/// /** * Phaser - Basic * * A useful "generic" object on which all GameObjects and Groups are based. * It has no size, position or graphical data. */ var Phaser; (function (Phaser) { var Basic = (function () { /** * Instantiate the basic object. */ function Basic(game) { /** * Allows you to give this object a name. Useful for debugging, but not actually used internally. */ this.name = ''; this._game = game; this.ID = -1; this.exists = true; this.active = true; this.visible = true; this.alive = true; this.isGroup = false; this.ignoreDrawDebug = false; } Basic.prototype.destroy = /** * Override this to null out iables or manually call * destroy() on class members if necessary. * Don't forget to call super.destroy()! */ function () { }; Basic.prototype.preUpdate = /** * Pre-update is called right before update() on each object in the game loop. */ function () { }; Basic.prototype.update = /** * Override this to update your class's position and appearance. * This is where most of your game rules and behavioral code will go. */ function () { }; Basic.prototype.postUpdate = /** * Post-update is called right after update() on each object in the game loop. */ function () { }; Basic.prototype.render = function (camera, cameraOffsetX, cameraOffsetY) { }; Basic.prototype.kill = /** * Handy for "killing" game objects. * Default behavior is to flag them as nonexistent AND dead. * However, if you want the "corpse" to remain in the game, * like to animate an effect or whatever, you should override this, * setting only alive to false, and leaving exists true. */ function () { this.alive = false; this.exists = false; }; Basic.prototype.revive = /** * Handy for bringing game objects "back to life". Just sets alive and exists back to true. * In practice, this is most often called by Object.reset(). */ function () { this.alive = true; this.exists = true; }; Basic.prototype.toString = /** * Convert object to readable string name. Useful for debugging, save games, etc. */ function () { return ""; }; return Basic; })(); Phaser.Basic = Basic; })(Phaser || (Phaser = {})); /// /** * Phaser - SignalBinding * * An object that represents a binding between a Signal and a listener function. * Based on JS Signals by Miller Medeiros. Converted by TypeScript by Richard Davey. * Released under the MIT license * http://millermedeiros.github.com/js-signals/ */ var Phaser; (function (Phaser) { var SignalBinding = (function () { /** * Object that represents a binding between a Signal and a listener function. *
- This is an internal constructor and shouldn't be called by regular users. *
- inspired by Joa Ebert AS3 SignalBinding and Robert Penner's Slot classes. * @author Miller Medeiros * @constructor * @internal * @name SignalBinding * @param {Signal} signal Reference to Signal object that listener is currently bound to. * @param {Function} listener Handler function bound to the signal. * @param {boolean} isOnce If binding should be executed just once. * @param {Object} [listenerContext] Context on which listener will be executed (object that should represent the `this` variable inside listener function). * @param {Number} [priority] The priority level of the event listener. (default = 0). */ function SignalBinding(signal, listener, isOnce, listenerContext, priority) { if (typeof priority === "undefined") { priority = 0; } /** * If binding is active and should be executed. * @type boolean */ this.active = true; /** * Default parameters passed to listener during `Signal.dispatch` and `SignalBinding.execute`. (curried parameters) * @type Array|null */ this.params = null; this._listener = listener; this._isOnce = isOnce; this.context = listenerContext; this._signal = signal; this.priority = priority || 0; } SignalBinding.prototype.execute = /** * Call listener passing arbitrary parameters. *

If binding was added using `Signal.addOnce()` it will be automatically removed from signal dispatch queue, this method is used internally for the signal dispatch.

* @param {Array} [paramsArr] Array of parameters that should be passed to the listener * @return {*} Value returned by the listener. */ function (paramsArr) { var handlerReturn; var params; if(this.active && !!this._listener) { params = this.params ? this.params.concat(paramsArr) : paramsArr; handlerReturn = this._listener.apply(this.context, params); if(this._isOnce) { this.detach(); } } return handlerReturn; }; SignalBinding.prototype.detach = /** * Detach binding from signal. * - alias to: mySignal.remove(myBinding.getListener()); * @return {Function|null} Handler function bound to the signal or `null` if binding was previously detached. */ function () { return this.isBound() ? this._signal.remove(this._listener, this.context) : null; }; SignalBinding.prototype.isBound = /** * @return {Boolean} `true` if binding is still bound to the signal and have a listener. */ function () { return (!!this._signal && !!this._listener); }; SignalBinding.prototype.isOnce = /** * @return {boolean} If SignalBinding will only be executed once. */ function () { return this._isOnce; }; SignalBinding.prototype.getListener = /** * @return {Function} Handler function bound to the signal. */ function () { return this._listener; }; SignalBinding.prototype.getSignal = /** * @return {Signal} Signal that listener is currently bound to. */ function () { return this._signal; }; SignalBinding.prototype._destroy = /** * Delete instance properties * @private */ function () { delete this._signal; delete this._listener; delete this.context; }; SignalBinding.prototype.toString = /** * @return {string} String representation of the object. */ function () { return '[SignalBinding isOnce:' + this._isOnce + ', isBound:' + this.isBound() + ', active:' + this.active + ']'; }; return SignalBinding; })(); Phaser.SignalBinding = SignalBinding; })(Phaser || (Phaser = {})); /// /** * Phaser - Signal * * A Signal is used for object communication via a custom broadcaster instead of Events. * Based on JS Signals by Miller Medeiros. Converted by TypeScript by Richard Davey. * Released under the MIT license * http://millermedeiros.github.com/js-signals/ */ var Phaser; (function (Phaser) { var Signal = (function () { function Signal() { /** * * @property _bindings * @type Array * @private */ this._bindings = []; /** * * @property _prevParams * @type Any * @private */ this._prevParams = null; /** * If Signal should keep record of previously dispatched parameters and * automatically execute listener during `add()`/`addOnce()` if Signal was * already dispatched before. * @type boolean */ this.memorize = false; /** * @type boolean * @private */ this._shouldPropagate = true; /** * If Signal is active and should broadcast events. *

IMPORTANT: Setting this property during a dispatch will only affect the next dispatch, if you want to stop the propagation of a signal use `halt()` instead.

* @type boolean */ this.active = true; } Signal.VERSION = '1.0.0'; Signal.prototype.validateListener = /** * * @method validateListener * @param {Any} listener * @param {Any} fnName */ function (listener, fnName) { if(typeof listener !== 'function') { throw new Error('listener is a required param of {fn}() and should be a Function.'.replace('{fn}', fnName)); } }; Signal.prototype._registerListener = /** * @param {Function} listener * @param {boolean} isOnce * @param {Object} [listenerContext] * @param {Number} [priority] * @return {SignalBinding} * @private */ function (listener, isOnce, listenerContext, priority) { var prevIndex = this._indexOfListener(listener, listenerContext); var binding; if(prevIndex !== -1) { binding = this._bindings[prevIndex]; if(binding.isOnce() !== isOnce) { throw new Error('You cannot add' + (isOnce ? '' : 'Once') + '() then add' + (!isOnce ? '' : 'Once') + '() the same listener without removing the relationship first.'); } } else { binding = new Phaser.SignalBinding(this, listener, isOnce, listenerContext, priority); this._addBinding(binding); } if(this.memorize && this._prevParams) { binding.execute(this._prevParams); } return binding; }; Signal.prototype._addBinding = /** * * @method _addBinding * @param {SignalBinding} binding * @private */ function (binding) { //simplified insertion sort var n = this._bindings.length; do { --n; }while(this._bindings[n] && binding.priority <= this._bindings[n].priority); this._bindings.splice(n + 1, 0, binding); }; Signal.prototype._indexOfListener = /** * * @method _indexOfListener * @param {Function} listener * @return {number} * @private */ function (listener, context) { var n = this._bindings.length; var cur; while(n--) { cur = this._bindings[n]; if(cur.getListener() === listener && cur.context === context) { return n; } } return -1; }; Signal.prototype.has = /** * Check if listener was attached to Signal. * @param {Function} listener * @param {Object} [context] * @return {boolean} if Signal has the specified listener. */ function (listener, context) { if (typeof context === "undefined") { context = null; } return this._indexOfListener(listener, context) !== -1; }; Signal.prototype.add = /** * Add a listener to the signal. * @param {Function} listener Signal handler function. * @param {Object} [listenerContext] Context on which listener will be executed (object that should represent the `this` variable inside listener function). * @param {Number} [priority] The priority level of the event listener. Listeners with higher priority will be executed before listeners with lower priority. Listeners with same priority level will be executed at the same order as they were added. (default = 0) * @return {SignalBinding} An Object representing the binding between the Signal and listener. */ function (listener, listenerContext, priority) { if (typeof listenerContext === "undefined") { listenerContext = null; } if (typeof priority === "undefined") { priority = 0; } this.validateListener(listener, 'add'); return this._registerListener(listener, false, listenerContext, priority); }; Signal.prototype.addOnce = /** * Add listener to the signal that should be removed after first execution (will be executed only once). * @param {Function} listener Signal handler function. * @param {Object} [listenerContext] Context on which listener will be executed (object that should represent the `this` variable inside listener function). * @param {Number} [priority] The priority level of the event listener. Listeners with higher priority will be executed before listeners with lower priority. Listeners with same priority level will be executed at the same order as they were added. (default = 0) * @return {SignalBinding} An Object representing the binding between the Signal and listener. */ function (listener, listenerContext, priority) { if (typeof listenerContext === "undefined") { listenerContext = null; } if (typeof priority === "undefined") { priority = 0; } this.validateListener(listener, 'addOnce'); return this._registerListener(listener, true, listenerContext, priority); }; Signal.prototype.remove = /** * Remove a single listener from the dispatch queue. * @param {Function} listener Handler function that should be removed. * @param {Object} [context] Execution context (since you can add the same handler multiple times if executing in a different context). * @return {Function} Listener handler function. */ function (listener, context) { if (typeof context === "undefined") { context = null; } this.validateListener(listener, 'remove'); var i = this._indexOfListener(listener, context); if(i !== -1) { this._bindings[i]._destroy()//no reason to a SignalBinding exist if it isn't attached to a signal ; this._bindings.splice(i, 1); } return listener; }; Signal.prototype.removeAll = /** * Remove all listeners from the Signal. */ function () { var n = this._bindings.length; while(n--) { this._bindings[n]._destroy(); } this._bindings.length = 0; }; Signal.prototype.getNumListeners = /** * @return {number} Number of listeners attached to the Signal. */ function () { return this._bindings.length; }; Signal.prototype.halt = /** * Stop propagation of the event, blocking the dispatch to next listeners on the queue. *

IMPORTANT: should be called only during signal dispatch, calling it before/after dispatch won't affect signal broadcast.

* @see Signal.prototype.disable */ function () { this._shouldPropagate = false; }; Signal.prototype.dispatch = /** * Dispatch/Broadcast Signal to all listeners added to the queue. * @param {...*} [params] Parameters that should be passed to each handler. */ function () { var paramsArr = []; for (var _i = 0; _i < (arguments.length - 0); _i++) { paramsArr[_i] = arguments[_i + 0]; } if(!this.active) { return; } var n = this._bindings.length; var bindings; if(this.memorize) { this._prevParams = paramsArr; } if(!n) { //should come after memorize return; } bindings = this._bindings.slice(0)//clone array in case add/remove items during dispatch ; this._shouldPropagate = true//in case `halt` was called before dispatch or during the previous dispatch. ; //execute all callbacks until end of the list or until a callback returns `false` or stops propagation //reverse loop since listeners with higher priority will be added at the end of the list do { n--; }while(bindings[n] && this._shouldPropagate && bindings[n].execute(paramsArr) !== false); }; Signal.prototype.forget = /** * Forget memorized arguments. * @see Signal.memorize */ function () { this._prevParams = null; }; Signal.prototype.dispose = /** * Remove all bindings from signal and destroy any reference to external objects (destroy Signal object). *

IMPORTANT: calling any method on the signal instance after calling dispose will throw errors.

