sprite first, before the star.
var platforms; function create() { // We're going to be using physics, so enable the Arcade Physics system game.physics.startSystem(Phaser.Physics.ARCADE); // A simple background for our game game.add.sprite(0, 0, 'sky'); // The platforms group contains the ground and the 2 ledges we can jump on platforms = game.add.group(); // We will enable physics for any object that is created in this group platforms.enableBody = true; // Here we create the ground. var ground = platforms.create(0, game.world.height - 64, 'ground'); // Scale it to fit the width of the game (the original sprite is 400x32 in size) ground.scale.setTo(2, 2); // This stops it from falling away when you jump on it ground.body.immovable = true; // Now let's create two ledges var ledge = platforms.create(400, 400, 'ground'); ledge.body.immovable = true; ledge = platforms.create(-150, 250, 'ground'); ledge.body.immovable = true; }If you run this, which you'll find as part4.html in the tutorial zip file, you should see a much more game-like scene: The first part is the same as the star sprite we had before, only instead we changed the key to 'sky' and it has displayed our sky background instead. This is an 800x600 PNG that fills the game screen.
platforms = game.add.group();As with sprites game.add creates our Group object. We assign it to a new local variable called platforms. Now created we can add objects to it. First up is the ground. This is positioned at the bottom of the game and uses the 'ground' image loaded earlier. The ground is scaled to fill the width of the game. Finally we set its 'immovable' property to true. Had we not done this the ground would move when the player collides with it (more on this in the Physics section). With the ground in place we create two smaller ledges to jump on to using the exact same technique as for the ground.
// The player and its settings player = game.add.sprite(32, game.world.height - 150, 'dude'); // We need to enable physics on the player game.physics.arcade.enable(player); // Player physics properties. Give the little guy a slight bounce. player.body.bounce.y = 0.2; player.body.gravity.y = 300; player.body.collideWorldBounds = true; // Our two animations, walking left and right. player.animations.add('left', [0, 1, 2, 3], 10, true); player.animations.add('right', [5, 6, 7, 8], 10, true);This creates a new sprite called 'player', positioned at 32 pixels by 150 pixels from the bottom of the game. We're telling it to use the 'dude' asset previously loaded. If you glance back to the preload function you'll see that 'dude' was loaded as a sprite sheet, not an image. That is because it contains animation frames. This is what the full sprite sheet looks like: You can see 9 frames in total, 4 for running left, 1 for facing the camera and 4 for running right. Note: Phaser supports flipping sprites to save on animation frames, but for the sake of this tutorial we'll keep it old school. We define two animations called 'left' and 'right'. The 'left' animation uses frames 0, 1, 2 and 3 and runs at 10 frames per second. The 'true' parameter tells the animation to loop. This is our standard run-cycle and we repeat it for running in the opposite direction. With the animations set we create a few physics properties.
player.body.gravity.y = 300;This is an arbitrary value, but logically, the higher the value, the heavier your object feels and the quicker it falls. If you add this to your code or run part5.html you will see that the player falls down without stopping, completely ignoring the ground we created earlier: The reason for this is that we're not yet testing for collision between the ground and the player. We already told Phaser that our ground and ledges would be immovable. Had we not done that when the player collided with them it would stop for a moment and then everything would have collapsed. This is because unless told otherwise, the ground sprite is a moving physical object (also known as a dynamic body) and when the player hits it, the resulting force of the collision is applied to the ground, therefore, the two bodies exchange their velocities and ground starts falling as well. So to allow the player to collide and take advantage of the physics properties we need to introduce a collision check in the update function:
function update() { // Collide the player and the stars with the platforms game.physics.arcade.collide(player, platforms); }The update function is called by the core game loop every frame. The Physics.collide function is the one that performs the magic. It takes two objects and tests for collision and performs separation against them. In this case we're giving it the player sprite and the platforms Group. It's clever enough to run collision against all Group members, so this one call will collide against the ground and both ledges. The result is a firm platform:
cursors = game.input.keyboard.createCursorKeys();This populates the cursors object with four properties: up, down, left, right, that are all instances of Phaser.Key objects. Then all we need to do is poll these in our update loop:
// Reset the players velocity (movement) player.body.velocity.x = 0; if (cursors.left.isDown) { // Move to the left player.body.velocity.x = -150; player.animations.play('left'); } else if (cursors.right.isDown) { // Move to the right player.body.velocity.x = 150; player.animations.play('right'); } else { // Stand still player.animations.stop(); player.frame = 4; } // Allow the player to jump if they are touching the ground. if (cursors.up.isDown && player.body.touching.down) { player.body.velocity.y = -350; }Although we've added a lot of code it should all be pretty readable. The first thing we do is reset the horizontal velocity on the sprite. Then we check to see if the left cursor key is held down. If it is we apply a negative horizontal velocity and start the 'left' running animation. If they are holding down 'right' instead we literally do the opposite. By clearing the velocity and setting it in this manner, every frame, it creates a 'stop-start' style of movement. The player sprite will move only when a key is held down and stop immediately they are not. Phaser also allows you to create more complex motions, with momentum and acceleration, but this gives us the effect we need for this game. The final part of the key check sets the frame to 4 if no keyis held down. Frame 4 in the sprite sheet is the one of the player looking at you, idle.
// Finally some stars to collect stars = game.add.group(); // We will enable physics for any star that is created in this group stars.enableBody = true; // Here we'll create 12 of them evenly spaced apart for (var i = 0; i < 12; i++) { // Create a star inside of the 'stars' group var star = stars.create(i * 70, 0, 'star'); // Let gravity do its thing star.body.gravity.y = 6; // This just gives each star a slightly random bounce value star.body.bounce.y = 0.7 + Math.random() * 0.2; }The process is similar to when we created the platforms Group. Using a JavaScript 'for' loop we tell it to create 12 stars in our game. They have an x coordinate of i * 70, which means they will be evenly spaced out in the scene 70 pixels apart. As with the player we give them a gravity value so they'll fall down, and a bounce value so they'll bounce a little when they hit the platforms. Bounce is a value between 0 (no bounce at all) and 1 (a full bounce). Ours will bounce somewhere between 0.7 and 0.9. If we were to run the code like this the stars would fall through the bottom of the game. To stop that we need to check for their collision against the platforms in our update loop:
game.physics.arcade.collide(stars, platforms);As well as doing this we will also check to see if the player overlaps with a star or not:
game.physics.arcade.overlap(player, stars, collectStar, null, this);This tells Phaser to check for an overlap between the player and any star in the stars Group. If found then pass them to the 'collectStar' function:
function collectStar (player, star) { // Removes the star from the screen star.kill(); }Quite simply the star is killed, which removes it from display. Running the game now gives us a player that can dash about, jumping, bouncing off the platforms and collecting the stars that fall from above. Not bad for a few lines of hopefully mostly quite readable code :)
var score = 0; var scoreText;The scoreText is set-up in the create function:
scoreText = game.add.text(16, 16, 'Score: 0', { fontSize: '32px', fill: '#000' });16x16 is the coordinate to display the text at. 'Score: 0' is the default string to display and the object that follows contains a font size and fill colour. By not specifying which font we'll actually use the browser will default, so on Windows it will be Arial. Next we need to modify the collectStar function so that when the player picks-up a star their score increases and the text is updated to reflect this:
function collectStar (player, star) { // Removes the star from the screen star.kill(); // Add and update the score score += 10; scoreText.text = 'Score: ' + score; }So 10 points are added for every star and the scoreText is updated to show this new total. If you run part9.html you will see the final game.