*/ function () { this.removeAll(); delete this._bindings; delete this._prevParams; }; Signal.prototype.toString = /** * @return {string} String representation of the object. */ function () { return '[Signal active:' + this.active + ' numListeners:' + this.getNumListeners() + ']'; }; return Signal; })(); Phaser.Signal = Signal; })(Phaser || (Phaser = {})); var __extends = this.__extends || function (d, b) { function __() { this.constructor = d; } __.prototype = b.prototype; d.prototype = new __(); }; /// /// /// /** * Phaser - GameObject * * This is the base GameObject on which all other game objects are derived. It contains all the logic required for position, * motion, size, collision and input. */ var Phaser; (function (Phaser) { var GameObject = (function (_super) { __extends(GameObject, _super); function GameObject(game, x, y, width, height) { if (typeof x === "undefined") { x = 0; } if (typeof y === "undefined") { y = 0; } if (typeof width === "undefined") { width = 16; } if (typeof height === "undefined") { height = 16; } _super.call(this, game); this._angle = 0; this.outOfBoundsAction = 0; this.z = 0; // This value is added to the angle of the GameObject. // For example if you had a sprite drawn facing straight up then you could set // rotationOffset to 90 and it would correspond correctly with Phasers rotation system this.rotationOffset = 0; this.renderRotation = true; this.moves = true; // Input this.inputEnabled = false; this._inputOver = false; this.bounds = new Phaser.Rectangle(x, y, width, height); this.exists = true; this.active = true; this.visible = true; this.alive = true; this.isGroup = false; this.alpha = 1; this.scale = new Phaser.MicroPoint(1, 1); this.last = new Phaser.MicroPoint(x, y); this.origin = new Phaser.MicroPoint(this.bounds.halfWidth, this.bounds.halfHeight); this.align = GameObject.ALIGN_TOP_LEFT; this.mass = 1; this.elasticity = 0; this.health = 1; this.immovable = false; this.moves = true; this.worldBounds = null; this.touching = Phaser.Collision.NONE; this.wasTouching = Phaser.Collision.NONE; this.allowCollisions = Phaser.Collision.ANY; this.velocity = new Phaser.MicroPoint(); this.acceleration = new Phaser.MicroPoint(); this.drag = new Phaser.MicroPoint(); this.maxVelocity = new Phaser.MicroPoint(10000, 10000); this.angle = 0; this.angularVelocity = 0; this.angularAcceleration = 0; this.angularDrag = 0; this.maxAngular = 10000; this.cameraBlacklist = []; this.scrollFactor = new Phaser.MicroPoint(1, 1); } GameObject.ALIGN_TOP_LEFT = 0; GameObject.ALIGN_TOP_CENTER = 1; GameObject.ALIGN_TOP_RIGHT = 2; GameObject.ALIGN_CENTER_LEFT = 3; GameObject.ALIGN_CENTER = 4; GameObject.ALIGN_CENTER_RIGHT = 5; GameObject.ALIGN_BOTTOM_LEFT = 6; GameObject.ALIGN_BOTTOM_CENTER = 7; GameObject.ALIGN_BOTTOM_RIGHT = 8; GameObject.OUT_OF_BOUNDS_STOP = 0; GameObject.OUT_OF_BOUNDS_KILL = 1; GameObject.prototype.preUpdate = function () { // flicker time this.last.x = this.bounds.x; this.last.y = this.bounds.y; }; GameObject.prototype.update = function () { }; GameObject.prototype.postUpdate = function () { if(this.moves) { this.updateMotion(); } if(this.worldBounds != null) { if(this.outOfBoundsAction == GameObject.OUT_OF_BOUNDS_KILL) { if(this.x < this.worldBounds.x || this.x > this.worldBounds.right || this.y < this.worldBounds.y || this.y > this.worldBounds.bottom) { this.kill(); } } else { if(this.x < this.worldBounds.x) { this.x = this.worldBounds.x; } else if(this.x > this.worldBounds.right) { this.x = this.worldBounds.right; } if(this.y < this.worldBounds.y) { this.y = this.worldBounds.y; } else if(this.y > this.worldBounds.bottom) { this.y = this.worldBounds.bottom; } } } if(this.inputEnabled) { this.updateInput(); } this.wasTouching = this.touching; this.touching = Phaser.Collision.NONE; }; GameObject.prototype.updateInput = function () { }; GameObject.prototype.updateMotion = function () { var delta; var velocityDelta; velocityDelta = (this._game.motion.computeVelocity(this.angularVelocity, this.angularAcceleration, this.angularDrag, this.maxAngular) - this.angularVelocity) / 2; this.angularVelocity += velocityDelta; this._angle += this.angularVelocity * this._game.time.elapsed; this.angularVelocity += velocityDelta; velocityDelta = (this._game.motion.computeVelocity(this.velocity.x, this.acceleration.x, this.drag.x, this.maxVelocity.x) - this.velocity.x) / 2; this.velocity.x += velocityDelta; delta = this.velocity.x * this._game.time.elapsed; this.velocity.x += velocityDelta; this.bounds.x += delta; velocityDelta = (this._game.motion.computeVelocity(this.velocity.y, this.acceleration.y, this.drag.y, this.maxVelocity.y) - this.velocity.y) / 2; this.velocity.y += velocityDelta; delta = this.velocity.y * this._game.time.elapsed; this.velocity.y += velocityDelta; this.bounds.y += delta; }; GameObject.prototype.overlaps = /** * Checks to see if some GameObject overlaps this GameObject or Group. * If the group has a LOT of things in it, it might be faster to use Collision.overlaps(). * WARNING: Currently tilemaps do NOT support screen space overlap checks! * * @param ObjectOrGroup The object or group being tested. * @param InScreenSpace Whether to take scroll factors numbero account when checking for overlap. Default is false, or "only compare in world space." * @param Camera Specify which game camera you want. If null getScreenXY() will just grab the first global camera. * * @return Whether or not the two objects overlap. */ function (ObjectOrGroup, InScreenSpace, Camera) { if (typeof InScreenSpace === "undefined") { InScreenSpace = false; } if (typeof Camera === "undefined") { Camera = null; } if(ObjectOrGroup.isGroup) { var results = false; var i = 0; var members = ObjectOrGroup.members; while(i < length) { if(this.overlaps(members[i++], InScreenSpace, Camera)) { results = true; } } return results; } if(!InScreenSpace) { return (ObjectOrGroup.x + ObjectOrGroup.width > this.x) && (ObjectOrGroup.x < this.x + this.width) && (ObjectOrGroup.y + ObjectOrGroup.height > this.y) && (ObjectOrGroup.y < this.y + this.height); } if(Camera == null) { Camera = this._game.camera; } var objectScreenPos = ObjectOrGroup.getScreenXY(null, Camera); this.getScreenXY(this._point, Camera); return (objectScreenPos.x + ObjectOrGroup.width > this._point.x) && (objectScreenPos.x < this._point.x + this.width) && (objectScreenPos.y + ObjectOrGroup.height > this._point.y) && (objectScreenPos.y < this._point.y + this.height); }; GameObject.prototype.overlapsAt = /** * Checks to see if this GameObject were located at the given position, would it overlap the GameObject or Group? * This is distinct from overlapsPoint(), which just checks that point, rather than taking the object's size numbero account. * WARNING: Currently tilemaps do NOT support screen space overlap checks! * * @param X The X position you want to check. Pretends this object (the caller, not the parameter) is located here. * @param Y The Y position you want to check. Pretends this object (the caller, not the parameter) is located here. * @param ObjectOrGroup The object or group being tested. * @param InScreenSpace Whether to take scroll factors numbero account when checking for overlap. Default is false, or "only compare in world space." * @param Camera Specify which game camera you want. If null getScreenXY() will just grab the first global camera. * * @return Whether or not the two objects overlap. */ function (X, Y, ObjectOrGroup, InScreenSpace, Camera) { if (typeof InScreenSpace === "undefined") { InScreenSpace = false; } if (typeof Camera === "undefined") { Camera = null; } if(ObjectOrGroup.isGroup) { var results = false; var basic; var i = 0; var members = ObjectOrGroup.members; while(i < length) { if(this.overlapsAt(X, Y, members[i++], InScreenSpace, Camera)) { results = true; } } return results; } if(!InScreenSpace) { return (ObjectOrGroup.x + ObjectOrGroup.width > X) && (ObjectOrGroup.x < X + this.width) && (ObjectOrGroup.y + ObjectOrGroup.height > Y) && (ObjectOrGroup.y < Y + this.height); } if(Camera == null) { Camera = this._game.camera; } var objectScreenPos = ObjectOrGroup.getScreenXY(null, Camera); this._point.x = X - Camera.scroll.x * this.scrollFactor.x//copied from getScreenXY() ; this._point.y = Y - Camera.scroll.y * this.scrollFactor.y; this._point.x += (this._point.x > 0) ? 0.0000001 : -0.0000001; this._point.y += (this._point.y > 0) ? 0.0000001 : -0.0000001; return (objectScreenPos.x + ObjectOrGroup.width > this._point.x) && (objectScreenPos.x < this._point.x + this.width) && (objectScreenPos.y + ObjectOrGroup.height > this._point.y) && (objectScreenPos.y < this._point.y + this.height); }; GameObject.prototype.overlapsPoint = /** * Checks to see if a point in 2D world space overlaps this GameObject. * * @param Point The point in world space you want to check. * @param InScreenSpace Whether to take scroll factors numbero account when checking for overlap. * @param Camera Specify which game camera you want. If null getScreenXY() will just grab the first global camera. * * @return Whether or not the point overlaps this object. */ function (point, InScreenSpace, Camera) { if (typeof InScreenSpace === "undefined") { InScreenSpace = false; } if (typeof Camera === "undefined") { Camera = null; } if(!InScreenSpace) { return (point.x > this.x) && (point.x < this.x + this.width) && (point.y > this.y) && (point.y < this.y + this.height); } if(Camera == null) { Camera = this._game.camera; } var X = point.x - Camera.scroll.x; var Y = point.y - Camera.scroll.y; this.getScreenXY(this._point, Camera); return (X > this._point.x) && (X < this._point.x + this.width) && (Y > this._point.y) && (Y < this._point.y + this.height); }; GameObject.prototype.onScreen = /** * Check and see if this object is currently on screen. * * @param Camera Specify which game camera you want. If null getScreenXY() will just grab the first global camera. * * @return Whether the object is on screen or not. */ function (Camera) { if (typeof Camera === "undefined") { Camera = null; } if(Camera == null) { Camera = this._game.camera; } this.getScreenXY(this._point, Camera); return (this._point.x + this.width > 0) && (this._point.x < Camera.width) && (this._point.y + this.height > 0) && (this._point.y < Camera.height); }; GameObject.prototype.getScreenXY = /** * Call this to figure out the on-screen position of the object. * * @param Camera Specify which game camera you want. If null getScreenXY() will just grab the first global camera. * @param Point Takes a MicroPoint object and assigns the post-scrolled X and Y values of this object to it. * * @return The MicroPoint you passed in, or a new Point if you didn't pass one, containing the screen X and Y position of this object. */ function (point, Camera) { if (typeof point === "undefined") { point = null; } if (typeof Camera === "undefined") { Camera = null; } if(point == null) { point = new Phaser.MicroPoint(); } if(Camera == null) { Camera = this._game.camera; } point.x = this.x - Camera.scroll.x * this.scrollFactor.x; point.y = this.y - Camera.scroll.y * this.scrollFactor.y; point.x += (point.x > 0) ? 0.0000001 : -0.0000001; point.y += (point.y > 0) ? 0.0000001 : -0.0000001; return point; }; Object.defineProperty(GameObject.prototype, "solid", { get: /** * Whether the object collides or not. For more control over what directions * the object will collide from, use collision constants (like LEFT, FLOOR, etc) * to set the value of allowCollisions directly. */ function () { return (this.allowCollisions & Phaser.Collision.ANY) > Phaser.Collision.NONE; }, set: /** * @private */ function (Solid) { if(Solid) { this.allowCollisions = Phaser.Collision.ANY; } else { this.allowCollisions = Phaser.Collision.NONE; } }, enumerable: true, configurable: true }); GameObject.prototype.getMidpoint = /** * Retrieve the midpoint of this object in world coordinates. * * @Point Allows you to pass in an existing Point object if you're so inclined. Otherwise a new one is created. * * @return A Point object containing the midpoint of this object in world coordinates. */ function (point) { if (typeof point === "undefined") { point = null; } if(point == null) { point = new Phaser.MicroPoint(); } point.copyFrom(this.bounds.center); return point; }; GameObject.prototype.reset = /** * Handy for reviving game objects. * Resets their existence flags and position. * * @param X The new X position of this object. * @param Y The new Y position of this object. */ function (X, Y) { this.revive(); this.touching = Phaser.Collision.NONE; this.wasTouching = Phaser.Collision.NONE; this.x = X; this.y = Y; this.last.x = X; this.last.y = Y; this.velocity.x = 0; this.velocity.y = 0; }; GameObject.prototype.isTouching = /** * Handy for checking if this object is touching a particular surface. * For slightly better performance you can just & the value directly numbero touching. * However, this method is good for readability and accessibility. * * @param Direction Any of the collision flags (e.g. LEFT, FLOOR, etc). * * @return Whether the object is touching an object in (any of) the specified direction(s) this frame. */ function (Direction) { return (this.touching & Direction) > Phaser.Collision.NONE; }; GameObject.prototype.justTouched = /** * Handy for checking if this object is just landed on a particular surface. * * @param Direction Any of the collision flags (e.g. LEFT, FLOOR, etc). * * @return Whether the object just landed on (any of) the specified surface(s) this frame. */ function (Direction) { return ((this.touching & Direction) > Phaser.Collision.NONE) && ((this.wasTouching & Direction) <= Phaser.Collision.NONE); }; GameObject.prototype.hurt = /** * Reduces the "health" variable of this sprite by the amount specified in Damage. * Calls kill() if health drops to or below zero. * * @param Damage How much health to take away (use a negative number to give a health bonus). */ function (Damage) { this.health = this.health - Damage; if(this.health <= 0) { this.kill(); } }; GameObject.prototype.setBounds = /** * Set the world bounds that this GameObject can exist within. By default a GameObject can exist anywhere * in the world. But by setting the bounds (which are given in world dimensions, not screen dimensions) * it can be stopped from leaving the world, or a section of it. */ function (x, y, width, height) { this.worldBounds = new Phaser.Quad(x, y, width, height); }; GameObject.prototype.hideFromCamera = /** * If you do not wish this object to be visible to a specific camera, pass the camera here. */ function (camera) { if(this.cameraBlacklist.indexOf(camera.ID) == -1) { this.cameraBlacklist.push(camera.ID); } }; GameObject.prototype.showToCamera = function (camera) { if(this.cameraBlacklist.indexOf(camera.ID) !== -1) { this.cameraBlacklist.slice(this.cameraBlacklist.indexOf(camera.ID), 1); } }; GameObject.prototype.clearCameraList = function () { this.cameraBlacklist.length = 0; }; GameObject.prototype.destroy = function () { }; Object.defineProperty(GameObject.prototype, "x", { get: function () { return this.bounds.x; }, set: function (value) { this.bounds.x = value; }, enumerable: true, configurable: true }); Object.defineProperty(GameObject.prototype, "y", { get: function () { return this.bounds.y; }, set: function (value) { this.bounds.y = value; }, enumerable: true, configurable: true }); Object.defineProperty(GameObject.prototype, "rotation", { get: function () { return this._angle; }, set: function (value) { this._angle = this._game.math.wrap(value, 360, 0); }, enumerable: true, configurable: true }); Object.defineProperty(GameObject.prototype, "angle", { get: function () { return this._angle; }, set: function (value) { this._angle = this._game.math.wrap(value, 360, 0); }, enumerable: true, configurable: true }); Object.defineProperty(GameObject.prototype, "width", { get: function () { return this.bounds.width; }, set: function (value) { this.bounds.width = value; }, enumerable: true, configurable: true }); Object.defineProperty(GameObject.prototype, "height", { get: function () { return this.bounds.height; }, set: function (value) { this.bounds.height = value; }, enumerable: true, configurable: true }); return GameObject; })(Phaser.Basic); Phaser.GameObject = GameObject; })(Phaser || (Phaser = {})); /// /// /** * Phaser - Camera * * A Camera is your view into the game world. It has a position, size, scale and rotation and renders only those objects * within its field of view. The game automatically creates a single Stage sized camera on boot, but it can be changed and * additional cameras created via the CameraManager. */ var Phaser; (function (Phaser) { var Camera = (function () { /** * Instantiates a new camera at the specified location, with the specified size and zoom level. * * @param X X location of the camera's display in pixels. Uses native, 1:1 resolution, ignores zoom. * @param Y Y location of the camera's display in pixels. Uses native, 1:1 resolution, ignores zoom. * @param Width The width of the camera display in pixels. * @param Height The height of the camera display in pixels. * @param Zoom The initial zoom level of the camera. A zoom level of 2 will make all pixels display at 2x resolution. */ function Camera(game, id, x, y, width, height) { this._clip = false; this._rotation = 0; this._target = null; this._sx = 0; this._sy = 0; this._fxFlashComplete = null; this._fxFlashDuration = 0; this._fxFlashAlpha = 0; this._fxFadeComplete = null; this._fxFadeDuration = 0; this._fxFadeAlpha = 0; this._fxShakeIntensity = 0; this._fxShakeDuration = 0; this._fxShakeComplete = null; this._fxShakeOffset = new Phaser.MicroPoint(0, 0); this._fxShakeDirection = 0; this._fxShakePrevX = 0; this._fxShakePrevY = 0; this.scale = new Phaser.MicroPoint(1, 1); this.scroll = new Phaser.MicroPoint(0, 0); this.bounds = null; this.deadzone = null; // Camera Border this.showBorder = false; this.borderColor = 'rgb(255,255,255)'; // Camera Background Color this.opaque = true; this._bgColor = 'rgb(0,0,0)'; this._bgTextureRepeat = 'repeat'; // Camera Shadow this.showShadow = false; this.shadowColor = 'rgb(0,0,0)'; this.shadowBlur = 10; this.shadowOffset = new Phaser.MicroPoint(4, 4); this.visible = true; this.alpha = 1; // The x/y position of the current input event in world coordinates this.inputX = 0; this.inputY = 0; this._game = game; this.ID = id; this._stageX = x; this._stageY = y; // The view into the world canvas we wish to render this.worldView = new Phaser.Rectangle(0, 0, width, height); this.checkClip(); } Camera.STYLE_LOCKON = 0; Camera.STYLE_PLATFORMER = 1; Camera.STYLE_TOPDOWN = 2; Camera.STYLE_TOPDOWN_TIGHT = 3; Camera.SHAKE_BOTH_AXES = 0; Camera.SHAKE_HORIZONTAL_ONLY = 1; Camera.SHAKE_VERTICAL_ONLY = 2; Camera.prototype.flash = /** * The camera is filled with this color and returns to normal at the given duration. * * @param Color The color you want to use in 0xRRGGBB format, i.e. 0xffffff for white. * @param Duration How long it takes for the flash to fade. * @param OnComplete An optional function you want to run when the flash finishes. Set to null for no callback. * @param Force Force an already running flash effect to reset. */ function (color, duration, onComplete, force) { if (typeof color === "undefined") { color = 0xffffff; } if (typeof duration === "undefined") { duration = 1; } if (typeof onComplete === "undefined") { onComplete = null; } if (typeof force === "undefined") { force = false; } if(force === false && this._fxFlashAlpha > 0) { // You can't flash again unless you force it return; } if(duration <= 0) { duration = 1; } var red = color >> 16 & 0xFF; var green = color >> 8 & 0xFF; var blue = color & 0xFF; this._fxFlashColor = 'rgba(' + red + ',' + green + ',' + blue + ','; this._fxFlashDuration = duration; this._fxFlashAlpha = 1; this._fxFlashComplete = onComplete; }; Camera.prototype.fade = /** * The camera is gradually filled with this color. * * @param Color The color you want to use in 0xRRGGBB format, i.e. 0xffffff for white. * @param Duration How long it takes for the flash to fade. * @param OnComplete An optional function you want to run when the flash finishes. Set to null for no callback. * @param Force Force an already running flash effect to reset. */ function (color, duration, onComplete, force) { if (typeof color === "undefined") { color = 0x000000; } if (typeof duration === "undefined") { duration = 1; } if (typeof onComplete === "undefined") { onComplete = null; } if (typeof force === "undefined") { force = false; } if(force === false && this._fxFadeAlpha > 0) { // You can't fade again unless you force it return; } if(duration <= 0) { duration = 1; } var red = color >> 16 & 0xFF; var green = color >> 8 & 0xFF; var blue = color & 0xFF; this._fxFadeColor = 'rgba(' + red + ',' + green + ',' + blue + ','; this._fxFadeDuration = duration; this._fxFadeAlpha = 0.01; this._fxFadeComplete = onComplete; }; Camera.prototype.shake = /** * A simple screen-shake effect. * * @param Intensity Percentage of screen size representing the maximum distance that the screen can move while shaking. * @param Duration The length in seconds that the shaking effect should last. * @param OnComplete A function you want to run when the shake effect finishes. * @param Force Force the effect to reset (default = true, unlike flash() and fade()!). * @param Direction Whether to shake on both axes, just up and down, or just side to side (use class constants SHAKE_BOTH_AXES, SHAKE_VERTICAL_ONLY, or SHAKE_HORIZONTAL_ONLY). */ function (intensity, duration, onComplete, force, direction) { if (typeof intensity === "undefined") { intensity = 0.05; } if (typeof duration === "undefined") { duration = 0.5; } if (typeof onComplete === "undefined") { onComplete = null; } if (typeof force === "undefined") { force = true; } if (typeof direction === "undefined") { direction = Camera.SHAKE_BOTH_AXES; } if(!force && ((this._fxShakeOffset.x != 0) || (this._fxShakeOffset.y != 0))) { return; } // If a shake is not already running we need to store the offsets here if(this._fxShakeOffset.x == 0 && this._fxShakeOffset.y == 0) { this._fxShakePrevX = this._stageX; this._fxShakePrevY = this._stageY; } this._fxShakeIntensity = intensity; this._fxShakeDuration = duration; this._fxShakeComplete = onComplete; this._fxShakeDirection = direction; this._fxShakeOffset.setTo(0, 0); }; Camera.prototype.stopFX = /** * Just turns off all the camera effects instantly. */ function () { this._fxFlashAlpha = 0; this._fxFadeAlpha = 0; if(this._fxShakeDuration !== 0) { this._fxShakeDuration = 0; this._fxShakeOffset.setTo(0, 0); this._stageX = this._fxShakePrevX; this._stageY = this._fxShakePrevY; } }; Camera.prototype.follow = function (target, style) { if (typeof style === "undefined") { style = Camera.STYLE_LOCKON; } this._target = target; var helper; switch(style) { case Camera.STYLE_PLATFORMER: var w = this.width / 8; var h = this.height / 3; this.deadzone = new Phaser.Rectangle((this.width - w) / 2, (this.height - h) / 2 - h * 0.25, w, h); break; case Camera.STYLE_TOPDOWN: helper = Math.max(this.width, this.height) / 4; this.deadzone = new Phaser.Rectangle((this.width - helper) / 2, (this.height - helper) / 2, helper, helper); break; case Camera.STYLE_TOPDOWN_TIGHT: helper = Math.max(this.width, this.height) / 8; this.deadzone = new Phaser.Rectangle((this.width - helper) / 2, (this.height - helper) / 2, helper, helper); break; case Camera.STYLE_LOCKON: default: this.deadzone = null; break; } }; Camera.prototype.focusOnXY = function (x, y) { x += (x > 0) ? 0.0000001 : -0.0000001; y += (y > 0) ? 0.0000001 : -0.0000001; this.scroll.x = Math.round(x - this.worldView.halfWidth); this.scroll.y = Math.round(y - this.worldView.halfHeight); }; Camera.prototype.focusOn = function (point) { point.x += (point.x > 0) ? 0.0000001 : -0.0000001; point.y += (point.y > 0) ? 0.0000001 : -0.0000001; this.scroll.x = Math.round(point.x - this.worldView.halfWidth); this.scroll.y = Math.round(point.y - this.worldView.halfHeight); }; Camera.prototype.setBounds = /** * Specify the boundaries of the world or where the camera is allowed to move. * * @param x The smallest X value of your world (usually 0). * @param y The smallest Y value of your world (usually 0). * @param width The largest X value of your world (usually the world width). * @param height The largest Y value of your world (usually the world height). */ function (x, y, width, height) { if (typeof x === "undefined") { x = 0; } if (typeof y === "undefined") { y = 0; } if (typeof width === "undefined") { width = 0; } if (typeof height === "undefined") { height = 0; } if(this.bounds == null) { this.bounds = new Phaser.Rectangle(); } this.bounds.setTo(x, y, width, height); this.scroll.setTo(0, 0); this.update(); }; Camera.prototype.update = function () { if(this._target !== null) { if(this.deadzone == null) { this.focusOnXY(this._target.x + this._target.origin.x, this._target.y + this._target.origin.y); } else { var edge; var targetX = this._target.x + ((this._target.x > 0) ? 0.0000001 : -0.0000001); var targetY = this._target.y + ((this._target.y > 0) ? 0.0000001 : -0.0000001); edge = targetX - this.deadzone.x; if(this.scroll.x > edge) { this.scroll.x = edge; } edge = targetX + this._target.width - this.deadzone.x - this.deadzone.width; if(this.scroll.x < edge) { this.scroll.x = edge; } edge = targetY - this.deadzone.y; if(this.scroll.y > edge) { this.scroll.y = edge; } edge = targetY + this._target.height - this.deadzone.y - this.deadzone.height; if(this.scroll.y < edge) { this.scroll.y = edge; } } } // Make sure we didn't go outside the cameras bounds if(this.bounds !== null) { if(this.scroll.x < this.bounds.left) { this.scroll.x = this.bounds.left; } if(this.scroll.x > this.bounds.right - this.width) { this.scroll.x = (this.bounds.right - this.width) + 1; } if(this.scroll.y < this.bounds.top) { this.scroll.y = this.bounds.top; } if(this.scroll.y > this.bounds.bottom - this.height) { this.scroll.y = (this.bounds.bottom - this.height) + 1; } } this.worldView.x = this.scroll.x; this.worldView.y = this.scroll.y; //console.log(this.worldView.width, this.worldView.height); // Input values this.inputX = this.worldView.x + this._game.input.x; this.inputY = this.worldView.y + this._game.input.y; // Update the Flash effect if(this._fxFlashAlpha > 0) { this._fxFlashAlpha -= this._game.time.elapsed / this._fxFlashDuration; this._fxFlashAlpha = this._game.math.roundTo(this._fxFlashAlpha, -2); if(this._fxFlashAlpha <= 0) { this._fxFlashAlpha = 0; if(this._fxFlashComplete !== null) { this._fxFlashComplete(); } } } // Update the Fade effect if(this._fxFadeAlpha > 0) { this._fxFadeAlpha += this._game.time.elapsed / this._fxFadeDuration; this._fxFadeAlpha = this._game.math.roundTo(this._fxFadeAlpha, -2); if(this._fxFadeAlpha >= 1) { this._fxFadeAlpha = 1; if(this._fxFadeComplete !== null) { this._fxFadeComplete(); } } } // Update the "shake" special effect if(this._fxShakeDuration > 0) { this._fxShakeDuration -= this._game.time.elapsed; this._fxShakeDuration = this._game.math.roundTo(this._fxShakeDuration, -2); if(this._fxShakeDuration <= 0) { this._fxShakeDuration = 0; this._fxShakeOffset.setTo(0, 0); this._stageX = this._fxShakePrevX; this._stageY = this._fxShakePrevY; if(this._fxShakeComplete != null) { this._fxShakeComplete(); } } else { if((this._fxShakeDirection == Camera.SHAKE_BOTH_AXES) || (this._fxShakeDirection == Camera.SHAKE_HORIZONTAL_ONLY)) { //this._fxShakeOffset.x = ((this._game.math.random() * this._fxShakeIntensity * this.worldView.width * 2 - this._fxShakeIntensity * this.worldView.width) * this._zoom; this._fxShakeOffset.x = (this._game.math.random() * this._fxShakeIntensity * this.worldView.width * 2 - this._fxShakeIntensity * this.worldView.width); } if((this._fxShakeDirection == Camera.SHAKE_BOTH_AXES) || (this._fxShakeDirection == Camera.SHAKE_VERTICAL_ONLY)) { //this._fxShakeOffset.y = (this._game.math.random() * this._fxShakeIntensity * this.worldView.height * 2 - this._fxShakeIntensity * this.worldView.height) * this._zoom; this._fxShakeOffset.y = (this._game.math.random() * this._fxShakeIntensity * this.worldView.height * 2 - this._fxShakeIntensity * this.worldView.height); } } } }; Camera.prototype.render = function () { if(this.visible === false || this.alpha < 0.1) { return; } if((this._fxShakeOffset.x != 0) || (this._fxShakeOffset.y != 0)) { //this._stageX = this._fxShakePrevX + (this.worldView.halfWidth * this._zoom) + this._fxShakeOffset.x; //this._stageY = this._fxShakePrevY + (this.worldView.halfHeight * this._zoom) + this._fxShakeOffset.y; this._stageX = this._fxShakePrevX + (this.worldView.halfWidth) + this._fxShakeOffset.x; this._stageY = this._fxShakePrevY + (this.worldView.halfHeight) + this._fxShakeOffset.y; //console.log('shake', this._fxShakeDuration, this._fxShakeIntensity, this._fxShakeOffset.x, this._fxShakeOffset.y); } //if (this._rotation !== 0 || this._clip || this.scale.x !== 1 || this.scale.y !== 1) //{ //this._game.stage.context.save(); //} // It may be safe/quicker to just save the context every frame regardless this._game.stage.context.save(); if(this.alpha !== 1) { this._game.stage.context.globalAlpha = this.alpha; } this._sx = this._stageX; this._sy = this._stageY; // Shadow if(this.showShadow) { this._game.stage.context.shadowColor = this.shadowColor; this._game.stage.context.shadowBlur = this.shadowBlur; this._game.stage.context.shadowOffsetX = this.shadowOffset.x; this._game.stage.context.shadowOffsetY = this.shadowOffset.y; } // Scale on if(this.scale.x !== 1 || this.scale.y !== 1) { this._game.stage.context.scale(this.scale.x, this.scale.y); this._sx = this._sx / this.scale.x; this._sy = this._sy / this.scale.y; } // Rotation - translate to the mid-point of the camera if(this._rotation !== 0) { this._game.stage.context.translate(this._sx + this.worldView.halfWidth, this._sy + this.worldView.halfHeight); this._game.stage.context.rotate(this._rotation * (Math.PI / 180)); // now shift back to where that should actually render this._game.stage.context.translate(-(this._sx + this.worldView.halfWidth), -(this._sy + this.worldView.halfHeight)); } // Background if(this.opaque == true) { if(this._bgTexture) { this._game.stage.context.fillStyle = this._bgTexture; this._game.stage.context.fillRect(this._sx, this._sy, this.worldView.width, this.worldView.height); } else { this._game.stage.context.fillStyle = this._bgColor; this._game.stage.context.fillRect(this._sx, this._sy, this.worldView.width, this.worldView.height); } } // Shadow off if(this.showShadow) { this._game.stage.context.shadowBlur = 0; this._game.stage.context.shadowOffsetX = 0; this._game.stage.context.shadowOffsetY = 0; } // Clip the camera so we don't get sprites appearing outside the edges if(this._clip) { this._game.stage.context.beginPath(); this._game.stage.context.rect(this._sx, this._sy, this.worldView.width, this.worldView.height); this._game.stage.context.closePath(); this._game.stage.context.clip(); } this._game.world.group.render(this, this._sx, this._sy); if(this.showBorder) { this._game.stage.context.strokeStyle = this.borderColor; this._game.stage.context.lineWidth = 1; this._game.stage.context.rect(this._sx, this._sy, this.worldView.width, this.worldView.height); this._game.stage.context.stroke(); } // "Flash" FX if(this._fxFlashAlpha > 0) { this._game.stage.context.fillStyle = this._fxFlashColor + this._fxFlashAlpha + ')'; this._game.stage.context.fillRect(this._sx, this._sy, this.worldView.width, this.worldView.height); } // "Fade" FX if(this._fxFadeAlpha > 0) { this._game.stage.context.fillStyle = this._fxFadeColor + this._fxFadeAlpha + ')'; this._game.stage.context.fillRect(this._sx, this._sy, this.worldView.width, this.worldView.height); } // Scale off if(this.scale.x !== 1 || this.scale.y !== 1) { this._game.stage.context.scale(1, 1); } if(this._rotation !== 0 || this._clip) { this._game.stage.context.translate(0, 0); } // maybe just do this every frame regardless? this._game.stage.context.restore(); if(this.alpha !== 1) { this._game.stage.context.globalAlpha = 1; } }; Object.defineProperty(Camera.prototype, "backgroundColor", { get: function () { return this._bgColor; }, set: function (color) { this._bgColor = color; }, enumerable: true, configurable: true }); Camera.prototype.setTexture = function (key, repeat) { if (typeof repeat === "undefined") { repeat = 'repeat'; } this._bgTexture = this._game.stage.context.createPattern(this._game.cache.getImage(key), repeat); this._bgTextureRepeat = repeat; }; Camera.prototype.setPosition = function (x, y) { this._stageX = x; this._stageY = y; this.checkClip(); }; Camera.prototype.setSize = function (width, height) { this.worldView.width = width; this.worldView.height = height; this.checkClip(); //console.log('Camera setSize', width, height); }; Camera.prototype.renderDebugInfo = function (x, y, color) { if (typeof color === "undefined") { color = 'rgb(255,255,255)'; } this._game.stage.context.fillStyle = color; this._game.stage.context.fillText('Camera ID: ' + this.ID + ' (' + this.worldView.width + ' x ' + this.worldView.height + ')', x, y); this._game.stage.context.fillText('X: ' + this._stageX + ' Y: ' + this._stageY + ' Rotation: ' + this._rotation, x, y + 14); this._game.stage.context.fillText('World X: ' + this.scroll.x.toFixed(1) + ' World Y: ' + this.scroll.y.toFixed(1), x, y + 28); if(this.bounds) { this._game.stage.context.fillText('Bounds: ' + this.bounds.width + ' x ' + this.bounds.height, x, y + 56); } }; Object.defineProperty(Camera.prototype, "x", { get: function () { return this._stageX; }, set: function (value) { this._stageX = value; this.checkClip(); }, enumerable: true, configurable: true }); Object.defineProperty(Camera.prototype, "y", { get: function () { return this._stageY; }, set: function (value) { this._stageY = value; this.checkClip(); }, enumerable: true, configurable: true }); Object.defineProperty(Camera.prototype, "width", { get: function () { return this.worldView.width; }, set: function (value) { if(value > this._game.stage.width) { value = this._game.stage.width; } this.worldView.width = value; this.checkClip(); }, enumerable: true, configurable: true }); Object.defineProperty(Camera.prototype, "height", { get: function () { return this.worldView.height; }, set: function (value) { if(value > this._game.stage.height) { value = this._game.stage.height; } this.worldView.height = value; this.checkClip(); }, enumerable: true, configurable: true }); Object.defineProperty(Camera.prototype, "rotation", { get: function () { return this._rotation; }, set: function (value) { this._rotation = this._game.math.wrap(value, 360, 0); }, enumerable: true, configurable: true }); Camera.prototype.checkClip = function () { if(this._stageX !== 0 || this._stageY !== 0 || this.worldView.width < this._game.stage.width || this.worldView.height < this._game.stage.height) { this._clip = true; } else { this._clip = false; } }; return Camera; })(); Phaser.Camera = Camera; })(Phaser || (Phaser = {})); /// /// /// /// /** * Phaser - Sprite * * The Sprite GameObject is an extension of the core GameObject that includes support for animation and dynamic textures. * It's probably the most used GameObject of all. */ var Phaser; (function (Phaser) { var Sprite = (function (_super) { __extends(Sprite, _super); function Sprite(game, x, y, key) { if (typeof x === "undefined") { x = 0; } if (typeof y === "undefined") { y = 0; } if (typeof key === "undefined") { key = null; } _super.call(this, game, x, y); this._dynamicTexture = false; // local rendering related temp vars to help avoid gc spikes this._sx = 0; this._sy = 0; this._sw = 0; this._sh = 0; this._dx = 0; this._dy = 0; this._dw = 0; this._dh = 0; this.renderDebug = false; this.renderDebugColor = 'rgba(0,255,0,0.5)'; this.renderDebugPointColor = 'rgba(255,255,255,1)'; this.flipped = false; this._texture = null; this.animations = new Phaser.AnimationManager(this._game, this); if(key !== null) { this.loadGraphic(key); } else { this.bounds.width = 16; this.bounds.height = 16; } } Sprite.prototype.loadGraphic = function (key) { if(this._game.cache.getImage(key) !== null) { if(this._game.cache.isSpriteSheet(key) == false) { this._texture = this._game.cache.getImage(key); this.bounds.width = this._texture.width; this.bounds.height = this._texture.height; } else { this._texture = this._game.cache.getImage(key); this.animations.loadFrameData(this._game.cache.getFrameData(key)); } this._dynamicTexture = false; } return this; }; Sprite.prototype.loadDynamicTexture = function (texture) { this._texture = texture; this.bounds.width = this._texture.width; this.bounds.height = this._texture.height; this._dynamicTexture = true; return this; }; Sprite.prototype.makeGraphic = function (width, height, color) { if (typeof color === "undefined") { color = 0xffffffff; } this._texture = null; this.width = width; this.height = height; this._dynamicTexture = false; return this; }; Sprite.prototype.inCamera = function (camera) { if(this.scrollFactor.x !== 1.0 || this.scrollFactor.y !== 1.0) { this._dx = this.bounds.x - (camera.x * this.scrollFactor.x); this._dy = this.bounds.y - (camera.y * this.scrollFactor.x); this._dw = this.bounds.width * this.scale.x; this._dh = this.bounds.height * this.scale.y; return (camera.right > this._dx) && (camera.x < this._dx + this._dw) && (camera.bottom > this._dy) && (camera.y < this._dy + this._dh); } else { return camera.intersects(this.bounds, this.bounds.length); } }; Sprite.prototype.postUpdate = function () { this.animations.update(); _super.prototype.postUpdate.call(this); }; Object.defineProperty(Sprite.prototype, "frame", { get: function () { return this.animations.frame; }, set: function (value) { this.animations.frame = value; }, enumerable: true, configurable: true }); Object.defineProperty(Sprite.prototype, "frameName", { get: function () { return this.animations.frameName; }, set: function (value) { this.animations.frameName = value; }, enumerable: true, configurable: true }); Sprite.prototype.render = function (camera, cameraOffsetX, cameraOffsetY) { // Render checks if(this.visible == false || this.scale.x == 0 || this.scale.y == 0 || this.alpha < 0.1 || this.cameraBlacklist.indexOf(camera.ID) !== -1 || this.inCamera(camera.worldView) == false) { return false; } // Alpha if(this.alpha !== 1) { var globalAlpha = this._game.stage.context.globalAlpha; this._game.stage.context.globalAlpha = this.alpha; } this._sx = 0; this._sy = 0; this._sw = this.bounds.width; this._sh = this.bounds.height; this._dx = cameraOffsetX + (this.bounds.topLeft.x - camera.worldView.x); this._dy = cameraOffsetY + (this.bounds.topLeft.y - camera.worldView.y); this._dw = this.bounds.width * this.scale.x; this._dh = this.bounds.height * this.scale.y; if(this.align == Phaser.GameObject.ALIGN_TOP_CENTER) { this._dx -= this.bounds.halfWidth * this.scale.x; } else if(this.align == Phaser.GameObject.ALIGN_TOP_RIGHT) { this._dx -= this.bounds.width * this.scale.x; } else if(this.align == Phaser.GameObject.ALIGN_CENTER_LEFT) { this._dy -= this.bounds.halfHeight * this.scale.y; } else if(this.align == Phaser.GameObject.ALIGN_CENTER) { this._dx -= this.bounds.halfWidth * this.scale.x; this._dy -= this.bounds.halfHeight * this.scale.y; } else if(this.align == Phaser.GameObject.ALIGN_CENTER_RIGHT) { this._dx -= this.bounds.width * this.scale.x; this._dy -= this.bounds.halfHeight * this.scale.y; } else if(this.align == Phaser.GameObject.ALIGN_BOTTOM_LEFT) { this._dy -= this.bounds.height * this.scale.y; } else if(this.align == Phaser.GameObject.ALIGN_BOTTOM_CENTER) { this._dx -= this.bounds.halfWidth * this.scale.x; this._dy -= this.bounds.height * this.scale.y; } else if(this.align == Phaser.GameObject.ALIGN_BOTTOM_RIGHT) { this._dx -= this.bounds.width * this.scale.x; this._dy -= this.bounds.height * this.scale.y; } if(this._dynamicTexture == false && this.animations.currentFrame !== null) { this._sx = this.animations.currentFrame.x; this._sy = this.animations.currentFrame.y; if(this.animations.currentFrame.trimmed) { this._dx += this.animations.currentFrame.spriteSourceSizeX; this._dy += this.animations.currentFrame.spriteSourceSizeY; } } // Apply camera difference if(this.scrollFactor.x !== 1.0 || this.scrollFactor.y !== 1.0) { this._dx -= (camera.worldView.x * this.scrollFactor.x); this._dy -= (camera.worldView.y * this.scrollFactor.y); } // Rotation - needs to work from origin point really, but for now from center if(this.angle !== 0 || this.rotationOffset !== 0 || this.flipped == true) { this._game.stage.context.save(); this._game.stage.context.translate(this._dx + (this._dw / 2), this._dy + (this._dh / 2)); if(this.renderRotation == true && (this.angle !== 0 || this.rotationOffset !== 0)) { this._game.stage.context.rotate((this.rotationOffset + this.angle) * (Math.PI / 180)); } this._dx = -(this._dw / 2); this._dy = -(this._dh / 2); if(this.flipped == true) { this._game.stage.context.scale(-1, 1); } } this._sx = Math.round(this._sx); this._sy = Math.round(this._sy); this._sw = Math.round(this._sw); this._sh = Math.round(this._sh); this._dx = Math.round(this._dx); this._dy = Math.round(this._dy); this._dw = Math.round(this._dw); this._dh = Math.round(this._dh); if(this._texture != null) { if(this._dynamicTexture) { this._game.stage.context.drawImage(this._texture.canvas, // Source Image this._sx, // Source X (location within the source image) this._sy, // Source Y this._sw, // Source Width this._sh, // Source Height this._dx, // Destination X (where on the canvas it'll be drawn) this._dy, // Destination Y this._dw, // Destination Width (always same as Source Width unless scaled) this._dh); // Destination Height (always same as Source Height unless scaled) } else { this._game.stage.context.drawImage(this._texture, // Source Image this._sx, // Source X (location within the source image) this._sy, // Source Y this._sw, // Source Width this._sh, // Source Height this._dx, // Destination X (where on the canvas it'll be drawn) this._dy, // Destination Y this._dw, // Destination Width (always same as Source Width unless scaled) this._dh); // Destination Height (always same as Source Height unless scaled) } } else { this._game.stage.context.fillStyle = 'rgb(255,255,255)'; this._game.stage.context.fillRect(this._dx, this._dy, this._dw, this._dh); } if(this.flipped === true || this.rotation !== 0 || this.rotationOffset !== 0) { //this._game.stage.context.translate(0, 0); this._game.stage.context.restore(); } if(this.renderDebug) { this.renderBounds(camera, cameraOffsetX, cameraOffsetY); } if(globalAlpha > -1) { this._game.stage.context.globalAlpha = globalAlpha; } return true; }; Sprite.prototype.renderBounds = // Renders the bounding box around this Sprite and the contact points. Useful for visually debugging. function (camera, cameraOffsetX, cameraOffsetY) { this._dx = cameraOffsetX + (this.bounds.topLeft.x - camera.worldView.x); this._dy = cameraOffsetY + (this.bounds.topLeft.y - camera.worldView.y); this._game.stage.context.fillStyle = this.renderDebugColor; this._game.stage.context.fillRect(this._dx, this._dy, this._dw, this._dh); this._game.stage.context.fillStyle = this.renderDebugPointColor; var hw = this.bounds.halfWidth * this.scale.x; var hh = this.bounds.halfHeight * this.scale.y; var sw = (this.bounds.width * this.scale.x) - 1; var sh = (this.bounds.height * this.scale.y) - 1; this._game.stage.context.fillRect(this._dx, this._dy, 1, 1)// top left ; this._game.stage.context.fillRect(this._dx + hw, this._dy, 1, 1)// top center ; this._game.stage.context.fillRect(this._dx + sw, this._dy, 1, 1)// top right ; this._game.stage.context.fillRect(this._dx, this._dy + hh, 1, 1)// left center ; this._game.stage.context.fillRect(this._dx + hw, this._dy + hh, 1, 1)// center ; this._game.stage.context.fillRect(this._dx + sw, this._dy + hh, 1, 1)// right center ; this._game.stage.context.fillRect(this._dx, this._dy + sh, 1, 1)// bottom left ; this._game.stage.context.fillRect(this._dx + hw, this._dy + sh, 1, 1)// bottom center ; this._game.stage.context.fillRect(this._dx + sw, this._dy + sh, 1, 1)// bottom right ; }; Sprite.prototype.renderDebugInfo = function (x, y, color) { if (typeof color === "undefined") { color = 'rgb(255,255,255)'; } this._game.stage.context.fillStyle = color; this._game.stage.context.fillText('Sprite: ' + this.name + ' (' + this.bounds.width + ' x ' + this.bounds.height + ')', x, y); this._game.stage.context.fillText('x: ' + this.bounds.x.toFixed(1) + ' y: ' + this.bounds.y.toFixed(1) + ' rotation: ' + this.angle.toFixed(1), x, y + 14); this._game.stage.context.fillText('dx: ' + this._dx.toFixed(1) + ' dy: ' + this._dy.toFixed(1) + ' dw: ' + this._dw.toFixed(1) + ' dh: ' + this._dh.toFixed(1), x, y + 28); this._game.stage.context.fillText('sx: ' + this._sx.toFixed(1) + ' sy: ' + this._sy.toFixed(1) + ' sw: ' + this._sw.toFixed(1) + ' sh: ' + this._sh.toFixed(1), x, y + 42); }; return Sprite; })(Phaser.GameObject); Phaser.Sprite = Sprite; })(Phaser || (Phaser = {})); /// /** * Phaser - Animation * * An Animation is a single animation. It is created by the AnimationManager and belongs to Sprite objects. */ var Phaser; (function (Phaser) { var Animation = (function () { function Animation(game, parent, frameData, name, frames, delay, looped) { this._game = game; this._parent = parent; this._frames = frames; this._frameData = frameData; this.name = name; this.delay = 1000 / delay; this.looped = looped; this.isFinished = false; this.isPlaying = false; this._frameIndex = 0; this.currentFrame = this._frameData.getFrame(this._frames[this._frameIndex]); } Object.defineProperty(Animation.prototype, "frameTotal", { get: function () { return this._frames.length; }, enumerable: true, configurable: true }); Object.defineProperty(Animation.prototype, "frame", { get: function () { return this._frameIndex; }, set: function (value) { this.currentFrame = this._frameData.getFrame(value); if(this.currentFrame !== null) { this._parent.bounds.width = this.currentFrame.width; this._parent.bounds.height = this.currentFrame.height; this._frameIndex = value; } }, enumerable: true, configurable: true }); Animation.prototype.play = function (frameRate, loop) { if (typeof frameRate === "undefined") { frameRate = null; } if(frameRate !== null) { this.delay = 1000 / frameRate; } if(loop !== undefined) { this.looped = loop; } this.isPlaying = true; this.isFinished = false; this._timeLastFrame = this._game.time.now; this._timeNextFrame = this._game.time.now + this.delay; this._frameIndex = 0; this.currentFrame = this._frameData.getFrame(this._frames[this._frameIndex]); }; Animation.prototype.restart = function () { this.isPlaying = true; this.isFinished = false; this._timeLastFrame = this._game.time.now; this._timeNextFrame = this._game.time.now + this.delay; this._frameIndex = 0; this.currentFrame = this._frameData.getFrame(this._frames[this._frameIndex]); }; Animation.prototype.stop = function () { this.isPlaying = false; this.isFinished = true; }; Animation.prototype.update = function () { if(this.isPlaying == true && this._game.time.now >= this._timeNextFrame) { this._frameIndex++; if(this._frameIndex == this._frames.length) { if(this.looped) { this._frameIndex = 0; this.currentFrame = this._frameData.getFrame(this._frames[this._frameIndex]); } else { this.onComplete(); } } else { this.currentFrame = this._frameData.getFrame(this._frames[this._frameIndex]); } this._timeLastFrame = this._game.time.now; this._timeNextFrame = this._game.time.now + this.delay; return true; } return false; }; Animation.prototype.destroy = function () { this._game = null; this._parent = null; this._frames = null; this._frameData = null; this.currentFrame = null; this.isPlaying = false; }; Animation.prototype.onComplete = function () { this.isPlaying = false; this.isFinished = true; // callback }; return Animation; })(); Phaser.Animation = Animation; })(Phaser || (Phaser = {})); /// /** * Phaser - AnimationLoader * * Responsible for parsing sprite sheet and JSON data into the internal FrameData format that Phaser uses for animations. */ var Phaser; (function (Phaser) { var AnimationLoader = (function () { function AnimationLoader() { } AnimationLoader.parseSpriteSheet = function parseSpriteSheet(game, key, frameWidth, frameHeight, frameMax) { // How big is our image? var img = game.cache.getImage(key); if(img == null) { return null; } var width = img.width; var height = img.height; var row = Math.round(width / frameWidth); var column = Math.round(height / frameHeight); var total = row * column; if(frameMax !== -1) { total = frameMax; } // Zero or smaller than frame sizes? if(width == 0 || height == 0 || width < frameWidth || height < frameHeight || total === 0) { return null; } // Let's create some frames then var data = new Phaser.FrameData(); var x = 0; var y = 0; for(var i = 0; i < total; i++) { data.addFrame(new Phaser.Frame(x, y, frameWidth, frameHeight, '')); x += frameWidth; if(x === width) { x = 0; y += frameHeight; } } return data; }; AnimationLoader.parseJSONData = function parseJSONData(game, json) { // Let's create some frames then var data = new Phaser.FrameData(); // By this stage frames is a fully parsed array var frames = json; var newFrame; for(var i = 0; i < frames.length; i++) { newFrame = data.addFrame(new Phaser.Frame(frames[i].frame.x, frames[i].frame.y, frames[i].frame.w, frames[i].frame.h, frames[i].filename)); newFrame.setTrim(frames[i].trimmed, frames[i].sourceSize.w, frames[i].sourceSize.h, frames[i].spriteSourceSize.x, frames[i].spriteSourceSize.y, frames[i].spriteSourceSize.w, frames[i].spriteSourceSize.h); } return data; }; return AnimationLoader; })(); Phaser.AnimationLoader = AnimationLoader; })(Phaser || (Phaser = {})); /// /** * Phaser - Frame * * A Frame is a single frame of an animation and is part of a FrameData collection. */ var Phaser; (function (Phaser) { var Frame = (function () { function Frame(x, y, width, height, name) { // Useful for Texture Atlas files (is set to the filename value) this.name = ''; // Rotated? (not yet implemented) this.rotated = false; // Either cw or ccw, rotation is always 90 degrees this.rotationDirection = 'cw'; this.x = x; this.y = y; this.width = width; this.height = height; this.name = name; this.rotated = false; this.trimmed = false; } Frame.prototype.setRotation = function (rotated, rotationDirection) { // Not yet supported }; Frame.prototype.setTrim = function (trimmed, actualWidth, actualHeight, destX, destY, destWidth, destHeight) { this.trimmed = trimmed; this.sourceSizeW = actualWidth; this.sourceSizeH = actualHeight; this.spriteSourceSizeX = destX; this.spriteSourceSizeY = destY; this.spriteSourceSizeW = destWidth; this.spriteSourceSizeH = destHeight; }; return Frame; })(); Phaser.Frame = Frame; })(Phaser || (Phaser = {})); /// /** * Phaser - FrameData * * FrameData is a container for Frame objects, the internal representation of animation data in Phaser. */ var Phaser; (function (Phaser) { var FrameData = (function () { function FrameData() { this._frames = []; this._frameNames = []; } Object.defineProperty(FrameData.prototype, "total", { get: function () { return this._frames.length; }, enumerable: true, configurable: true }); FrameData.prototype.addFrame = function (frame) { frame.index = this._frames.length; this._frames.push(frame); if(frame.name !== '') { this._frameNames[frame.name] = frame.index; } return frame; }; FrameData.prototype.getFrame = function (index) { if(this._frames[index]) { return this._frames[index]; } return null; }; FrameData.prototype.getFrameByName = function (name) { if(this._frameNames[name] >= 0) { return this._frames[this._frameNames[name]]; } return null; }; FrameData.prototype.checkFrameName = function (name) { if(this._frameNames[name] >= 0) { return true; } return false; }; FrameData.prototype.getFrameRange = function (start, end, output) { if (typeof output === "undefined") { output = []; } for(var i = start; i <= end; i++) { output.push(this._frames[i]); } return output; }; FrameData.prototype.getFrameIndexes = function (output) { if (typeof output === "undefined") { output = []; } output.length = 0; for(var i = 0; i < this._frames.length; i++) { output.push(i); } return output; }; FrameData.prototype.getFrameIndexesByName = function (input) { var output = []; for(var i = 0; i < input.length; i++) { if(this.getFrameByName(input[i])) { output.push(this.getFrameByName(input[i]).index); } } return output; }; FrameData.prototype.getAllFrames = function () { return this._frames; }; FrameData.prototype.getFrames = function (range) { var output = []; for(var i = 0; i < range.length; i++) { output.push(this._frames[i]); } return output; }; return FrameData; })(); Phaser.FrameData = FrameData; })(Phaser || (Phaser = {})); /// /// /// /// /// /// /** * Phaser - AnimationManager * * Any Sprite that has animation contains an instance of the AnimationManager, which is used to add, play and update * sprite specific animations. */ var Phaser; (function (Phaser) { var AnimationManager = (function () { function AnimationManager(game, parent) { this._frameData = null; this.currentFrame = null; this._game = game; this._parent = parent; this._anims = { }; } AnimationManager.prototype.loadFrameData = function (frameData) { this._frameData = frameData; this.frame = 0; }; AnimationManager.prototype.add = function (name, frames, frameRate, loop, useNumericIndex) { if (typeof frames === "undefined") { frames = null; } if (typeof frameRate === "undefined") { frameRate = 60; } if (typeof loop === "undefined") { loop = false; } if (typeof useNumericIndex === "undefined") { useNumericIndex = true; } if(this._frameData == null) { return; } if(frames == null) { frames = this._frameData.getFrameIndexes(); } else { if(this.validateFrames(frames, useNumericIndex) == false) { throw Error('Invalid frames given to Animation ' + name); return; } } if(useNumericIndex == false) { frames = this._frameData.getFrameIndexesByName(frames); } this._anims[name] = new Phaser.Animation(this._game, this._parent, this._frameData, name, frames, frameRate, loop); this.currentAnim = this._anims[name]; this.currentFrame = this.currentAnim.currentFrame; }; AnimationManager.prototype.validateFrames = function (frames, useNumericIndex) { for(var i = 0; i < frames.length; i++) { if(useNumericIndex == true) { if(frames[i] > this._frameData.total) { return false; } } else { if(this._frameData.checkFrameName(frames[i]) == false) { return false; } } } return true; }; AnimationManager.prototype.play = function (name, frameRate, loop) { if (typeof frameRate === "undefined") { frameRate = null; } if(this._anims[name]) { if(this.currentAnim == this._anims[name]) { if(this.currentAnim.isPlaying == false) { this.currentAnim.play(frameRate, loop); } } else { this.currentAnim = this._anims[name]; this.currentAnim.play(frameRate, loop); } } }; AnimationManager.prototype.stop = function (name) { if(this._anims[name]) { this.currentAnim = this._anims[name]; this.currentAnim.stop(); } }; AnimationManager.prototype.update = function () { if(this.currentAnim && this.currentAnim.update() == true) { this.currentFrame = this.currentAnim.currentFrame; this._parent.bounds.width = this.currentFrame.width; this._parent.bounds.height = this.currentFrame.height; } }; Object.defineProperty(AnimationManager.prototype, "frameData", { get: function () { return this._frameData; }, enumerable: true, configurable: true }); Object.defineProperty(AnimationManager.prototype, "frameTotal", { get: function () { return this._frameData.total; }, enumerable: true, configurable: true }); Object.defineProperty(AnimationManager.prototype, "frame", { get: function () { return this._frameIndex; }, set: function (value) { if(this._frameData.getFrame(value) !== null) { this.currentFrame = this._frameData.getFrame(value); this._parent.bounds.width = this.currentFrame.width; this._parent.bounds.height = this.currentFrame.height; this._frameIndex = value; } }, enumerable: true, configurable: true }); Object.defineProperty(AnimationManager.prototype, "frameName", { get: function () { return this.currentFrame.name; }, set: function (value) { if(this._frameData.getFrameByName(value) !== null) { this.currentFrame = this._frameData.getFrameByName(value); this._parent.bounds.width = this.currentFrame.width; this._parent.bounds.height = this.currentFrame.height; this._frameIndex = this.currentFrame.index; } }, enumerable: true, configurable: true }); return AnimationManager; })(); Phaser.AnimationManager = AnimationManager; })(Phaser || (Phaser = {})); /// /** * Phaser - Cache * * A game only has one instance of a Cache and it is used to store all externally loaded assets such * as images, sounds and data files as a result of Loader calls. Cache items use string based keys for look-up. */ var Phaser; (function (Phaser) { var Cache = (function () { function Cache(game) { this._game = game; this._canvases = { }; this._images = { }; this._sounds = { }; this._text = { }; } Cache.prototype.addCanvas = function (key, canvas, context) { this._canvases[key] = { canvas: canvas, context: context }; }; Cache.prototype.addSpriteSheet = function (key, url, data, frameWidth, frameHeight, frameMax) { this._images[key] = { url: url, data: data, spriteSheet: true, frameWidth: frameWidth, frameHeight: frameHeight }; this._images[key].frameData = Phaser.AnimationLoader.parseSpriteSheet(this._game, key, frameWidth, frameHeight, frameMax); }; Cache.prototype.addTextureAtlas = function (key, url, data, jsonData) { this._images[key] = { url: url, data: data, spriteSheet: true }; this._images[key].frameData = Phaser.AnimationLoader.parseJSONData(this._game, jsonData); }; Cache.prototype.addImage = function (key, url, data) { this._images[key] = { url: url, data: data, spriteSheet: false }; }; Cache.prototype.addSound = function (key, url, data) { this._sounds[key] = { url: url, data: data, decoded: false }; }; Cache.prototype.decodedSound = function (key, data) { this._sounds[key].data = data; this._sounds[key].decoded = true; }; Cache.prototype.addText = function (key, url, data) { this._text[key] = { url: url, data: data }; }; Cache.prototype.getCanvas = function (key) { if(this._canvases[key]) { return this._canvases[key].canvas; } return null; }; Cache.prototype.getImage = function (key) { if(this._images[key]) { return this._images[key].data; } return null; }; Cache.prototype.getFrameData = function (key) { if(this._images[key] && this._images[key].spriteSheet == true) { return this._images[key].frameData; } return null; }; Cache.prototype.getSound = function (key) { if(this._sounds[key]) { return this._sounds[key].data; } return null; }; Cache.prototype.isSoundDecoded = function (key) { if(this._sounds[key]) { return this._sounds[key].decoded; } }; Cache.prototype.isSpriteSheet = function (key) { if(this._images[key]) { return this._images[key].spriteSheet; } }; Cache.prototype.getText = function (key) { if(this._text[key]) { return this._text[key].data; } return null; }; Cache.prototype.destroy = function () { for(var item in this._canvases) { delete this._canvases[item['key']]; } for(var item in this._images) { delete this._images[item['key']]; } for(var item in this._sounds) { delete this._sounds[item['key']]; } for(var item in this._text) { delete this._text[item['key']]; } }; return Cache; })(); Phaser.Cache = Cache; })(Phaser || (Phaser = {})); /// /// /** * Phaser - CameraManager * * Your game only has one CameraManager instance and it's responsible for looking after, creating and destroying * all of the cameras in the world. * * TODO: If the Camera is larger than the Stage size then the rotation offset isn't correct * TODO: Texture Repeat doesn't scroll, because it's part of the camera not the world, need to think about this more */ var Phaser; (function (Phaser) { var CameraManager = (function () { function CameraManager(game, x, y, width, height) { this._cameraInstance = 0; this._game = game; this._cameras = []; this.current = this.addCamera(x, y, width, height); } CameraManager.prototype.getAll = function () { return this._cameras; }; CameraManager.prototype.update = function () { this._cameras.forEach(function (camera) { return camera.update(); }); }; CameraManager.prototype.render = function () { this._cameras.forEach(function (camera) { return camera.render(); }); }; CameraManager.prototype.addCamera = function (x, y, width, height) { var newCam = new Phaser.Camera(this._game, this._cameraInstance, x, y, width, height); this._cameras.push(newCam); this._cameraInstance++; return newCam; }; CameraManager.prototype.removeCamera = function (id) { for(var c = 0; c < this._cameras.length; c++) { if(this._cameras[c].ID == id) { if(this.current.ID === this._cameras[c].ID) { this.current = null; } this._cameras.splice(c, 1); return true; } } return false; }; CameraManager.prototype.destroy = function () { this._cameras.length = 0; this.current = this.addCamera(0, 0, this._game.stage.width, this._game.stage.height); }; return CameraManager; })(); Phaser.CameraManager = CameraManager; })(Phaser || (Phaser = {})); /// /** * Phaser - Point * * The Point object represents a location in a two-dimensional coordinate system, where x represents the horizontal axis and y represents the vertical axis. */ var Phaser; (function (Phaser) { var Point = (function () { /** * Creates a new point. If you pass no parameters to this method, a point is created at (0,0). * @class Point * @constructor * @param {Number} x The horizontal position of this point (default 0) * @param {Number} y The vertical position of this point (default 0) **/ function Point(x, y) { if (typeof x === "undefined") { x = 0; } if (typeof y === "undefined") { y = 0; } this.setTo(x, y); } Point.prototype.add = /** * Adds the coordinates of another point to the coordinates of this point to create a new point. * @method add * @param {Point} point - The point to be added. * @return {Point} The new Point object. **/ function (toAdd, output) { if (typeof output === "undefined") { output = new Point(); } return output.setTo(this.x + toAdd.x, this.y + toAdd.y); }; Point.prototype.addTo = /** * Adds the given values to the coordinates of this point and returns it * @method addTo * @param {Number} x - The amount to add to the x value of the point * @param {Number} y - The amount to add to the x value of the point * @return {Point} This Point object. **/ function (x, y) { if (typeof x === "undefined") { x = 0; } if (typeof y === "undefined") { y = 0; } return this.setTo(this.x + x, this.y + y); }; Point.prototype.subtractFrom = /** * Adds the given values to the coordinates of this point and returns it * @method addTo * @param {Number} x - The amount to add to the x value of the point * @param {Number} y - The amount to add to the x value of the point * @return {Point} This Point object. **/ function (x, y) { if (typeof x === "undefined") { x = 0; } if (typeof y === "undefined") { y = 0; } return this.setTo(this.x - x, this.y - y); }; Point.prototype.invert = /** * Inverts the x and y values of this point * @method invert * @return {Point} This Point object. **/ function () { return this.setTo(this.y, this.x); }; Point.prototype.clamp = /** * Clamps this Point object to be between the given min and max * @method clamp * @param {number} The minimum value to clamp this Point to * @param {number} The maximum value to clamp this Point to * @return {Point} This Point object. **/ function (min, max) { this.clampX(min, max); this.clampY(min, max); return this; }; Point.prototype.clampX = /** * Clamps the x value of this Point object to be between the given min and max * @method clampX * @param {number} The minimum value to clamp this Point to * @param {number} The maximum value to clamp this Point to * @return {Point} This Point object. **/ function (min, max) { this.x = Math.max(Math.min(this.x, max), min); return this; }; Point.prototype.clampY = /** * Clamps the y value of this Point object to be between the given min and max * @method clampY * @param {number} The minimum value to clamp this Point to * @param {number} The maximum value to clamp this Point to * @return {Point} This Point object. **/ function (min, max) { this.x = Math.max(Math.min(this.x, max), min); this.y = Math.max(Math.min(this.y, max), min); return this; }; Point.prototype.clone = /** * Creates a copy of this Point. * @method clone * @param {Point} output Optional Point object. If given the values will be set into this object, otherwise a brand new Point object will be created and returned. * @return {Point} The new Point object. **/ function (output) { if (typeof output === "undefined") { output = new Point(); } return output.setTo(this.x, this.y); }; Point.prototype.copyFrom = /** * Copies the point data from the source Point object into this Point object. * @method copyFrom * @param {Point} source - The point to copy from. * @return {Point} This Point object. Useful for chaining method calls. **/ function (source) { return this.setTo(source.x, source.y); }; Point.prototype.copyTo = /** * Copies the point data from this Point object to the given target Point object. * @method copyTo * @param {Point} target - The point to copy to. * @return {Point} The target Point object. **/ function (target) { return target.setTo(this.x, this.y); }; Point.prototype.distanceTo = /** * Returns the distance from this Point object to the given Point object. * @method distanceFrom * @param {Point} target - The destination Point object. * @param {Boolean} round - Round the distance to the nearest integer (default false) * @return {Number} The distance between this Point object and the destination Point object. **/ function (target, round) { if (typeof round === "undefined") { round = false; } var dx = this.x - target.x; var dy = this.y - target.y; if(round === true) { return Math.round(Math.sqrt(dx * dx + dy * dy)); } else { return Math.sqrt(dx * dx + dy * dy); } }; Point.distanceBetween = /** * Returns the distance between the two Point objects. * @method distanceBetween * @param {Point} pointA - The first Point object. * @param {Point} pointB - The second Point object. * @param {Boolean} round - Round the distance to the nearest integer (default false) * @return {Number} The distance between the two Point objects. **/ function distanceBetween(pointA, pointB, round) { if (typeof round === "undefined") { round = false; } var dx = pointA.x - pointB.x; var dy = pointA.y - pointB.y; if(round === true) { return Math.round(Math.sqrt(dx * dx + dy * dy)); } else { return Math.sqrt(dx * dx + dy * dy); } }; Point.prototype.distanceCompare = /** * Returns true if the distance between this point and a target point is greater than or equal a specified distance. * This avoids using a costly square root operation * @method distanceCompare * @param {Point} target - The Point object to use for comparison. * @param {Number} distance - The distance to use for comparison. * @return {Boolena} True if distance is >= specified distance. **/ function (target, distance) { if(this.distanceTo(target) >= distance) { return true; } else { return false; } }; Point.prototype.equals = /** * Determines whether this Point object and the given point object are equal. They are equal if they have the same x and y values. * @method equals * @param {Point} point - The point to compare against. * @return {Boolean} A value of true if the object is equal to this Point object; false if it is not equal. **/ function (toCompare) { if(this.x === toCompare.x && this.y === toCompare.y) { return true; } else { return false; } }; Point.prototype.interpolate = /** * Determines a point between two specified points. The parameter f determines where the new interpolated point is located relative to the two end points specified by parameters pt1 and pt2. * The closer the value of the parameter f is to 1.0, the closer the interpolated point is to the first point (parameter pt1). The closer the value of the parameter f is to 0, the closer the interpolated point is to the second point (parameter pt2). * @method interpolate * @param {Point} pointA - The first Point object. * @param {Point} pointB - The second Point object. * @param {Number} f - The level of interpolation between the two points. Indicates where the new point will be, along the line between pt1 and pt2. If f=1, pt1 is returned; if f=0, pt2 is returned. * @return {Point} The new interpolated Point object. **/ function (pointA, pointB, f) { }; Point.prototype.offset = /** * Offsets the Point object by the specified amount. The value of dx is added to the original value of x to create the new x value. * The value of dy is added to the original value of y to create the new y value. * @method offset * @param {Number} dx - The amount by which to offset the horizontal coordinate, x. * @param {Number} dy - The amount by which to offset the vertical coordinate, y. * @return {Point} This Point object. Useful for chaining method calls. **/ function (dx, dy) { this.x += dx; this.y += dy; return this; }; Point.prototype.polar = /** * Converts a pair of polar coordinates to a Cartesian point coordinate. * @method polar * @param {Number} length - The length coordinate of the polar pair. * @param {Number} angle - The angle, in radians, of the polar pair. * @return {Point} The new Cartesian Point object. **/ function (length, angle) { }; Point.prototype.setTo = /** * Sets the x and y values of this Point object to the given coordinates. * @method setTo * @param {Number} x - The horizontal position of this point. * @param {Number} y - The vertical position of this point. * @return {Point} This Point object. Useful for chaining method calls. **/ function (x, y) { this.x = x; this.y = y; return this; }; Point.prototype.subtract = /** * Subtracts the coordinates of another point from the coordinates of this point to create a new point. * @method subtract * @param {Point} point - The point to be subtracted. * @param {Point} output Optional Point object. If given the values will be set into this object, otherwise a brand new Point object will be created and returned. * @return {Point} The new Point object. **/ function (point, output) { if (typeof output === "undefined") { output = new Point(); } return output.setTo(this.x - point.x, this.y - point.y); }; Point.prototype.toString = /** * Returns a string representation of this object. * @method toString * @return {string} a string representation of the instance. **/ function () { return '[{Point (x=' + this.x + ' y=' + this.y + ')}]'; }; return Point; })(); Phaser.Point = Point; })(Phaser || (Phaser = {})); /// /** * Phaser - MicroPoint * * The MicroPoint object represents a location in a two-dimensional coordinate system, * where x represents the horizontal axis and y represents the vertical axis. * It is different to the Point class in that it doesn't contain any of the help methods like add/substract/distanceTo, etc. * Use a MicroPoint when all you literally need is a solid container for x and y (such as in the Rectangle class). */ var Phaser; (function (Phaser) { var MicroPoint = (function () { /** * Creates a new point. If you pass no parameters to this method, a point is created at (0,0). * @class MicroPoint * @constructor * @param {Number} x The horizontal position of this point (default 0) * @param {Number} y The vertical position of this point (default 0) **/ function MicroPoint(x, y, parent) { if (typeof x === "undefined") { x = 0; } if (typeof y === "undefined") { y = 0; } if (typeof parent === "undefined") { parent = null; } this._x = x; this._y = y; this.parent = parent; } Object.defineProperty(MicroPoint.prototype, "x", { get: /** * The x coordinate of the top-left corner of the rectangle * @property x * @type Number **/ function () { return this._x; }, set: /** * The x coordinate of the top-left corner of the rectangle * @property x * @type Number **/ function (value) { this._x = value; if(this.parent) { this.parent.updateBounds(); } }, enumerable: true, configurable: true }); Object.defineProperty(MicroPoint.prototype, "y", { get: /** * The y coordinate of the top-left corner of the rectangle * @property y * @type Number **/ function () { return this._y; }, set: /** * The y coordinate of the top-left corner of the rectangle * @property y * @type Number **/ function (value) { this._y = value; if(this.parent) { this.parent.updateBounds(); } }, enumerable: true, configurable: true }); MicroPoint.prototype.copyFrom = /** * Copies the x and y values from any given object to this MicroPoint. * @method copyFrom * @param {any} source - The object to copy from. * @return {MicroPoint} This MicroPoint object. Useful for chaining method calls. **/ function (source) { return this.setTo(source.x, source.y); }; MicroPoint.prototype.copyTo = /** * Copies the x and y values from this MicroPoint to any given object. * @method copyTo * @param {any} target - The object to copy to. * @return {any} The target object. **/ function (target) { target.x = this._x; target.y = this._y; return target; }; MicroPoint.prototype.setTo = /** * Sets the x and y values of this MicroPoint object to the given coordinates. * @method setTo * @param {Number} x - The horizontal position of this point. * @param {Number} y - The vertical position of this point. * @return {MicroPoint} This MicroPoint object. Useful for chaining method calls. **/ function (x, y, callParent) { if (typeof callParent === "undefined") { callParent = true; } this._x = x; this._y = y; if(this.parent != null && callParent == true) { this.parent.updateBounds(); } return this; }; MicroPoint.prototype.equals = /** * Determines whether this MicroPoint object and the given object are equal. They are equal if they have the same x and y values. * @method equals * @param {any} point - The object to compare against. Must have x and y properties. * @return {Boolean} A value of true if the object is equal to this MicroPoin object; false if it is not equal. **/ function (toCompare) { if(this._x === toCompare.x && this._y === toCompare.y) { return true; } else { return false; } }; MicroPoint.prototype.toString = /** * Returns a string representation of this object. * @method toString * @return {string} a string representation of the instance. **/ function () { return '[{MicroPoint (x=' + this._x + ' y=' + this._y + ')}]'; }; return MicroPoint; })(); Phaser.MicroPoint = MicroPoint; })(Phaser || (Phaser = {})); /// /// /** * Phaser - Rectangle * * A Rectangle object is an area defined by its position, as indicated by its top-left corner (x,y) and width and height. */ var Phaser; (function (Phaser) { var Rectangle = (function () { /** * Creates a new Rectangle object with the top-left corner specified by the x and y parameters and with the specified width and height parameters. * If you call this function without parameters, a rectangle with x, y, width, and height properties set to 0 is created. * @class Rectangle * @constructor * @param {Number} x The x coordinate of the top-left corner of the rectangle. * @param {Number} y The y coordinate of the top-left corner of the rectangle. * @param {Number} width The width of the rectangle. * @param {Number} height The height of the rectangle. * @return {Rectangle} This rectangle object **/ function Rectangle(x, y, width, height) { if (typeof x === "undefined") { x = 0; } if (typeof y === "undefined") { y = 0; } if (typeof width === "undefined") { width = 0; } if (typeof height === "undefined") { height = 0; } this._tempX = null; this._tempY = null; this._tempWidth = null; this._tempHeight = null; /** * The width of the rectangle * @property width * @type Number **/ this._width = 0; /** * The height of the rectangle * @property height * @type Number **/ this._height = 0; /** * Half of the width of the rectangle * @property halfWidth * @type Number **/ this._halfWidth = 0; /** * Half of the height of the rectangle * @property halfHeight * @type Number **/ this._halfHeight = 0; /** * The size of the longest side (width or height) * @property length * @type Number **/ this.length = 0; this._width = width; if(width > 0) { this._halfWidth = Math.round(width / 2); } this._height = height; if(height > 0) { this._halfHeight = Math.round(height / 2); } this.length = Math.max(this._width, this._height); this.topLeft = new Phaser.MicroPoint(x, y, this); this.topCenter = new Phaser.MicroPoint(x + this._halfWidth, y, this); this.topRight = new Phaser.MicroPoint(x + this._width - 1, y, this); this.leftCenter = new Phaser.MicroPoint(x, y + this._halfHeight, this); this.center = new Phaser.MicroPoint(x + this._halfWidth, y + this._halfHeight, this); this.rightCenter = new Phaser.MicroPoint(x + this._width - 1, y + this._halfHeight, this); this.bottomLeft = new Phaser.MicroPoint(x, y + this._height - 1, this); this.bottomCenter = new Phaser.MicroPoint(x + this._halfWidth, y + this._height - 1, this); this.bottomRight = new Phaser.MicroPoint(x + this._width - 1, y + this._height - 1, this); } Object.defineProperty(Rectangle.prototype, "x", { get: /** * The x coordinate of the top-left corner of the rectangle * @property x * @type Number **/ function () { return this.topLeft.x; }, set: /** * The x coordinate of the top-left corner of the rectangle * @property x * @type Number **/ function (value) { this.topLeft.x = value; }, enumerable: true, configurable: true }); Object.defineProperty(Rectangle.prototype, "y", { get: /** * The y coordinate of the top-left corner of the rectangle * @property y * @type Number **/ function () { return this.topLeft.y; }, set: /** * The y coordinate of the top-left corner of the rectangle * @property y * @type Number **/ function (value) { this.topLeft.y = value; }, enumerable: true, configurable: true }); Rectangle.prototype.updateBounds = /** * Updates all of the MicroPoints based on the values of width and height. * You should not normally call this directly. **/ function () { if(this._tempWidth !== null) { this._width = this._tempWidth; this._halfWidth = 0; if(this._width > 0) { this._halfWidth = Math.round(this._width / 2); } } if(this._tempHeight !== null) { this._height = this._tempHeight; this._halfHeight = 0; if(this._height > 0) { this._halfHeight = Math.round(this._height / 2); } } this.length = Math.max(this._width, this._height); if(this._tempX !== null && this._tempY !== null) { this.topLeft.setTo(this._tempX, this._tempY, false); } else if(this._tempX !== null && this._tempY == null) { this.topLeft.setTo(this._tempX, this.topLeft.y, false); } else if(this._tempX == null && this._tempY !== null) { this.topLeft.setTo(this.topLeft.x, this._tempY, false); } else { this.topLeft.setTo(this.x, this.y, false); } this.topCenter.setTo(this.x + this._halfWidth, this.y, false); this.topRight.setTo(this.x + this._width - 1, this.y, false); this.leftCenter.setTo(this.x, this.y + this._halfHeight, false); this.center.setTo(this.x + this._halfWidth, this.y + this._halfHeight, false); this.rightCenter.setTo(this.x + this._width - 1, this.y + this._halfHeight, false); this.bottomLeft.setTo(this.x, this.y + this._height - 1, false); this.bottomCenter.setTo(this.x + this._halfWidth, this.y + this._height - 1, false); this.bottomRight.setTo(this.x + this._width - 1, this.y + this._height - 1, false); this._tempX = null; this._tempY = null; this._tempWidth = null; this._tempHeight = null; }; Object.defineProperty(Rectangle.prototype, "width", { get: /** * The width of the rectangle * @property width * @type Number **/ function () { return this._width; }, set: /** * The width of the rectangle * @property width * @type Number **/ function (value) { this._width = value; this._halfWidth = Math.round(value / 2); this.updateBounds(); }, enumerable: true, configurable: true }); Object.defineProperty(Rectangle.prototype, "height", { get: /** * The height of the rectangle * @property height * @type Number **/ function () { return this._height; }, set: /** * The height of the rectangle * @property height * @type Number **/ function (value) { this._height = value; this._halfHeight = Math.round(value / 2); this.updateBounds(); }, enumerable: true, configurable: true }); Object.defineProperty(Rectangle.prototype, "halfWidth", { get: /** * Half of the width of the rectangle * @property halfWidth * @type Number **/ function () { return this._halfWidth; }, enumerable: true, configurable: true }); Object.defineProperty(Rectangle.prototype, "halfHeight", { get: /** * Half of the height of the rectangle * @property halfHeight * @type Number **/ function () { return this._halfHeight; }, enumerable: true, configurable: true }); Object.defineProperty(Rectangle.prototype, "bottom", { get: /** * The sum of the y and height properties. * Changing the bottom property of a Rectangle object has no effect on the x, y and width properties, but does change the height property. * @method bottom * @return {Number} **/ function () { return this.bottomCenter.y; }, set: /** * The sum of the y and height properties. * Changing the bottom property of a Rectangle object has no effect on the x, y and width properties, but does change the height property. * @method bottom * @param {Number} value **/ function (value) { if(value < this.y) { this._tempHeight = 0; } else { this._tempHeight = this.y + value; } this.updateBounds(); }, enumerable: true, configurable: true }); Object.defineProperty(Rectangle.prototype, "left", { get: /** * The x coordinate of the top-left corner of the rectangle. * Changing the left property of a Rectangle object has no effect on the y and height properties. * However it does affect the width property, whereas changing the x value does not affect the width property. * @method left * @ return {number} **/ function () { return this.x; }, set: /** * The x coordinate of the top-left corner of the rectangle. * Changing the left property of a Rectangle object has no effect on the y and height properties. * However it does affect the width property, whereas changing the x value does not affect the width property. * @method left * @param {Number} value **/ function (value) { var diff = this.x - value; if(this._width + diff < 0) { this._tempWidth = 0; this._tempX = value; } else { this._tempWidth = this._width + diff; this._tempX = value; } this.updateBounds(); }, enumerable: true, configurable: true }); Object.defineProperty(Rectangle.prototype, "right", { get: /** * The sum of the x and width properties. * Changing the right property of a Rectangle object has no effect on the x, y and height properties. * However it does affect the width property. * @method right * @return {Number} **/ function () { return this.rightCenter.x; }, set: /** * The sum of the x and width properties. * Changing the right property of a Rectangle object has no effect on the x, y and height properties. * However it does affect the width property. * @method right * @param {Number} value **/ function (value) { if(value < this.topLeft.x) { this._tempWidth = 0; } else { this._tempWidth = (value - this.topLeft.x); } this.updateBounds(); }, enumerable: true, configurable: true }); Rectangle.prototype.size = /** * The size of the Rectangle object, expressed as a Point object with the values of the width and height properties. * @method size * @param {Point} output Optional Point object. If given the values will be set into the object, otherwise a brand new Point object will be created and returned. * @return {Point} The size of the Rectangle object **/ function (output) { if (typeof output === "undefined") { output = new Phaser.Point(); } return output.setTo(this._width, this._height); }; Object.defineProperty(Rectangle.prototype, "volume", { get: /** * The volume of the Rectangle object in pixels, derived from width * height * @method volume * @return {Number} **/ function () { return this._width * this._height; }, enumerable: true, configurable: true }); Object.defineProperty(Rectangle.prototype, "perimeter", { get: /** * The perimeter size of the Rectangle object in pixels. This is the sum of all 4 sides. * @method perimeter * @return {Number} **/ function () { return (this._width * 2) + (this._height * 2); }, enumerable: true, configurable: true }); Object.defineProperty(Rectangle.prototype, "top", { get: /** * The y coordinate of the top-left corner of the rectangle. * Changing the top property of a Rectangle object has no effect on the x and width properties. * However it does affect the height property, whereas changing the y value does not affect the height property. * @method top * @return {Number} **/ function () { return this.topCenter.y; }, set: /** * The y coordinate of the top-left corner of the rectangle. * Changing the top property of a Rectangle object has no effect on the x and width properties. * However it does affect the height property, whereas changing the y value does not affect the height property. * @method top * @param {Number} value **/ function (value) { var diff = this.topCenter.y - value; if(this._height + diff < 0) { this._tempHeight = 0; this._tempY = value; } else { this._tempHeight = this._height + diff; this._tempY = value; } this.updateBounds(); }, enumerable: true, configurable: true }); Rectangle.prototype.clone = /** * Returns a new Rectangle object with the same values for the x, y, width, and height properties as the original Rectangle object. * @method clone * @param {Rectangle} output Optional Rectangle object. If given the values will be set into the object, otherwise a brand new Rectangle object will be created and returned. * @return {Rectangle} **/ function (output) { if (typeof output === "undefined") { output = new Rectangle(); } return output.setTo(this.x, this.y, this.width, this.height); }; Rectangle.prototype.contains = /** * Determines whether the specified coordinates are contained within the region defined by this Rectangle object. * @method contains * @param {Number} x The x coordinate of the point to test. * @param {Number} y The y coordinate of the point to test. * @return {Boolean} A value of true if the Rectangle object contains the specified point; otherwise false. **/ function (x, y) { if(x >= this.topLeft.x && x <= this.topRight.x && y >= this.topLeft.y && y <= this.bottomRight.y) { return true; } return false; }; Rectangle.prototype.containsPoint = /** * Determines whether the specified point is contained within the rectangular region defined by this Rectangle object. * This method is similar to the Rectangle.contains() method, except that it takes a Point object as a parameter. * @method containsPoint * @param {Point} point The point object being checked. Can be Point or any object with .x and .y values. * @return {Boolean} A value of true if the Rectangle object contains the specified point; otherwise false. **/ function (point) { return this.contains(point.x, point.y); }; Rectangle.prototype.containsRect = /** * Determines whether the Rectangle object specified by the rect parameter is contained within this Rectangle object. * A Rectangle object is said to contain another if the second Rectangle object falls entirely within the boundaries of the first. * @method containsRect * @param {Rectangle} rect The rectangle object being checked. * @return {Boolean} A value of true if the Rectangle object contains the specified point; otherwise false. **/ function (rect) { // If the given rect has a larger volume than this one then it can never contain it if(rect.volume > this.volume) { return false; } if(rect.x >= this.topLeft.x && rect.y >= this.topLeft.y && rect.rightCenter.x <= this.rightCenter.x && rect.bottomCenter.y <= this.bottomCenter.y) { return true; } return false; }; Rectangle.prototype.copyFrom = /** * Copies all of rectangle data from the source Rectangle object into the calling Rectangle object. * @method copyFrom * @param {Rectangle} rect The source rectangle object to copy from * @return {Rectangle} This rectangle object **/ function (source) { return this.setTo(source.x, source.y, source.width, source.height); }; Rectangle.prototype.copyTo = /** * Copies all the rectangle data from this Rectangle object into the destination Rectangle object. * @method copyTo * @param {Rectangle} rect The destination rectangle object to copy in to * @return {Rectangle} The destination rectangle object **/ function (target) { return target.copyFrom(this); }; Rectangle.prototype.equals = /** * Determines whether the object specified in the toCompare parameter is equal to this Rectangle object. * This method compares the x, y, width, and height properties of an object against the same properties of this Rectangle object. * @method equals * @param {Rectangle} toCompare The rectangle to compare to this Rectangle object. * @return {Boolean} A value of true if the object has exactly the same values for the x, y, width, and height properties as this Rectangle object; otherwise false. **/ function (toCompare) { if(this.topLeft.equals(toCompare.topLeft) && this.bottomRight.equals(toCompare.bottomRight)) { return true; } return false; }; Rectangle.prototype.inflate = /** * Increases the size of the Rectangle object by the specified amounts. * The center point of the Rectangle object stays the same, and its size increases to the left and right by the dx value, * and to the top and the bottom by the dy value. * @method inflate * @param {Number} dx The amount to be added to the left side of this Rectangle. * @param {Number} dy The amount to be added to the bottom side of this Rectangle. * @return {Rectangle} This Rectangle object. **/ function (dx, dy) { this._tempX = this.topLeft.x - dx; this._tempWidth = this._width + (2 * dx); this._tempY = this.topLeft.y - dy; this._tempHeight = this._height + (2 * dy); this.updateBounds(); return this; }; Rectangle.prototype.inflatePoint = /** * Increases the size of the Rectangle object. * This method is similar to the Rectangle.inflate() method except it takes a Point object as a parameter. * @method inflatePoint * @param {Point} point The x property of this Point object is used to increase the horizontal dimension of the Rectangle object. The y property is used to increase the vertical dimension of the Rectangle object. * @return {Rectangle} This Rectangle object. **/ function (point) { return this.inflate(point.x, point.y); }; Rectangle.prototype.intersection = /** * If the Rectangle object specified in the toIntersect parameter intersects with this Rectangle object, * returns the area of intersection as a Rectangle object. If the rectangles do not intersect, this method * returns an empty Rectangle object with its properties set to 0. * @method intersection * @param {Rectangle} toIntersect The Rectangle object to compare against to see if it intersects with this Rectangle object. * @param {Rectangle} output Optional Rectangle object. If given the intersection values will be set into this object, otherwise a brand new Rectangle object will be created and returned. * @return {Rectangle} A Rectangle object that equals the area of intersection. If the rectangles do not intersect, this method returns an empty Rectangle object; that is, a rectangle with its x, y, width, and height properties set to 0. **/ function (toIntersect, output) { if (typeof output === "undefined") { output = new Rectangle(); } if(this.intersects(toIntersect) === true) { output.x = Math.max(toIntersect.topLeft.x, this.topLeft.x); output.y = Math.max(toIntersect.topLeft.y, this.topLeft.y); output.width = Math.min(toIntersect.rightCenter.x, this.rightCenter.x) - output.x; output.height = Math.min(toIntersect.bottomCenter.y, this.bottomCenter.y) - output.y; } return output; }; Rectangle.prototype.intersects = /** * Determines whether the object specified intersects (overlaps) with this Rectangle object. * This method checks the x, y, width, and height properties of the specified Rectangle object to see if it intersects with this Rectangle object. * @method intersects * @param {Rectangle} r2 The Rectangle object to compare against to see if it intersects with this Rectangle object. * @param {Number} t A tolerance value to allow for an intersection test with padding, default to 0 * @return {Boolean} A value of true if the specified object intersects with this Rectangle object; otherwise false. **/ function (r2, t) { if (typeof t === "undefined") { t = 0; } return !(r2.left > this.right + t || r2.right < this.left - t || r2.top > this.bottom + t || r2.bottom < this.top - t); }; Object.defineProperty(Rectangle.prototype, "isEmpty", { get: /** * Determines whether or not this Rectangle object is empty. * @method isEmpty * @return {Boolean} A value of true if the Rectangle object's width or height is less than or equal to 0; otherwise false. **/ function () { if(this.width < 1 || this.height < 1) { return true; } return false; }, enumerable: true, configurable: true }); Rectangle.prototype.offset = /** * Adjusts the location of the Rectangle object, as determined by its top-left corner, by the specified amounts. * @method offset * @param {Number} dx Moves the x value of the Rectangle object by this amount. * @param {Number} dy Moves the y value of the Rectangle object by this amount. * @return {Rectangle} This Rectangle object. **/ function (dx, dy) { if(!isNaN(dx) && !isNaN(dy)) { this.x += dx; this.y += dy; } return this; }; Rectangle.prototype.offsetPoint = /** * Adjusts the location of the Rectangle object using a Point object as a parameter. This method is similar to the Rectangle.offset() method, except that it takes a Point object as a parameter. * @method offsetPoint * @param {Point} point A Point object to use to offset this Rectangle object. * @return {Rectangle} This Rectangle object. **/ function (point) { return this.offset(point.x, point.y); }; Rectangle.prototype.setEmpty = /** * Sets all of the Rectangle object's properties to 0. A Rectangle object is empty if its width or height is less than or equal to 0. * @method setEmpty * @return {Rectangle} This rectangle object **/ function () { return this.setTo(0, 0, 0, 0); }; Rectangle.prototype.setTo = /** * Sets the members of Rectangle to the specified values. * @method setTo * @param {Number} x The x coordinate of the top-left corner of the rectangle. * @param {Number} y The y coordinate of the top-left corner of the rectangle. * @param {Number} width The width of the rectangle in pixels. * @param {Number} height The height of the rectangle in pixels. * @return {Rectangle} This rectangle object **/ function (x, y, width, height) { this._tempX = x; this._tempY = y; this._tempWidth = width; this._tempHeight = height; this.updateBounds(); return this; }; Rectangle.prototype.union = /** * Adds two rectangles together to create a new Rectangle object, by filling in the horizontal and vertical space between the two rectangles. * @method union * @param {Rectangle} toUnion A Rectangle object to add to this Rectangle object. * @param {Rectangle} output Optional Rectangle object. If given the new values will be set into this object, otherwise a brand new Rectangle object will be created and returned. * @return {Rectangle} A Rectangle object that is the union of the two rectangles. **/ function (toUnion, output) { if (typeof output === "undefined") { output = new Rectangle(); } return output.setTo(Math.min(toUnion.x, this.x), Math.min(toUnion.y, this.y), Math.max(toUnion.right, this.right), Math.max(toUnion.bottom, this.bottom)); }; Rectangle.prototype.toString = /** * Returns a string representation of this object. * @method toString * @return {string} a string representation of the instance. **/ function () { return "[{Rectangle (x=" + this.x + " y=" + this.y + " width=" + this.width + " height=" + this.height + " empty=" + this.isEmpty + ")}]"; }; return Rectangle; })(); Phaser.Rectangle = Rectangle; })(Phaser || (Phaser = {})); /// /** * Phaser - Quad * * A Quad object is an area defined by its position, as indicated by its top-left corner (x,y) and width and height. * Very much like a Rectangle only without all of the additional methods and properties of that class. */ var Phaser; (function (Phaser) { var Quad = (function () { /** * Creates a new Quad object with the top-left corner specified by the x and y parameters and with the specified width and height parameters. If you call this function without parameters, a rectangle with x, y, width, and height properties set to 0 is created. * @class Quad * @constructor * @param {Number} x The x coordinate of the top-left corner of the quad. * @param {Number} y The y coordinate of the top-left corner of the quad. * @param {Number} width The width of the quad. * @param {Number} height The height of the quad. * @return {Quad } This object **/ function Quad(x, y, width, height) { if (typeof x === "undefined") { x = 0; } if (typeof y === "undefined") { y = 0; } if (typeof width === "undefined") { width = 0; } if (typeof height === "undefined") { height = 0; } this.setTo(x, y, width, height); } Quad.prototype.setTo = /** * Sets the Quad to the specified size. * @method setTo * @param {Number} x The x coordinate of the top-left corner of the quad. * @param {Number} y The y coordinate of the top-left corner of the quad. * @param {Number} width The width of the quad. * @param {Number} height The height of the quad. * @return {Quad} This object **/ function (x, y, width, height) { this.x = x; this.y = y; this.width = width; this.height = height; return this; }; Object.defineProperty(Quad.prototype, "left", { get: function () { return this.x; }, enumerable: true, configurable: true }); Object.defineProperty(Quad.prototype, "right", { get: function () { return this.x + this.width; }, enumerable: true, configurable: true }); Object.defineProperty(Quad.prototype, "top", { get: function () { return this.y; }, enumerable: true, configurable: true }); Object.defineProperty(Quad.prototype, "bottom", { get: function () { return this.y + this.height; }, enumerable: true, configurable: true }); Object.defineProperty(Quad.prototype, "halfWidth", { get: function () { return this.width / 2; }, enumerable: true, configurable: true }); Object.defineProperty(Quad.prototype, "halfHeight", { get: function () { return this.height / 2; }, enumerable: true, configurable: true }); Quad.prototype.intersects = /** * Determines whether the object specified intersects (overlaps) with this Quad object. * This method checks the x, y, width, and height properties of the specified Quad object to see if it intersects with this Quad object. * @method intersects * @param {Object} q The object to check for intersection with this Quad. Must have left/right/top/bottom properties (Rectangle, Quad). * @param {Number} t A tolerance value to allow for an intersection test with padding, default to 0 * @return {Boolean} A value of true if the specified object intersects with this Quad; otherwise false. **/ function (q, t) { if (typeof t === "undefined") { t = 0; } return !(q.left > this.right + t || q.right < this.left - t || q.top > this.bottom + t || q.bottom < this.top - t); }; Quad.prototype.toString = /** * Returns a string representation of this object. * @method toString * @return {string} a string representation of the object. **/ function () { return "[{Quad (x=" + this.x + " y=" + this.y + " width=" + this.width + " height=" + this.height + ")}]"; }; return Quad; })(); Phaser.Quad = Quad; })(Phaser || (Phaser = {})); /// /** * Phaser - Circle * * A Circle object is an area defined by its position, as indicated by its center point (x,y) and diameter. */ var Phaser; (function (Phaser) { var Circle = (function () { /** * Creates a new Circle object with the center coordinate specified by the x and y parameters and the diameter specified by the diameter parameter. If you call this function without parameters, a circle with x, y, diameter and radius properties set to 0 is created. * @class Circle * @constructor * @param {Number} x The x coordinate of the center of the circle. * @param {Number} y The y coordinate of the center of the circle. * @return {Circle} This circle object **/ function Circle(x, y, diameter) { if (typeof x === "undefined") { x = 0; } if (typeof y === "undefined") { y = 0; } if (typeof diameter === "undefined") { diameter = 0; } this._diameter = 0; this._radius = 0; /** * The x coordinate of the center of the circle * @property x * @type Number **/ this.x = 0; /** * The y coordinate of the center of the circle * @property y * @type Number **/ this.y = 0; this.setTo(x, y, diameter); } Object.defineProperty(Circle.prototype, "diameter", { get: /** * The diameter of the circle. The largest distance between any two points on the circle. The same as the radius * 2. * @method diameter * @return {Number} **/ function () { return this._diameter; }, set: /** * The diameter of the circle. The largest distance between any two points on the circle. The same as the radius * 2. * @method diameter * @param {Number} The diameter of the circle. **/ function (value) { if(value > 0) { this._diameter = value; this._radius = value * 0.5; } }, enumerable: true, configurable: true }); Object.defineProperty(Circle.prototype, "radius", { get: /** * The radius of the circle. The length of a line extending from the center of the circle to any point on the circle itself. The same as half the diameter. * @method radius * @return {Number} **/ function () { return this._radius; }, set: /** * The radius of the circle. The length of a line extending from the center of the circle to any point on the circle itself. The same as half the diameter. * @method radius * @param {Number} The radius of the circle. **/ function (value) { if(value > 0) { this._radius = value; this._diameter = value * 2; } }, enumerable: true, configurable: true }); Circle.prototype.circumference = /** * The circumference of the circle. * @method circumference * @return {Number} **/ function () { return 2 * (Math.PI * this._radius); }; Object.defineProperty(Circle.prototype, "bottom", { get: /** * The sum of the y and radius properties. Changing the bottom property of a Circle object has no effect on the x and y properties, but does change the diameter. * @method bottom * @return {Number} **/ function () { return this.y + this._radius; }, set: /** * The sum of the y and radius properties. Changing the bottom property of a Circle object has no effect on the x and y properties, but does change the diameter. * @method bottom * @param {Number} The value to adjust the height of the circle by. **/ function (value) { if(!isNaN(value)) { if(value < this.y) { this._radius = 0; this._diameter = 0; } else { this.radius = value - this.y; } } }, enumerable: true, configurable: true }); Object.defineProperty(Circle.prototype, "left", { get: /** * The x coordinate of the leftmost point of the circle. Changing the left property of a Circle object has no effect on the x and y properties. However it does affect the diameter, whereas changing the x value does not affect the diameter property. * @method left * @return {Number} The x coordinate of the leftmost point of the circle. **/ function () { return this.x - this._radius; }, set: /** * The x coordinate of the leftmost point of the circle. Changing the left property of a Circle object has no effect on the x and y properties. However it does affect the diameter, whereas changing the x value does not affect the diameter property. * @method left * @param {Number} The value to adjust the position of the leftmost point of the circle by. **/ function (value) { if(!isNaN(value)) { if(value < this.x) { this.radius = this.x - value; } else { this._radius = 0; this._diameter = 0; } } }, enumerable: true, configurable: true }); Object.defineProperty(Circle.prototype, "right", { get: /** * The x coordinate of the rightmost point of the circle. Changing the right property of a Circle object has no effect on the x and y properties. However it does affect the diameter, whereas changing the x value does not affect the diameter property. * @method right * @return {Number} **/ function () { return this.x + this._radius; }, set: /** * The x coordinate of the rightmost point of the circle. Changing the right property of a Circle object has no effect on the x and y properties. However it does affect the diameter, whereas changing the x value does not affect the diameter property. * @method right * @param {Number} The amount to adjust the diameter of the circle by. **/ function (value) { if(!isNaN(value)) { if(value > this.x) { this.radius = value - this.x; } else { this._radius = 0; this._diameter = 0; } } }, enumerable: true, configurable: true }); Object.defineProperty(Circle.prototype, "top", { get: /** * The sum of the y minus the radius property. Changing the top property of a Circle object has no effect on the x and y properties, but does change the diameter. * @method bottom * @return {Number} **/ function () { return this.y - this._radius; }, set: /** * The sum of the y minus the radius property. Changing the top property of a Circle object has no effect on the x and y properties, but does change the diameter. * @method bottom * @param {Number} The amount to adjust the height of the circle by. **/ function (value) { if(!isNaN(value)) { if(value > this.y) { this._radius = 0; this._diameter = 0; } else { this.radius = this.y - value; } } }, enumerable: true, configurable: true }); Object.defineProperty(Circle.prototype, "area", { get: /** * Gets the area of this Circle. * @method area * @return {Number} This area of this circle. **/ function () { if(this._radius > 0) { return Math.PI * this._radius * this._radius; } else { return 0; } }, enumerable: true, configurable: true }); Object.defineProperty(Circle.prototype, "isEmpty", { get: /** * Determines whether or not this Circle object is empty. * @method isEmpty * @return {Boolean} A value of true if the Circle objects diameter is less than or equal to 0; otherwise false. **/ function () { if(this._diameter <= 0) { return true; } return false; }, enumerable: true, configurable: true }); Circle.prototype.intersectCircleLine = /** * Whether the circle intersects with a line. Checks against infinite line defined by the two points on the line, not the line segment. * If you need details about the intersection then use Collision.lineToCircle instead. * @method intersectCircleLine * @param {Object} the line object to check. * @return {Boolean} **/ function (line) { return Phaser.Collision.lineToCircle(line, this).result; }; Circle.prototype.clone = /** * Returns a new Circle object with the same values for the x, y, width, and height properties as the original Circle object. * @method clone * @param {Circle} output Optional Circle object. If given the values will be set into the object, otherwise a brand new Circle object will be created and returned. * @return {Phaser.Circle} **/ function (output) { if (typeof output === "undefined") { output = new Circle(); } return output.setTo(this.x, this.y, this._diameter); }; Circle.prototype.contains = /** * Return true if the given x/y coordinates are within this Circle object. * If you need details about the intersection then use Phaser.Intersect.circleContainsPoint instead. * @method contains * @param {Number} The X value of the coordinate to test. * @param {Number} The Y value of the coordinate to test. * @return {Boolean} True if the coordinates are within this circle, otherwise false. **/ function (x, y) { return Phaser.Collision.circleContainsPoint(this, { x: x, y: y }).result; }; Circle.prototype.containsPoint = /** * Return true if the coordinates of the given Point object are within this Circle object. * If you need details about the intersection then use Phaser.Intersect.circleContainsPoint instead. * @method containsPoint * @param {Phaser.Point} The Point object to test. * @return {Boolean} True if the coordinates are within this circle, otherwise false. **/ function (point) { return Phaser.Collision.circleContainsPoint(this, point).result; }; Circle.prototype.containsCircle = /** * Return true if the given Circle is contained entirely within this Circle object. * If you need details about the intersection then use Phaser.Intersect.circleToCircle instead. * @method containsCircle * @param {Phaser.Circle} The Circle object to test. * @return {Boolean} True if the coordinates are within this circle, otherwise false. **/ function (circle) { return Phaser.Collision.circleToCircle(this, circle).result; }; Circle.prototype.copyFrom = /** * Copies all of circle data from the source Circle object into the calling Circle object. * @method copyFrom * @param {Circle} rect The source circle object to copy from * @return {Circle} This circle object **/ function (source) { return this.setTo(source.x, source.y, source.diameter); }; Circle.prototype.copyTo = /** * Copies all of circle data from this Circle object into the destination Circle object. * @method copyTo * @param {Circle} circle The destination circle object to copy in to * @return {Circle} The destination circle object **/ function (target) { return target.copyFrom(this); }; Circle.prototype.distanceTo = /** * Returns the distance from the center of this Circle object to the given object (can be Circle, Point or anything with x/y values) * @method distanceFrom * @param {Circle/Point} target - The destination Point object. * @param {Boolean} round - Round the distance to the nearest integer (default false) * @return {Number} The distance between this Point object and the destination Point object. **/ function (target, round) { if (typeof round === "undefined") { round = false; } var dx = this.x - target.x; var dy = this.y - target.y; if(round === true) { return Math.round(Math.sqrt(dx * dx + dy * dy)); } else { return Math.sqrt(dx * dx + dy * dy); } }; Circle.prototype.equals = /** * Determines whether the object specified in the toCompare parameter is equal to this Circle object. This method compares the x, y and diameter properties of an object against the same properties of this Circle object. * @method equals * @param {Circle} toCompare The circle to compare to this Circle object. * @return {Boolean} A value of true if the object has exactly the same values for the x, y and diameter properties as this Circle object; otherwise false. **/ function (toCompare) { if(this.x === toCompare.x && this.y === toCompare.y && this.diameter === toCompare.diameter) { return true; } return false; }; Circle.prototype.intersects = /** * Determines whether the Circle object specified in the toIntersect parameter intersects with this Circle object. This method checks the radius distances between the two Circle objects to see if they intersect. * @method intersects * @param {Circle} toIntersect The Circle object to compare against to see if it intersects with this Circle object. * @return {Boolean} A value of true if the specified object intersects with this Circle object; otherwise false. **/ function (toIntersect) { if(this.distanceTo(toIntersect, false) < (this._radius + toIntersect._radius)) { return true; } return false; }; Circle.prototype.circumferencePoint = /** * Returns a Point object containing the coordinates of a point on the circumference of this Circle based on the given angle. * @method circumferencePoint * @param {Number} The angle in radians (unless asDegrees is true) to return the point from. * @param {Boolean} Is the given angle in radians (false) or degrees (true)? * @param {Phaser.Point} An optional Point object to put the result in to. If none specified a new Point object will be created. * @return {Phaser.Point} The Point object holding the result. **/ function (angle, asDegrees, output) { if (typeof asDegrees === "undefined") { asDegrees = false; } if (typeof output === "undefined") { output = new Phaser.Point(); } if(asDegrees === true) { angle = angle * Phaser.GameMath.DEG_TO_RAD; } output.x = this.x + this._radius * Math.cos(angle); output.y = this.y + this._radius * Math.sin(angle); return output; }; Circle.prototype.offset = /** * Adjusts the location of the Circle object, as determined by its center coordinate, by the specified amounts. * @method offset * @param {Number} dx Moves the x value of the Circle object by this amount. * @param {Number} dy Moves the y value of the Circle object by this amount. * @return {Circle} This Circle object. **/ function (dx, dy) { if(!isNaN(dx) && !isNaN(dy)) { this.x += dx; this.y += dy; } return this; }; Circle.prototype.offsetPoint = /** * Adjusts the location of the Circle object using a Point object as a parameter. This method is similar to the Circle.offset() method, except that it takes a Point object as a parameter. * @method offsetPoint * @param {Point} point A Point object to use to offset this Circle object. * @return {Circle} This Circle object. **/ function (point) { return this.offset(point.x, point.y); }; Circle.prototype.setTo = /** * Sets the members of Circle to the specified values. * @method setTo * @param {Number} x The x coordinate of the center of the circle. * @param {Number} y The y coordinate of the center of the circle. * @param {Number} diameter The diameter of the circle in pixels. * @return {Circle} This circle object **/ function (x, y, diameter) { this.x = x; this.y = y; this._diameter = diameter; this._radius = diameter * 0.5; return this; }; Circle.prototype.toString = /** * Returns a string representation of this object. * @method toString * @return {string} a string representation of the instance. **/ function () { return "[{Circle (x=" + this.x + " y=" + this.y + " diameter=" + this.diameter + " radius=" + this.radius + ")}]"; }; return Circle; })(); Phaser.Circle = Circle; })(Phaser || (Phaser = {})); /// /** * Phaser - Line * * A Line object is an infinte line through space. The two sets of x/y coordinates define the Line Segment. */ var Phaser; (function (Phaser) { var Line = (function () { /** * * @constructor * @param {Number} x1 * @param {Number} y1 * @param {Number} x2 * @param {Number} y2 * @return {Phaser.Line} This Object */ function Line(x1, y1, x2, y2) { if (typeof x1 === "undefined") { x1 = 0; } if (typeof y1 === "undefined") { y1 = 0; } if (typeof x2 === "undefined") { x2 = 0; } if (typeof y2 === "undefined") { y2 = 0; } /** * * @property x1 * @type Number */ this.x1 = 0; /** * * @property y1 * @type Number */ this.y1 = 0; /** * * @property x2 * @type Number */ this.x2 = 0; /** * * @property y2 * @type Number */ this.y2 = 0; this.setTo(x1, y1, x2, y2); } Line.prototype.clone = /** * * @method clone * @param {Phaser.Line} [output] * @return {Phaser.Line} */ function (output) { if (typeof output === "undefined") { output = new Line(); } return output.setTo(this.x1, this.y1, this.x2, this.y2); }; Line.prototype.copyFrom = /** * * @method copyFrom * @param {Phaser.Line} source * @return {Phaser.Line} */ function (source) { return this.setTo(source.x1, source.y1, source.x2, source.y2); }; Line.prototype.copyTo = /** * * @method copyTo * @param {Phaser.Line} target * @return {Phaser.Line} */ function (target) { return target.copyFrom(this); }; Line.prototype.setTo = /** * * @method setTo * @param {Number} x1 * @param {Number} y1 * @param {Number} x2 * @param {Number} y2 * @return {Phaser.Line} */ function (x1, y1, x2, y2) { if (typeof x1 === "undefined") { x1 = 0; } if (typeof y1 === "undefined") { y1 = 0; } if (typeof x2 === "undefined") { x2 = 0; } if (typeof y2 === "undefined") { y2 = 0; } this.x1 = x1; this.y1 = y1; this.x2 = x2; this.y2 = y2; return this; }; Object.defineProperty(Line.prototype, "width", { get: function () { return Math.max(this.x1, this.x2) - Math.min(this.x1, this.x2); }, enumerable: true, configurable: true }); Object.defineProperty(Line.prototype, "height", { get: function () { return Math.max(this.y1, this.y2) - Math.min(this.y1, this.y2); }, enumerable: true, configurable: true }); Object.defineProperty(Line.prototype, "length", { get: /** * * @method length * @return {Number} */ function () { return Math.sqrt((this.x2 - this.x1) * (this.x2 - this.x1) + (this.y2 - this.y1) * (this.y2 - this.y1)); }, enumerable: true, configurable: true }); Line.prototype.getY = /** * * @method getY * @param {Number} x * @return {Number} */ function (x) { return this.slope * x + this.yIntercept; }; Object.defineProperty(Line.prototype, "angle", { get: /** * * @method angle * @return {Number} */ function () { return Math.atan2(this.x2 - this.x1, this.y2 - this.y1); }, enumerable: true, configurable: true }); Object.defineProperty(Line.prototype, "slope", { get: /** * * @method slope * @return {Number} */ function () { return (this.y2 - this.y1) / (this.x2 - this.x1); }, enumerable: true, configurable: true }); Object.defineProperty(Line.prototype, "perpSlope", { get: /** * * @method perpSlope * @return {Number} */ function () { return -((this.x2 - this.x1) / (this.y2 - this.y1)); }, enumerable: true, configurable: true }); Object.defineProperty(Line.prototype, "yIntercept", { get: /** * * @method yIntercept * @return {Number} */ function () { return (this.y1 - this.slope * this.x1); }, enumerable: true, configurable: true }); Line.prototype.isPointOnLine = /** * * @method isPointOnLine * @param {Number} x * @param {Number} y * @return {Boolean} */ function (x, y) { if((x - this.x1) * (this.y2 - this.y1) === (this.x2 - this.x1) * (y - this.y1)) { return true; } else { return false; } }; Line.prototype.isPointOnLineSegment = /** * * @method isPointOnLineSegment * @param {Number} x * @param {Number} y * @return {Boolean} */ function (x, y) { var xMin = Math.min(this.x1, this.x2); var xMax = Math.max(this.x1, this.x2); var yMin = Math.min(this.y1, this.y2); var yMax = Math.max(this.y1, this.y2); if(this.isPointOnLine(x, y) && (x >= xMin && x <= xMax) && (y >= yMin && y <= yMax)) { return true; } else { return false; } }; Line.prototype.intersectLineLine = /** * * @method intersectLineLine * @param {Any} line * @return {Any} */ function (line) { //return Phaser.intersectLineLine(this,line); }; Line.prototype.perp = /** * * @method perp * @param {Number} x * @param {Number} y * @param {Phaser.Line} [output] * @return {Phaser.Line} */ function (x, y, output) { if(this.y1 === this.y2) { if(output) { output.setTo(x, y, x, this.y1); } else { return new Line(x, y, x, this.y1); } } var yInt = (y - this.perpSlope * x); var pt = this.intersectLineLine({ x1: x, y1: y, x2: 0, y2: yInt }); if(output) { output.setTo(x, y, pt.x, pt.y); } else { return new Line(x, y, pt.x, pt.y); } }; Line.prototype.toString = /* intersectLineCircle (circle:Circle) { var perp = this.perp() return Phaser.intersectLineCircle(this,circle); } */ /** * * @method toString * @return {String} */ function () { return "[{Line (x1=" + this.x1 + " y1=" + this.y1 + " x2=" + this.x2 + " y2=" + this.y2 + ")}]"; }; return Line; })(); Phaser.Line = Line; })(Phaser || (Phaser = {})); /// /** * Phaser - IntersectResult * * A light-weight result object to hold the results of an intersection. For when you need more than just true/false. */ var Phaser; (function (Phaser) { var IntersectResult = (function () { function IntersectResult() { /** * Did they intersect or not? * @property result * @type Boolean */ this.result = false; } IntersectResult.prototype.setTo = /** * * @method setTo * @param {Number} x1 * @param {Number} y1 * @param {Number} [x2] * @param {Number} [y2] * @param {Number} [width] * @param {Number} [height] */ function (x1, y1, x2, y2, width, height) { if (typeof x2 === "undefined") { x2 = 0; } if (typeof y2 === "undefined") { y2 = 0; } if (typeof width === "undefined") { width = 0; } if (typeof height === "undefined") { height = 0; } this.x = x1; this.y = y1; this.x1 = x1; this.y1 = y1; this.x2 = x2; this.y2 = y2; this.width = width; this.height = height; }; return IntersectResult; })(); Phaser.IntersectResult = IntersectResult; })(Phaser || (Phaser = {})); /// /** * Phaser - LinkedList * * A miniature linked list class. Useful for optimizing time-critical or highly repetitive tasks! */ var Phaser; (function (Phaser) { var LinkedList = (function () { /** * Creates a new link, and sets object and next to null. */ function LinkedList() { this.object = null; this.next = null; } LinkedList.prototype.destroy = /** * Clean up memory. */ function () { this.object = null; if(this.next != null) { this.next.destroy(); } this.next = null; }; return LinkedList; })(); Phaser.LinkedList = LinkedList; })(Phaser || (Phaser = {})); /// /// /** * Phaser - QuadTree * * A fairly generic quad tree structure for rapid overlap checks. QuadTree is also configured for single or dual list operation. * You can add items either to its A list or its B list. When you do an overlap check, you can compare the A list to itself, * or the A list against the B list. Handy for different things! */ var Phaser; (function (Phaser) { var QuadTree = (function (_super) { __extends(QuadTree, _super); /** * Instantiate a new Quad Tree node. * * @param X The X-coordinate of the point in space. * @param Y The Y-coordinate of the point in space. * @param Width Desired width of this node. * @param Height Desired height of this node. * @param Parent The parent branch or node. Pass null to create a root. */ function QuadTree(X, Y, Width, Height, Parent) { if (typeof Parent === "undefined") { Parent = null; } _super.call(this, X, Y, Width, Height); //console.log('-------- QuadTree',X,Y,Width,Height); this._headA = this._tailA = new Phaser.LinkedList(); this._headB = this._tailB = new Phaser.LinkedList(); //Copy the parent's children (if there are any) if(Parent != null) { //console.log('Parent not null'); var iterator; var ot; if(Parent._headA.object != null) { iterator = Parent._headA; //console.log('iterator set to parent headA'); while(iterator != null) { if(this._tailA.object != null) { ot = this._tailA; this._tailA = new Phaser.LinkedList(); ot.next = this._tailA; } this._tailA.object = iterator.object; iterator = iterator.next; } } if(Parent._headB.object != null) { iterator = Parent._headB; //console.log('iterator set to parent headB'); while(iterator != null) { if(this._tailB.object != null) { ot = this._tailB; this._tailB = new Phaser.LinkedList(); ot.next = this._tailB; } this._tailB.object = iterator.object; iterator = iterator.next; } } } else { QuadTree._min = (this.width + this.height) / (2 * QuadTree.divisions); } this._canSubdivide = (this.width > QuadTree._min) || (this.height > QuadTree._min); //console.log('canSubdivided', this._canSubdivide); //Set up comparison/sort helpers this._northWestTree = null; this._northEastTree = null; this._southEastTree = null; this._southWestTree = null; this._leftEdge = this.x; this._rightEdge = this.x + this.width; this._halfWidth = this.width / 2; this._midpointX = this._leftEdge + this._halfWidth; this._topEdge = this.y; this._bottomEdge = this.y + this.height; this._halfHeight = this.height / 2; this._midpointY = this._topEdge + this._halfHeight; } QuadTree.A_LIST = 0; QuadTree.B_LIST = 1; QuadTree.prototype.destroy = /** * Clean up memory. */ function () { this._tailA.destroy(); this._tailB.destroy(); this._headA.destroy(); this._headB.destroy(); this._tailA = null; this._tailB = null; this._headA = null; this._headB = null; if(this._northWestTree != null) { this._northWestTree.destroy(); } if(this._northEastTree != null) { this._northEastTree.destroy(); } if(this._southEastTree != null) { this._southEastTree.destroy(); } if(this._southWestTree != null) { this._southWestTree.destroy(); } this._northWestTree = null; this._northEastTree = null; this._southEastTree = null; this._southWestTree = null; QuadTree._object = null; QuadTree._processingCallback = null; QuadTree._notifyCallback = null; }; QuadTree.prototype.load = /** * Load objects and/or groups into the quad tree, and register notify and processing callbacks. * * @param ObjectOrGroup1 Any object that is or extends GameObject or Group. * @param ObjectOrGroup2 Any object that is or extends GameObject or Group. If null, the first parameter will be checked against itself. * @param NotifyCallback A function with the form myFunction(Object1:GameObject,Object2:GameObject) that is called whenever two objects are found to overlap in world space, and either no ProcessCallback is specified, or the ProcessCallback returns true. * @param ProcessCallback A function with the form myFunction(Object1:GameObject,Object2:GameObject):bool that is called whenever two objects are found to overlap in world space. The NotifyCallback is only called if this function returns true. See GameObject.separate(). */ function (ObjectOrGroup1, ObjectOrGroup2, NotifyCallback, ProcessCallback) { if (typeof ObjectOrGroup2 === "undefined") { ObjectOrGroup2 = null; } if (typeof NotifyCallback === "undefined") { NotifyCallback = null; } if (typeof ProcessCallback === "undefined") { ProcessCallback = null; } //console.log('quadtree load', QuadTree.divisions, ObjectOrGroup1, ObjectOrGroup2); this.add(ObjectOrGroup1, QuadTree.A_LIST); if(ObjectOrGroup2 != null) { this.add(ObjectOrGroup2, QuadTree.B_LIST); QuadTree._useBothLists = true; } else { QuadTree._useBothLists = false; } QuadTree._notifyCallback = NotifyCallback; QuadTree._processingCallback = ProcessCallback; //console.log('use both', QuadTree._useBothLists); //console.log('------------ end of load'); }; QuadTree.prototype.add = /** * Call this function to add an object to the root of the tree. * This function will recursively add all group members, but * not the groups themselves. * * @param ObjectOrGroup GameObjects are just added, Groups are recursed and their applicable members added accordingly. * @param List A uint flag indicating the list to which you want to add the objects. Options are QuadTree.A_LIST and QuadTree.B_LIST. */ function (ObjectOrGroup, List) { QuadTree._list = List; if(ObjectOrGroup.isGroup == true) { var i = 0; var basic; var members = ObjectOrGroup['members']; var l = ObjectOrGroup['length']; while(i < l) { basic = members[i++]; if((basic != null) && basic.exists) { if(basic.isGroup) { this.add(basic, List); } else { QuadTree._object = basic; if(QuadTree._object.exists && QuadTree._object.allowCollisions) { QuadTree._objectLeftEdge = QuadTree._object.x; QuadTree._objectTopEdge = QuadTree._object.y; QuadTree._objectRightEdge = QuadTree._object.x + QuadTree._object.width; QuadTree._objectBottomEdge = QuadTree._object.y + QuadTree._object.height; this.addObject(); } } } } } else { QuadTree._object = ObjectOrGroup; //console.log('add - not group:', ObjectOrGroup.name); if(QuadTree._object.exists && QuadTree._object.allowCollisions) { QuadTree._objectLeftEdge = QuadTree._object.x; QuadTree._objectTopEdge = QuadTree._object.y; QuadTree._objectRightEdge = QuadTree._object.x + QuadTree._object.width; QuadTree._objectBottomEdge = QuadTree._object.y + QuadTree._object.height; //console.log('object properties', QuadTree._objectLeftEdge, QuadTree._objectTopEdge, QuadTree._objectRightEdge, QuadTree._objectBottomEdge); this.addObject(); } } }; QuadTree.prototype.addObject = /** * Internal function for recursively navigating and creating the tree * while adding objects to the appropriate nodes. */ function () { //console.log('addObject'); //If this quad (not its children) lies entirely inside this object, add it here if(!this._canSubdivide || ((this._leftEdge >= QuadTree._objectLeftEdge) && (this._rightEdge <= QuadTree._objectRightEdge) && (this._topEdge >= QuadTree._objectTopEdge) && (this._bottomEdge <= QuadTree._objectBottomEdge))) { //console.log('add To List'); this.addToList(); return; } //See if the selected object fits completely inside any of the quadrants if((QuadTree._objectLeftEdge > this._leftEdge) && (QuadTree._objectRightEdge < this._midpointX)) { if((QuadTree._objectTopEdge > this._topEdge) && (QuadTree._objectBottomEdge < this._midpointY)) { //console.log('Adding NW tree'); if(this._northWestTree == null) { this._northWestTree = new QuadTree(this._leftEdge, this._topEdge, this._halfWidth, this._halfHeight, this); } this._northWestTree.addObject(); return; } if((QuadTree._objectTopEdge > this._midpointY) && (QuadTree._objectBottomEdge < this._bottomEdge)) { //console.log('Adding SW tree'); if(this._southWestTree == null) { this._southWestTree = new QuadTree(this._leftEdge, this._midpointY, this._halfWidth, this._halfHeight, this); } this._southWestTree.addObject(); return; } } if((QuadTree._objectLeftEdge > this._midpointX) && (QuadTree._objectRightEdge < this._rightEdge)) { if((QuadTree._objectTopEdge > this._topEdge) && (QuadTree._objectBottomEdge < this._midpointY)) { //console.log('Adding NE tree'); if(this._northEastTree == null) { this._northEastTree = new QuadTree(this._midpointX, this._topEdge, this._halfWidth, this._halfHeight, this); } this._northEastTree.addObject(); return; } if((QuadTree._objectTopEdge > this._midpointY) && (QuadTree._objectBottomEdge < this._bottomEdge)) { //console.log('Adding SE tree'); if(this._southEastTree == null) { this._southEastTree = new QuadTree(this._midpointX, this._midpointY, this._halfWidth, this._halfHeight, this); } this._southEastTree.addObject(); return; } } //If it wasn't completely contained we have to check out the partial overlaps if((QuadTree._objectRightEdge > this._leftEdge) && (QuadTree._objectLeftEdge < this._midpointX) && (QuadTree._objectBottomEdge > this._topEdge) && (QuadTree._objectTopEdge < this._midpointY)) { if(this._northWestTree == null) { this._northWestTree = new QuadTree(this._leftEdge, this._topEdge, this._halfWidth, this._halfHeight, this); } //console.log('added to north west partial tree'); this._northWestTree.addObject(); } if((QuadTree._objectRightEdge > this._midpointX) && (QuadTree._objectLeftEdge < this._rightEdge) && (QuadTree._objectBottomEdge > this._topEdge) && (QuadTree._objectTopEdge < this._midpointY)) { if(this._northEastTree == null) { this._northEastTree = new QuadTree(this._midpointX, this._topEdge, this._halfWidth, this._halfHeight, this); } //console.log('added to north east partial tree'); this._northEastTree.addObject(); } if((QuadTree._objectRightEdge > this._midpointX) && (QuadTree._objectLeftEdge < this._rightEdge) && (QuadTree._objectBottomEdge > this._midpointY) && (QuadTree._objectTopEdge < this._bottomEdge)) { if(this._southEastTree == null) { this._southEastTree = new QuadTree(this._midpointX, this._midpointY, this._halfWidth, this._halfHeight, this); } //console.log('added to south east partial tree'); this._southEastTree.addObject(); } if((QuadTree._objectRightEdge > this._leftEdge) && (QuadTree._objectLeftEdge < this._midpointX) && (QuadTree._objectBottomEdge > this._midpointY) && (QuadTree._objectTopEdge < this._bottomEdge)) { if(this._southWestTree == null) { this._southWestTree = new QuadTree(this._leftEdge, this._midpointY, this._halfWidth, this._halfHeight, this); } //console.log('added to south west partial tree'); this._southWestTree.addObject(); } }; QuadTree.prototype.addToList = /** * Internal function for recursively adding objects to leaf lists. */ function () { //console.log('Adding to List'); var ot; if(QuadTree._list == QuadTree.A_LIST) { //console.log('A LIST'); if(this._tailA.object != null) { ot = this._tailA; this._tailA = new Phaser.LinkedList(); ot.next = this._tailA; } this._tailA.object = QuadTree._object; } else { //console.log('B LIST'); if(this._tailB.object != null) { ot = this._tailB; this._tailB = new Phaser.LinkedList(); ot.next = this._tailB; } this._tailB.object = QuadTree._object; } if(!this._canSubdivide) { return; } if(this._northWestTree != null) { this._northWestTree.addToList(); } if(this._northEastTree != null) { this._northEastTree.addToList(); } if(this._southEastTree != null) { this._southEastTree.addToList(); } if(this._southWestTree != null) { this._southWestTree.addToList(); } }; QuadTree.prototype.execute = /** * QuadTree's other main function. Call this after adding objects * using QuadTree.load() to compare the objects that you loaded. * * @return Whether or not any overlaps were found. */ function () { //console.log('quadtree execute'); var overlapProcessed = false; var iterator; if(this._headA.object != null) { //console.log('---------------------------------------------------'); //console.log('headA iterator'); iterator = this._headA; while(iterator != null) { QuadTree._object = iterator.object; if(QuadTree._useBothLists) { QuadTree._iterator = this._headB; } else { QuadTree._iterator = iterator.next; } if(QuadTree._object.exists && (QuadTree._object.allowCollisions > 0) && (QuadTree._iterator != null) && (QuadTree._iterator.object != null) && QuadTree._iterator.object.exists && this.overlapNode()) { //console.log('headA iterator overlapped true'); overlapProcessed = true; } iterator = iterator.next; } } //Advance through the tree by calling overlap on each child if((this._northWestTree != null) && this._northWestTree.execute()) { //console.log('NW quadtree execute'); overlapProcessed = true; } if((this._northEastTree != null) && this._northEastTree.execute()) { //console.log('NE quadtree execute'); overlapProcessed = true; } if((this._southEastTree != null) && this._southEastTree.execute()) { //console.log('SE quadtree execute'); overlapProcessed = true; } if((this._southWestTree != null) && this._southWestTree.execute()) { //console.log('SW quadtree execute'); overlapProcessed = true; } return overlapProcessed; }; QuadTree.prototype.overlapNode = /** * An private for comparing an object against the contents of a node. * * @return Whether or not any overlaps were found. */ function () { //Walk the list and check for overlaps var overlapProcessed = false; var checkObject; while(QuadTree._iterator != null) { if(!QuadTree._object.exists || (QuadTree._object.allowCollisions <= 0)) { //console.log('break 1'); break; } checkObject = QuadTree._iterator.object; if((QuadTree._object === checkObject) || !checkObject.exists || (checkObject.allowCollisions <= 0)) { //console.log('break 2'); QuadTree._iterator = QuadTree._iterator.next; continue; } //calculate bulk hull for QuadTree._object QuadTree._objectHullX = (QuadTree._object.x < QuadTree._object.last.x) ? QuadTree._object.x : QuadTree._object.last.x; QuadTree._objectHullY = (QuadTree._object.y < QuadTree._object.last.y) ? QuadTree._object.y : QuadTree._object.last.y; QuadTree._objectHullWidth = QuadTree._object.x - QuadTree._object.last.x; QuadTree._objectHullWidth = QuadTree._object.width + ((QuadTree._objectHullWidth > 0) ? QuadTree._objectHullWidth : -QuadTree._objectHullWidth); QuadTree._objectHullHeight = QuadTree._object.y - QuadTree._object.last.y; QuadTree._objectHullHeight = QuadTree._object.height + ((QuadTree._objectHullHeight > 0) ? QuadTree._objectHullHeight : -QuadTree._objectHullHeight); //calculate bulk hull for checkObject QuadTree._checkObjectHullX = (checkObject.x < checkObject.last.x) ? checkObject.x : checkObject.last.x; QuadTree._checkObjectHullY = (checkObject.y < checkObject.last.y) ? checkObject.y : checkObject.last.y; QuadTree._checkObjectHullWidth = checkObject.x - checkObject.last.x; QuadTree._checkObjectHullWidth = checkObject.width + ((QuadTree._checkObjectHullWidth > 0) ? QuadTree._checkObjectHullWidth : -QuadTree._checkObjectHullWidth); QuadTree._checkObjectHullHeight = checkObject.y - checkObject.last.y; QuadTree._checkObjectHullHeight = checkObject.height + ((QuadTree._checkObjectHullHeight > 0) ? QuadTree._checkObjectHullHeight : -QuadTree._checkObjectHullHeight); //check for intersection of the two hulls if((QuadTree._objectHullX + QuadTree._objectHullWidth > QuadTree._checkObjectHullX) && (QuadTree._objectHullX < QuadTree._checkObjectHullX + QuadTree._checkObjectHullWidth) && (QuadTree._objectHullY + QuadTree._objectHullHeight > QuadTree._checkObjectHullY) && (QuadTree._objectHullY < QuadTree._checkObjectHullY + QuadTree._checkObjectHullHeight)) { //console.log('intersection!'); //Execute callback functions if they exist if((QuadTree._processingCallback == null) || QuadTree._processingCallback(QuadTree._object, checkObject)) { overlapProcessed = true; } if(overlapProcessed && (QuadTree._notifyCallback != null)) { QuadTree._notifyCallback(QuadTree._object, checkObject); } } QuadTree._iterator = QuadTree._iterator.next; } return overlapProcessed; }; return QuadTree; })(Phaser.Rectangle); Phaser.QuadTree = QuadTree; })(Phaser || (Phaser = {})); /// /// /// /// /// /// /// /// /** * Phaser - Collision * * A set of extremely useful collision and geometry intersection functions. */ var Phaser; (function (Phaser) { var Collision = (function () { /** * Collision constructor * @param game A reference to the current Game */ function Collision(game) { this._game = game; } Collision.LEFT = 0x0001; Collision.RIGHT = 0x0010; Collision.UP = 0x0100; Collision.DOWN = 0x1000; Collision.NONE = 0; Collision.CEILING = Collision.UP; Collision.FLOOR = Collision.DOWN; Collision.WALL = Collision.LEFT | Collision.RIGHT; Collision.ANY = Collision.LEFT | Collision.RIGHT | Collision.UP | Collision.DOWN; Collision.OVERLAP_BIAS = 4; Collision.TILE_OVERLAP = false; Collision.lineToLine = /** * Checks for Line to Line intersection and returns an IntersectResult object containing the results of the intersection. * @param line1 The first Line object to check * @param line2 The second Line object to check * @param output An optional IntersectResult object to store the intersection values in. One is created if none given. * @returns {IntersectResult=} An IntersectResult object containing the results of the intersection */ function lineToLine(line1, line2, output) { if (typeof output === "undefined") { output = new Phaser.IntersectResult(); } var denominator = (line1.x1 - line1.x2) * (line2.y1 - line2.y2) - (line1.y1 - line1.y2) * (line2.x1 - line2.x2); if(denominator !== 0) { output.result = true; output.x = ((line1.x1 * line1.y2 - line1.y1 * line1.x2) * (line2.x1 - line2.x2) - (line1.x1 - line1.x2) * (line2.x1 * line2.y2 - line2.y1 * line2.x2)) / denominator; output.y = ((line1.x1 * line1.y2 - line1.y1 * line1.x2) * (line2.y1 - line2.y2) - (line1.y1 - line1.y2) * (line2.x1 * line2.y2 - line2.y1 * line2.x2)) / denominator; } return output; }; Collision.lineToLineSegment = /** * Checks for Line to Line Segment intersection and returns an IntersectResult object containing the results of the intersection. * @param line The Line object to check * @param seg The Line segment object to check * @param output An optional IntersectResult object to store the intersection values in. One is created if none given. * @returns {IntersectResult=} An IntersectResult object containing the results of the intersection */ function lineToLineSegment(line, seg, output) { if (typeof output === "undefined") { output = new Phaser.IntersectResult(); } var denominator = (line.x1 - line.x2) * (seg.y1 - seg.y2) - (line.y1 - line.y2) * (seg.x1 - seg.x2); if(denominator !== 0) { output.x = ((line.x1 * line.y2 - line.y1 * line.x2) * (seg.x1 - seg.x2) - (line.x1 - line.x2) * (seg.x1 * seg.y2 - seg.y1 * seg.x2)) / denominator; output.y = ((line.x1 * line.y2 - line.y1 * line.x2) * (seg.y1 - seg.y2) - (line.y1 - line.y2) * (seg.x1 * seg.y2 - seg.y1 * seg.x2)) / denominator; var maxX = Math.max(seg.x1, seg.x2); var minX = Math.min(seg.x1, seg.x2); var maxY = Math.max(seg.y1, seg.y2); var minY = Math.min(seg.y1, seg.y2); if((output.x <= maxX && output.x >= minX) === true || (output.y <= maxY && output.y >= minY) === true) { output.result = true; } } return output; }; Collision.lineToRawSegment = /** * Checks for Line to Raw Line Segment intersection and returns the result in the IntersectResult object. * @param line The Line object to check * @param x1 The start x coordinate of the raw segment * @param y1 The start y coordinate of the raw segment * @param x2 The end x coordinate of the raw segment * @param y2 The end y coordinate of the raw segment * @param output An optional IntersectResult object to store the intersection values in. One is created if none given. * @returns {IntersectResult=} An IntersectResult object containing the results of the intersection */ function lineToRawSegment(line, x1, y1, x2, y2, output) { if (typeof output === "undefined") { output = new Phaser.IntersectResult(); } var denominator = (line.x1 - line.x2) * (y1 - y2) - (line.y1 - line.y2) * (x1 - x2); if(denominator !== 0) { output.x = ((line.x1 * line.y2 - line.y1 * line.x2) * (x1 - x2) - (line.x1 - line.x2) * (x1 * y2 - y1 * x2)) / denominator; output.y = ((line.x1 * line.y2 - line.y1 * line.x2) * (y1 - y2) - (line.y1 - line.y2) * (x1 * y2 - y1 * x2)) / denominator; var maxX = Math.max(x1, x2); var minX = Math.min(x1, x2); var maxY = Math.max(y1, y2); var minY = Math.min(y1, y2); if((output.x <= maxX && output.x >= minX) === true || (output.y <= maxY && output.y >= minY) === true) { output.result = true; } } return output; }; Collision.lineToRay = /** * Checks for Line to Ray intersection and returns the result in an IntersectResult object. * @param line1 The Line object to check * @param ray The Ray object to check * @param output An optional IntersectResult object to store the intersection values in. One is created if none given. * @returns {IntersectResult=} An IntersectResult object containing the results of the intersection */ function lineToRay(line1, ray, output) { if (typeof output === "undefined") { output = new Phaser.IntersectResult(); } var denominator = (line1.x1 - line1.x2) * (ray.y1 - ray.y2) - (line1.y1 - line1.y2) * (ray.x1 - ray.x2); if(denominator !== 0) { output.x = ((line1.x1 * line1.y2 - line1.y1 * line1.x2) * (ray.x1 - ray.x2) - (line1.x1 - line1.x2) * (ray.x1 * ray.y2 - ray.y1 * ray.x2)) / denominator; output.y = ((line1.x1 * line1.y2 - line1.y1 * line1.x2) * (ray.y1 - ray.y2) - (line1.y1 - line1.y2) * (ray.x1 * ray.y2 - ray.y1 * ray.x2)) / denominator; output.result = true// true unless either of the 2 following conditions are met ; if(!(ray.x1 >= ray.x2) && output.x < ray.x1) { output.result = false; } if(!(ray.y1 >= ray.y2) && output.y < ray.y1) { output.result = false; } } return output; }; Collision.lineToCircle = /** * Check if the Line and Circle objects intersect * @param line The Line object to check * @param circle The Circle object to check * @param output An optional IntersectResult object to store the intersection values in. One is created if none given. * @returns {IntersectResult=} An IntersectResult object containing the results of the intersection */ function lineToCircle(line, circle, output) { if (typeof output === "undefined") { output = new Phaser.IntersectResult(); } // Get a perpendicular line running to the center of the circle if(line.perp(circle.x, circle.y).length <= circle.radius) { output.result = true; } return output; }; Collision.lineToRectangle = /** * Check if the Line intersects each side of the Rectangle * @param line The Line object to check * @param rect The Rectangle object to check * @param output An optional IntersectResult object to store the intersection values in. One is created if none given. * @returns {IntersectResult=} An IntersectResult object containing the results of the intersection */ function lineToRectangle(line, rect, output) { if (typeof output === "undefined") { output = new Phaser.IntersectResult(); } // Top of the Rectangle vs the Line Collision.lineToRawSegment(line, rect.x, rect.y, rect.right, rect.y, output); if(output.result === true) { return output; } // Left of the Rectangle vs the Line Collision.lineToRawSegment(line, rect.x, rect.y, rect.x, rect.bottom, output); if(output.result === true) { return output; } // Bottom of the Rectangle vs the Line Collision.lineToRawSegment(line, rect.x, rect.bottom, rect.right, rect.bottom, output); if(output.result === true) { return output; } // Right of the Rectangle vs the Line Collision.lineToRawSegment(line, rect.right, rect.y, rect.right, rect.bottom, output); return output; }; Collision.lineSegmentToLineSegment = /** * Check if the two Line Segments intersect and returns the result in an IntersectResult object. * @param line1 The first Line Segment to check * @param line2 The second Line Segment to check * @param output An optional IntersectResult object to store the intersection values in. One is created if none given. * @returns {IntersectResult=} An IntersectResult object containing the results of the intersection */ function lineSegmentToLineSegment(line1, line2, output) { if (typeof output === "undefined") { output = new Phaser.IntersectResult(); } Collision.lineToLineSegment(line1, line2); if(output.result === true) { if(!(output.x >= Math.min(line1.x1, line1.x2) && output.x <= Math.max(line1.x1, line1.x2) && output.y >= Math.min(line1.y1, line1.y2) && output.y <= Math.max(line1.y1, line1.y2))) { output.result = false; } } return output; }; Collision.lineSegmentToRay = /** * Check if the Line Segment intersects with the Ray and returns the result in an IntersectResult object. * @param line The Line Segment to check. * @param ray The Ray to check. * @param output An optional IntersectResult object to store the intersection values in. One is created if none given. * @returns {IntersectResult=} An IntersectResult object containing the results of the intersection */ function lineSegmentToRay(line, ray, output) { if (typeof output === "undefined") { output = new Phaser.IntersectResult(); } Collision.lineToRay(line, ray, output); if(output.result === true) { if(!(output.x >= Math.min(line.x1, line.x2) && output.x <= Math.max(line.x1, line.x2) && output.y >= Math.min(line.y1, line.y2) && output.y <= Math.max(line.y1, line.y2))) { output.result = false; } } return output; }; Collision.lineSegmentToCircle = /** * Check if the Line Segment intersects with the Circle and returns the result in an IntersectResult object. * @param seg The Line Segment to check. * @param circle The Circle to check * @param output An optional IntersectResult object to store the intersection values in. One is created if none given. * @returns {IntersectResult=} An IntersectResult object containing the results of the intersection */ function lineSegmentToCircle(seg, circle, output) { if (typeof output === "undefined") { output = new Phaser.IntersectResult(); } var perp = seg.perp(circle.x, circle.y); if(perp.length <= circle.radius) { // Line intersects circle - check if segment does var maxX = Math.max(seg.x1, seg.x2); var minX = Math.min(seg.x1, seg.x2); var maxY = Math.max(seg.y1, seg.y2); var minY = Math.min(seg.y1, seg.y2); if((perp.x2 <= maxX && perp.x2 >= minX) && (perp.y2 <= maxY && perp.y2 >= minY)) { output.result = true; } else { // Worst case - segment doesn't traverse center, so no perpendicular connection. if(Collision.circleContainsPoint(circle, { x: seg.x1, y: seg.y1 }) || Collision.circleContainsPoint(circle, { x: seg.x2, y: seg.y2 })) { output.result = true; } } } return output; }; Collision.lineSegmentToRectangle = /** * Check if the Line Segment intersects with the Rectangle and returns the result in an IntersectResult object. * @param seg The Line Segment to check. * @param rect The Rectangle to check. * @param output An optional IntersectResult object to store the intersection values in. One is created if none given. * @returns {IntersectResult=} An IntersectResult object containing the results of the intersection */ function lineSegmentToRectangle(seg, rect, output) { if (typeof output === "undefined") { output = new Phaser.IntersectResult(); } if(rect.contains(seg.x1, seg.y1) && rect.contains(seg.x2, seg.y2)) { output.result = true; } else { // Top of the Rectangle vs the Line Collision.lineToRawSegment(seg, rect.x, rect.y, rect.right, rect.bottom, output); if(output.result === true) { return output; } // Left of the Rectangle vs the Line Collision.lineToRawSegment(seg, rect.x, rect.y, rect.x, rect.bottom, output); if(output.result === true) { return output; } // Bottom of the Rectangle vs the Line Collision.lineToRawSegment(seg, rect.x, rect.bottom, rect.right, rect.bottom, output); if(output.result === true) { return output; } // Right of the Rectangle vs the Line Collision.lineToRawSegment(seg, rect.right, rect.y, rect.right, rect.bottom, output); return output; } return output; }; Collision.rayToRectangle = /** * Check for Ray to Rectangle intersection and returns the result in an IntersectResult object. * @param ray The Ray to check. * @param rect The Rectangle to check. * @param output An optional IntersectResult object to store the intersection values in. One is created if none given. * @returns {IntersectResult=} An IntersectResult object containing the results of the intersection */ function rayToRectangle(ray, rect, output) { if (typeof output === "undefined") { output = new Phaser.IntersectResult(); } // Currently just finds first intersection - might not be closest to ray pt1 Collision.lineToRectangle(ray, rect, output); return output; }; Collision.rayToLineSegment = /** * Check whether a Ray intersects a Line segment and returns the parametric value where the intersection occurs in an IntersectResult object. * @param rayX1 * @param rayY1 * @param rayX2 * @param rayY2 * @param lineX1 * @param lineY1 * @param lineX2 * @param lineY2 * @param output An optional IntersectResult object to store the intersection values in. One is created if none given. * @returns {IntersectResult=} An IntersectResult object containing the results of the intersection */ function rayToLineSegment(rayX1, rayY1, rayX2, rayY2, lineX1, lineY1, lineX2, lineY2, output) { if (typeof output === "undefined") { output = new Phaser.IntersectResult(); } var r; var s; var d; // Check lines are not parallel if((rayY2 - rayY1) / (rayX2 - rayX1) != (lineY2 - lineY1) / (lineX2 - lineX1)) { d = (((rayX2 - rayX1) * (lineY2 - lineY1)) - (rayY2 - rayY1) * (lineX2 - lineX1)); if(d != 0) { r = (((rayY1 - lineY1) * (lineX2 - lineX1)) - (rayX1 - lineX1) * (lineY2 - lineY1)) / d; s = (((rayY1 - lineY1) * (rayX2 - rayX1)) - (rayX1 - lineX1) * (rayY2 - rayY1)) / d; if(r >= 0) { if(s >= 0 && s <= 1) { output.result = true; output.x = rayX1 + r * (rayX2 - rayX1); output.y = rayY1 + r * (rayY2 - rayY1); } } } } return output; }; Collision.pointToRectangle = /** * Determines whether the specified point is contained within the rectangular region defined by the Rectangle object and returns the result in an IntersectResult object. * @param point The Point or MicroPoint object to check, or any object with x and y properties. * @param rect The Rectangle object to check the point against * @param output An optional IntersectResult object to store the intersection values in. One is created if none given. * @returns {IntersectResult=} An IntersectResult object containing the results of the intersection */ function pointToRectangle(point, rect, output) { if (typeof output === "undefined") { output = new Phaser.IntersectResult(); } output.setTo(point.x, point.y); output.result = rect.containsPoint(point); return output; }; Collision.rectangleToRectangle = /** * Check whether two axis aligned Rectangles intersect and returns the intersecting rectangle dimensions in an IntersectResult object if they do. * @param rect1 The first Rectangle object. * @param rect2 The second Rectangle object. * @param output An optional IntersectResult object to store the intersection values in. One is created if none given. * @returns {IntersectResult=} An IntersectResult object containing the results of the intersection */ function rectangleToRectangle(rect1, rect2, output) { if (typeof output === "undefined") { output = new Phaser.IntersectResult(); } var leftX = Math.max(rect1.x, rect2.x); var rightX = Math.min(rect1.right, rect2.right); var topY = Math.max(rect1.y, rect2.y); var bottomY = Math.min(rect1.bottom, rect2.bottom); output.setTo(leftX, topY, rightX - leftX, bottomY - topY, rightX - leftX, bottomY - topY); var cx = output.x + output.width * .5; var cy = output.y + output.height * .5; if((cx > rect1.x && cx < rect1.right) && (cy > rect1.y && cy < rect1.bottom)) { output.result = true; } return output; }; Collision.rectangleToCircle = /** * Checks if the Rectangle and Circle objects intersect and returns the result in an IntersectResult object. * @param rect The Rectangle object to check * @param circle The Circle object to check * @param output An optional IntersectResult object to store the intersection values in. One is created if none given. * @returns {IntersectResult=} An IntersectResult object containing the results of the intersection */ function rectangleToCircle(rect, circle, output) { if (typeof output === "undefined") { output = new Phaser.IntersectResult(); } return Collision.circleToRectangle(circle, rect, output); }; Collision.circleToCircle = /** * Checks if the two Circle objects intersect and returns the result in an IntersectResult object. * @param circle1 The first Circle object to check * @param circle2 The second Circle object to check * @param output An optional IntersectResult object to store the intersection values in. One is created if none given. * @returns {IntersectResult=} An IntersectResult object containing the results of the intersection */ function circleToCircle(circle1, circle2, output) { if (typeof output === "undefined") { output = new Phaser.IntersectResult(); } output.result = ((circle1.radius + circle2.radius) * (circle1.radius + circle2.radius)) >= Collision.distanceSquared(circle1.x, circle1.y, circle2.x, circle2.y); return output; }; Collision.circleToRectangle = /** * Checks if the Circle object intersects with the Rectangle and returns the result in an IntersectResult object. * @param circle The Circle object to check * @param rect The Rectangle object to check * @param output An optional IntersectResult object to store the intersection values in. One is created if none given. * @returns {IntersectResult=} An IntersectResult object containing the results of the intersection */ function circleToRectangle(circle, rect, output) { if (typeof output === "undefined") { output = new Phaser.IntersectResult(); } var inflatedRect = rect.clone(); inflatedRect.inflate(circle.radius, circle.radius); output.result = inflatedRect.contains(circle.x, circle.y); return output; }; Collision.circleContainsPoint = /** * Checks if the Point object is contained within the Circle and returns the result in an IntersectResult object. * @param circle The Circle object to check * @param point A Point or MicroPoint object to check, or any object with x and y properties * @param output An optional IntersectResult object to store the intersection values in. One is created if none given. * @returns {IntersectResult=} An IntersectResult object containing the results of the intersection */ function circleContainsPoint(circle, point, output) { if (typeof output === "undefined") { output = new Phaser.IntersectResult(); } output.result = circle.radius * circle.radius >= Collision.distanceSquared(circle.x, circle.y, point.x, point.y); return output; }; Collision.prototype.overlap = /** * Checks for overlaps between two objects using the world QuadTree. Can be GameObject vs. GameObject, GameObject vs. Group or Group vs. Group. * Note: Does not take the objects scrollFactor into account. All overlaps are check in world space. * @param object1 The first GameObject or Group to check. If null the world.group is used. * @param object2 The second GameObject or Group to check. * @param notifyCallback A callback function that is called if the objects overlap. The two objects will be passed to this function in the same order in which you passed them to Collision.overlap. * @param processCallback A callback function that lets you perform additional checks against the two objects if they overlap. If this is set then notifyCallback will only be called if processCallback returns true. * @returns {boolean} true if the objects overlap, otherwise false. */ function (object1, object2, notifyCallback, processCallback) { if (typeof object1 === "undefined") { object1 = null; } if (typeof object2 === "undefined") { object2 = null; } if (typeof notifyCallback === "undefined") { notifyCallback = null; } if (typeof processCallback === "undefined") { processCallback = null; } if(object1 == null) { object1 = this._game.world.group; } if(object2 == object1) { object2 = null; } Phaser.QuadTree.divisions = this._game.world.worldDivisions; var quadTree = new Phaser.QuadTree(this._game.world.bounds.x, this._game.world.bounds.y, this._game.world.bounds.width, this._game.world.bounds.height); quadTree.load(object1, object2, notifyCallback, processCallback); var result = quadTree.execute(); quadTree.destroy(); quadTree = null; return result; }; Collision.separate = /** * The core Collision separation function used by Collision.overlap. * @param object1 The first GameObject to separate * @param object2 The second GameObject to separate * @returns {boolean} Returns true if the objects were separated, otherwise false. */ function separate(object1, object2) { var separatedX = Collision.separateX(object1, object2); var separatedY = Collision.separateY(object1, object2); return separatedX || separatedY; }; Collision.separateTile = /** * Collision resolution specifically for GameObjects vs. Tiles. * @param object The GameObject to separate * @param tile The Tile to separate * @returns {boolean} Whether the objects in fact touched and were separated */ function separateTile(object, x, y, width, height, mass, collideLeft, collideRight, collideUp, collideDown) { var separatedX = Collision.separateTileX(object, x, y, width, height, mass, collideLeft, collideRight); var separatedY = Collision.separateTileY(object, x, y, width, height, mass, collideUp, collideDown); return separatedX || separatedY; }; Collision.separateTileX = /** * Separates the two objects on their x axis * @param object The GameObject to separate * @param tile The Tile to separate * @returns {boolean} Whether the objects in fact touched and were separated along the X axis. */ function separateTileX(object, x, y, width, height, mass, collideLeft, collideRight) { // Can't separate two immovable objects (tiles are always immovable) if(object.immovable) { return false; } // First, get the object delta var overlap = 0; var objDelta = object.x - object.last.x; if(objDelta != 0) { // Check if the X hulls actually overlap var objDeltaAbs = (objDelta > 0) ? objDelta : -objDelta; var objBounds = new Phaser.Quad(object.x - ((objDelta > 0) ? objDelta : 0), object.last.y, object.width + ((objDelta > 0) ? objDelta : -objDelta), object.height); if((objBounds.x + objBounds.width > x) && (objBounds.x < x + width) && (objBounds.y + objBounds.height > y) && (objBounds.y < y + height)) { var maxOverlap = objDeltaAbs + Collision.OVERLAP_BIAS; // If they did overlap (and can), figure out by how much and flip the corresponding flags if(objDelta > 0) { overlap = object.x + object.width - x; if((overlap > maxOverlap) || !(object.allowCollisions & Collision.RIGHT) || collideLeft == false) { overlap = 0; } else { object.touching |= Collision.RIGHT; } } else if(objDelta < 0) { overlap = object.x - width - x; if((-overlap > maxOverlap) || !(object.allowCollisions & Collision.LEFT) || collideRight == false) { overlap = 0; } else { object.touching |= Collision.LEFT; } } } } // Then adjust their positions and velocities accordingly (if there was any overlap) if(overlap != 0) { object.x = object.x - overlap; object.velocity.x = -(object.velocity.x * object.elasticity); Collision.TILE_OVERLAP = true; return true; } else { return false; } }; Collision.separateTileY = /** * Separates the two objects on their y axis * @param object The first GameObject to separate * @param tile The second GameObject to separate * @returns {boolean} Whether the objects in fact touched and were separated along the Y axis. */ function separateTileY(object, x, y, width, height, mass, collideUp, collideDown) { // Can't separate two immovable objects (tiles are always immovable) if(object.immovable) { return false; } // First, get the two object deltas var overlap = 0; var objDelta = object.y - object.last.y; if(objDelta != 0) { // Check if the Y hulls actually overlap var objDeltaAbs = (objDelta > 0) ? objDelta : -objDelta; var objBounds = new Phaser.Quad(object.x, object.y - ((objDelta > 0) ? objDelta : 0), object.width, object.height + objDeltaAbs); if((objBounds.x + objBounds.width > x) && (objBounds.x < x + width) && (objBounds.y + objBounds.height > y) && (objBounds.y < y + height)) { var maxOverlap = objDeltaAbs + Collision.OVERLAP_BIAS; // If they did overlap (and can), figure out by how much and flip the corresponding flags if(objDelta > 0) { overlap = object.y + object.height - y; if((overlap > maxOverlap) || !(object.allowCollisions & Collision.DOWN) || collideUp == false) { overlap = 0; } else { object.touching |= Collision.DOWN; } } else if(objDelta < 0) { overlap = object.y - height - y; if((-overlap > maxOverlap) || !(object.allowCollisions & Collision.UP) || collideDown == false) { overlap = 0; } else { object.touching |= Collision.UP; } } } } // TODO - with super low velocities you get lots of stuttering, set some kind of base minimum here // Then adjust their positions and velocities accordingly (if there was any overlap) if(overlap != 0) { object.y = object.y - overlap; object.velocity.y = -(object.velocity.y * object.elasticity); Collision.TILE_OVERLAP = true; return true; } else { return false; } }; Collision.separateX = /** * Separates the two objects on their x axis * @param object1 The first GameObject to separate * @param object2 The second GameObject to separate * @returns {boolean} Whether the objects in fact touched and were separated along the X axis. */ function separateX(object1, object2) { // Can't separate two immovable objects if(object1.immovable && object2.immovable) { return false; } // First, get the two object deltas var overlap = 0; var obj1Delta = object1.x - object1.last.x; var obj2Delta = object2.x - object2.last.x; if(obj1Delta != obj2Delta) { // Check if the X hulls actually overlap var obj1DeltaAbs = (obj1Delta > 0) ? obj1Delta : -obj1Delta; var obj2DeltaAbs = (obj2Delta > 0) ? obj2Delta : -obj2Delta; var obj1Bounds = new Phaser.Quad(object1.x - ((obj1Delta > 0) ? obj1Delta : 0), object1.last.y, object1.width + ((obj1Delta > 0) ? obj1Delta : -obj1Delta), object1.height); var obj2Bounds = new Phaser.Quad(object2.x - ((obj2Delta > 0) ? obj2Delta : 0), object2.last.y, object2.width + ((obj2Delta > 0) ? obj2Delta : -obj2Delta), object2.height); if((obj1Bounds.x + obj1Bounds.width > obj2Bounds.x) && (obj1Bounds.x < obj2Bounds.x + obj2Bounds.width) && (obj1Bounds.y + obj1Bounds.height > obj2Bounds.y) && (obj1Bounds.y < obj2Bounds.y + obj2Bounds.height)) { var maxOverlap = obj1DeltaAbs + obj2DeltaAbs + Collision.OVERLAP_BIAS; // If they did overlap (and can), figure out by how much and flip the corresponding flags if(obj1Delta > obj2Delta) { overlap = object1.x + object1.width - object2.x; if((overlap > maxOverlap) || !(object1.allowCollisions & Collision.RIGHT) || !(object2.allowCollisions & Collision.LEFT)) { overlap = 0; } else { object1.touching |= Collision.RIGHT; object2.touching |= Collision.LEFT; } } else if(obj1Delta < obj2Delta) { overlap = object1.x - object2.width - object2.x; if((-overlap > maxOverlap) || !(object1.allowCollisions & Collision.LEFT) || !(object2.allowCollisions & Collision.RIGHT)) { overlap = 0; } else { object1.touching |= Collision.LEFT; object2.touching |= Collision.RIGHT; } } } } // Then adjust their positions and velocities accordingly (if there was any overlap) if(overlap != 0) { var obj1Velocity = object1.velocity.x; var obj2Velocity = object2.velocity.x; if(!object1.immovable && !object2.immovable) { overlap *= 0.5; object1.x = object1.x - overlap; object2.x += overlap; var obj1NewVelocity = Math.sqrt((obj2Velocity * obj2Velocity * object2.mass) / object1.mass) * ((obj2Velocity > 0) ? 1 : -1); var obj2NewVelocity = Math.sqrt((obj1Velocity * obj1Velocity * object1.mass) / object2.mass) * ((obj1Velocity > 0) ? 1 : -1); var average = (obj1NewVelocity + obj2NewVelocity) * 0.5; obj1NewVelocity -= average; obj2NewVelocity -= average; object1.velocity.x = average + obj1NewVelocity * object1.elasticity; object2.velocity.x = average + obj2NewVelocity * object2.elasticity; } else if(!object1.immovable) { object1.x = object1.x - overlap; object1.velocity.x = obj2Velocity - obj1Velocity * object1.elasticity; } else if(!object2.immovable) { object2.x += overlap; object2.velocity.x = obj1Velocity - obj2Velocity * object2.elasticity; } return true; } else { return false; } }; Collision.separateY = /** * Separates the two objects on their y axis * @param object1 The first GameObject to separate * @param object2 The second GameObject to separate * @returns {boolean} Whether the objects in fact touched and were separated along the Y axis. */ function separateY(object1, object2) { // Can't separate two immovable objects if(object1.immovable && object2.immovable) { return false; } // First, get the two object deltas var overlap = 0; var obj1Delta = object1.y - object1.last.y; var obj2Delta = object2.y - object2.last.y; if(obj1Delta != obj2Delta) { // Check if the Y hulls actually overlap var obj1DeltaAbs = (obj1Delta > 0) ? obj1Delta : -obj1Delta; var obj2DeltaAbs = (obj2Delta > 0) ? obj2Delta : -obj2Delta; var obj1Bounds = new Phaser.Quad(object1.x, object1.y - ((obj1Delta > 0) ? obj1Delta : 0), object1.width, object1.height + obj1DeltaAbs); var obj2Bounds = new Phaser.Quad(object2.x, object2.y - ((obj2Delta > 0) ? obj2Delta : 0), object2.width, object2.height + obj2DeltaAbs); if((obj1Bounds.x + obj1Bounds.width > obj2Bounds.x) && (obj1Bounds.x < obj2Bounds.x + obj2Bounds.width) && (obj1Bounds.y + obj1Bounds.height > obj2Bounds.y) && (obj1Bounds.y < obj2Bounds.y + obj2Bounds.height)) { var maxOverlap = obj1DeltaAbs + obj2DeltaAbs + Collision.OVERLAP_BIAS; // If they did overlap (and can), figure out by how much and flip the corresponding flags if(obj1Delta > obj2Delta) { overlap = object1.y + object1.height - object2.y; if((overlap > maxOverlap) || !(object1.allowCollisions & Collision.DOWN) || !(object2.allowCollisions & Collision.UP)) { overlap = 0; } else { object1.touching |= Collision.DOWN; object2.touching |= Collision.UP; } } else if(obj1Delta < obj2Delta) { overlap = object1.y - object2.height - object2.y; if((-overlap > maxOverlap) || !(object1.allowCollisions & Collision.UP) || !(object2.allowCollisions & Collision.DOWN)) { overlap = 0; } else { object1.touching |= Collision.UP; object2.touching |= Collision.DOWN; } } } } // Then adjust their positions and velocities accordingly (if there was any overlap) if(overlap != 0) { var obj1Velocity = object1.velocity.y; var obj2Velocity = object2.velocity.y; if(!object1.immovable && !object2.immovable) { overlap *= 0.5; object1.y = object1.y - overlap; object2.y += overlap; var obj1NewVelocity = Math.sqrt((obj2Velocity * obj2Velocity * object2.mass) / object1.mass) * ((obj2Velocity > 0) ? 1 : -1); var obj2NewVelocity = Math.sqrt((obj1Velocity * obj1Velocity * object1.mass) / object2.mass) * ((obj1Velocity > 0) ? 1 : -1); var average = (obj1NewVelocity + obj2NewVelocity) * 0.5; obj1NewVelocity -= average; obj2NewVelocity -= average; object1.velocity.y = average + obj1NewVelocity * object1.elasticity; object2.velocity.y = average + obj2NewVelocity * object2.elasticity; } else if(!object1.immovable) { object1.y = object1.y - overlap; object1.velocity.y = obj2Velocity - obj1Velocity * object1.elasticity; // This is special case code that handles things like horizontal moving platforms you can ride if(object2.active && object2.moves && (obj1Delta > obj2Delta)) { object1.x += object2.x - object2.last.x; } } else if(!object2.immovable) { object2.y += overlap; object2.velocity.y = obj1Velocity - obj2Velocity * object2.elasticity; // This is special case code that handles things like horizontal moving platforms you can ride if(object1.active && object1.moves && (obj1Delta < obj2Delta)) { object2.x += object1.x - object1.last.x; } } return true; } else { return false; } }; Collision.distance = /** * Returns the distance between the two given coordinates. * @param x1 The X value of the first coordinate * @param y1 The Y value of the first coordinate * @param x2 The X value of the second coordinate * @param y2 The Y value of the second coordinate * @returns {number} The distance between the two coordinates */ function distance(x1, y1, x2, y2) { return Math.sqrt((x2 - x1) * (x2 - x1) + (y2 - y1) * (y2 - y1)); }; Collision.distanceSquared = /** * Returns the distanced squared between the two given coordinates. * @param x1 The X value of the first coordinate * @param y1 The Y value of the first coordinate * @param x2 The X value of the second coordinate * @param y2 The Y value of the second coordinate * @returns {number} The distance between the two coordinates */ function distanceSquared(x1, y1, x2, y2) { return (x2 - x1) * (x2 - x1) + (y2 - y1) * (y2 - y1); }; return Collision; })(); Phaser.Collision = Collision; })(Phaser || (Phaser = {})); /// /** * Phaser - DynamicTexture * * A DynamicTexture can be thought of as a mini canvas into which you can draw anything. * Game Objects can be assigned a DynamicTexture, so when they render in the world they do so * based on the contents of the texture at the time. This allows you to create powerful effects * once and have them replicated across as many game objects as you like. */ var Phaser; (function (Phaser) { var DynamicTexture = (function () { function DynamicTexture(game, width, height) { this._sx = 0; this._sy = 0; this._sw = 0; this._sh = 0; this._dx = 0; this._dy = 0; this._dw = 0; this._dh = 0; this._game = game; this.canvas = document.createElement('canvas'); this.canvas.width = width; this.canvas.height = height; this.context = this.canvas.getContext('2d'); this.bounds = new Phaser.Rectangle(0, 0, width, height); } DynamicTexture.prototype.getPixel = function (x, y) { //r = imageData.data[0]; //g = imageData.data[1]; //b = imageData.data[2]; //a = imageData.data[3]; var imageData = this.context.getImageData(x, y, 1, 1); return this.getColor(imageData.data[0], imageData.data[1], imageData.data[2]); }; DynamicTexture.prototype.getPixel32 = function (x, y) { var imageData = this.context.getImageData(x, y, 1, 1); return this.getColor32(imageData.data[3], imageData.data[0], imageData.data[1], imageData.data[2]); }; DynamicTexture.prototype.getPixels = // Returns a CanvasPixelArray function (rect) { return this.context.getImageData(rect.x, rect.y, rect.width, rect.height); }; DynamicTexture.prototype.setPixel = function (x, y, color) { this.context.fillStyle = color; this.context.fillRect(x, y, 1, 1); }; DynamicTexture.prototype.setPixel32 = function (x, y, color) { this.context.fillStyle = color; this.context.fillRect(x, y, 1, 1); }; DynamicTexture.prototype.setPixels = function (rect, input) { this.context.putImageData(input, rect.x, rect.y); }; DynamicTexture.prototype.fillRect = function (rect, color) { this.context.fillStyle = color; this.context.fillRect(rect.x, rect.y, rect.width, rect.height); }; DynamicTexture.prototype.pasteImage = function (key, frame, destX, destY, destWidth, destHeight) { if (typeof frame === "undefined") { frame = -1; } if (typeof destX === "undefined") { destX = 0; } if (typeof destY === "undefined") { destY = 0; } if (typeof destWidth === "undefined") { destWidth = null; } if (typeof destHeight === "undefined") { destHeight = null; } var texture = null; var frameData; this._sx = 0; this._sy = 0; this._dx = destX; this._dy = destY; // TODO - Load a frame from a sprite sheet, otherwise we'll draw the whole lot if(frame > -1) { //if (this._game.cache.isSpriteSheet(key)) //{ // texture = this._game.cache.getImage(key); //this.animations.loadFrameData(this._game.cache.getFrameData(key)); //} } else { texture = this._game.cache.getImage(key); this._sw = texture.width; this._sh = texture.height; this._dw = texture.width; this._dh = texture.height; } if(destWidth !== null) { this._dw = destWidth; } if(destHeight !== null) { this._dh = destHeight; } if(texture != null) { this.context.drawImage(texture, // Source Image this._sx, // Source X (location within the source image) this._sy, // Source Y this._sw, // Source Width this._sh, // Source Height this._dx, // Destination X (where on the canvas it'll be drawn) this._dy, // Destination Y this._dw, // Destination Width (always same as Source Width unless scaled) this._dh); // Destination Height (always same as Source Height unless scaled) } }; DynamicTexture.prototype.copyPixels = // TODO - Add in support for: alphaBitmapData: BitmapData = null, alphaPoint: Point = null, mergeAlpha: bool = false function (sourceTexture, sourceRect, destPoint) { // Swap for drawImage if the sourceRect is the same size as the sourceTexture to avoid a costly getImageData call if(sourceRect.equals(this.bounds) == true) { this.context.drawImage(sourceTexture.canvas, destPoint.x, destPoint.y); } else { this.context.putImageData(sourceTexture.getPixels(sourceRect), destPoint.x, destPoint.y); } }; DynamicTexture.prototype.clear = function () { this.context.clearRect(0, 0, this.bounds.width, this.bounds.height); }; Object.defineProperty(DynamicTexture.prototype, "width", { get: function () { return this.bounds.width; }, enumerable: true, configurable: true }); Object.defineProperty(DynamicTexture.prototype, "height", { get: function () { return this.bounds.height; }, enumerable: true, configurable: true }); DynamicTexture.prototype.getColor32 = /** * Given an alpha and 3 color values this will return an integer representation of it * * @param alpha The Alpha value (between 0 and 255) * @param red The Red channel value (between 0 and 255) * @param green The Green channel value (between 0 and 255) * @param blue The Blue channel value (between 0 and 255) * * @return A native color value integer (format: 0xAARRGGBB) */ function (alpha, red, green, blue) { return alpha << 24 | red << 16 | green << 8 | blue; }; DynamicTexture.prototype.getColor = /** * Given 3 color values this will return an integer representation of it * * @param red The Red channel value (between 0 and 255) * @param green The Green channel value (between 0 and 255) * @param blue The Blue channel value (between 0 and 255) * * @return A native color value integer (format: 0xRRGGBB) */ function (red, green, blue) { return red << 16 | green << 8 | blue; }; return DynamicTexture; })(); Phaser.DynamicTexture = DynamicTexture; })(Phaser || (Phaser = {})); /// /** * Phaser - GameMath * * Adds a set of extra Math functions used through-out Phaser. * Includes methods written by Dylan Engelman and Adam Saltsman. */ var Phaser; (function (Phaser) { var GameMath = (function () { function GameMath(game) { //arbitrary 8 digit epsilon this.cosTable = []; this.sinTable = []; /** * The global random number generator seed (for deterministic behavior in recordings and saves). */ this.globalSeed = Math.random(); this._game = game; } GameMath.PI = 3.141592653589793; GameMath.PI_2 = 1.5707963267948965; GameMath.PI_4 = 0.7853981633974483; GameMath.PI_8 = 0.39269908169872413; GameMath.PI_16 = 0.19634954084936206; GameMath.TWO_PI = 6.283185307179586; GameMath.THREE_PI_2 = 4.7123889803846895; GameMath.E = 2.71828182845905; GameMath.LN10 = 2.302585092994046; GameMath.LN2 = 0.6931471805599453; GameMath.LOG10E = 0.4342944819032518; GameMath.LOG2E = 1.442695040888963387; GameMath.SQRT1_2 = 0.7071067811865476; GameMath.SQRT2 = 1.4142135623730951; GameMath.DEG_TO_RAD = 0.017453292519943294444444444444444; GameMath.RAD_TO_DEG = 57.295779513082325225835265587527; GameMath.B_16 = 65536; GameMath.B_31 = 2147483648; GameMath.B_32 = 4294967296; GameMath.B_48 = 281474976710656; GameMath.B_53 = 9007199254740992; GameMath.B_64 = 18446744073709551616; GameMath.ONE_THIRD = 0.333333333333333333333333333333333; GameMath.TWO_THIRDS = 0.666666666666666666666666666666666; GameMath.ONE_SIXTH = 0.166666666666666666666666666666666; GameMath.COS_PI_3 = 0.86602540378443864676372317075294; GameMath.SIN_2PI_3 = 0.03654595; GameMath.CIRCLE_ALPHA = 0.5522847498307933984022516322796; GameMath.ON = true; GameMath.OFF = false; GameMath.SHORT_EPSILON = 0.1; GameMath.PERC_EPSILON = 0.001; GameMath.EPSILON = 0.0001; GameMath.LONG_EPSILON = 0.00000001; GameMath.prototype.fuzzyEqual = function (a, b, epsilon) { if (typeof epsilon === "undefined") { epsilon = 0.0001; } return Math.abs(a - b) < epsilon; }; GameMath.prototype.fuzzyLessThan = function (a, b, epsilon) { if (typeof epsilon === "undefined") { epsilon = 0.0001; } return a < b + epsilon; }; GameMath.prototype.fuzzyGreaterThan = function (a, b, epsilon) { if (typeof epsilon === "undefined") { epsilon = 0.0001; } return a > b - epsilon; }; GameMath.prototype.fuzzyCeil = function (val, epsilon) { if (typeof epsilon === "undefined") { epsilon = 0.0001; } return Math.ceil(val - epsilon); }; GameMath.prototype.fuzzyFloor = function (val, epsilon) { if (typeof epsilon === "undefined") { epsilon = 0.0001; } return Math.floor(val + epsilon); }; GameMath.prototype.average = function () { var args = []; for (var _i = 0; _i < (arguments.length - 0); _i++) { args[_i] = arguments[_i + 0]; } var avg = 0; for(var i = 0; i < args.length; i++) { avg += args[i]; } return avg / args.length; }; GameMath.prototype.slam = function (value, target, epsilon) { if (typeof epsilon === "undefined") { epsilon = 0.0001; } return (Math.abs(value - target) < epsilon) ? target : value; }; GameMath.prototype.percentageMinMax = /** * ratio of value to a range */ function (val, max, min) { if (typeof min === "undefined") { min = 0; } val -= min; max -= min; if(!max) { return 0; } else { return val / max; } }; GameMath.prototype.sign = /** * a value representing the sign of the value. * -1 for negative, +1 for positive, 0 if value is 0 */ function (n) { if(n) { return n / Math.abs(n); } else { return 0; } }; GameMath.prototype.truncate = function (n) { return (n > 0) ? Math.floor(n) : Math.ceil(n); }; GameMath.prototype.shear = function (n) { return n % 1; }; GameMath.prototype.wrap = /** * wrap a value around a range, similar to modulus with a floating minimum */ function (val, max, min) { if (typeof min === "undefined") { min = 0; } val -= min; max -= min; if(max == 0) { return min; } val %= max; val += min; while(val < min) { val += max; } return val; }; GameMath.prototype.arithWrap = /** * arithmetic version of wrap... need to decide which is more efficient */ function (value, max, min) { if (typeof min === "undefined") { min = 0; } max -= min; if(max == 0) { return min; } return value - max * Math.floor((value - min) / max); }; GameMath.prototype.clamp = /** * force a value within the boundaries of two values * * if max < min, min is returned */ function (input, max, min) { if (typeof min === "undefined") { min = 0; } return Math.max(min, Math.min(max, input)); }; GameMath.prototype.snapTo = /** * Snap a value to nearest grid slice, using rounding. * * example if you have an interval gap of 5 and a position of 12... you will snap to 10. Where as 14 will snap to 15 * * @param input - the value to snap * @param gap - the interval gap of the grid * @param start - optional starting offset for gap */ function (input, gap, start) { if (typeof start === "undefined") { start = 0; } if(gap == 0) { return input; } input -= start; input = gap * Math.round(input / gap); return start + input; }; GameMath.prototype.snapToFloor = /** * Snap a value to nearest grid slice, using floor. * * example if you have an interval gap of 5 and a position of 12... you will snap to 10. As will 14 snap to 10... but 16 will snap to 15 * * @param input - the value to snap * @param gap - the interval gap of the grid * @param start - optional starting offset for gap */ function (input, gap, start) { if (typeof start === "undefined") { start = 0; } if(gap == 0) { return input; } input -= start; input = gap * Math.floor(input / gap); return start + input; }; GameMath.prototype.snapToCeil = /** * Snap a value to nearest grid slice, using ceil. * * example if you have an interval gap of 5 and a position of 12... you will snap to 15. As will 14 will snap to 15... but 16 will snap to 20 * * @param input - the value to snap * @param gap - the interval gap of the grid * @param start - optional starting offset for gap */ function (input, gap, start) { if (typeof start === "undefined") { start = 0; } if(gap == 0) { return input; } input -= start; input = gap * Math.ceil(input / gap); return start + input; }; GameMath.prototype.snapToInArray = /** * Snaps a value to the nearest value in an array. */ function (input, arr, sort) { if (typeof sort === "undefined") { sort = true; } if(sort) { arr.sort(); } if(input < arr[0]) { return arr[0]; } var i = 1; while(arr[i] < input) { i++; } var low = arr[i - 1]; var high = (i < arr.length) ? arr[i] : Number.POSITIVE_INFINITY; return ((high - input) <= (input - low)) ? high : low; }; GameMath.prototype.roundTo = /** * roundTo some place comparative to a 'base', default is 10 for decimal place * * 'place' is represented by the power applied to 'base' to get that place * * @param value - the value to round * @param place - the place to round to * @param base - the base to round in... default is 10 for decimal * * e.g. * * 2000/7 ~= 285.714285714285714285714 ~= (bin)100011101.1011011011011011 * * roundTo(2000/7,3) == 0 * roundTo(2000/7,2) == 300 * roundTo(2000/7,1) == 290 * roundTo(2000/7,0) == 286 * roundTo(2000/7,-1) == 285.7 * roundTo(2000/7,-2) == 285.71 * roundTo(2000/7,-3) == 285.714 * roundTo(2000/7,-4) == 285.7143 * roundTo(2000/7,-5) == 285.71429 * * roundTo(2000/7,3,2) == 288 -- 100100000 * roundTo(2000/7,2,2) == 284 -- 100011100 * roundTo(2000/7,1,2) == 286 -- 100011110 * roundTo(2000/7,0,2) == 286 -- 100011110 * roundTo(2000/7,-1,2) == 285.5 -- 100011101.1 * roundTo(2000/7,-2,2) == 285.75 -- 100011101.11 * roundTo(2000/7,-3,2) == 285.75 -- 100011101.11 * roundTo(2000/7,-4,2) == 285.6875 -- 100011101.1011 * roundTo(2000/7,-5,2) == 285.71875 -- 100011101.10111 * * note what occurs when we round to the 3rd space (8ths place), 100100000, this is to be assumed * because we are rounding 100011.1011011011011011 which rounds up. */ function (value, place, base) { if (typeof place === "undefined") { place = 0; } if (typeof base === "undefined") { base = 10; } var p = Math.pow(base, -place); return Math.round(value * p) / p; }; GameMath.prototype.floorTo = function (value, place, base) { if (typeof place === "undefined") { place = 0; } if (typeof base === "undefined") { base = 10; } var p = Math.pow(base, -place); return Math.floor(value * p) / p; }; GameMath.prototype.ceilTo = function (value, place, base) { if (typeof place === "undefined") { place = 0; } if (typeof base === "undefined") { base = 10; } var p = Math.pow(base, -place); return Math.ceil(value * p) / p; }; GameMath.prototype.interpolateFloat = /** * a one dimensional linear interpolation of a value. */ function (a, b, weight) { return (b - a) * weight + a; }; GameMath.prototype.radiansToDegrees = /** * convert radians to degrees */ function (angle) { return angle * GameMath.RAD_TO_DEG; }; GameMath.prototype.degreesToRadians = /** * convert degrees to radians */ function (angle) { return angle * GameMath.DEG_TO_RAD; }; GameMath.prototype.angleBetween = /** * Find the angle of a segment from (x1, y1) -> (x2, y2 ) */ function (x1, y1, x2, y2) { return Math.atan2(y2 - y1, x2 - x1); }; GameMath.prototype.normalizeAngle = /** * set an angle with in the bounds of -PI to PI */ function (angle, radians) { if (typeof radians === "undefined") { radians = true; } var rd = (radians) ? GameMath.PI : 180; return this.wrap(angle, rd, -rd); }; GameMath.prototype.nearestAngleBetween = /** * closest angle between two angles from a1 to a2 * absolute value the return for exact angle */ function (a1, a2, radians) { if (typeof radians === "undefined") { radians = true; } var rd = (radians) ? GameMath.PI : 180; a1 = this.normalizeAngle(a1, radians); a2 = this.normalizeAngle(a2, radians); if(a1 < -rd / 2 && a2 > rd / 2) { a1 += rd * 2; } if(a2 < -rd / 2 && a1 > rd / 2) { a2 += rd * 2; } return a2 - a1; }; GameMath.prototype.normalizeAngleToAnother = /** * normalizes independent and then sets dep to the nearest value respective to independent * * for instance if dep=-170 and ind=170 then 190 will be returned as an alternative to -170 */ function (dep, ind, radians) { if (typeof radians === "undefined") { radians = true; } return ind + this.nearestAngleBetween(ind, dep, radians); }; GameMath.prototype.normalizeAngleAfterAnother = /** * normalize independent and dependent and then set dependent to an angle relative to 'after/clockwise' independent * * for instance dep=-170 and ind=170, then 190 will be reutrned as alternative to -170 */ function (dep, ind, radians) { if (typeof radians === "undefined") { radians = true; } dep = this.normalizeAngle(dep - ind, radians); return ind + dep; }; GameMath.prototype.normalizeAngleBeforeAnother = /** * normalizes indendent and dependent and then sets dependent to an angle relative to 'before/counterclockwise' independent * * for instance dep = 190 and ind = 170, then -170 will be returned as an alternative to 190 */ function (dep, ind, radians) { if (typeof radians === "undefined") { radians = true; } dep = this.normalizeAngle(ind - dep, radians); return ind - dep; }; GameMath.prototype.interpolateAngles = /** * interpolate across the shortest arc between two angles */ function (a1, a2, weight, radians, ease) { if (typeof radians === "undefined") { radians = true; } if (typeof ease === "undefined") { ease = null; } a1 = this.normalizeAngle(a1, radians); a2 = this.normalizeAngleToAnother(a2, a1, radians); return (typeof ease === 'function') ? ease(weight, a1, a2 - a1, 1) : this.interpolateFloat(a1, a2, weight); }; GameMath.prototype.logBaseOf = /** * Compute the logarithm of any value of any base * * a logarithm is the exponent that some constant (base) would have to be raised to * to be equal to value. * * i.e. * 4 ^ x = 16 * can be rewritten as to solve for x * logB4(16) = x * which with this function would be * LoDMath.logBaseOf(16,4) * * which would return 2, because 4^2 = 16 */ function (value, base) { return Math.log(value) / Math.log(base); }; GameMath.prototype.GCD = /** * Greatest Common Denominator using Euclid's algorithm */ function (m, n) { var r; //make sure positive, GCD is always positive m = Math.abs(m); n = Math.abs(n); //m must be >= n if(m < n) { r = m; m = n; n = r; } //now start loop while(true) { r = m % n; if(!r) { return n; } m = n; n = r; } return 1; }; GameMath.prototype.LCM = /** * Lowest Common Multiple */ function (m, n) { return (m * n) / this.GCD(m, n); }; GameMath.prototype.factorial = /** * Factorial - N! * * simple product series * * by definition: * 0! == 1 */ function (value) { if(value == 0) { return 1; } var res = value; while(--value) { res *= value; } return res; }; GameMath.prototype.gammaFunction = /** * gamma function * * defined: gamma(N) == (N - 1)! */ function (value) { return this.factorial(value - 1); }; GameMath.prototype.fallingFactorial = /** * falling factorial * * defined: (N)! / (N - x)! * * written subscript: (N)x OR (base)exp */ function (base, exp) { return this.factorial(base) / this.factorial(base - exp); }; GameMath.prototype.risingFactorial = /** * rising factorial * * defined: (N + x - 1)! / (N - 1)! * * written superscript N^(x) OR base^(exp) */ function (base, exp) { //expanded from gammaFunction for speed return this.factorial(base + exp - 1) / this.factorial(base - 1); }; GameMath.prototype.binCoef = /** * binomial coefficient * * defined: N! / (k!(N-k)!) * reduced: N! / (N-k)! == (N)k (fallingfactorial) * reduced: (N)k / k! */ function (n, k) { return this.fallingFactorial(n, k) / this.factorial(k); }; GameMath.prototype.risingBinCoef = /** * rising binomial coefficient * * as one can notice in the analysis of binCoef(...) that * binCoef is the (N)k divided by k!. Similarly rising binCoef * is merely N^(k) / k! */ function (n, k) { return this.risingFactorial(n, k) / this.factorial(k); }; GameMath.prototype.chanceRoll = /** * Generate a random boolean result based on the chance value *

* Returns true or false based on the chance value (default 50%). For example if you wanted a player to have a 30% chance * of getting a bonus, call chanceRoll(30) - true means the chance passed, false means it failed. *

* @param chance The chance of receiving the value. A number between 0 and 100 (effectively 0% to 100%) * @return true if the roll passed, or false */ function (chance) { if (typeof chance === "undefined") { chance = 50; } if(chance <= 0) { return false; } else if(chance >= 100) { return true; } else { if(Math.random() * 100 >= chance) { return false; } else { return true; } } }; GameMath.prototype.maxAdd = /** * Adds the given amount to the value, but never lets the value go over the specified maximum * * @param value The value to add the amount to * @param amount The amount to add to the value * @param max The maximum the value is allowed to be * @return The new value */ function (value, amount, max) { value += amount; if(value > max) { value = max; } return value; }; GameMath.prototype.minSub = /** * Subtracts the given amount from the value, but never lets the value go below the specified minimum * * @param value The base value * @param amount The amount to subtract from the base value * @param min The minimum the value is allowed to be * @return The new value */ function (value, amount, min) { value -= amount; if(value < min) { value = min; } return value; }; GameMath.prototype.wrapValue = /** * Adds value to amount and ensures that the result always stays between 0 and max, by wrapping the value around. *

Values must be positive integers, and are passed through Math.abs

* * @param value The value to add the amount to * @param amount The amount to add to the value * @param max The maximum the value is allowed to be * @return The wrapped value */ function (value, amount, max) { var diff; value = Math.abs(value); amount = Math.abs(amount); max = Math.abs(max); diff = (value + amount) % max; return diff; }; GameMath.prototype.randomSign = /** * Randomly returns either a 1 or -1 * * @return 1 or -1 */ function () { return (Math.random() > 0.5) ? 1 : -1; }; GameMath.prototype.isOdd = /** * Returns true if the number given is odd. * * @param n The number to check * * @return True if the given number is odd. False if the given number is even. */ function (n) { if(n & 1) { return true; } else { return false; } }; GameMath.prototype.isEven = /** * Returns true if the number given is even. * * @param n The number to check * * @return True if the given number is even. False if the given number is odd. */ function (n) { if(n & 1) { return false; } else { return true; } }; GameMath.prototype.wrapAngle = /** * Keeps an angle value between -180 and +180
* Should be called whenever the angle is updated on the Sprite to stop it from going insane. * * @param angle The angle value to check * * @return The new angle value, returns the same as the input angle if it was within bounds */ function (angle) { var result = angle; // Nothing needs to change if(angle >= -180 && angle <= 180) { return angle; } // Else normalise it to -180, 180 result = (angle + 180) % 360; if(result < 0) { result += 360; } return result - 180; }; GameMath.prototype.angleLimit = /** * Keeps an angle value between the given min and max values * * @param angle The angle value to check. Must be between -180 and +180 * @param min The minimum angle that is allowed (must be -180 or greater) * @param max The maximum angle that is allowed (must be 180 or less) * * @return The new angle value, returns the same as the input angle if it was within bounds */ function (angle, min, max) { var result = angle; if(angle > max) { result = max; } else if(angle < min) { result = min; } return result; }; GameMath.prototype.linearInterpolation = /** * @method linear * @param {Any} v * @param {Any} k * @static */ function (v, k) { var m = v.length - 1; var f = m * k; var i = Math.floor(f); if(k < 0) { return this.linear(v[0], v[1], f); } if(k > 1) { return this.linear(v[m], v[m - 1], m - f); } return this.linear(v[i], v[i + 1 > m ? m : i + 1], f - i); }; GameMath.prototype.bezierInterpolation = /** * @method Bezier * @param {Any} v * @param {Any} k * @static */ function (v, k) { var b = 0; var n = v.length - 1; for(var i = 0; i <= n; i++) { b += Math.pow(1 - k, n - i) * Math.pow(k, i) * v[i] * this.bernstein(n, i); } return b; }; GameMath.prototype.catmullRomInterpolation = /** * @method CatmullRom * @param {Any} v * @param {Any} k * @static */ function (v, k) { var m = v.length - 1; var f = m * k; var i = Math.floor(f); if(v[0] === v[m]) { if(k < 0) { i = Math.floor(f = m * (1 + k)); } return this.catmullRom(v[(i - 1 + m) % m], v[i], v[(i + 1) % m], v[(i + 2) % m], f - i); } else { if(k < 0) { return v[0] - (this.catmullRom(v[0], v[0], v[1], v[1], -f) - v[0]); } if(k > 1) { return v[m] - (this.catmullRom(v[m], v[m], v[m - 1], v[m - 1], f - m) - v[m]); } return this.catmullRom(v[i ? i - 1 : 0], v[i], v[m < i + 1 ? m : i + 1], v[m < i + 2 ? m : i + 2], f - i); } }; GameMath.prototype.linear = /** * @method Linear * @param {Any} p0 * @param {Any} p1 * @param {Any} t * @static */ function (p0, p1, t) { return (p1 - p0) * t + p0; }; GameMath.prototype.bernstein = /** * @method Bernstein * @param {Any} n * @param {Any} i * @static */ function (n, i) { return this.factorial(n) / this.factorial(i) / this.factorial(n - i); }; GameMath.prototype.catmullRom = /** * @method CatmullRom * @param {Any} p0 * @param {Any} p1 * @param {Any} p2 * @param {Any} p3 * @param {Any} t * @static */ function (p0, p1, p2, p3, t) { var v0 = (p2 - p0) * 0.5, v1 = (p3 - p1) * 0.5, t2 = t * t, t3 = t * t2; return (2 * p1 - 2 * p2 + v0 + v1) * t3 + (-3 * p1 + 3 * p2 - 2 * v0 - v1) * t2 + v0 * t + p1; }; GameMath.prototype.difference = function (a, b) { return Math.abs(a - b); }; GameMath.prototype.random = /** * Generates a random number. Deterministic, meaning safe * to use if you want to record replays in random environments. * * @return A Number between 0 and 1. */ function () { return this.globalSeed = this.srand(this.globalSeed); }; GameMath.prototype.srand = /** * Generates a random number based on the seed provided. * * @param Seed A number between 0 and 1, used to generate a predictable random number (very optional). * * @return A Number between 0 and 1. */ function (Seed) { return ((69621 * (Seed * 0x7FFFFFFF)) % 0x7FFFFFFF) / 0x7FFFFFFF; }; GameMath.prototype.getRandom = /** * Fetch a random entry from the given array. * Will return null if random selection is missing, or array has no entries. * G.getRandom() is deterministic and safe for use with replays/recordings. * HOWEVER, U.getRandom() is NOT deterministic and unsafe for use with replays/recordings. * * @param Objects An array of objects. * @param StartIndex Optional offset off the front of the array. Default value is 0, or the beginning of the array. * @param Length Optional restriction on the number of values you want to randomly select from. * * @return The random object that was selected. */ function (Objects, StartIndex, Length) { if (typeof StartIndex === "undefined") { StartIndex = 0; } if (typeof Length === "undefined") { Length = 0; } if(Objects != null) { var l = Length; if((l == 0) || (l > Objects.length - StartIndex)) { l = Objects.length - StartIndex; } if(l > 0) { return Objects[StartIndex + Math.floor(Math.random() * l)]; } } return null; }; GameMath.prototype.floor = /** * Round down to the next whole number. E.g. floor(1.7) == 1, and floor(-2.7) == -2. * * @param Value Any number. * * @return The rounded value of that number. */ function (Value) { var n = Value | 0; return (Value > 0) ? (n) : ((n != Value) ? (n - 1) : (n)); }; GameMath.prototype.ceil = /** * Round up to the next whole number. E.g. ceil(1.3) == 2, and ceil(-2.3) == -3. * * @param Value Any number. * * @return The rounded value of that number. */ function (Value) { var n = Value | 0; return (Value > 0) ? ((n != Value) ? (n + 1) : (n)) : (n); }; GameMath.prototype.sinCosGenerator = /** * Generate a sine and cosine table simultaneously and extremely quickly. Based on research by Franky of scene.at *

* The parameters allow you to specify the length, amplitude and frequency of the wave. Once you have called this function * you should get the results via getSinTable() and getCosTable(). This generator is fast enough to be used in real-time. *

* @param length The length of the wave * @param sinAmplitude The amplitude to apply to the sine table (default 1.0) if you need values between say -+ 125 then give 125 as the value * @param cosAmplitude The amplitude to apply to the cosine table (default 1.0) if you need values between say -+ 125 then give 125 as the value * @param frequency The frequency of the sine and cosine table data * @return Returns the sine table * @see getSinTable * @see getCosTable */ function (length, sinAmplitude, cosAmplitude, frequency) { if (typeof sinAmplitude === "undefined") { sinAmplitude = 1.0; } if (typeof cosAmplitude === "undefined") { cosAmplitude = 1.0; } if (typeof frequency === "undefined") { frequency = 1.0; } var sin = sinAmplitude; var cos = cosAmplitude; var frq = frequency * Math.PI / length; this.cosTable = []; this.sinTable = []; for(var c = 0; c < length; c++) { cos -= sin * frq; sin += cos * frq; this.cosTable[c] = cos; this.sinTable[c] = sin; } return this.sinTable; }; GameMath.prototype.shiftSinTable = /** * Shifts through the sin table data by one value and returns it. * This effectively moves the position of the data from the start to the end of the table. * @return The sin value. */ function () { if(this.sinTable) { var s = this.sinTable.shift(); this.sinTable.push(s); return s; } }; GameMath.prototype.shiftCosTable = /** * Shifts through the cos table data by one value and returns it. * This effectively moves the position of the data from the start to the end of the table. * @return The cos value. */ function () { if(this.cosTable) { var s = this.cosTable.shift(); this.cosTable.push(s); return s; } }; GameMath.prototype.vectorLength = /** * Finds the length of the given vector * * @param dx * @param dy * * @return */ function (dx, dy) { return Math.sqrt(dx * dx + dy * dy); }; GameMath.prototype.dotProduct = /** * Finds the dot product value of two vectors * * @param ax Vector X * @param ay Vector Y * @param bx Vector X * @param by Vector Y * * @return Dot product */ function (ax, ay, bx, by) { return ax * bx + ay * by; }; return GameMath; })(); Phaser.GameMath = GameMath; })(Phaser || (Phaser = {})); /// /// /** * Phaser - Group * * This class is used for organising, updating and sorting game objects. * */ var Phaser; (function (Phaser) { var Group = (function (_super) { __extends(Group, _super); function Group(game, MaxSize) { if (typeof MaxSize === "undefined") { MaxSize = 0; } _super.call(this, game); this.isGroup = true; this.members = []; this.length = 0; this._maxSize = MaxSize; this._marker = 0; this._sortIndex = null; } Group.ASCENDING = -1; Group.DESCENDING = 1; Group.prototype.destroy = /** * Override this function to handle any deleting or "shutdown" type operations you might need, * such as removing traditional Flash children like Basic objects. */ function () { if(this.members != null) { var basic; var i = 0; while(i < this.length) { basic = this.members[i++]; if(basic != null) { basic.destroy(); } } this.members.length = 0; } this._sortIndex = null; }; Group.prototype.update = /** * Automatically goes through and calls update on everything you added. */ function () { var basic; var i = 0; while(i < this.length) { basic = this.members[i++]; if((basic != null) && basic.exists && basic.active) { basic.preUpdate(); basic.update(); basic.postUpdate(); } } }; Group.prototype.render = /** * Automatically goes through and calls render on everything you added. */ function (camera, cameraOffsetX, cameraOffsetY) { var basic; var i = 0; while(i < this.length) { basic = this.members[i++]; if((basic != null) && basic.exists && basic.visible) { basic.render(camera, cameraOffsetX, cameraOffsetY); } } }; Object.defineProperty(Group.prototype, "maxSize", { get: /** * The maximum capacity of this group. Default is 0, meaning no max capacity, and the group can just grow. */ function () { return this._maxSize; }, set: /** * @private */ function (Size) { this._maxSize = Size; if(this._marker >= this._maxSize) { this._marker = 0; } if((this._maxSize == 0) || (this.members == null) || (this._maxSize >= this.members.length)) { return; } //If the max size has shrunk, we need to get rid of some objects var basic; var i = this._maxSize; var l = this.members.length; while(i < l) { basic = this.members[i++]; if(basic != null) { basic.destroy(); } } this.length = this.members.length = this._maxSize; }, enumerable: true, configurable: true }); Group.prototype.add = /** * Adds a new Basic subclass (Basic, Basic, Enemy, etc) to the group. * Group will try to replace a null member of the array first. * Failing that, Group will add it to the end of the member array, * assuming there is room for it, and doubling the size of the array if necessary. * *

WARNING: If the group has a maxSize that has already been met, * the object will NOT be added to the group!

* * @param Object The object you want to add to the group. * * @return The same Basic object that was passed in. */ function (Object) { //Don't bother adding an object twice. if(this.members.indexOf(Object) >= 0) { return Object; } //First, look for a null entry where we can add the object. var i = 0; var l = this.members.length; while(i < l) { if(this.members[i] == null) { this.members[i] = Object; if(i >= this.length) { this.length = i + 1; } return Object; } i++; } //Failing that, expand the array (if we can) and add the object. if(this._maxSize > 0) { if(this.members.length >= this._maxSize) { return Object; } else if(this.members.length * 2 <= this._maxSize) { this.members.length *= 2; } else { this.members.length = this._maxSize; } } else { this.members.length *= 2; } //If we made it this far, then we successfully grew the group, //and we can go ahead and add the object at the first open slot. this.members[i] = Object; this.length = i + 1; return Object; }; Group.prototype.recycle = /** * Recycling is designed to help you reuse game objects without always re-allocating or "newing" them. * *

If you specified a maximum size for this group (like in Emitter), * then recycle will employ what we're calling "rotating" recycling. * Recycle() will first check to see if the group is at capacity yet. * If group is not yet at capacity, recycle() returns a new object. * If the group IS at capacity, then recycle() just returns the next object in line.

* *

If you did NOT specify a maximum size for this group, * then recycle() will employ what we're calling "grow-style" recycling. * Recycle() will return either the first object with exists == false, * or, finding none, add a new object to the array, * doubling the size of the array if necessary.

* *

WARNING: If this function needs to create a new object, * and no object class was provided, it will return null * instead of a valid object!

* * @param ObjectClass The class type you want to recycle (e.g. Basic, EvilRobot, etc). Do NOT "new" the class in the parameter! * * @return A reference to the object that was created. Don't forget to cast it back to the Class you want (e.g. myObject = myGroup.recycle(myObjectClass) as myObjectClass;). */ function (ObjectClass) { if (typeof ObjectClass === "undefined") { ObjectClass = null; } var basic; if(this._maxSize > 0) { if(this.length < this._maxSize) { if(ObjectClass == null) { return null; } return this.add(new ObjectClass(this._game)); } else { basic = this.members[this._marker++]; if(this._marker >= this._maxSize) { this._marker = 0; } return basic; } } else { basic = this.getFirstAvailable(ObjectClass); if(basic != null) { return basic; } if(ObjectClass == null) { return null; } return this.add(new ObjectClass(this._game)); } }; Group.prototype.remove = /** * Removes an object from the group. * * @param Object The Basic you want to remove. * @param Splice Whether the object should be cut from the array entirely or not. * * @return The removed object. */ function (Object, Splice) { if (typeof Splice === "undefined") { Splice = false; } var index = this.members.indexOf(Object); if((index < 0) || (index >= this.members.length)) { return null; } if(Splice) { this.members.splice(index, 1); this.length--; } else { this.members[index] = null; } return Object; }; Group.prototype.replace = /** * Replaces an existing Basic with a new one. * * @param OldObject The object you want to replace. * @param NewObject The new object you want to use instead. * * @return The new object. */ function (OldObject, NewObject) { var index = this.members.indexOf(OldObject); if((index < 0) || (index >= this.members.length)) { return null; } this.members[index] = NewObject; return NewObject; }; Group.prototype.sort = /** * Call this function to sort the group according to a particular value and order. * For example, to sort game objects for Zelda-style overlaps you might call * myGroup.sort("y",Group.ASCENDING) at the bottom of your * State.update() override. To sort all existing objects after * a big explosion or bomb attack, you might call myGroup.sort("exists",Group.DESCENDING). * * @param Index The string name of the member variable you want to sort on. Default value is "y". * @param Order A Group constant that defines the sort order. Possible values are Group.ASCENDING and Group.DESCENDING. Default value is Group.ASCENDING. */ function (Index, Order) { if (typeof Index === "undefined") { Index = "y"; } if (typeof Order === "undefined") { Order = Group.ASCENDING; } this._sortIndex = Index; this._sortOrder = Order; this.members.sort(this.sortHandler); }; Group.prototype.setAll = /** * Go through and set the specified variable to the specified value on all members of the group. * * @param VariableName The string representation of the variable name you want to modify, for example "visible" or "scrollFactor". * @param Value The value you want to assign to that variable. * @param Recurse Default value is true, meaning if setAll() encounters a member that is a group, it will call setAll() on that group rather than modifying its variable. */ function (VariableName, Value, Recurse) { if (typeof Recurse === "undefined") { Recurse = true; } var basic; var i = 0; while(i < length) { basic = this.members[i++]; if(basic != null) { if(Recurse && (basic.isGroup == true)) { basic['setAll'](VariableName, Value, Recurse); } else { basic[VariableName] = Value; } } } }; Group.prototype.callAll = /** * Go through and call the specified function on all members of the group. * Currently only works on functions that have no required parameters. * * @param FunctionName The string representation of the function you want to call on each object, for example "kill()" or "init()". * @param Recurse Default value is true, meaning if callAll() encounters a member that is a group, it will call callAll() on that group rather than calling the group's function. */ function (FunctionName, Recurse) { if (typeof Recurse === "undefined") { Recurse = true; } var basic; var i = 0; while(i < this.length) { basic = this.members[i++]; if(basic != null) { if(Recurse && (basic.isGroup == true)) { basic['callAll'](FunctionName, Recurse); } else { basic[FunctionName](); } } } }; Group.prototype.forEach = function (callback, recursive) { if (typeof recursive === "undefined") { recursive = false; } var basic; var i = 0; while(i < this.length) { basic = this.members[i++]; if(basic != null) { if(recursive && (basic.isGroup == true)) { basic.forEach(callback, true); } else { callback.call(this, basic); } } } }; Group.prototype.forEachAlive = function (context, callback, recursive) { if (typeof recursive === "undefined") { recursive = false; } var basic; var i = 0; while(i < this.length) { basic = this.members[i++]; if(basic != null && basic.alive) { if(recursive && (basic.isGroup == true)) { basic.forEachAlive(context, callback, true); } else { callback.call(context, basic); } } } }; Group.prototype.getFirstAvailable = /** * Call this function to retrieve the first object with exists == false in the group. * This is handy for recycling in general, e.g. respawning enemies. * * @param ObjectClass An optional parameter that lets you narrow the results to instances of this particular class. * * @return A Basic currently flagged as not existing. */ function (ObjectClass) { if (typeof ObjectClass === "undefined") { ObjectClass = null; } var basic; var i = 0; while(i < this.length) { basic = this.members[i++]; if((basic != null) && !basic.exists && ((ObjectClass == null) || (typeof basic === ObjectClass))) { return basic; } } return null; }; Group.prototype.getFirstNull = /** * Call this function to retrieve the first index set to 'null'. * Returns -1 if no index stores a null object. * * @return An int indicating the first null slot in the group. */ function () { var basic; var i = 0; var l = this.members.length; while(i < l) { if(this.members[i] == null) { return i; } else { i++; } } return -1; }; Group.prototype.getFirstExtant = /** * Call this function to retrieve the first object with exists == true in the group. * This is handy for checking if everything's wiped out, or choosing a squad leader, etc. * * @return A Basic currently flagged as existing. */ function () { var basic; var i = 0; while(i < length) { basic = this.members[i++]; if((basic != null) && basic.exists) { return basic; } } return null; }; Group.prototype.getFirstAlive = /** * Call this function to retrieve the first object with dead == false in the group. * This is handy for checking if everything's wiped out, or choosing a squad leader, etc. * * @return A Basic currently flagged as not dead. */ function () { var basic; var i = 0; while(i < this.length) { basic = this.members[i++]; if((basic != null) && basic.exists && basic.alive) { return basic; } } return null; }; Group.prototype.getFirstDead = /** * Call this function to retrieve the first object with dead == true in the group. * This is handy for checking if everything's wiped out, or choosing a squad leader, etc. * * @return A Basic currently flagged as dead. */ function () { var basic; var i = 0; while(i < this.length) { basic = this.members[i++]; if((basic != null) && !basic.alive) { return basic; } } return null; }; Group.prototype.countLiving = /** * Call this function to find out how many members of the group are not dead. * * @return The number of Basics flagged as not dead. Returns -1 if group is empty. */ function () { var count = -1; var basic; var i = 0; while(i < this.length) { basic = this.members[i++]; if(basic != null) { if(count < 0) { count = 0; } if(basic.exists && basic.alive) { count++; } } } return count; }; Group.prototype.countDead = /** * Call this function to find out how many members of the group are dead. * * @return The number of Basics flagged as dead. Returns -1 if group is empty. */ function () { var count = -1; var basic; var i = 0; while(i < this.length) { basic = this.members[i++]; if(basic != null) { if(count < 0) { count = 0; } if(!basic.alive) { count++; } } } return count; }; Group.prototype.getRandom = /** * Returns a member at random from the group. * * @param StartIndex Optional offset off the front of the array. Default value is 0, or the beginning of the array. * @param Length Optional restriction on the number of values you want to randomly select from. * * @return A Basic from the members list. */ function (StartIndex, Length) { if (typeof StartIndex === "undefined") { StartIndex = 0; } if (typeof Length === "undefined") { Length = 0; } if(Length == 0) { Length = this.length; } return this._game.math.getRandom(this.members, StartIndex, Length); }; Group.prototype.clear = /** * Remove all instances of Basic subclass (Basic, Block, etc) from the list. * WARNING: does not destroy() or kill() any of these objects! */ function () { this.length = this.members.length = 0; }; Group.prototype.kill = /** * Calls kill on the group's members and then on the group itself. */ function () { var basic; var i = 0; while(i < this.length) { basic = this.members[i++]; if((basic != null) && basic.exists) { basic.kill(); } } }; Group.prototype.sortHandler = /** * Helper function for the sort process. * * @param Obj1 The first object being sorted. * @param Obj2 The second object being sorted. * * @return An integer value: -1 (Obj1 before Obj2), 0 (same), or 1 (Obj1 after Obj2). */ function (Obj1, Obj2) { if(Obj1[this._sortIndex] < Obj2[this._sortIndex]) { return this._sortOrder; } else if(Obj1[this._sortIndex] > Obj2[this._sortIndex]) { return -this._sortOrder; } return 0; }; return Group; })(Phaser.Basic); Phaser.Group = Group; })(Phaser || (Phaser = {})); /// /** * Phaser - Loader * * The Loader handles loading all external content such as Images, Sounds, Texture Atlases and data files. * It uses a combination of Image() loading and xhr and provides for progress and completion callbacks. */ var Phaser; (function (Phaser) { var Loader = (function () { function Loader(game, callback) { this._game = game; this._gameCreateComplete = callback; this._keys = []; this._fileList = { }; this._xhr = new XMLHttpRequest(); this._queueSize = 0; } Loader.prototype.reset = function () { this._queueSize = 0; }; Object.defineProperty(Loader.prototype, "queueSize", { get: function () { return this._queueSize; }, enumerable: true, configurable: true }); Loader.prototype.addImageFile = function (key, url) { if(this.checkKeyExists(key) === false) { this._queueSize++; this._fileList[key] = { type: 'image', key: key, url: url, data: null, error: false, loaded: false }; this._keys.push(key); } }; Loader.prototype.addSpriteSheet = function (key, url, frameWidth, frameHeight, frameMax) { if (typeof frameMax === "undefined") { frameMax = -1; } if(this.checkKeyExists(key) === false) { this._queueSize++; this._fileList[key] = { type: 'spritesheet', key: key, url: url, data: null, frameWidth: frameWidth, frameHeight: frameHeight, frameMax: frameMax, error: false, loaded: false }; this._keys.push(key); } }; Loader.prototype.addTextureAtlas = function (key, url, jsonURL, jsonData) { if (typeof jsonURL === "undefined") { jsonURL = null; } if (typeof jsonData === "undefined") { jsonData = null; } if(this.checkKeyExists(key) === false) { if(jsonURL !== null) { // A URL to a json file has been given this._queueSize++; this._fileList[key] = { type: 'textureatlas', key: key, url: url, data: null, jsonURL: jsonURL, jsonData: null, error: false, loaded: false }; this._keys.push(key); } else { // A json string or object has been given if(typeof jsonData === 'string') { var data = JSON.parse(jsonData); // Malformed? if(data['frames']) { this._queueSize++; this._fileList[key] = { type: 'textureatlas', key: key, url: url, data: null, jsonURL: null, jsonData: data['frames'], error: false, loaded: false }; this._keys.push(key); } } else { // Malformed? if(jsonData['frames']) { this._queueSize++; this._fileList[key] = { type: 'textureatlas', key: key, url: url, data: null, jsonURL: null, jsonData: jsonData['frames'], error: false, loaded: false }; this._keys.push(key); } } } } }; Loader.prototype.addAudioFile = function (key, url) { if(this.checkKeyExists(key) === false) { this._queueSize++; this._fileList[key] = { type: 'audio', key: key, url: url, data: null, buffer: null, error: false, loaded: false }; this._keys.push(key); } }; Loader.prototype.addTextFile = function (key, url) { if(this.checkKeyExists(key) === false) { this._queueSize++; this._fileList[key] = { type: 'text', key: key, url: url, data: null, error: false, loaded: false }; this._keys.push(key); } }; Loader.prototype.removeFile = function (key) { delete this._fileList[key]; }; Loader.prototype.removeAll = function () { this._fileList = { }; }; Loader.prototype.load = function (onFileLoadCallback, onCompleteCallback) { if (typeof onFileLoadCallback === "undefined") { onFileLoadCallback = null; } if (typeof onCompleteCallback === "undefined") { onCompleteCallback = null; } this.progress = 0; this.hasLoaded = false; this._onComplete = onCompleteCallback; if(onCompleteCallback == null) { this._onComplete = this._game.onCreateCallback; } this._onFileLoad = onFileLoadCallback; if(this._keys.length > 0) { this._progressChunk = 100 / this._keys.length; this.loadFile(); } else { this.progress = 1; this.hasLoaded = true; this._gameCreateComplete.call(this._game); if(this._onComplete !== null) { this._onComplete.call(this._game.callbackContext); } } }; Loader.prototype.loadFile = function () { var _this = this; var file = this._fileList[this._keys.pop()]; // Image or Data? switch(file.type) { case 'image': case 'spritesheet': case 'textureatlas': file.data = new Image(); file.data.name = file.key; file.data.onload = function () { return _this.fileComplete(file.key); }; file.data.onerror = function () { return _this.fileError(file.key); }; file.data.src = file.url; break; case 'audio': this._xhr.open("GET", file.url, true); this._xhr.responseType = "arraybuffer"; this._xhr.onload = function () { return _this.fileComplete(file.key); }; this._xhr.onerror = function () { return _this.fileError(file.key); }; this._xhr.send(); break; case 'text': this._xhr.open("GET", file.url, true); this._xhr.responseType = "text"; this._xhr.onload = function () { return _this.fileComplete(file.key); }; this._xhr.onerror = function () { return _this.fileError(file.key); }; this._xhr.send(); break; } }; Loader.prototype.fileError = function (key) { this._fileList[key].loaded = true; this._fileList[key].error = true; this.nextFile(key, false); }; Loader.prototype.fileComplete = function (key) { var _this = this; this._fileList[key].loaded = true; var file = this._fileList[key]; var loadNext = true; switch(file.type) { case 'image': this._game.cache.addImage(file.key, file.url, file.data); break; case 'spritesheet': this._game.cache.addSpriteSheet(file.key, file.url, file.data, file.frameWidth, file.frameHeight, file.frameMax); break; case 'textureatlas': if(file.jsonURL == null) { this._game.cache.addTextureAtlas(file.key, file.url, file.data, file.jsonData); } else { // Load the JSON before carrying on with the next file loadNext = false; this._xhr.open("GET", file.jsonURL, true); this._xhr.responseType = "text"; this._xhr.onload = function () { return _this.jsonLoadComplete(file.key); }; this._xhr.onerror = function () { return _this.jsonLoadError(file.key); }; this._xhr.send(); } break; case 'audio': file.data = this._xhr.response; this._game.cache.addSound(file.key, file.url, file.data); break; case 'text': file.data = this._xhr.response; this._game.cache.addText(file.key, file.url, file.data); break; } if(loadNext) { this.nextFile(key, true); } }; Loader.prototype.jsonLoadComplete = function (key) { var data = JSON.parse(this._xhr.response); // Malformed? if(data['frames']) { var file = this._fileList[key]; this._game.cache.addTextureAtlas(file.key, file.url, file.data, data['frames']); } this.nextFile(key, true); }; Loader.prototype.jsonLoadError = function (key) { var file = this._fileList[key]; file.error = true; this.nextFile(key, true); }; Loader.prototype.nextFile = function (previousKey, success) { this.progress = Math.round(this.progress + this._progressChunk); if(this.progress > 1) { this.progress = 1; } if(this._onFileLoad) { this._onFileLoad.call(this._game.callbackContext, this.progress, previousKey, success); } if(this._keys.length > 0) { this.loadFile(); } else { this.hasLoaded = true; this.removeAll(); this._gameCreateComplete.call(this._game); if(this._onComplete !== null) { this._onComplete.call(this._game.callbackContext); } } }; Loader.prototype.checkKeyExists = function (key) { if(this._fileList[key]) { return true; } else { return false; } }; return Loader; })(); Phaser.Loader = Loader; })(Phaser || (Phaser = {})); /// /// /** * Phaser - Motion * * The Motion class contains lots of useful functions for moving game objects around in world space. */ var Phaser; (function (Phaser) { var Motion = (function () { function Motion(game) { this._game = game; } Motion.prototype.computeVelocity = /** * A tween-like function that takes a starting velocity and some other factors and returns an altered velocity. * * @param Velocity Any component of velocity (e.g. 20). * @param Acceleration Rate at which the velocity is changing. * @param Drag Really kind of a deceleration, this is how much the velocity changes if Acceleration is not set. * @param Max An absolute value cap for the velocity. * * @return The altered Velocity value. */ function (Velocity, Acceleration, Drag, Max) { if (typeof Acceleration === "undefined") { Acceleration = 0; } if (typeof Drag === "undefined") { Drag = 0; } if (typeof Max === "undefined") { Max = 10000; } if(Acceleration !== 0) { Velocity += Acceleration * this._game.time.elapsed; } else if(Drag !== 0) { var drag = Drag * this._game.time.elapsed; if(Velocity - drag > 0) { Velocity = Velocity - drag; } else if(Velocity + drag < 0) { Velocity += drag; } else { Velocity = 0; } } if((Velocity != 0) && (Max != 10000)) { if(Velocity > Max) { Velocity = Max; } else if(Velocity < -Max) { Velocity = -Max; } } return Velocity; }; Motion.prototype.velocityFromAngle = /** * Given the angle and speed calculate the velocity and return it as a Point * * @param angle The angle (in degrees) calculated in clockwise positive direction (down = 90 degrees positive, right = 0 degrees positive, up = 90 degrees negative) * @param speed The speed it will move, in pixels per second sq * * @return A Point where Point.x contains the velocity x value and Point.y contains the velocity y value */ function (angle, speed) { if(isNaN(speed)) { speed = 0; } var a = this._game.math.degreesToRadians(angle); return new Phaser.Point((Math.cos(a) * speed), (Math.sin(a) * speed)); }; Motion.prototype.moveTowardsObject = /** * Sets the source Sprite x/y velocity so it will move directly towards the destination Sprite at the speed given (in pixels per second)
* If you specify a maxTime then it will adjust the speed (over-writing what you set) so it arrives at the destination in that number of seconds.
* Timings are approximate due to the way Flash timers work, and irrespective of SWF frame rate. Allow for a variance of +- 50ms.
* The source object doesn't stop moving automatically should it ever reach the destination coordinates.
* If you need the object to accelerate, see accelerateTowardsObject() instead * Note: Doesn't take into account acceleration, maxVelocity or drag (if you set drag or acceleration too high this object may not move at all) * * @param source The Sprite on which the velocity will be set * @param dest The Sprite where the source object will move to * @param speed The speed it will move, in pixels per second (default is 60 pixels/sec) * @param maxTime Time given in milliseconds (1000 = 1 sec). If set the speed is adjusted so the source will arrive at destination in the given number of ms */ function (source, dest, speed, maxTime) { if (typeof speed === "undefined") { speed = 60; } if (typeof maxTime === "undefined") { maxTime = 0; } var a = this.angleBetween(source, dest); if(maxTime > 0) { var d = this.distanceBetween(source, dest); // We know how many pixels we need to move, but how fast? speed = d / (maxTime / 1000); } source.velocity.x = Math.cos(a) * speed; source.velocity.y = Math.sin(a) * speed; }; Motion.prototype.accelerateTowardsObject = /** * Sets the x/y acceleration on the source Sprite so it will move towards the destination Sprite at the speed given (in pixels per second)
* You must give a maximum speed value, beyond which the Sprite won't go any faster.
* If you don't need acceleration look at moveTowardsObject() instead. * * @param source The Sprite on which the acceleration will be set * @param dest The Sprite where the source object will move towards * @param speed The speed it will accelerate in pixels per second * @param xSpeedMax The maximum speed in pixels per second in which the sprite can move horizontally * @param ySpeedMax The maximum speed in pixels per second in which the sprite can move vertically */ function (source, dest, speed, xSpeedMax, ySpeedMax) { var a = this.angleBetween(source, dest); source.velocity.x = 0; source.velocity.y = 0; source.acceleration.x = Math.cos(a) * speed; source.acceleration.y = Math.sin(a) * speed; source.maxVelocity.x = xSpeedMax; source.maxVelocity.y = ySpeedMax; }; Motion.prototype.moveTowardsMouse = /** * Move the given Sprite towards the mouse pointer coordinates at a steady velocity * If you specify a maxTime then it will adjust the speed (over-writing what you set) so it arrives at the destination in that number of seconds.
* Timings are approximate due to the way Flash timers work, and irrespective of SWF frame rate. Allow for a variance of +- 50ms.
* The source object doesn't stop moving automatically should it ever reach the destination coordinates.
* * @param source The Sprite to move * @param speed The speed it will move, in pixels per second (default is 60 pixels/sec) * @param maxTime Time given in milliseconds (1000 = 1 sec). If set the speed is adjusted so the source will arrive at destination in the given number of ms */ function (source, speed, maxTime) { if (typeof speed === "undefined") { speed = 60; } if (typeof maxTime === "undefined") { maxTime = 0; } var a = this.angleBetweenMouse(source); if(maxTime > 0) { var d = this.distanceToMouse(source); // We know how many pixels we need to move, but how fast? speed = d / (maxTime / 1000); } source.velocity.x = Math.cos(a) * speed; source.velocity.y = Math.sin(a) * speed; }; Motion.prototype.accelerateTowardsMouse = /** * Sets the x/y acceleration on the source Sprite so it will move towards the mouse coordinates at the speed given (in pixels per second)
* You must give a maximum speed value, beyond which the Sprite won't go any faster.
* If you don't need acceleration look at moveTowardsMouse() instead. * * @param source The Sprite on which the acceleration will be set * @param speed The speed it will accelerate in pixels per second * @param xSpeedMax The maximum speed in pixels per second in which the sprite can move horizontally * @param ySpeedMax The maximum speed in pixels per second in which the sprite can move vertically */ function (source, speed, xSpeedMax, ySpeedMax) { var a = this.angleBetweenMouse(source); source.velocity.x = 0; source.velocity.y = 0; source.acceleration.x = Math.cos(a) * speed; source.acceleration.y = Math.sin(a) * speed; source.maxVelocity.x = xSpeedMax; source.maxVelocity.y = ySpeedMax; }; Motion.prototype.moveTowardsPoint = /** * Sets the x/y velocity on the source Sprite so it will move towards the target coordinates at the speed given (in pixels per second)
* If you specify a maxTime then it will adjust the speed (over-writing what you set) so it arrives at the destination in that number of seconds.
* Timings are approximate due to the way Flash timers work, and irrespective of SWF frame rate. Allow for a variance of +- 50ms.
* The source object doesn't stop moving automatically should it ever reach the destination coordinates.
* * @param source The Sprite to move * @param target The Point coordinates to move the source Sprite towards * @param speed The speed it will move, in pixels per second (default is 60 pixels/sec) * @param maxTime Time given in milliseconds (1000 = 1 sec). If set the speed is adjusted so the source will arrive at destination in the given number of ms */ function (source, target, speed, maxTime) { if (typeof speed === "undefined") { speed = 60; } if (typeof maxTime === "undefined") { maxTime = 0; } var a = this.angleBetweenPoint(source, target); if(maxTime > 0) { var d = this.distanceToPoint(source, target); // We know how many pixels we need to move, but how fast? speed = d / (maxTime / 1000); } source.velocity.x = Math.cos(a) * speed; source.velocity.y = Math.sin(a) * speed; }; Motion.prototype.accelerateTowardsPoint = /** * Sets the x/y acceleration on the source Sprite so it will move towards the target coordinates at the speed given (in pixels per second)
* You must give a maximum speed value, beyond which the Sprite won't go any faster.
* If you don't need acceleration look at moveTowardsPoint() instead. * * @param source The Sprite on which the acceleration will be set * @param target The Point coordinates to move the source Sprite towards * @param speed The speed it will accelerate in pixels per second * @param xSpeedMax The maximum speed in pixels per second in which the sprite can move horizontally * @param ySpeedMax The maximum speed in pixels per second in which the sprite can move vertically */ function (source, target, speed, xSpeedMax, ySpeedMax) { var a = this.angleBetweenPoint(source, target); source.velocity.x = 0; source.velocity.y = 0; source.acceleration.x = Math.cos(a) * speed; source.acceleration.y = Math.sin(a) * speed; source.maxVelocity.x = xSpeedMax; source.maxVelocity.y = ySpeedMax; }; Motion.prototype.distanceBetween = /** * Find the distance (in pixels, rounded) between two Sprites, taking their origin into account * * @param a The first Sprite * @param b The second Sprite * @return int Distance (in pixels) */ function (a, b) { var dx = (a.x + a.origin.x) - (b.x + b.origin.x); var dy = (a.y + a.origin.y) - (b.y + b.origin.y); return this._game.math.vectorLength(dx, dy); }; Motion.prototype.distanceToPoint = /** * Find the distance (in pixels, rounded) from an Sprite to the given Point, taking the source origin into account * * @param a The Sprite * @param target The Point * @return int Distance (in pixels) */ function (a, target) { var dx = (a.x + a.origin.x) - (target.x); var dy = (a.y + a.origin.y) - (target.y); return this._game.math.vectorLength(dx, dy); }; Motion.prototype.distanceToMouse = /** * Find the distance (in pixels, rounded) from the object x/y and the mouse x/y * * @param a The Sprite to test against * @return int The distance between the given sprite and the mouse coordinates */ function (a) { var dx = (a.x + a.origin.x) - this._game.input.x; var dy = (a.y + a.origin.y) - this._game.input.y; return this._game.math.vectorLength(dx, dy); }; Motion.prototype.angleBetweenPoint = /** * Find the angle (in radians) between an Sprite and an Point. The source sprite takes its x/y and origin into account. * The angle is calculated in clockwise positive direction (down = 90 degrees positive, right = 0 degrees positive, up = 90 degrees negative) * * @param a The Sprite to test from * @param target The Point to angle the Sprite towards * @param asDegrees If you need the value in degrees instead of radians, set to true * * @return Number The angle (in radians unless asDegrees is true) */ function (a, target, asDegrees) { if (typeof asDegrees === "undefined") { asDegrees = false; } var dx = (target.x) - (a.x + a.origin.x); var dy = (target.y) - (a.y + a.origin.y); if(asDegrees) { return this._game.math.radiansToDegrees(Math.atan2(dy, dx)); } else { return Math.atan2(dy, dx); } }; Motion.prototype.angleBetween = /** * Find the angle (in radians) between the two Sprite, taking their x/y and origin into account. * The angle is calculated in clockwise positive direction (down = 90 degrees positive, right = 0 degrees positive, up = 90 degrees negative) * * @param a The Sprite to test from * @param b The Sprite to test to * @param asDegrees If you need the value in degrees instead of radians, set to true * * @return Number The angle (in radians unless asDegrees is true) */ function (a, b, asDegrees) { if (typeof asDegrees === "undefined") { asDegrees = false; } var dx = (b.x + b.origin.x) - (a.x + a.origin.x); var dy = (b.y + b.origin.y) - (a.y + a.origin.y); if(asDegrees) { return this._game.math.radiansToDegrees(Math.atan2(dy, dx)); } else { return Math.atan2(dy, dx); } }; Motion.prototype.velocityFromFacing = /** * Given the GameObject and speed calculate the velocity and return it as an Point based on the direction the sprite is facing * * @param parent The Sprite to get the facing value from * @param speed The speed it will move, in pixels per second sq * * @return An Point where Point.x contains the velocity x value and Point.y contains the velocity y value */ function (parent, speed) { var a; if(parent.facing == Phaser.Collision.LEFT) { a = this._game.math.degreesToRadians(180); } else if(parent.facing == Phaser.Collision.RIGHT) { a = this._game.math.degreesToRadians(0); } else if(parent.facing == Phaser.Collision.UP) { a = this._game.math.degreesToRadians(-90); } else if(parent.facing == Phaser.Collision.DOWN) { a = this._game.math.degreesToRadians(90); } return new Phaser.Point(Math.cos(a) * speed, Math.sin(a) * speed); }; Motion.prototype.angleBetweenMouse = /** * Find the angle (in radians) between an Sprite and the mouse, taking their x/y and origin into account. * The angle is calculated in clockwise positive direction (down = 90 degrees positive, right = 0 degrees positive, up = 90 degrees negative) * * @param a The Object to test from * @param asDegrees If you need the value in degrees instead of radians, set to true * * @return Number The angle (in radians unless asDegrees is true) */ function (a, asDegrees) { if (typeof asDegrees === "undefined") { asDegrees = false; } // In order to get the angle between the object and mouse, we need the objects screen coordinates (rather than world coordinates) var p = a.getScreenXY(); var dx = a._game.input.x - p.x; var dy = a._game.input.y - p.y; if(asDegrees) { return this._game.math.radiansToDegrees(Math.atan2(dy, dx)); } else { return Math.atan2(dy, dx); } }; return Motion; })(); Phaser.Motion = Motion; })(Phaser || (Phaser = {})); /// /// /** * Phaser - Sound * * A Sound file, used by the Game.SoundManager for playback. */ var Phaser; (function (Phaser) { var Sound = (function () { function Sound(context, gainNode, data, volume, loop) { if (typeof volume === "undefined") { volume = 1; } if (typeof loop === "undefined") { loop = false; } this.loop = false; this.isPlaying = false; this.isDecoding = false; this._context = context; this._gainNode = gainNode; this._buffer = data; this._volume = volume; this.loop = loop; // Local volume control if(this._context !== null) { this._localGainNode = this._context.createGainNode(); this._localGainNode.connect(this._gainNode); this._localGainNode.gain.value = this._volume; } if(this._buffer === null) { this.isDecoding = true; } else { this.play(); } } Sound.prototype.setDecodedBuffer = function (data) { this._buffer = data; this.isDecoding = false; this.play(); }; Sound.prototype.play = function () { if(this._buffer === null || this.isDecoding === true) { return; } this._sound = this._context.createBufferSource(); this._sound.buffer = this._buffer; this._sound.connect(this._localGainNode); if(this.loop) { this._sound.loop = true; } this._sound.noteOn(0)// the zero is vitally important, crashes iOS6 without it ; this.duration = this._sound.buffer.duration; this.isPlaying = true; }; Sound.prototype.stop = function () { if(this.isPlaying === true) { this.isPlaying = false; this._sound.noteOff(0); } }; Sound.prototype.mute = function () { this._localGainNode.gain.value = 0; }; Sound.prototype.unmute = function () { this._localGainNode.gain.value = this._volume; }; Object.defineProperty(Sound.prototype, "volume", { get: function () { return this._volume; }, set: function (value) { this._volume = value; this._localGainNode.gain.value = this._volume; }, enumerable: true, configurable: true }); return Sound; })(); Phaser.Sound = Sound; })(Phaser || (Phaser = {})); /// /// /** * Phaser - SoundManager * * This is an embroyonic web audio sound management class. There is a lot of work still to do here. */ var Phaser; (function (Phaser) { var SoundManager = (function () { function SoundManager(game) { this._context = null; this._game = game; if(game.device.webaudio == true) { if(!!window['AudioContext']) { this._context = new window['AudioContext'](); } else if(!!window['webkitAudioContext']) { this._context = new window['webkitAudioContext'](); } if(this._context !== null) { this._gainNode = this._context.createGainNode(); this._gainNode.connect(this._context.destination); this._volume = 1; } } } SoundManager.prototype.mute = function () { this._gainNode.gain.value = 0; }; SoundManager.prototype.unmute = function () { this._gainNode.gain.value = this._volume; }; Object.defineProperty(SoundManager.prototype, "volume", { get: function () { return this._volume; }, set: function (value) { this._volume = value; this._gainNode.gain.value = this._volume; }, enumerable: true, configurable: true }); SoundManager.prototype.decode = function (key, callback, sound) { if (typeof callback === "undefined") { callback = null; } if (typeof sound === "undefined") { sound = null; } var soundData = this._game.cache.getSound(key); if(soundData) { if(this._game.cache.isSoundDecoded(key) === false) { var that = this; this._context.decodeAudioData(soundData, function (buffer) { that._game.cache.decodedSound(key, buffer); if(sound) { sound.setDecodedBuffer(buffer); } callback(); }); } } }; SoundManager.prototype.play = function (key, volume, loop) { if (typeof volume === "undefined") { volume = 1; } if (typeof loop === "undefined") { loop = false; } var _this = this; if(this._context === null) { return; } var soundData = this._game.cache.getSound(key); if(soundData) { // Does the sound need decoding? if(this._game.cache.isSoundDecoded(key) === true) { return new Phaser.Sound(this._context, this._gainNode, soundData, volume, loop); } else { var tempSound = new Phaser.Sound(this._context, this._gainNode, null, volume, loop); // this is an async process, so we can return the Sound object anyway, it just won't be playing yet this.decode(key, function () { return _this.play(key); }, tempSound); return tempSound; } } }; return SoundManager; })(); Phaser.SoundManager = SoundManager; })(Phaser || (Phaser = {})); /** * Phaser * * v0.9.4 - April 28th 2013 * * A small and feature-packed 2D canvas game framework born from the firey pits of Flixel and Kiwi. * * Richard Davey (@photonstorm) * * Many thanks to Adam Saltsman (@ADAMATOMIC) for the original Flixel AS3 code on which Phaser is based. * * "If you want your children to be intelligent, read them fairy tales." * "If you want them to be more intelligent, read them more fairy tales." * -- Albert Einstein */ var Phaser; (function (Phaser) { Phaser.VERSION = 'Phaser version 0.9.4'; })(Phaser || (Phaser = {})); /// /** * Phaser - StageScaleMode * * This class controls the scaling of your game. On mobile devices it will also remove the URL bar and allow * you to maintain proportion and aspect ratio. * It is based on a technique taken from Viewporter v2.0 by Zynga Inc. http://github.com/zynga/viewporter */ var Phaser; (function (Phaser) { var StageScaleMode = (function () { function StageScaleMode(game) { var _this = this; this._startHeight = 0; this.width = 0; this.height = 0; this._game = game; this.orientation = window['orientation']; window.addEventListener('orientationchange', function (event) { return _this.checkOrientation(event); }, false); } StageScaleMode.EXACT_FIT = 0; StageScaleMode.NO_SCALE = 1; StageScaleMode.SHOW_ALL = 2; StageScaleMode.prototype.update = function () { if(this._game.stage.scaleMode !== StageScaleMode.NO_SCALE && (window.innerWidth !== this.width || window.innerHeight !== this.height)) { this.refresh(); } }; Object.defineProperty(StageScaleMode.prototype, "isLandscape", { get: function () { return window['orientation'] === 90 || window['orientation'] === -90; }, enumerable: true, configurable: true }); StageScaleMode.prototype.checkOrientation = function (event) { if(window['orientation'] !== this.orientation) { this.refresh(); this.orientation = window['orientation']; } }; StageScaleMode.prototype.refresh = function () { var _this = this; // We can't do anything about the status bars in iPads, web apps or desktops if(this._game.device.iPad == false && this._game.device.webApp == false && this._game.device.desktop == false) { document.documentElement.style.minHeight = '5000px'; this._startHeight = window.innerHeight; if(this._game.device.android && this._game.device.chrome == false) { window.scrollTo(0, 1); } else { window.scrollTo(0, 0); } } if(this._check == null) { this._iterations = 40; this._check = window.setInterval(function () { return _this.setScreenSize(); }, 10); } }; StageScaleMode.prototype.setScreenSize = function () { if(this._game.device.iPad == false && this._game.device.webApp == false && this._game.device.desktop == false) { if(this._game.device.android && this._game.device.chrome == false) { window.scrollTo(0, 1); } else { window.scrollTo(0, 0); } } this._iterations--; if(window.innerHeight > this._startHeight || this._iterations < 0) { // Set minimum height of content to new window height document.documentElement.style.minHeight = window.innerHeight + 'px'; if(this._game.stage.scaleMode == StageScaleMode.EXACT_FIT) { if(this._game.stage.maxScaleX && window.innerWidth > this._game.stage.maxScaleX) { this.width = this._game.stage.maxScaleX; } else { this.width = window.innerWidth; } if(this._game.stage.maxScaleY && window.innerHeight > this._game.stage.maxScaleY) { this.height = this._game.stage.maxScaleY; } else { this.height = window.innerHeight; } } else if(this._game.stage.scaleMode == StageScaleMode.SHOW_ALL) { var multiplier = Math.min((window.innerHeight / this._game.stage.height), (window.innerWidth / this._game.stage.width)); this.width = Math.round(this._game.stage.width * multiplier); this.height = Math.round(this._game.stage.height * multiplier); if(this._game.stage.maxScaleX && this.width > this._game.stage.maxScaleX) { this.width = this._game.stage.maxScaleX; } if(this._game.stage.maxScaleY && this.height > this._game.stage.maxScaleY) { this.height = this._game.stage.maxScaleY; } } this._game.stage.canvas.style.width = this.width + 'px'; this._game.stage.canvas.style.height = this.height + 'px'; this._game.input.scaleX = this._game.stage.width / this.width; this._game.input.scaleY = this._game.stage.height / this.height; clearInterval(this._check); this._check = null; } }; return StageScaleMode; })(); Phaser.StageScaleMode = StageScaleMode; })(Phaser || (Phaser = {})); /// /// /// /** * Phaser - Stage * * The Stage is the canvas on which everything is displayed. This class handles display within the web browser, focus handling, * resizing, scaling and pause/boot screens. */ var Phaser; (function (Phaser) { var Stage = (function () { function Stage(game, parent, width, height) { var _this = this; this.clear = true; this.disablePauseScreen = false; this.minScaleX = null; this.maxScaleX = null; this.minScaleY = null; this.maxScaleY = null; this._logo = "data:image/png;base64,iVBORw0KGgoAAAANSUhEUgAAABAAAAAQCAYAAAAf8/9hAAAAGXRFWHRTb2Z0d2FyZQBBZG9iZSBJbWFnZVJlYWR5ccllPAAAAO1JREFUeNpi/P//PwM6YGRkxBQEAqBaRnQxFmwa10d6MAjrMqMofHv5L1we2SBGmAtAktg0ogOQQYHLd8ANYYFpPtTmzUAMAFmwnsEDrAdkCAvMZlIAsiFMMAEYsKvaSrQhIMCELkGsV2AAbIC8gCQYgwKIUABiNYBf9yoYH7n7n6CzN274g2IYEyFbsNmKLIaSkHpP7WSwUfbA0ASzFQRslBlxp0RcAF0TRhggA3zhAJIDpUKU5A9KyshpHDkjFZu5g2nJMFcwXVJSgqIGnBKx5bKenh4w/XzVbgbPtlIUcVgSxuoCUgHIIIAAAwArtXwJBABO6QAAAABJRU5ErkJggg=="; this._game = game; this.canvas = document.createElement('canvas'); this.canvas.width = width; this.canvas.height = height; if(document.getElementById(parent)) { document.getElementById(parent).appendChild(this.canvas); document.getElementById(parent).style.overflow = 'hidden'; } else { document.body.appendChild(this.canvas); } // Consume default actions on the canvas this.canvas.style.msTouchAction = 'none'; this.canvas.style['touch-action'] = 'none'; this.context = this.canvas.getContext('2d'); this.offset = this.getOffset(this.canvas); this.bounds = new Phaser.Rectangle(this.offset.x, this.offset.y, width, height); this.aspectRatio = width / height; this.scaleMode = Phaser.StageScaleMode.NO_SCALE; this.scale = new Phaser.StageScaleMode(this._game); document.addEventListener('visibilitychange', function (event) { return _this.visibilityChange(event); }, false); document.addEventListener('webkitvisibilitychange', function (event) { return _this.visibilityChange(event); }, false); window.onblur = function (event) { return _this.visibilityChange(event); }; window.onfocus = function (event) { return _this.visibilityChange(event); }; } Stage.ORIENTATION_LANDSCAPE = 0; Stage.ORIENTATION_PORTRAIT = 1; Stage.prototype.update = function () { this.scale.update(); if(this.clear) { // implement dirty rect? could take up more cpu time than it saves. needs benching. this.context.clearRect(0, 0, this.width, this.height); } }; Stage.prototype.renderDebugInfo = function () { this.context.fillStyle = 'rgb(255,255,255)'; this.context.fillText(Phaser.VERSION, 10, 20); this.context.fillText('Game Size: ' + this.width + ' x ' + this.height, 10, 40); this.context.fillText('x: ' + this.x + ' y: ' + this.y, 10, 60); }; Stage.prototype.visibilityChange = //if (document['hidden'] === true || document['webkitHidden'] === true) function (event) { //console.log(event); if(this.disablePauseScreen) { return; } if(event.type == 'blur' && this._game.paused == false && this._game.isBooted == true) { this._game.paused = true; this.drawPauseScreen(); } else if(event.type == 'focus') { this._game.paused = false; } }; Stage.prototype.drawInitScreen = function () { this.context.fillStyle = 'rgb(40, 40, 40)'; this.context.fillRect(0, 0, this.width, this.height); this.context.fillStyle = 'rgb(255,255,255)'; this.context.font = 'bold 18px Arial'; this.context.textBaseline = 'top'; this.context.fillText(Phaser.VERSION, 54, 32); this.context.fillText('Game Size: ' + this.width + ' x ' + this.height, 32, 64); this.context.fillText('www.photonstorm.com', 32, 96); this.context.font = '16px Arial'; this.context.fillText('You are seeing this screen because you didn\'t specify any default', 32, 160); this.context.fillText('functions in the Game constructor, or use Game.loadState()', 32, 184); var image = new Image(); var that = this; image.onload = function () { that.context.drawImage(image, 32, 32); }; image.src = this._logo; }; Stage.prototype.drawPauseScreen = function () { this.saveCanvasValues(); this.context.fillStyle = 'rgba(0, 0, 0, 0.4)'; this.context.fillRect(0, 0, this.width, this.height); // Draw a 'play' arrow var arrowWidth = Math.round(this.width / 2); var arrowHeight = Math.round(this.height / 2); var sx = this.centerX - arrowWidth / 2; var sy = this.centerY - arrowHeight / 2; this.context.beginPath(); this.context.moveTo(sx, sy); this.context.lineTo(sx, sy + arrowHeight); this.context.lineTo(sx + arrowWidth, this.centerY); this.context.fillStyle = 'rgba(255, 255, 255, 0.8)'; this.context.fill(); this.context.closePath(); this.restoreCanvasValues(); }; Stage.prototype.getOffset = function (element) { var box = element.getBoundingClientRect(); var clientTop = element.clientTop || document.body.clientTop || 0; var clientLeft = element.clientLeft || document.body.clientLeft || 0; var scrollTop = window.pageYOffset || element.scrollTop || document.body.scrollTop; var scrollLeft = window.pageXOffset || element.scrollLeft || document.body.scrollLeft; return new Phaser.Point(box.left + scrollLeft - clientLeft, box.top + scrollTop - clientTop); }; Stage.prototype.saveCanvasValues = function () { this.strokeStyle = this.context.strokeStyle; this.lineWidth = this.context.lineWidth; this.fillStyle = this.context.fillStyle; }; Stage.prototype.restoreCanvasValues = function () { this.context.strokeStyle = this.strokeStyle; this.context.lineWidth = this.lineWidth; this.context.fillStyle = this.fillStyle; }; Object.defineProperty(Stage.prototype, "backgroundColor", { get: function () { return this._bgColor; }, set: function (color) { this.canvas.style.backgroundColor = color; }, enumerable: true, configurable: true }); Object.defineProperty(Stage.prototype, "x", { get: function () { return this.bounds.x; }, enumerable: true, configurable: true }); Object.defineProperty(Stage.prototype, "y", { get: function () { return this.bounds.y; }, enumerable: true, configurable: true }); Object.defineProperty(Stage.prototype, "width", { get: function () { return this.bounds.width; }, enumerable: true, configurable: true }); Object.defineProperty(Stage.prototype, "height", { get: function () { return this.bounds.height; }, enumerable: true, configurable: true }); Object.defineProperty(Stage.prototype, "centerX", { get: function () { return this.bounds.halfWidth; }, enumerable: true, configurable: true }); Object.defineProperty(Stage.prototype, "centerY", { get: function () { return this.bounds.halfHeight; }, enumerable: true, configurable: true }); Object.defineProperty(Stage.prototype, "randomX", { get: function () { return Math.round(Math.random() * this.bounds.width); }, enumerable: true, configurable: true }); Object.defineProperty(Stage.prototype, "randomY", { get: function () { return Math.round(Math.random() * this.bounds.height); }, enumerable: true, configurable: true }); return Stage; })(); Phaser.Stage = Stage; })(Phaser || (Phaser = {})); /// /** * Phaser - Time * * This is the game clock and it manages elapsed time and calculation of delta values, used for game object motion. */ var Phaser; (function (Phaser) { var Time = (function () { function Time(game) { this.timeScale = 1.0; this.elapsed = 0; /** * * @property time * @type Number */ this.time = 0; /** * * @property now * @type Number */ this.now = 0; /** * * @property delta * @type Number */ this.delta = 0; this.fps = 0; this.fpsMin = 1000; this.fpsMax = 0; this.msMin = 1000; this.msMax = 0; this.frames = 0; this._timeLastSecond = 0; this._started = Date.now(); this._timeLastSecond = this._started; this.time = this._started; } Object.defineProperty(Time.prototype, "totalElapsedSeconds", { get: /** * * @method totalElapsedSeconds * @return {Number} */ function () { return (this.now - this._started) * 0.001; }, enumerable: true, configurable: true }); Time.prototype.update = /** * * @method update */ function () { // Can we use performance.now() ? this.now = Date.now()// mark ; this.delta = this.now - this.time// elapsedMS ; this.msMin = Math.min(this.msMin, this.delta); this.msMax = Math.max(this.msMax, this.delta); this.frames++; if(this.now > this._timeLastSecond + 1000) { this.fps = Math.round((this.frames * 1000) / (this.now - this._timeLastSecond)); this.fpsMin = Math.min(this.fpsMin, this.fps); this.fpsMax = Math.max(this.fpsMax, this.fps); this._timeLastSecond = this.now; this.frames = 0; } this.time = this.now// _total ; //// Lock the delta at 0.1 to minimise fps tunneling //if (this.delta > 0.1) //{ // this.delta = 0.1; //} }; Time.prototype.elapsedSince = /** * * @method elapsedSince * @param {Number} since * @return {Number} */ function (since) { return this.now - since; }; Time.prototype.elapsedSecondsSince = /** * * @method elapsedSecondsSince * @param {Number} since * @return {Number} */ function (since) { return (this.now - since) * 0.001; }; Time.prototype.reset = /** * * @method reset */ function () { this._started = this.now; }; return Time; })(); Phaser.Time = Time; })(Phaser || (Phaser = {})); var Phaser; (function (Phaser) { /// /** * Phaser - Easing - Back * * For use with Phaser.Tween */ (function (Easing) { var Back = (function () { function Back() { } Back.In = function In(k) { var s = 1.70158; return k * k * ((s + 1) * k - s); }; Back.Out = function Out(k) { var s = 1.70158; return --k * k * ((s + 1) * k + s) + 1; }; Back.InOut = function InOut(k) { var s = 1.70158 * 1.525; if((k *= 2) < 1) { return 0.5 * (k * k * ((s + 1) * k - s)); } return 0.5 * ((k -= 2) * k * ((s + 1) * k + s) + 2); }; return Back; })(); Easing.Back = Back; })(Phaser.Easing || (Phaser.Easing = {})); var Easing = Phaser.Easing; })(Phaser || (Phaser = {})); var Phaser; (function (Phaser) { /// /** * Phaser - Easing - Bounce * * For use with Phaser.Tween */ (function (Easing) { var Bounce = (function () { function Bounce() { } Bounce.In = function In(k) { return 1 - Phaser.Easing.Bounce.Out(1 - k); }; Bounce.Out = function Out(k) { if(k < (1 / 2.75)) { return 7.5625 * k * k; } else if(k < (2 / 2.75)) { return 7.5625 * (k -= (1.5 / 2.75)) * k + 0.75; } else if(k < (2.5 / 2.75)) { return 7.5625 * (k -= (2.25 / 2.75)) * k + 0.9375; } else { return 7.5625 * (k -= (2.625 / 2.75)) * k + 0.984375; } }; Bounce.InOut = function InOut(k) { if(k < 0.5) { return Phaser.Easing.Bounce.In(k * 2) * 0.5; } return Phaser.Easing.Bounce.Out(k * 2 - 1) * 0.5 + 0.5; }; return Bounce; })(); Easing.Bounce = Bounce; })(Phaser.Easing || (Phaser.Easing = {})); var Easing = Phaser.Easing; })(Phaser || (Phaser = {})); var Phaser; (function (Phaser) { /// /** * Phaser - Easing - Circular * * For use with Phaser.Tween */ (function (Easing) { var Circular = (function () { function Circular() { } Circular.In = function In(k) { return 1 - Math.sqrt(1 - k * k); }; Circular.Out = function Out(k) { return Math.sqrt(1 - (--k * k)); }; Circular.InOut = function InOut(k) { if((k *= 2) < 1) { return -0.5 * (Math.sqrt(1 - k * k) - 1); } return 0.5 * (Math.sqrt(1 - (k -= 2) * k) + 1); }; return Circular; })(); Easing.Circular = Circular; })(Phaser.Easing || (Phaser.Easing = {})); var Easing = Phaser.Easing; })(Phaser || (Phaser = {})); var Phaser; (function (Phaser) { /// /** * Phaser - Easing - Cubic * * For use with Phaser.Tween */ (function (Easing) { var Cubic = (function () { function Cubic() { } Cubic.In = function In(k) { return k * k * k; }; Cubic.Out = function Out(k) { return --k * k * k + 1; }; Cubic.InOut = function InOut(k) { if((k *= 2) < 1) { return 0.5 * k * k * k; } return 0.5 * ((k -= 2) * k * k + 2); }; return Cubic; })(); Easing.Cubic = Cubic; })(Phaser.Easing || (Phaser.Easing = {})); var Easing = Phaser.Easing; })(Phaser || (Phaser = {})); var Phaser; (function (Phaser) { /// /** * Phaser - Easing - Elastic * * For use with Phaser.Tween */ (function (Easing) { var Elastic = (function () { function Elastic() { } Elastic.In = function In(k) { var s, a = 0.1, p = 0.4; if(k === 0) { return 0; } if(k === 1) { return 1; } if(!a || a < 1) { a = 1; s = p / 4; } else { s = p * Math.asin(1 / a) / (2 * Math.PI); } return -(a * Math.pow(2, 10 * (k -= 1)) * Math.sin((k - s) * (2 * Math.PI) / p)); }; Elastic.Out = function Out(k) { var s, a = 0.1, p = 0.4; if(k === 0) { return 0; } if(k === 1) { return 1; } if(!a || a < 1) { a = 1; s = p / 4; } else { s = p * Math.asin(1 / a) / (2 * Math.PI); } return (a * Math.pow(2, -10 * k) * Math.sin((k - s) * (2 * Math.PI) / p) + 1); }; Elastic.InOut = function InOut(k) { var s, a = 0.1, p = 0.4; if(k === 0) { return 0; } if(k === 1) { return 1; } if(!a || a < 1) { a = 1; s = p / 4; } else { s = p * Math.asin(1 / a) / (2 * Math.PI); } if((k *= 2) < 1) { return -0.5 * (a * Math.pow(2, 10 * (k -= 1)) * Math.sin((k - s) * (2 * Math.PI) / p)); } return a * Math.pow(2, -10 * (k -= 1)) * Math.sin((k - s) * (2 * Math.PI) / p) * 0.5 + 1; }; return Elastic; })(); Easing.Elastic = Elastic; })(Phaser.Easing || (Phaser.Easing = {})); var Easing = Phaser.Easing; })(Phaser || (Phaser = {})); var Phaser; (function (Phaser) { /// /** * Phaser - Easing - Exponential * * For use with Phaser.Tween */ (function (Easing) { var Exponential = (function () { function Exponential() { } Exponential.In = function In(k) { return k === 0 ? 0 : Math.pow(1024, k - 1); }; Exponential.Out = function Out(k) { return k === 1 ? 1 : 1 - Math.pow(2, -10 * k); }; Exponential.InOut = function InOut(k) { if(k === 0) { return 0; } if(k === 1) { return 1; } if((k *= 2) < 1) { return 0.5 * Math.pow(1024, k - 1); } return 0.5 * (-Math.pow(2, -10 * (k - 1)) + 2); }; return Exponential; })(); Easing.Exponential = Exponential; })(Phaser.Easing || (Phaser.Easing = {})); var Easing = Phaser.Easing; })(Phaser || (Phaser = {})); var Phaser; (function (Phaser) { /// /** * Phaser - Easing - Linear * * For use with Phaser.Tween */ (function (Easing) { var Linear = (function () { function Linear() { } Linear.None = function None(k) { return k; }; return Linear; })(); Easing.Linear = Linear; })(Phaser.Easing || (Phaser.Easing = {})); var Easing = Phaser.Easing; })(Phaser || (Phaser = {})); var Phaser; (function (Phaser) { /// /** * Phaser - Easing - Quadratic * * For use with Phaser.Tween */ (function (Easing) { var Quadratic = (function () { function Quadratic() { } Quadratic.In = function In(k) { return k * k; }; Quadratic.Out = function Out(k) { return k * (2 - k); }; Quadratic.InOut = function InOut(k) { if((k *= 2) < 1) { return 0.5 * k * k; } return -0.5 * (--k * (k - 2) - 1); }; return Quadratic; })(); Easing.Quadratic = Quadratic; })(Phaser.Easing || (Phaser.Easing = {})); var Easing = Phaser.Easing; })(Phaser || (Phaser = {})); var Phaser; (function (Phaser) { /// /** * Phaser - Easing - Quartic * * For use with Phaser.Tween */ (function (Easing) { var Quartic = (function () { function Quartic() { } Quartic.In = function In(k) { return k * k * k * k; }; Quartic.Out = function Out(k) { return 1 - (--k * k * k * k); }; Quartic.InOut = function InOut(k) { if((k *= 2) < 1) { return 0.5 * k * k * k * k; } return -0.5 * ((k -= 2) * k * k * k - 2); }; return Quartic; })(); Easing.Quartic = Quartic; })(Phaser.Easing || (Phaser.Easing = {})); var Easing = Phaser.Easing; })(Phaser || (Phaser = {})); var Phaser; (function (Phaser) { /// /** * Phaser - Easing - Quintic * * For use with Phaser.Tween */ (function (Easing) { var Quintic = (function () { function Quintic() { } Quintic.In = function In(k) { return k * k * k * k * k; }; Quintic.Out = function Out(k) { return --k * k * k * k * k + 1; }; Quintic.InOut = function InOut(k) { if((k *= 2) < 1) { return 0.5 * k * k * k * k * k; } return 0.5 * ((k -= 2) * k * k * k * k + 2); }; return Quintic; })(); Easing.Quintic = Quintic; })(Phaser.Easing || (Phaser.Easing = {})); var Easing = Phaser.Easing; })(Phaser || (Phaser = {})); var Phaser; (function (Phaser) { /// /** * Phaser - Easing - Sinusoidal * * For use with Phaser.Tween */ (function (Easing) { var Sinusoidal = (function () { function Sinusoidal() { } Sinusoidal.In = function In(k) { return 1 - Math.cos(k * Math.PI / 2); }; Sinusoidal.Out = function Out(k) { return Math.sin(k * Math.PI / 2); }; Sinusoidal.InOut = function InOut(k) { return 0.5 * (1 - Math.cos(Math.PI * k)); }; return Sinusoidal; })(); Easing.Sinusoidal = Sinusoidal; })(Phaser.Easing || (Phaser.Easing = {})); var Easing = Phaser.Easing; })(Phaser || (Phaser = {})); /// /// /// /// /// /// /// /// /// /// /// /// /** * Phaser - Tween * * Based heavily on tween.js by sole (https://github.com/sole/tween.js) converted to TypeScript and integrated into Phaser */ var Phaser; (function (Phaser) { var Tween = (function () { function Tween(object, game) { this._object = null; this._pausedTime = 0; this._valuesStart = { }; this._valuesEnd = { }; this._duration = 1000; this._delayTime = 0; this._startTime = null; this._chainedTweens = []; this._object = object; this._game = game; this._manager = this._game.tweens; this._interpolationFunction = this._game.math.linearInterpolation; this._easingFunction = Phaser.Easing.Linear.None; this.onStart = new Phaser.Signal(); this.onUpdate = new Phaser.Signal(); this.onComplete = new Phaser.Signal(); } Tween.prototype.to = function (properties, duration, ease, autoStart) { if (typeof duration === "undefined") { duration = 1000; } if (typeof ease === "undefined") { ease = null; } if (typeof autoStart === "undefined") { autoStart = false; } this._duration = duration; // If properties isn't an object this will fail, sanity check it here somehow? this._valuesEnd = properties; if(ease !== null) { this._easingFunction = ease; } if(autoStart === true) { return this.start(); } else { return this; } }; Tween.prototype.start = function () { if(this._game === null || this._object === null) { return; } this._manager.add(this); this.onStart.dispatch(this._object); this._startTime = this._game.time.now + this._delayTime; for(var property in this._valuesEnd) { // This prevents the interpolation of null values or of non-existing properties if(this._object[property] === null || !(property in this._object)) { throw Error('Phaser.Tween interpolation of null value of non-existing property'); continue; } // check if an Array was provided as property value if(this._valuesEnd[property] instanceof Array) { if(this._valuesEnd[property].length === 0) { continue; } // create a local copy of the Array with the start value at the front this._valuesEnd[property] = [ this._object[property] ].concat(this._valuesEnd[property]); } this._valuesStart[property] = this._object[property]; } return this; }; Tween.prototype.stop = function () { if(this._manager !== null) { this._manager.remove(this); } return this; }; Object.defineProperty(Tween.prototype, "parent", { set: function (value) { this._game = value; this._manager = this._game.tweens; }, enumerable: true, configurable: true }); Object.defineProperty(Tween.prototype, "delay", { get: function () { return this._delayTime; }, set: function (amount) { this._delayTime = amount; }, enumerable: true, configurable: true }); Object.defineProperty(Tween.prototype, "easing", { get: function () { return this._easingFunction; }, set: function (easing) { this._easingFunction = easing; }, enumerable: true, configurable: true }); Object.defineProperty(Tween.prototype, "interpolation", { get: function () { return this._interpolationFunction; }, set: function (interpolation) { this._interpolationFunction = interpolation; }, enumerable: true, configurable: true }); Tween.prototype.chain = function (tween) { this._chainedTweens.push(tween); return this; }; Tween.prototype.update = function (time) { if(this._game.paused == true) { if(this._pausedTime == 0) { this._pausedTime = time; } } else { // Ok we aren't paused, but was there some time gained? if(this._pausedTime > 0) { this._startTime += (time - this._pausedTime); this._pausedTime = 0; } } if(time < this._startTime) { return true; } var elapsed = (time - this._startTime) / this._duration; elapsed = elapsed > 1 ? 1 : elapsed; var value = this._easingFunction(elapsed); for(var property in this._valuesStart) { // Add checks for object, array, numeric up front if(this._valuesEnd[property] instanceof Array) { this._object[property] = this._interpolationFunction(this._valuesEnd[property], value); } else { this._object[property] = this._valuesStart[property] + (this._valuesEnd[property] - this._valuesStart[property]) * value; } } this.onUpdate.dispatch(this._object, value); if(elapsed == 1) { this.onComplete.dispatch(this._object); for(var i = 0; i < this._chainedTweens.length; i++) { this._chainedTweens[i].start(); } return false; } return true; }; return Tween; })(); Phaser.Tween = Tween; })(Phaser || (Phaser = {})); /// /// /** * Phaser - TweenManager * * The Game has a single instance of the TweenManager through which all Tween objects are created and updated. * Tweens are hooked into the game clock and pause system, adjusting based on the game state. * TweenManager is based heavily on tween.js by sole (http://soledadpenades.com). * I converted it to TypeScript, swapped the callbacks for signals and patched a few issues with regard * to properties and completion errors. Please see https://github.com/sole/tween.js for a full list of contributors. */ var Phaser; (function (Phaser) { var TweenManager = (function () { function TweenManager(game) { this._game = game; this._tweens = []; } TweenManager.prototype.getAll = function () { return this._tweens; }; TweenManager.prototype.removeAll = function () { this._tweens.length = 0; }; TweenManager.prototype.create = function (object) { return new Phaser.Tween(object, this._game); }; TweenManager.prototype.add = function (tween) { tween.parent = this._game; this._tweens.push(tween); return tween; }; TweenManager.prototype.remove = function (tween) { var i = this._tweens.indexOf(tween); if(i !== -1) { this._tweens.splice(i, 1); } }; TweenManager.prototype.update = function () { if(this._tweens.length === 0) { return false; } var i = 0; var numTweens = this._tweens.length; while(i < numTweens) { if(this._tweens[i].update(this._game.time.now)) { i++; } else { this._tweens.splice(i, 1); numTweens--; } } return true; }; return TweenManager; })(); Phaser.TweenManager = TweenManager; })(Phaser || (Phaser = {})); /// /** * Phaser - World * * A game has only one world. The world is an abstract place in which all game objects live. It is not bound * by stage limits and can be any size or dimension. You look into the world via cameras and all game objects * live within the world at world-based coordinates. By default a world is created the same size as your Stage. */ var Phaser; (function (Phaser) { var World = (function () { function World(game, width, height) { this._game = game; this.cameras = new Phaser.CameraManager(this._game, 0, 0, width, height); this._game.camera = this.cameras.current; this.group = new Phaser.Group(this._game, 0); this.bounds = new Phaser.Rectangle(0, 0, width, height); this.worldDivisions = 6; } World.prototype.update = function () { this.group.preUpdate(); this.group.update(); this.group.postUpdate(); this.cameras.update(); }; World.prototype.render = function () { // Unlike in flixel our render process is camera driven, not group driven this.cameras.render(); }; World.prototype.destroy = function () { this.group.destroy(); this.cameras.destroy(); }; World.prototype.setSize = // World methods function (width, height, updateCameraBounds) { if (typeof updateCameraBounds === "undefined") { updateCameraBounds = true; } this.bounds.width = width; this.bounds.height = height; if(updateCameraBounds == true) { this._game.camera.setBounds(0, 0, width, height); } }; Object.defineProperty(World.prototype, "width", { get: function () { return this.bounds.width; }, set: function (value) { this.bounds.width = value; }, enumerable: true, configurable: true }); Object.defineProperty(World.prototype, "height", { get: function () { return this.bounds.height; }, set: function (value) { this.bounds.height = value; }, enumerable: true, configurable: true }); Object.defineProperty(World.prototype, "centerX", { get: function () { return this.bounds.halfWidth; }, enumerable: true, configurable: true }); Object.defineProperty(World.prototype, "centerY", { get: function () { return this.bounds.halfHeight; }, enumerable: true, configurable: true }); Object.defineProperty(World.prototype, "randomX", { get: function () { return Math.round(Math.random() * this.bounds.width); }, enumerable: true, configurable: true }); Object.defineProperty(World.prototype, "randomY", { get: function () { return Math.round(Math.random() * this.bounds.height); }, enumerable: true, configurable: true }); World.prototype.createCamera = // Cameras function (x, y, width, height) { return this.cameras.addCamera(x, y, width, height); }; World.prototype.removeCamera = function (id) { return this.cameras.removeCamera(id); }; World.prototype.getAllCameras = function () { return this.cameras.getAll(); }; World.prototype.createSprite = // Game Objects function (x, y, key) { if (typeof key === "undefined") { key = ''; } return this.group.add(new Phaser.Sprite(this._game, x, y, key)); }; World.prototype.createGeomSprite = function (x, y) { return this.group.add(new Phaser.GeomSprite(this._game, x, y)); }; World.prototype.createDynamicTexture = function (width, height) { return new Phaser.DynamicTexture(this._game, width, height); }; World.prototype.createGroup = function (MaxSize) { if (typeof MaxSize === "undefined") { MaxSize = 0; } return this.group.add(new Phaser.Group(this._game, MaxSize)); }; World.prototype.createScrollZone = function (key, x, y, width, height) { if (typeof x === "undefined") { x = 0; } if (typeof y === "undefined") { y = 0; } if (typeof width === "undefined") { width = 0; } if (typeof height === "undefined") { height = 0; } return this.group.add(new Phaser.ScrollZone(this._game, key, x, y, width, height)); }; World.prototype.createTilemap = function (key, mapData, format, resizeWorld, tileWidth, tileHeight) { if (typeof resizeWorld === "undefined") { resizeWorld = true; } if (typeof tileWidth === "undefined") { tileWidth = 0; } if (typeof tileHeight === "undefined") { tileHeight = 0; } return this.group.add(new Phaser.Tilemap(this._game, key, mapData, format, resizeWorld, tileWidth, tileHeight)); }; World.prototype.createParticle = function () { return new Phaser.Particle(this._game); }; World.prototype.createEmitter = function (x, y, size) { if (typeof x === "undefined") { x = 0; } if (typeof y === "undefined") { y = 0; } if (typeof size === "undefined") { size = 0; } return this.group.add(new Phaser.Emitter(this._game, x, y, size)); }; return World; })(); Phaser.World = World; })(Phaser || (Phaser = {})); /// /** * Phaser - Device * * Detects device support capabilities. Using some elements from System.js by MrDoob and Modernizr * https://github.com/Modernizr/Modernizr/blob/master/feature-detects/audio.js */ var Phaser; (function (Phaser) { var Device = (function () { /** * * @constructor * @return {Device} This Object */ function Device() { // Operating System this.desktop = false; /** * * @property iOS * @type Boolean */ this.iOS = false; /** * * @property android * @type Boolean */ this.android = false; /** * * @property chromeOS * @type Boolean */ this.chromeOS = false; /** * * @property linux * @type Boolean */ this.linux = false; /** * * @property maxOS * @type Boolean */ this.macOS = false; /** * * @property windows * @type Boolean */ this.windows = false; // Features /** * * @property canvas * @type Boolean */ this.canvas = false; /** * * @property file * @type Boolean */ this.file = false; /** * * @property fileSystem * @type Boolean */ this.fileSystem = false; /** * * @property localStorage * @type Boolean */ this.localStorage = false; /** * * @property webGL * @type Boolean */ this.webGL = false; /** * * @property worker * @type Boolean */ this.worker = false; /** * * @property touch * @type Boolean */ this.touch = false; /** * * @property css3D * @type Boolean */ this.css3D = false; // Browser /** * * @property arora * @type Boolean */ this.arora = false; /** * * @property chrome * @type Boolean */ this.chrome = false; /** * * @property epiphany * @type Boolean */ this.epiphany = false; /** * * @property firefox * @type Boolean */ this.firefox = false; /** * * @property ie * @type Boolean */ this.ie = false; /** * * @property ieVersion * @type Number */ this.ieVersion = 0; /** * * @property mobileSafari * @type Boolean */ this.mobileSafari = false; /** * * @property midori * @type Boolean */ this.midori = false; /** * * @property opera * @type Boolean */ this.opera = false; /** * * @property safari * @type Boolean */ this.safari = false; this.webApp = false; // Audio /** * * @property audioData * @type Boolean */ this.audioData = false; /** * * @property webaudio * @type Boolean */ this.webaudio = false; /** * * @property ogg * @type Boolean */ this.ogg = false; /** * * @property mp3 * @type Boolean */ this.mp3 = false; /** * * @property wav * @type Boolean */ this.wav = false; /** * * @property m4a * @type Boolean */ this.m4a = false; // Device /** * * @property iPhone * @type Boolean */ this.iPhone = false; /** * * @property iPhone4 * @type Boolean */ this.iPhone4 = false; /** * * @property iPad * @type Boolean */ this.iPad = false; /** * * @property pixelRatio * @type Number */ this.pixelRatio = 0; this._checkAudio(); this._checkBrowser(); this._checkCSS3D(); this._checkDevice(); this._checkFeatures(); this._checkOS(); } Device.prototype._checkOS = /** * * @method _checkOS * @private */ function () { var ua = navigator.userAgent; if(/Android/.test(ua)) { this.android = true; } else if(/CrOS/.test(ua)) { this.chromeOS = true; } else if(/iP[ao]d|iPhone/i.test(ua)) { this.iOS = true; } else if(/Linux/.test(ua)) { this.linux = true; } else if(/Mac OS/.test(ua)) { this.macOS = true; } else if(/Windows/.test(ua)) { this.windows = true; } if(this.windows || this.macOS || this.linux) { this.desktop = true; } }; Device.prototype._checkFeatures = /** * * @method _checkFeatures * @private */ function () { this.canvas = !!window['CanvasRenderingContext2D']; try { this.localStorage = !!localStorage.getItem; } catch (error) { this.localStorage = false; } this.file = !!window['File'] && !!window['FileReader'] && !!window['FileList'] && !!window['Blob']; this.fileSystem = !!window['requestFileSystem']; this.webGL = !!window['WebGLRenderingContext']; this.worker = !!window['Worker']; if('ontouchstart' in document.documentElement || window.navigator.msPointerEnabled) { this.touch = true; } }; Device.prototype._checkBrowser = /** * * @method _checkBrowser * @private */ function () { var ua = navigator.userAgent; if(/Arora/.test(ua)) { this.arora = true; } else if(/Chrome/.test(ua)) { this.chrome = true; } else if(/Epiphany/.test(ua)) { this.epiphany = true; } else if(/Firefox/.test(ua)) { this.firefox = true; } else if(/Mobile Safari/.test(ua)) { this.mobileSafari = true; } else if(/MSIE (\d+\.\d+);/.test(ua)) { this.ie = true; this.ieVersion = parseInt(RegExp.$1); } else if(/Midori/.test(ua)) { this.midori = true; } else if(/Opera/.test(ua)) { this.opera = true; } else if(/Safari/.test(ua)) { this.safari = true; } // WebApp mode in iOS if(navigator['standalone']) { this.webApp = true; } }; Device.prototype._checkAudio = /** * * @method _checkAudio * @private */ function () { this.audioData = !!(window['Audio']); this.webaudio = !!(window['webkitAudioContext'] || window['AudioContext']); var audioElement = document.createElement('audio'); var result = false; try { if(result = !!audioElement.canPlayType) { if(audioElement.canPlayType('audio/ogg; codecs="vorbis"').replace(/^no$/, '')) { this.ogg = true; } if(audioElement.canPlayType('audio/mpeg;').replace(/^no$/, '')) { this.mp3 = true; } // Mimetypes accepted: // developer.mozilla.org/En/Media_formats_supported_by_the_audio_and_video_elements // bit.ly/iphoneoscodecs if(audioElement.canPlayType('audio/wav; codecs="1"').replace(/^no$/, '')) { this.wav = true; } if(audioElement.canPlayType('audio/x-m4a;') || audioElement.canPlayType('audio/aac;').replace(/^no$/, '')) { this.m4a = true; } } } catch (e) { } }; Device.prototype._checkDevice = /** * * @method _checkDevice * @private */ function () { this.pixelRatio = window['devicePixelRatio'] || 1; this.iPhone = navigator.userAgent.toLowerCase().indexOf('iphone') != -1; this.iPhone4 = (this.pixelRatio == 2 && this.iPhone); this.iPad = navigator.userAgent.toLowerCase().indexOf('ipad') != -1; }; Device.prototype._checkCSS3D = /** * * @method _checkCSS3D * @private */ function () { var el = document.createElement('p'); var has3d; var transforms = { 'webkitTransform': '-webkit-transform', 'OTransform': '-o-transform', 'msTransform': '-ms-transform', 'MozTransform': '-moz-transform', 'transform': 'transform' }; // Add it to the body to get the computed style. document.body.insertBefore(el, null); for(var t in transforms) { if(el.style[t] !== undefined) { el.style[t] = "translate3d(1px,1px,1px)"; has3d = window.getComputedStyle(el).getPropertyValue(transforms[t]); } } document.body.removeChild(el); this.css3D = (has3d !== undefined && has3d.length > 0 && has3d !== "none"); }; Device.prototype.getAll = /** * * @method getAll * @return {String} */ function () { var output = ''; output = output.concat('Device\n'); output = output.concat('iPhone : ' + this.iPhone + '\n'); output = output.concat('iPhone4 : ' + this.iPhone4 + '\n'); output = output.concat('iPad : ' + this.iPad + '\n'); output = output.concat('\n'); output = output.concat('Operating System\n'); output = output.concat('iOS: ' + this.iOS + '\n'); output = output.concat('Android: ' + this.android + '\n'); output = output.concat('ChromeOS: ' + this.chromeOS + '\n'); output = output.concat('Linux: ' + this.linux + '\n'); output = output.concat('MacOS: ' + this.macOS + '\n'); output = output.concat('Windows: ' + this.windows + '\n'); output = output.concat('\n'); output = output.concat('Browser\n'); output = output.concat('Arora: ' + this.arora + '\n'); output = output.concat('Chrome: ' + this.chrome + '\n'); output = output.concat('Epiphany: ' + this.epiphany + '\n'); output = output.concat('Firefox: ' + this.firefox + '\n'); output = output.concat('Internet Explorer: ' + this.ie + ' (' + this.ieVersion + ')\n'); output = output.concat('Mobile Safari: ' + this.mobileSafari + '\n'); output = output.concat('Midori: ' + this.midori + '\n'); output = output.concat('Opera: ' + this.opera + '\n'); output = output.concat('Safari: ' + this.safari + '\n'); output = output.concat('\n'); output = output.concat('Features\n'); output = output.concat('Canvas: ' + this.canvas + '\n'); output = output.concat('File: ' + this.file + '\n'); output = output.concat('FileSystem: ' + this.fileSystem + '\n'); output = output.concat('LocalStorage: ' + this.localStorage + '\n'); output = output.concat('WebGL: ' + this.webGL + '\n'); output = output.concat('Worker: ' + this.worker + '\n'); output = output.concat('Touch: ' + this.touch + '\n'); output = output.concat('CSS 3D: ' + this.css3D + '\n'); output = output.concat('\n'); output = output.concat('Audio\n'); output = output.concat('Audio Data: ' + this.canvas + '\n'); output = output.concat('Web Audio: ' + this.canvas + '\n'); output = output.concat('Can play OGG: ' + this.canvas + '\n'); output = output.concat('Can play MP3: ' + this.canvas + '\n'); output = output.concat('Can play M4A: ' + this.canvas + '\n'); output = output.concat('Can play WAV: ' + this.canvas + '\n'); return output; }; return Device; })(); Phaser.Device = Device; })(Phaser || (Phaser = {})); /// /** * Phaser - RandomDataGenerator * * An extremely useful repeatable random data generator. Access it via Game.rnd * Based on Nonsense by Josh Faul https://github.com/jocafa/Nonsense * Random number generator from http://baagoe.org/en/wiki/Better_random_numbers_for_javascript */ var Phaser; (function (Phaser) { var RandomDataGenerator = (function () { /** * @constructor * @param {Array} seeds * @return {Phaser.RandomDataGenerator} */ function RandomDataGenerator(seeds) { if (typeof seeds === "undefined") { seeds = []; } /** * @property c * @type Number * @private */ this.c = 1; this.sow(seeds); } RandomDataGenerator.prototype.uint32 = /** * @method uint32 * @private */ function () { return this.rnd.apply(this) * 0x100000000;// 2^32 }; RandomDataGenerator.prototype.fract32 = /** * @method fract32 * @private */ function () { return this.rnd.apply(this) + (this.rnd.apply(this) * 0x200000 | 0) * 1.1102230246251565e-16;// 2^-53 }; RandomDataGenerator.prototype.rnd = // private random helper /** * @method rnd * @private */ function () { var t = 2091639 * this.s0 + this.c * 2.3283064365386963e-10;// 2^-32 this.c = t | 0; this.s0 = this.s1; this.s1 = this.s2; this.s2 = t - this.c; return this.s2; }; RandomDataGenerator.prototype.hash = /** * @method hash * @param {Any} data * @private */ function (data) { var h, i, n; n = 0xefc8249d; data = data.toString(); for(i = 0; i < data.length; i++) { n += data.charCodeAt(i); h = 0.02519603282416938 * n; n = h >>> 0; h -= n; h *= n; n = h >>> 0; h -= n; n += h * 0x100000000// 2^32 ; } return (n >>> 0) * 2.3283064365386963e-10;// 2^-32 }; RandomDataGenerator.prototype.sow = /** * Reset the seed of the random data generator * @method sow * @param {Array} seeds */ function (seeds) { if (typeof seeds === "undefined") { seeds = []; } this.s0 = this.hash(' '); this.s1 = this.hash(this.s0); this.s2 = this.hash(this.s1); var seed; for(var i = 0; seed = seeds[i++]; ) { this.s0 -= this.hash(seed); this.s0 += ~~(this.s0 < 0); this.s1 -= this.hash(seed); this.s1 += ~~(this.s1 < 0); this.s2 -= this.hash(seed); this.s2 += ~~(this.s2 < 0); } }; Object.defineProperty(RandomDataGenerator.prototype, "integer", { get: /** * Returns a random integer between 0 and 2^32 * @method integer * @return {Number} */ function () { return this.uint32(); }, enumerable: true, configurable: true }); Object.defineProperty(RandomDataGenerator.prototype, "frac", { get: /** * Returns a random real number between 0 and 1 * @method frac * @return {Number} */ function () { return this.fract32(); }, enumerable: true, configurable: true }); Object.defineProperty(RandomDataGenerator.prototype, "real", { get: /** * Returns a random real number between 0 and 2^32 * @method real * @return {Number} */ function () { return this.uint32() + this.fract32(); }, enumerable: true, configurable: true }); RandomDataGenerator.prototype.integerInRange = /** * Returns a random integer between min and max * @method integerInRange * @param {Number} min * @param {Number} max * @return {Number} */ function (min, max) { return Math.floor(this.realInRange(min, max)); }; RandomDataGenerator.prototype.realInRange = /** * Returns a random real number between min and max * @method realInRange * @param {Number} min * @param {Number} max * @return {Number} */ function (min, max) { min = min || 0; max = max || 0; return this.frac * (max - min) + min; }; Object.defineProperty(RandomDataGenerator.prototype, "normal", { get: /** * Returns a random real number between -1 and 1 * @method normal * @return {Number} */ function () { return 1 - 2 * this.frac; }, enumerable: true, configurable: true }); Object.defineProperty(RandomDataGenerator.prototype, "uuid", { get: /** * Returns a valid v4 UUID hex string (from https://gist.github.com/1308368) * @method uuid * @return {String} */ function () { var a, b; for(b = a = ''; a++ < 36; b += ~a % 5 | a * 3 & 4 ? (a ^ 15 ? 8 ^ this.frac * (a ^ 20 ? 16 : 4) : 4).toString(16) : '-') { ; } return b; }, enumerable: true, configurable: true }); RandomDataGenerator.prototype.pick = /** * Returns a random member of `array` * @method pick * @param {Any} array */ function (array) { return array[this.integerInRange(0, array.length)]; }; RandomDataGenerator.prototype.weightedPick = /** * Returns a random member of `array`, favoring the earlier entries * @method weightedPick * @param {Any} array */ function (array) { return array[~~(Math.pow(this.frac, 2) * array.length)]; }; RandomDataGenerator.prototype.timestamp = /** * Returns a random timestamp between min and max, or between the beginning of 2000 and the end of 2020 if min and max aren't specified * @method timestamp * @param {Number} min * @param {Number} max */ function (min, max) { if (typeof min === "undefined") { min = 946684800000; } if (typeof max === "undefined") { max = 1577862000000; } return this.realInRange(min, max); }; Object.defineProperty(RandomDataGenerator.prototype, "angle", { get: /** * Returns a random angle between -180 and 180 * @method angle */ function () { return this.integerInRange(-180, 180); }, enumerable: true, configurable: true }); return RandomDataGenerator; })(); Phaser.RandomDataGenerator = RandomDataGenerator; })(Phaser || (Phaser = {})); /// /** * Phaser - RequestAnimationFrame * * Abstracts away the use of RAF or setTimeOut for the core game update loop. The callback can be re-mapped on the fly. */ var Phaser; (function (Phaser) { var RequestAnimationFrame = (function () { /** * Constructor * @param {Any} callback * @return {RequestAnimationFrame} This object. */ function RequestAnimationFrame(callback, callbackContext) { /** * * @property _isSetTimeOut * @type Boolean * @private **/ this._isSetTimeOut = false; /** * * @property lastTime * @type Number **/ this.lastTime = 0; /** * * @property currentTime * @type Number **/ this.currentTime = 0; /** * * @property isRunning * @type Boolean **/ this.isRunning = false; this._callback = callback; this._callbackContext = callbackContext; var vendors = [ 'ms', 'moz', 'webkit', 'o' ]; for(var x = 0; x < vendors.length && !window.requestAnimationFrame; x++) { window.requestAnimationFrame = window[vendors[x] + 'RequestAnimationFrame']; window.cancelAnimationFrame = window[vendors[x] + 'CancelAnimationFrame']; } this.start(); } RequestAnimationFrame.prototype.setCallback = /** * * @method callback * @param {Any} callback **/ function (callback) { this._callback = callback; }; RequestAnimationFrame.prototype.isUsingSetTimeOut = /** * * @method usingSetTimeOut * @return Boolean **/ function () { return this._isSetTimeOut; }; RequestAnimationFrame.prototype.isUsingRAF = /** * * @method usingRAF * @return Boolean **/ function () { if(this._isSetTimeOut === true) { return false; } else { return true; } }; RequestAnimationFrame.prototype.start = /** * * @method start * @param {Any} [callback] **/ function (callback) { if (typeof callback === "undefined") { callback = null; } var _this = this; if(callback) { this._callback = callback; } if(!window.requestAnimationFrame) { this._isSetTimeOut = true; this._timeOutID = window.setTimeout(function () { return _this.SetTimeoutUpdate(); }, 0); } else { this._isSetTimeOut = false; window.requestAnimationFrame(function () { return _this.RAFUpdate(); }); } this.isRunning = true; }; RequestAnimationFrame.prototype.stop = /** * * @method stop **/ function () { if(this._isSetTimeOut) { clearTimeout(this._timeOutID); } else { window.cancelAnimationFrame; } this.isRunning = false; }; RequestAnimationFrame.prototype.RAFUpdate = function () { var _this = this; // Not in IE8 (but neither is RAF) also doesn't use a high performance timer (window.performance.now) this.currentTime = Date.now(); if(this._callback) { this._callback.call(this._callbackContext); } var timeToCall = Math.max(0, 16 - (this.currentTime - this.lastTime)); window.requestAnimationFrame(function () { return _this.RAFUpdate(); }); this.lastTime = this.currentTime + timeToCall; }; RequestAnimationFrame.prototype.SetTimeoutUpdate = /** * * @method SetTimeoutUpdate **/ function () { var _this = this; // Not in IE8 this.currentTime = Date.now(); if(this._callback) { this._callback.call(this._callbackContext); } var timeToCall = Math.max(0, 16 - (this.currentTime - this.lastTime)); this._timeOutID = window.setTimeout(function () { return _this.SetTimeoutUpdate(); }, timeToCall); this.lastTime = this.currentTime + timeToCall; }; return RequestAnimationFrame; })(); Phaser.RequestAnimationFrame = RequestAnimationFrame; })(Phaser || (Phaser = {})); /// /// /** * Phaser - Input * * A game specific Input manager that looks after the mouse, keyboard and touch objects. This is updated by the core game loop. */ var Phaser; (function (Phaser) { var Input = (function () { function Input(game) { this.x = 0; this.y = 0; this.scaleX = 1; this.scaleY = 1; this.worldX = 0; this.worldY = 0; this._game = game; this.mouse = new Phaser.Mouse(this._game); this.keyboard = new Phaser.Keyboard(this._game); this.touch = new Phaser.Touch(this._game); this.onDown = new Phaser.Signal(); this.onUp = new Phaser.Signal(); } Input.prototype.update = function () { this.x = Math.round(this.x); this.y = Math.round(this.y); this.worldX = this._game.camera.worldView.x + this.x; this.worldY = this._game.camera.worldView.y + this.y; this.mouse.update(); this.touch.update(); }; Input.prototype.reset = function () { this.mouse.reset(); this.keyboard.reset(); this.touch.reset(); }; Input.prototype.getWorldX = function (camera) { if (typeof camera === "undefined") { camera = this._game.camera; } return camera.worldView.x + this.x; }; Input.prototype.getWorldY = function (camera) { if (typeof camera === "undefined") { camera = this._game.camera; } return camera.worldView.y + this.y; }; Input.prototype.renderDebugInfo = function (x, y, color) { if (typeof color === "undefined") { color = 'rgb(255,255,255)'; } this._game.stage.context.font = '14px Courier'; this._game.stage.context.fillStyle = color; this._game.stage.context.fillText('Input', x, y); this._game.stage.context.fillText('Screen X: ' + this.x + ' Screen Y: ' + this.y, x, y + 14); this._game.stage.context.fillText('World X: ' + this.worldX + ' World Y: ' + this.worldY, x, y + 28); this._game.stage.context.fillText('Scale X: ' + this.scaleX.toFixed(1) + ' Scale Y: ' + this.scaleY.toFixed(1), x, y + 42); }; return Input; })(); Phaser.Input = Input; })(Phaser || (Phaser = {})); /// /** * Phaser - Keyboard * * The Keyboard class handles keyboard interactions with the game and the resulting events. * The avoid stealing all browser input we don't use event.preventDefault. If you would like to trap a specific key however * then use the addKeyCapture() method. */ var Phaser; (function (Phaser) { var Keyboard = (function () { function Keyboard(game) { this._keys = { }; this._capture = { }; this._game = game; this.start(); } Keyboard.prototype.start = function () { var _this = this; document.body.addEventListener('keydown', function (event) { return _this.onKeyDown(event); }, false); document.body.addEventListener('keyup', function (event) { return _this.onKeyUp(event); }, false); }; Keyboard.prototype.addKeyCapture = function (keycode) { if(typeof keycode === 'object') { for(var i = 0; i < keycode.length; i++) { this._capture[keycode[i]] = true; } } else { this._capture[keycode] = true; } }; Keyboard.prototype.removeKeyCapture = function (keycode) { delete this._capture[keycode]; }; Keyboard.prototype.clearCaptures = function () { this._capture = { }; }; Keyboard.prototype.onKeyDown = function (event) { if(this._capture[event.keyCode]) { event.preventDefault(); } if(!this._keys[event.keyCode]) { this._keys[event.keyCode] = { isDown: true, timeDown: this._game.time.now, timeUp: 0 }; } else { this._keys[event.keyCode].isDown = true; this._keys[event.keyCode].timeDown = this._game.time.now; } }; Keyboard.prototype.onKeyUp = function (event) { if(this._capture[event.keyCode]) { event.preventDefault(); } if(!this._keys[event.keyCode]) { this._keys[event.keyCode] = { isDown: false, timeDown: 0, timeUp: this._game.time.now }; } else { this._keys[event.keyCode].isDown = false; this._keys[event.keyCode].timeUp = this._game.time.now; } }; Keyboard.prototype.reset = function () { for(var key in this._keys) { this._keys[key].isDown = false; } }; Keyboard.prototype.justPressed = function (keycode, duration) { if (typeof duration === "undefined") { duration = 250; } if(this._keys[keycode] && this._keys[keycode].isDown === true && (this._game.time.now - this._keys[keycode].timeDown < duration)) { return true; } else { return false; } }; Keyboard.prototype.justReleased = function (keycode, duration) { if (typeof duration === "undefined") { duration = 250; } if(this._keys[keycode] && this._keys[keycode].isDown === false && (this._game.time.now - this._keys[keycode].timeUp < duration)) { return true; } else { return false; } }; Keyboard.prototype.isDown = function (keycode) { if(this._keys[keycode]) { return this._keys[keycode].isDown; } else { return false; } }; Keyboard.A = "A".charCodeAt(0); Keyboard.B = "B".charCodeAt(0); Keyboard.C = "C".charCodeAt(0); Keyboard.D = "D".charCodeAt(0); Keyboard.E = "E".charCodeAt(0); Keyboard.F = "F".charCodeAt(0); Keyboard.G = "G".charCodeAt(0); Keyboard.H = "H".charCodeAt(0); Keyboard.I = "I".charCodeAt(0); Keyboard.J = "J".charCodeAt(0); Keyboard.K = "K".charCodeAt(0); Keyboard.L = "L".charCodeAt(0); Keyboard.M = "M".charCodeAt(0); Keyboard.N = "N".charCodeAt(0); Keyboard.O = "O".charCodeAt(0); Keyboard.P = "P".charCodeAt(0); Keyboard.Q = "Q".charCodeAt(0); Keyboard.R = "R".charCodeAt(0); Keyboard.S = "S".charCodeAt(0); Keyboard.T = "T".charCodeAt(0); Keyboard.U = "U".charCodeAt(0); Keyboard.V = "V".charCodeAt(0); Keyboard.W = "W".charCodeAt(0); Keyboard.X = "X".charCodeAt(0); Keyboard.Y = "Y".charCodeAt(0); Keyboard.Z = "Z".charCodeAt(0); Keyboard.ZERO = "0".charCodeAt(0); Keyboard.ONE = "1".charCodeAt(0); Keyboard.TWO = "2".charCodeAt(0); Keyboard.THREE = "3".charCodeAt(0); Keyboard.FOUR = "4".charCodeAt(0); Keyboard.FIVE = "5".charCodeAt(0); Keyboard.SIX = "6".charCodeAt(0); Keyboard.SEVEN = "7".charCodeAt(0); Keyboard.EIGHT = "8".charCodeAt(0); Keyboard.NINE = "9".charCodeAt(0); Keyboard.NUMPAD_0 = 96; Keyboard.NUMPAD_1 = 97; Keyboard.NUMPAD_2 = 98; Keyboard.NUMPAD_3 = 99; Keyboard.NUMPAD_4 = 100; Keyboard.NUMPAD_5 = 101; Keyboard.NUMPAD_6 = 102; Keyboard.NUMPAD_7 = 103; Keyboard.NUMPAD_8 = 104; Keyboard.NUMPAD_9 = 105; Keyboard.NUMPAD_MULTIPLY = 106; Keyboard.NUMPAD_ADD = 107; Keyboard.NUMPAD_ENTER = 108; Keyboard.NUMPAD_SUBTRACT = 109; Keyboard.NUMPAD_DECIMAL = 110; Keyboard.NUMPAD_DIVIDE = 111; Keyboard.F1 = 112; Keyboard.F2 = 113; Keyboard.F3 = 114; Keyboard.F4 = 115; Keyboard.F5 = 116; Keyboard.F6 = 117; Keyboard.F7 = 118; Keyboard.F8 = 119; Keyboard.F9 = 120; Keyboard.F10 = 121; Keyboard.F11 = 122; Keyboard.F12 = 123; Keyboard.F13 = 124; Keyboard.F14 = 125; Keyboard.F15 = 126; Keyboard.COLON = 186; Keyboard.EQUALS = 187; Keyboard.UNDERSCORE = 189; Keyboard.QUESTION_MARK = 191; Keyboard.TILDE = 192; Keyboard.OPEN_BRACKET = 219; Keyboard.BACKWARD_SLASH = 220; Keyboard.CLOSED_BRACKET = 221; Keyboard.QUOTES = 222; Keyboard.BACKSPACE = 8; Keyboard.TAB = 9; Keyboard.CLEAR = 12; Keyboard.ENTER = 13; Keyboard.SHIFT = 16; Keyboard.CONTROL = 17; Keyboard.ALT = 18; Keyboard.CAPS_LOCK = 20; Keyboard.ESC = 27; Keyboard.SPACEBAR = 32; Keyboard.PAGE_UP = 33; Keyboard.PAGE_DOWN = 34; Keyboard.END = 35; Keyboard.HOME = 36; Keyboard.LEFT = 37; Keyboard.UP = 38; Keyboard.RIGHT = 39; Keyboard.DOWN = 40; Keyboard.INSERT = 45; Keyboard.DELETE = 46; Keyboard.HELP = 47; Keyboard.NUM_LOCK = 144; return Keyboard; })(); Phaser.Keyboard = Keyboard; })(Phaser || (Phaser = {})); /// /** * Phaser - Mouse * * The Mouse class handles mouse interactions with the game and the resulting events. */ var Phaser; (function (Phaser) { var Mouse = (function () { function Mouse(game) { this._x = 0; this._y = 0; this.isDown = false; this.isUp = true; this.timeDown = 0; this.duration = 0; this.timeUp = 0; this._game = game; this.start(); } Mouse.LEFT_BUTTON = 0; Mouse.MIDDLE_BUTTON = 1; Mouse.RIGHT_BUTTON = 2; Mouse.prototype.start = function () { var _this = this; this._game.stage.canvas.addEventListener('mousedown', function (event) { return _this.onMouseDown(event); }, true); this._game.stage.canvas.addEventListener('mousemove', function (event) { return _this.onMouseMove(event); }, true); this._game.stage.canvas.addEventListener('mouseup', function (event) { return _this.onMouseUp(event); }, true); }; Mouse.prototype.reset = function () { this.isDown = false; this.isUp = true; }; Mouse.prototype.onMouseDown = function (event) { this.button = event.button; this._x = event.clientX - this._game.stage.x; this._y = event.clientY - this._game.stage.y; this._game.input.x = this._x * this._game.input.scaleX; this._game.input.y = this._y * this._game.input.scaleY; this.isDown = true; this.isUp = false; this.timeDown = this._game.time.now; this._game.input.onDown.dispatch(this._game.input.x, this._game.input.y, this.timeDown); }; Mouse.prototype.update = function () { //this._game.input.x = this._x * this._game.input.scaleX; //this._game.input.y = this._y * this._game.input.scaleY; if(this.isDown) { this.duration = this._game.time.now - this.timeDown; } }; Mouse.prototype.onMouseMove = function (event) { this.button = event.button; this._x = event.clientX - this._game.stage.x; this._y = event.clientY - this._game.stage.y; this._game.input.x = this._x * this._game.input.scaleX; this._game.input.y = this._y * this._game.input.scaleY; }; Mouse.prototype.onMouseUp = function (event) { this.button = event.button; this.isDown = false; this.isUp = true; this.timeUp = this._game.time.now; this.duration = this.timeUp - this.timeDown; this._x = event.clientX - this._game.stage.x; this._y = event.clientY - this._game.stage.y; this._game.input.x = this._x * this._game.input.scaleX; this._game.input.y = this._y * this._game.input.scaleY; this._game.input.onUp.dispatch(this._game.input.x, this._game.input.y, this.timeDown); }; return Mouse; })(); Phaser.Mouse = Mouse; })(Phaser || (Phaser = {})); /// /** * Phaser - Finger * * A Finger object is used by the Touch manager and represents a single finger on the touch screen. */ var Phaser; (function (Phaser) { var Finger = (function () { /** * Constructor * @param {Phaser.Game} game. * @return {Phaser.Finger} This object. */ function Finger(game) { /** * * @property point * @type Point **/ this.point = null; /** * * @property circle * @type Circle **/ this.circle = null; /** * * @property withinGame * @type Boolean */ this.withinGame = false; /** * The horizontal coordinate of point relative to the viewport in pixels, excluding any scroll offset * @property clientX * @type Number */ this.clientX = -1; // /** * The vertical coordinate of point relative to the viewport in pixels, excluding any scroll offset * @property clientY * @type Number */ this.clientY = -1; // /** * The horizontal coordinate of point relative to the viewport in pixels, including any scroll offset * @property pageX * @type Number */ this.pageX = -1; /** * The vertical coordinate of point relative to the viewport in pixels, including any scroll offset * @property pageY * @type Number */ this.pageY = -1; /** * The horizontal coordinate of point relative to the screen in pixels * @property screenX * @type Number */ this.screenX = -1; /** * The vertical coordinate of point relative to the screen in pixels * @property screenY * @type Number */ this.screenY = -1; /** * The horizontal coordinate of point relative to the game element * @property x * @type Number */ this.x = -1; /** * The vertical coordinate of point relative to the game element * @property y * @type Number */ this.y = -1; /** * * @property isDown * @type Boolean **/ this.isDown = false; /** * * @property isUp * @type Boolean **/ this.isUp = false; /** * * @property timeDown * @type Number **/ this.timeDown = 0; /** * * @property duration * @type Number **/ this.duration = 0; /** * * @property timeUp * @type Number **/ this.timeUp = 0; /** * * @property justPressedRate * @type Number **/ this.justPressedRate = 200; /** * * @property justReleasedRate * @type Number **/ this.justReleasedRate = 200; this._game = game; this.active = false; } Finger.prototype.start = /** * * @method start * @param {Any} event */ function (event) { this.identifier = event.identifier; this.target = event.target; // populate geom objects if(this.point === null) { this.point = new Phaser.Point(); } if(this.circle === null) { this.circle = new Phaser.Circle(0, 0, 44); } this.move(event); this.active = true; this.withinGame = true; this.isDown = true; this.isUp = false; this.timeDown = this._game.time.now; }; Finger.prototype.move = /** * * @method move * @param {Any} event */ function (event) { this.clientX = event.clientX; this.clientY = event.clientY; this.pageX = event.pageX; this.pageY = event.pageY; this.screenX = event.screenX; this.screenY = event.screenY; this.x = this.pageX - this._game.stage.offset.x; this.y = this.pageY - this._game.stage.offset.y; this.point.setTo(this.x, this.y); this.circle.setTo(this.x, this.y, 44); // Droppings history (used for gestures and motion tracking) this.duration = this._game.time.now - this.timeDown; }; Finger.prototype.leave = /** * * @method leave * @param {Any} event */ function (event) { this.withinGame = false; this.move(event); }; Finger.prototype.stop = /** * * @method stop * @param {Any} event */ function (event) { this.active = false; this.withinGame = false; this.isDown = false; this.isUp = true; this.timeUp = this._game.time.now; this.duration = this.timeUp - this.timeDown; }; Finger.prototype.justPressed = /** * * @method justPressed * @param {Number} [duration]. * @return {Boolean} */ function (duration) { if (typeof duration === "undefined") { duration = this.justPressedRate; } if(this.isDown === true && (this.timeDown + duration) > this._game.time.now) { return true; } else { return false; } }; Finger.prototype.justReleased = /** * * @method justReleased * @param {Number} [duration]. * @return {Boolean} */ function (duration) { if (typeof duration === "undefined") { duration = this.justReleasedRate; } if(this.isUp === true && (this.timeUp + duration) > this._game.time.now) { return true; } else { return false; } }; Finger.prototype.toString = /** * Returns a string representation of this object. * @method toString * @return {string} a string representation of the instance. **/ function () { return "[{Finger (identifer=" + this.identifier + " active=" + this.active + " duration=" + this.duration + " withinGame=" + this.withinGame + " x=" + this.x + " y=" + this.y + " clientX=" + this.clientX + " clientY=" + this.clientY + " screenX=" + this.screenX + " screenY=" + this.screenY + " pageX=" + this.pageX + " pageY=" + this.pageY + ")}]"; }; return Finger; })(); Phaser.Finger = Finger; })(Phaser || (Phaser = {})); /// /// /** * Phaser - Touch * * The Touch class handles touch interactions with the game and the resulting Finger objects. * http://www.w3.org/TR/touch-events/ * https://developer.mozilla.org/en-US/docs/DOM/TouchList * http://www.html5rocks.com/en/mobile/touchandmouse/ * Note: Android 2.x only supports 1 touch event at once, no multi-touch * * @todo Try and resolve update lag in Chrome/Android * Gestures (pinch, zoom, swipe) * GameObject Touch * Touch point within GameObject * Input Zones (mouse and touch) - lock entities within them + axis aligned drags */ var Phaser; (function (Phaser) { var Touch = (function () { /** * Constructor * @param {Game} game. * @return {Touch} This object. */ function Touch(game) { /** * * @property x * @type Number **/ this.x = 0; /** * * @property y * @type Number **/ this.y = 0; /** * * @property isDown * @type Boolean **/ this.isDown = false; /** * * @property isUp * @type Boolean **/ this.isUp = true; this._game = game; this.finger1 = new Phaser.Finger(this._game); this.finger2 = new Phaser.Finger(this._game); this.finger3 = new Phaser.Finger(this._game); this.finger4 = new Phaser.Finger(this._game); this.finger5 = new Phaser.Finger(this._game); this.finger6 = new Phaser.Finger(this._game); this.finger7 = new Phaser.Finger(this._game); this.finger8 = new Phaser.Finger(this._game); this.finger9 = new Phaser.Finger(this._game); this.finger10 = new Phaser.Finger(this._game); this._fingers = [ this.finger1, this.finger2, this.finger3, this.finger4, this.finger5, this.finger6, this.finger7, this.finger8, this.finger9, this.finger10 ]; this.touchDown = new Phaser.Signal(); this.touchUp = new Phaser.Signal(); this.start(); } Touch.prototype.start = /** * * @method start */ function () { var _this = this; this._game.stage.canvas.addEventListener('touchstart', function (event) { return _this.onTouchStart(event); }, false); this._game.stage.canvas.addEventListener('touchmove', function (event) { return _this.onTouchMove(event); }, false); this._game.stage.canvas.addEventListener('touchend', function (event) { return _this.onTouchEnd(event); }, false); this._game.stage.canvas.addEventListener('touchenter', function (event) { return _this.onTouchEnter(event); }, false); this._game.stage.canvas.addEventListener('touchleave', function (event) { return _this.onTouchLeave(event); }, false); this._game.stage.canvas.addEventListener('touchcancel', function (event) { return _this.onTouchCancel(event); }, false); document.addEventListener('touchmove', function (event) { return _this.consumeTouchMove(event); }, false); }; Touch.prototype.consumeTouchMove = /** * Prevent iOS bounce-back (doesn't work?) * @method consumeTouchMove * @param {Any} event **/ function (event) { event.preventDefault(); }; Touch.prototype.onTouchStart = /** * * @method onTouchStart * @param {Any} event **/ function (event) { event.preventDefault(); // A list of all the touch points that BECAME active with the current event // https://developer.mozilla.org/en-US/docs/DOM/TouchList // event.targetTouches = list of all touches on the TARGET ELEMENT (i.e. game dom element) // event.touches = list of all touches on the ENTIRE DOCUMENT, not just the target element // event.changedTouches = the touches that CHANGED in this event, not the total number of them for(var i = 0; i < event.changedTouches.length; i++) { for(var f = 0; f < this._fingers.length; f++) { if(this._fingers[f].active === false) { this._fingers[f].start(event.changedTouches[i]); this.x = this._fingers[f].x; this.y = this._fingers[f].y; this._game.input.x = this.x * this._game.input.scaleX; this._game.input.y = this.y * this._game.input.scaleY; this.touchDown.dispatch(this._fingers[f].x, this._fingers[f].y, this._fingers[f].timeDown, this._fingers[f].timeUp, this._fingers[f].duration); this._game.input.onDown.dispatch(this._game.input.x, this._game.input.y, this._fingers[f].timeDown); this.isDown = true; this.isUp = false; break; } } } }; Touch.prototype.onTouchCancel = /** * Doesn't appear to be supported by most browsers yet * @method onTouchCancel * @param {Any} event **/ function (event) { event.preventDefault(); // Touch cancel - touches that were disrupted (perhaps by moving into a plugin or browser chrome) // http://www.w3.org/TR/touch-events/#dfn-touchcancel // event.changedTouches = the touches that CHANGED in this event, not the total number of them for(var i = 0; i < event.changedTouches.length; i++) { for(var f = 0; f < this._fingers.length; f++) { if(this._fingers[f].identifier === event.changedTouches[i].identifier) { this._fingers[f].stop(event.changedTouches[i]); break; } } } }; Touch.prototype.onTouchEnter = /** * Doesn't appear to be supported by most browsers yet * @method onTouchEnter * @param {Any} event **/ function (event) { event.preventDefault(); // For touch enter and leave its a list of the touch points that have entered or left the target // event.targetTouches = list of all touches on the TARGET ELEMENT (i.e. game dom element) // event.touches = list of all touches on the ENTIRE DOCUMENT, not just the target element // event.changedTouches = the touches that CHANGED in this event, not the total number of them for(var i = 0; i < event.changedTouches.length; i++) { for(var f = 0; f < this._fingers.length; f++) { if(this._fingers[f].active === false) { this._fingers[f].start(event.changedTouches[i]); break; } } } }; Touch.prototype.onTouchLeave = /** * Doesn't appear to be supported by most browsers yet * @method onTouchLeave * @param {Any} event **/ function (event) { event.preventDefault(); // For touch enter and leave its a list of the touch points that have entered or left the target // event.changedTouches = the touches that CHANGED in this event, not the total number of them for(var i = 0; i < event.changedTouches.length; i++) { for(var f = 0; f < this._fingers.length; f++) { if(this._fingers[f].identifier === event.changedTouches[i].identifier) { this._fingers[f].leave(event.changedTouches[i]); break; } } } }; Touch.prototype.onTouchMove = /** * * @method onTouchMove * @param {Any} event **/ function (event) { event.preventDefault(); // event.targetTouches = list of all touches on the TARGET ELEMENT (i.e. game dom element) // event.touches = list of all touches on the ENTIRE DOCUMENT, not just the target element // event.changedTouches = the touches that CHANGED in this event, not the total number of them for(var i = 0; i < event.changedTouches.length; i++) { for(var f = 0; f < this._fingers.length; f++) { if(this._fingers[f].identifier === event.changedTouches[i].identifier) { this._fingers[f].move(event.changedTouches[i]); this.x = this._fingers[f].x; this.y = this._fingers[f].y; this._game.input.x = this.x * this._game.input.scaleX; this._game.input.y = this.y * this._game.input.scaleY; break; } } } }; Touch.prototype.onTouchEnd = /** * * @method onTouchEnd * @param {Any} event **/ function (event) { event.preventDefault(); // For touch end its a list of the touch points that have been removed from the surface // https://developer.mozilla.org/en-US/docs/DOM/TouchList // event.changedTouches = the touches that CHANGED in this event, not the total number of them for(var i = 0; i < event.changedTouches.length; i++) { for(var f = 0; f < this._fingers.length; f++) { if(this._fingers[f].identifier === event.changedTouches[i].identifier) { this._fingers[f].stop(event.changedTouches[i]); this.x = this._fingers[f].x; this.y = this._fingers[f].y; this._game.input.x = this.x * this._game.input.scaleX; this._game.input.y = this.y * this._game.input.scaleY; this.touchUp.dispatch(this._fingers[f].x, this._fingers[f].y, this._fingers[f].timeDown, this._fingers[f].timeUp, this._fingers[f].duration); this._game.input.onUp.dispatch(this._game.input.x, this._game.input.y, this._fingers[f].timeUp); this.isDown = false; this.isUp = true; break; } } } }; Touch.prototype.calculateDistance = /** * * @method calculateDistance * @param {Finger} finger1 * @param {Finger} finger2 **/ function (finger1, finger2) { }; Touch.prototype.calculateAngle = /** * * @method calculateAngle * @param {Finger} finger1 * @param {Finger} finger2 **/ function (finger1, finger2) { }; Touch.prototype.checkOverlap = /** * * @method checkOverlap * @param {Finger} finger1 * @param {Finger} finger2 **/ function (finger1, finger2) { }; Touch.prototype.update = /** * * @method update */ function () { }; Touch.prototype.stop = /** * * @method stop */ function () { //this._domElement.addEventListener('touchstart', (event) => this.onTouchStart(event), false); //this._domElement.addEventListener('touchmove', (event) => this.onTouchMove(event), false); //this._domElement.addEventListener('touchend', (event) => this.onTouchEnd(event), false); //this._domElement.addEventListener('touchenter', (event) => this.onTouchEnter(event), false); //this._domElement.addEventListener('touchleave', (event) => this.onTouchLeave(event), false); //this._domElement.addEventListener('touchcancel', (event) => this.onTouchCancel(event), false); }; Touch.prototype.reset = /** * * @method reset **/ function () { this.isDown = false; this.isUp = false; }; return Touch; })(); Phaser.Touch = Touch; })(Phaser || (Phaser = {})); /// /// /** * Phaser - Emitter * * Emitter is a lightweight particle emitter. It can be used for one-time explosions or for * continuous effects like rain and fire. All it really does is launch Particle objects out * at set intervals, and fixes their positions and velocities accorindgly. */ var Phaser; (function (Phaser) { var Emitter = (function (_super) { __extends(Emitter, _super); /** * Creates a new Emitter object at a specific position. * Does NOT automatically generate or attach particles! * * @param X The X position of the emitter. * @param Y The Y position of the emitter. * @param Size Optional, specifies a maximum capacity for this emitter. */ function Emitter(game, X, Y, Size) { if (typeof X === "undefined") { X = 0; } if (typeof Y === "undefined") { Y = 0; } if (typeof Size === "undefined") { Size = 0; } _super.call(this, game, Size); this.x = X; this.y = Y; this.width = 0; this.height = 0; this.minParticleSpeed = new Phaser.MicroPoint(-100, -100); this.maxParticleSpeed = new Phaser.MicroPoint(100, 100); this.minRotation = -360; this.maxRotation = 360; this.gravity = 0; this.particleClass = null; this.particleDrag = new Phaser.MicroPoint(); this.frequency = 0.1; this.lifespan = 3; this.bounce = 0; this._quantity = 0; this._counter = 0; this._explode = true; this.on = false; this._point = new Phaser.MicroPoint(); } Emitter.prototype.destroy = /** * Clean up memory. */ function () { this.minParticleSpeed = null; this.maxParticleSpeed = null; this.particleDrag = null; this.particleClass = null; this._point = null; _super.prototype.destroy.call(this); }; Emitter.prototype.makeParticles = /** * This function generates a new array of particle sprites to attach to the emitter. * * @param Graphics If you opted to not pre-configure an array of Sprite objects, you can simply pass in a particle image or sprite sheet. * @param Quantity The number of particles to generate when using the "create from image" option. * @param BakedRotations How many frames of baked rotation to use (boosts performance). Set to zero to not use baked rotations. * @param Multiple Whether the image in the Graphics param is a single particle or a bunch of particles (if it's a bunch, they need to be square!). * @param Collide Whether the particles should be flagged as not 'dead' (non-colliding particles are higher performance). 0 means no collisions, 0-1 controls scale of particle's bounding box. * * @return This Emitter instance (nice for chaining stuff together, if you're into that). */ function (Graphics, Quantity, BakedRotations, Multiple, Collide) { if (typeof Quantity === "undefined") { Quantity = 50; } if (typeof BakedRotations === "undefined") { BakedRotations = 16; } if (typeof Multiple === "undefined") { Multiple = false; } if (typeof Collide === "undefined") { Collide = 0; } this.maxSize = Quantity; var totalFrames = 1; /* if(Multiple) { var sprite:Sprite = new Sprite(this._game); sprite.loadGraphic(Graphics,true); totalFrames = sprite.frames; sprite.destroy(); } */ var randomFrame; var particle; var i = 0; while(i < Quantity) { if(this.particleClass == null) { particle = new Phaser.Particle(this._game); } else { particle = new this.particleClass(this._game); } if(Multiple) { /* randomFrame = this._game.math.random()*totalFrames; if(BakedRotations > 0) particle.loadRotatedGraphic(Graphics,BakedRotations,randomFrame); else { particle.loadGraphic(Graphics,true); particle.frame = randomFrame; } */ } else { /* if (BakedRotations > 0) particle.loadRotatedGraphic(Graphics,BakedRotations); else particle.loadGraphic(Graphics); */ if(Graphics) { particle.loadGraphic(Graphics); } } if(Collide > 0) { particle.allowCollisions = Phaser.Collision.ANY; particle.width *= Collide; particle.height *= Collide; //particle.centerOffsets(); } else { particle.allowCollisions = Phaser.Collision.NONE; } particle.exists = false; this.add(particle); i++; } return this; }; Emitter.prototype.update = /** * Called automatically by the game loop, decides when to launch particles and when to "die". */ function () { if(this.on) { if(this._explode) { this.on = false; var i = 0; var l = this._quantity; if((l <= 0) || (l > this.length)) { l = this.length; } while(i < l) { this.emitParticle(); i++; } this._quantity = 0; } else { this._timer += this._game.time.elapsed; while((this.frequency > 0) && (this._timer > this.frequency) && this.on) { this._timer -= this.frequency; this.emitParticle(); if((this._quantity > 0) && (++this._counter >= this._quantity)) { this.on = false; this._quantity = 0; } } } } _super.prototype.update.call(this); }; Emitter.prototype.kill = /** * Call this function to turn off all the particles and the emitter. */ function () { this.on = false; _super.prototype.kill.call(this); }; Emitter.prototype.start = /** * Call this function to start emitting particles. * * @param Explode Whether the particles should all burst out at once. * @param Lifespan How long each particle lives once emitted. 0 = forever. * @param Frequency Ignored if Explode is set to true. Frequency is how often to emit a particle. 0 = never emit, 0.1 = 1 particle every 0.1 seconds, 5 = 1 particle every 5 seconds. * @param Quantity How many particles to launch. 0 = "all of the particles". */ function (Explode, Lifespan, Frequency, Quantity) { if (typeof Explode === "undefined") { Explode = true; } if (typeof Lifespan === "undefined") { Lifespan = 0; } if (typeof Frequency === "undefined") { Frequency = 0.1; } if (typeof Quantity === "undefined") { Quantity = 0; } this.revive(); this.visible = true; this.on = true; this._explode = Explode; this.lifespan = Lifespan; this.frequency = Frequency; this._quantity += Quantity; this._counter = 0; this._timer = 0; }; Emitter.prototype.emitParticle = /** * This function can be used both internally and externally to emit the next particle. */ function () { var particle = this.recycle(Phaser.Particle); particle.lifespan = this.lifespan; particle.elasticity = this.bounce; particle.reset(this.x - (particle.width >> 1) + this._game.math.random() * this.width, this.y - (particle.height >> 1) + this._game.math.random() * this.height); particle.visible = true; if(this.minParticleSpeed.x != this.maxParticleSpeed.x) { particle.velocity.x = this.minParticleSpeed.x + this._game.math.random() * (this.maxParticleSpeed.x - this.minParticleSpeed.x); } else { particle.velocity.x = this.minParticleSpeed.x; } if(this.minParticleSpeed.y != this.maxParticleSpeed.y) { particle.velocity.y = this.minParticleSpeed.y + this._game.math.random() * (this.maxParticleSpeed.y - this.minParticleSpeed.y); } else { particle.velocity.y = this.minParticleSpeed.y; } particle.acceleration.y = this.gravity; if(this.minRotation != this.maxRotation && this.minRotation !== 0 && this.maxRotation !== 0) { particle.angularVelocity = this.minRotation + this._game.math.random() * (this.maxRotation - this.minRotation); } else { particle.angularVelocity = this.minRotation; } if(particle.angularVelocity != 0) { particle.angle = this._game.math.random() * 360 - 180; } particle.drag.x = this.particleDrag.x; particle.drag.y = this.particleDrag.y; particle.onEmit(); }; Emitter.prototype.setSize = /** * A more compact way of setting the width and height of the emitter. * * @param Width The desired width of the emitter (particles are spawned randomly within these dimensions). * @param Height The desired height of the emitter. */ function (Width, Height) { this.width = Width; this.height = Height; }; Emitter.prototype.setXSpeed = /** * A more compact way of setting the X velocity range of the emitter. * * @param Min The minimum value for this range. * @param Max The maximum value for this range. */ function (Min, Max) { if (typeof Min === "undefined") { Min = 0; } if (typeof Max === "undefined") { Max = 0; } this.minParticleSpeed.x = Min; this.maxParticleSpeed.x = Max; }; Emitter.prototype.setYSpeed = /** * A more compact way of setting the Y velocity range of the emitter. * * @param Min The minimum value for this range. * @param Max The maximum value for this range. */ function (Min, Max) { if (typeof Min === "undefined") { Min = 0; } if (typeof Max === "undefined") { Max = 0; } this.minParticleSpeed.y = Min; this.maxParticleSpeed.y = Max; }; Emitter.prototype.setRotation = /** * A more compact way of setting the angular velocity constraints of the emitter. * * @param Min The minimum value for this range. * @param Max The maximum value for this range. */ function (Min, Max) { if (typeof Min === "undefined") { Min = 0; } if (typeof Max === "undefined") { Max = 0; } this.minRotation = Min; this.maxRotation = Max; }; Emitter.prototype.at = /** * Change the emitter's midpoint to match the midpoint of a Object. * * @param Object The Object that you want to sync up with. */ function (Object) { Object.getMidpoint(this._point); this.x = this._point.x - (this.width >> 1); this.y = this._point.y - (this.height >> 1); }; return Emitter; })(Phaser.Group); Phaser.Emitter = Emitter; })(Phaser || (Phaser = {})); /// /** * Phaser - GeomSprite * * A GeomSprite is a special kind of GameObject that contains a base geometry class (Circle, Line, Point, Rectangle). * They can be rendered in the game and used for collision just like any other game object. Display of them is controlled * via the lineWidth / lineColor / fillColor and renderOutline / renderFill properties. */ var Phaser; (function (Phaser) { var GeomSprite = (function (_super) { __extends(GeomSprite, _super); function GeomSprite(game, x, y) { if (typeof x === "undefined") { x = 0; } if (typeof y === "undefined") { y = 0; } _super.call(this, game, x, y); // local rendering related temp vars to help avoid gc spikes this._dx = 0; this._dy = 0; this._dw = 0; this._dh = 0; this.type = 0; this.renderOutline = true; this.renderFill = true; this.lineWidth = 1; this.lineColor = 'rgb(0,255,0)'; this.fillColor = 'rgb(0,100,0)'; this.type = GeomSprite.UNASSIGNED; return this; } GeomSprite.UNASSIGNED = 0; GeomSprite.CIRCLE = 1; GeomSprite.LINE = 2; GeomSprite.POINT = 3; GeomSprite.RECTANGLE = 4; GeomSprite.prototype.loadCircle = function (circle) { this.refresh(); this.circle = circle; this.type = GeomSprite.CIRCLE; return this; }; GeomSprite.prototype.loadLine = function (line) { this.refresh(); this.line = line; this.type = GeomSprite.LINE; return this; }; GeomSprite.prototype.loadPoint = function (point) { this.refresh(); this.point = point; this.type = GeomSprite.POINT; return this; }; GeomSprite.prototype.loadRectangle = function (rect) { this.refresh(); this.rect = rect; this.type = GeomSprite.RECTANGLE; return this; }; GeomSprite.prototype.createCircle = function (diameter) { this.refresh(); this.circle = new Phaser.Circle(this.x, this.y, diameter); this.type = GeomSprite.CIRCLE; this.bounds.setTo(this.circle.x - this.circle.radius, this.circle.y - this.circle.radius, this.circle.diameter, this.circle.diameter); return this; }; GeomSprite.prototype.createLine = function (x, y) { this.refresh(); this.line = new Phaser.Line(this.x, this.y, x, y); this.type = GeomSprite.LINE; this.bounds.setTo(this.x, this.y, this.line.width, this.line.height); return this; }; GeomSprite.prototype.createPoint = function () { this.refresh(); this.point = new Phaser.Point(this.x, this.y); this.type = GeomSprite.POINT; this.bounds.width = 1; this.bounds.height = 1; return this; }; GeomSprite.prototype.createRectangle = function (width, height) { this.refresh(); this.rect = new Phaser.Rectangle(this.x, this.y, width, height); this.type = GeomSprite.RECTANGLE; this.bounds.copyFrom(this.rect); return this; }; GeomSprite.prototype.refresh = function () { this.circle = null; this.line = null; this.point = null; this.rect = null; }; GeomSprite.prototype.update = function () { // Update bounds and position? if(this.type == GeomSprite.UNASSIGNED) { return; } else if(this.type == GeomSprite.CIRCLE) { this.circle.x = this.x; this.circle.y = this.y; this.bounds.width = this.circle.diameter; this.bounds.height = this.circle.diameter; } else if(this.type == GeomSprite.LINE) { this.line.x1 = this.x; this.line.y1 = this.y; this.bounds.setTo(this.x, this.y, this.line.width, this.line.height); } else if(this.type == GeomSprite.POINT) { this.point.x = this.x; this.point.y = this.y; } else if(this.type == GeomSprite.RECTANGLE) { this.rect.x = this.x; this.rect.y = this.y; this.bounds.copyFrom(this.rect); } }; GeomSprite.prototype.inCamera = function (camera) { if(this.scrollFactor.x !== 1.0 || this.scrollFactor.y !== 1.0) { this._dx = this.bounds.x - (camera.x * this.scrollFactor.x); this._dy = this.bounds.y - (camera.y * this.scrollFactor.x); this._dw = this.bounds.width * this.scale.x; this._dh = this.bounds.height * this.scale.y; return (camera.right > this._dx) && (camera.x < this._dx + this._dw) && (camera.bottom > this._dy) && (camera.y < this._dy + this._dh); } else { return camera.intersects(this.bounds); } }; GeomSprite.prototype.render = function (camera, cameraOffsetX, cameraOffsetY) { // Render checks if(this.type == GeomSprite.UNASSIGNED || this.visible === false || this.scale.x == 0 || this.scale.y == 0 || this.alpha < 0.1 || this.cameraBlacklist.indexOf(camera.ID) !== -1 || this.inCamera(camera.worldView) == false) { return false; } // Alpha if(this.alpha !== 1) { var globalAlpha = this._game.stage.context.globalAlpha; this._game.stage.context.globalAlpha = this.alpha; } this._dx = cameraOffsetX + (this.bounds.x - camera.worldView.x); this._dy = cameraOffsetY + (this.bounds.y - camera.worldView.y); this._dw = this.bounds.width * this.scale.x; this._dh = this.bounds.height * this.scale.y; // Circles are drawn center based if(this.type == GeomSprite.CIRCLE) { this._dx += this.circle.radius; this._dy += this.circle.radius; } // Apply camera difference if(this.scrollFactor.x !== 1.0 || this.scrollFactor.y !== 1.0) { this._dx -= (camera.worldView.x * this.scrollFactor.x); this._dy -= (camera.worldView.y * this.scrollFactor.y); } // Rotation is disabled for now as I don't want it to be misleading re: collision /* if (this.angle !== 0) { this._game.stage.context.save(); this._game.stage.context.translate(this._dx + (this._dw / 2) - this.origin.x, this._dy + (this._dh / 2) - this.origin.y); this._game.stage.context.rotate(this.angle * (Math.PI / 180)); this._dx = -(this._dw / 2); this._dy = -(this._dh / 2); } */ this._dx = Math.round(this._dx); this._dy = Math.round(this._dy); this._dw = Math.round(this._dw); this._dh = Math.round(this._dh); this._game.stage.saveCanvasValues(); // Debug //this._game.stage.context.fillStyle = 'rgba(255,0,0,0.5)'; //this._game.stage.context.fillRect(this.bounds.x, this.bounds.y, this.bounds.width, this.bounds.height); this._game.stage.context.lineWidth = this.lineWidth; this._game.stage.context.strokeStyle = this.lineColor; this._game.stage.context.fillStyle = this.fillColor; if(this._game.stage.fillStyle !== this.fillColor) { } // Primitive Renderer if(this.type == GeomSprite.CIRCLE) { this._game.stage.context.beginPath(); this._game.stage.context.arc(this._dx, this._dy, this.circle.radius, 0, Math.PI * 2); this._game.stage.context.stroke(); if(this.renderFill) { this._game.stage.context.fill(); } this._game.stage.context.closePath(); } else if(this.type == GeomSprite.LINE) { this._game.stage.context.beginPath(); this._game.stage.context.moveTo(this._dx, this._dy); this._game.stage.context.lineTo(this.line.x2, this.line.y2); this._game.stage.context.stroke(); this._game.stage.context.closePath(); } else if(this.type == GeomSprite.POINT) { this._game.stage.context.fillRect(this._dx, this._dy, 2, 2); } else if(this.type == GeomSprite.RECTANGLE) { // We can use the faster fillRect if we don't need the outline if(this.renderOutline == false) { this._game.stage.context.fillRect(this._dx, this._dy, this.rect.width, this.rect.height); } else { this._game.stage.context.beginPath(); this._game.stage.context.rect(this._dx, this._dy, this.rect.width, this.rect.height); this._game.stage.context.stroke(); if(this.renderFill) { this._game.stage.context.fill(); } this._game.stage.context.closePath(); } // And now the edge points this._game.stage.context.fillStyle = 'rgb(255,255,255)'; this.renderPoint(this._dx, this._dy, this.rect.topLeft, 2); this.renderPoint(this._dx, this._dy, this.rect.topCenter, 2); this.renderPoint(this._dx, this._dy, this.rect.topRight, 2); this.renderPoint(this._dx, this._dy, this.rect.leftCenter, 2); this.renderPoint(this._dx, this._dy, this.rect.center, 2); this.renderPoint(this._dx, this._dy, this.rect.rightCenter, 2); this.renderPoint(this._dx, this._dy, this.rect.bottomLeft, 2); this.renderPoint(this._dx, this._dy, this.rect.bottomCenter, 2); this.renderPoint(this._dx, this._dy, this.rect.bottomRight, 2); } this._game.stage.restoreCanvasValues(); if(this.rotation !== 0) { this._game.stage.context.translate(0, 0); this._game.stage.context.restore(); } if(globalAlpha > -1) { this._game.stage.context.globalAlpha = globalAlpha; } return true; }; GeomSprite.prototype.renderPoint = function (offsetX, offsetY, point, size) { offsetX = 0; offsetY = 0; this._game.stage.context.fillRect(offsetX + point.x, offsetY + point.y, 1, 1); }; GeomSprite.prototype.renderDebugInfo = function (x, y, color) { if (typeof color === "undefined") { color = 'rgb(255,255,255)'; } //this._game.stage.context.fillStyle = color; //this._game.stage.context.fillText('Sprite: ' + this.name + ' (' + this.bounds.width + ' x ' + this.bounds.height + ')', x, y); //this._game.stage.context.fillText('x: ' + this.bounds.x.toFixed(1) + ' y: ' + this.bounds.y.toFixed(1) + ' rotation: ' + this.angle.toFixed(1), x, y + 14); //this._game.stage.context.fillText('dx: ' + this._dx.toFixed(1) + ' dy: ' + this._dy.toFixed(1) + ' dw: ' + this._dw.toFixed(1) + ' dh: ' + this._dh.toFixed(1), x, y + 28); //this._game.stage.context.fillText('sx: ' + this._sx.toFixed(1) + ' sy: ' + this._sy.toFixed(1) + ' sw: ' + this._sw.toFixed(1) + ' sh: ' + this._sh.toFixed(1), x, y + 42); }; GeomSprite.prototype.collide = // Gives a basic boolean response to a geometric collision. // If you need the details of the collision use the Collision functions instead and inspect the IntersectResult object. function (source) { // Circle vs. Circle if(this.type == GeomSprite.CIRCLE && source.type == GeomSprite.CIRCLE) { return Phaser.Collision.circleToCircle(this.circle, source.circle).result; } // Circle vs. Rect if(this.type == GeomSprite.CIRCLE && source.type == GeomSprite.RECTANGLE) { return Phaser.Collision.circleToRectangle(this.circle, source.rect).result; } // Circle vs. Point if(this.type == GeomSprite.CIRCLE && source.type == GeomSprite.POINT) { return Phaser.Collision.circleContainsPoint(this.circle, source.point).result; } // Circle vs. Line if(this.type == GeomSprite.CIRCLE && source.type == GeomSprite.LINE) { return Phaser.Collision.lineToCircle(source.line, this.circle).result; } // Rect vs. Rect if(this.type == GeomSprite.RECTANGLE && source.type == GeomSprite.RECTANGLE) { return Phaser.Collision.rectangleToRectangle(this.rect, source.rect).result; } // Rect vs. Circle if(this.type == GeomSprite.RECTANGLE && source.type == GeomSprite.CIRCLE) { return Phaser.Collision.circleToRectangle(source.circle, this.rect).result; } // Rect vs. Point if(this.type == GeomSprite.RECTANGLE && source.type == GeomSprite.POINT) { return Phaser.Collision.pointToRectangle(source.point, this.rect).result; } // Rect vs. Line if(this.type == GeomSprite.RECTANGLE && source.type == GeomSprite.LINE) { return Phaser.Collision.lineToRectangle(source.line, this.rect).result; } // Point vs. Point if(this.type == GeomSprite.POINT && source.type == GeomSprite.POINT) { return this.point.equals(source.point); } // Point vs. Circle if(this.type == GeomSprite.POINT && source.type == GeomSprite.CIRCLE) { return Phaser.Collision.circleContainsPoint(source.circle, this.point).result; } // Point vs. Rect if(this.type == GeomSprite.POINT && source.type == GeomSprite.RECTANGLE) { return Phaser.Collision.pointToRectangle(this.point, source.rect).result; } // Point vs. Line if(this.type == GeomSprite.POINT && source.type == GeomSprite.LINE) { return source.line.isPointOnLine(this.point.x, this.point.y); } // Line vs. Line if(this.type == GeomSprite.LINE && source.type == GeomSprite.LINE) { return Phaser.Collision.lineSegmentToLineSegment(this.line, source.line).result; } // Line vs. Circle if(this.type == GeomSprite.LINE && source.type == GeomSprite.CIRCLE) { return Phaser.Collision.lineToCircle(this.line, source.circle).result; } // Line vs. Rect if(this.type == GeomSprite.LINE && source.type == GeomSprite.RECTANGLE) { return Phaser.Collision.lineSegmentToRectangle(this.line, source.rect).result; } // Line vs. Point if(this.type == GeomSprite.LINE && source.type == GeomSprite.POINT) { return this.line.isPointOnLine(source.point.x, source.point.y); } return false; }; return GeomSprite; })(Phaser.GameObject); Phaser.GeomSprite = GeomSprite; })(Phaser || (Phaser = {})); /// /// /** * Phaser - Particle * * This is a simple particle class that extends a Sprite to have a slightly more * specialised behaviour. It is used exclusively by the Emitter class and can be extended as required. */ var Phaser; (function (Phaser) { var Particle = (function (_super) { __extends(Particle, _super); /** * Instantiate a new particle. Like Sprite, all meaningful creation * happens during loadGraphic() or makeGraphic() or whatever. */ function Particle(game) { _super.call(this, game); this.lifespan = 0; this.friction = 500; } Particle.prototype.update = /** * The particle's main update logic. Basically it checks to see if it should * be dead yet, and then has some special bounce behavior if there is some gravity on it. */ function () { //lifespan behavior if(this.lifespan <= 0) { return; } this.lifespan -= this._game.time.elapsed; if(this.lifespan <= 0) { this.kill(); } //simpler bounce/spin behavior for now if(this.touching) { if(this.angularVelocity != 0) { this.angularVelocity = -this.angularVelocity; } } if(this.acceleration.y > 0)//special behavior for particles with gravity { if(this.touching & Phaser.Collision.FLOOR) { this.drag.x = this.friction; if(!(this.wasTouching & Phaser.Collision.FLOOR)) { if(this.velocity.y < -this.elasticity * 10) { if(this.angularVelocity != 0) { this.angularVelocity *= -this.elasticity; } } else { this.velocity.y = 0; this.angularVelocity = 0; } } } else { this.drag.x = 0; } } }; Particle.prototype.onEmit = /** * Triggered whenever this object is launched by a Emitter. * You can override this to add custom behavior like a sound or AI or something. */ function () { }; return Particle; })(Phaser.Sprite); Phaser.Particle = Particle; })(Phaser || (Phaser = {})); /// /** * Phaser - TilemapLayer * * A Tilemap Layer. Tiled format maps can have multiple overlapping layers. */ var Phaser; (function (Phaser) { var TilemapLayer = (function () { function TilemapLayer(game, parent, key, mapFormat, name, tileWidth, tileHeight) { this._startX = 0; this._startY = 0; this._maxX = 0; this._maxY = 0; this._tx = 0; this._ty = 0; this._dx = 0; this._dy = 0; this._oldCameraX = 0; this._oldCameraY = 0; this.alpha = 1; this.exists = true; this.visible = true; this.widthInTiles = 0; this.heightInTiles = 0; this.widthInPixels = 0; this.heightInPixels = 0; this.tileMargin = 0; this.tileSpacing = 0; this._game = game; this._parent = parent; this.name = name; this.mapFormat = mapFormat; this.tileWidth = tileWidth; this.tileHeight = tileHeight; this.boundsInTiles = new Phaser.Rectangle(); //this.scrollFactor = new MicroPoint(1, 1); this.mapData = []; this._texture = this._game.cache.getImage(key); } TilemapLayer.prototype.getTileFromWorldXY = function (x, y) { x = this._game.math.snapToFloor(x, this.tileWidth) / this.tileWidth; y = this._game.math.snapToFloor(y, this.tileHeight) / this.tileHeight; return this.getTileIndex(x, y); }; TilemapLayer.prototype.getTileOverlaps = function (object) { // If the object is outside of the world coordinates then abort the check (tilemap has to exist within world bounds) if(object.bounds.x < 0 || object.bounds.x > this.widthInPixels || object.bounds.y < 0 || object.bounds.bottom > this.heightInPixels) { return; } // What tiles do we need to check against? this._tempTileX = this._game.math.snapToFloor(object.bounds.x, this.tileWidth) / this.tileWidth; this._tempTileY = this._game.math.snapToFloor(object.bounds.y, this.tileHeight) / this.tileHeight; this._tempTileW = (this._game.math.snapToCeil(object.bounds.width, this.tileWidth) + this.tileWidth) / this.tileWidth; this._tempTileH = (this._game.math.snapToCeil(object.bounds.height, this.tileHeight) + this.tileHeight) / this.tileHeight; // Loop through the tiles we've got and check overlaps accordingly var tiles = this.getTileBlock(this._tempTileX, this._tempTileY, this._tempTileW, this._tempTileH); Phaser.Collision.TILE_OVERLAP = false; for(var r = 0; r < tiles.length; r++) { if(tiles[r].tile.allowCollisions != Phaser.Collision.NONE) { Phaser.Collision.separateTile(object, tiles[r].x * this.tileWidth, tiles[r].y * this.tileHeight, this.tileWidth, this.tileHeight, tiles[r].tile.mass, tiles[r].tile.collideLeft, tiles[r].tile.collideRight, tiles[r].tile.collideUp, tiles[r].tile.collideDown); } } return Phaser.Collision.TILE_OVERLAP; }; TilemapLayer.prototype.getTileBlock = function (x, y, width, height) { if(x < 0) { x = 0; } if(y < 0) { y = 0; } if(width > this.widthInTiles) { width = this.widthInTiles; } if(height > this.heightInTiles) { height = this.heightInTiles; } var output = []; for(var ty = y; ty < y + height; ty++) { for(var tx = x; tx < x + width; tx++) { if(this.mapData[ty] && this.mapData[ty][tx]) { output.push({ x: tx, y: ty, tile: this._parent.tiles[this.mapData[ty][tx]] }); } } } return output; }; TilemapLayer.prototype.getTileIndex = function (x, y) { if(y >= 0 && y < this.mapData.length) { if(x >= 0 && x < this.mapData[y].length) { return this.mapData[y][x]; } } return null; }; TilemapLayer.prototype.addColumn = function (column) { var data = []; for(var c = 0; c < column.length; c++) { data[c] = parseInt(column[c]); } if(this.widthInTiles == 0) { this.widthInTiles = data.length; this.widthInPixels = this.widthInTiles * this.tileWidth; } this.mapData.push(data); this.heightInTiles++; this.heightInPixels += this.tileHeight; }; TilemapLayer.prototype.updateBounds = function () { this.boundsInTiles.setTo(0, 0, this.widthInTiles, this.heightInTiles); //console.log('layer bounds', this.boundsInTiles); }; TilemapLayer.prototype.parseTileOffsets = function () { this._tileOffsets = []; var i = 0; if(this.mapFormat == Phaser.Tilemap.FORMAT_TILED_JSON) { // For some reason Tiled counts from 1 not 0 this._tileOffsets[0] = null; i = 1; } for(var ty = this.tileMargin; ty < this._texture.height; ty += (this.tileHeight + this.tileSpacing)) { for(var tx = this.tileMargin; tx < this._texture.width; tx += (this.tileWidth + this.tileSpacing)) { this._tileOffsets[i] = { x: tx, y: ty }; i++; } } return this._tileOffsets.length; }; TilemapLayer.prototype.renderDebugInfo = function (x, y, color) { if (typeof color === "undefined") { color = 'rgb(255,255,255)'; } this._game.stage.context.fillStyle = color; this._game.stage.context.fillText('TilemapLayer: ' + this.name, x, y); this._game.stage.context.fillText('startX: ' + this._startX + ' endX: ' + this._maxX, x, y + 14); this._game.stage.context.fillText('startY: ' + this._startY + ' endY: ' + this._maxY, x, y + 28); this._game.stage.context.fillText('dx: ' + this._dx + ' dy: ' + this._dy, x, y + 42); }; TilemapLayer.prototype.render = function (camera, dx, dy) { if(this.visible === false || this.alpha < 0.1) { return false; } // Work out how many tiles we can fit into our camera and round it up for the edges this._maxX = this._game.math.ceil(camera.width / this.tileWidth) + 1; this._maxY = this._game.math.ceil(camera.height / this.tileHeight) + 1; // And now work out where in the tilemap the camera actually is this._startX = this._game.math.floor(camera.worldView.x / this.tileWidth); this._startY = this._game.math.floor(camera.worldView.y / this.tileHeight); // Tilemap bounds check if(this._startX < 0) { this._startX = 0; } if(this._startY < 0) { this._startY = 0; } if(this._maxX > this.widthInTiles) { this._maxX = this.widthInTiles; } if(this._maxY > this.heightInTiles) { this._maxY = this.heightInTiles; } if(this._startX + this._maxX > this.widthInTiles) { this._startX = this.widthInTiles - this._maxX; } if(this._startY + this._maxY > this.heightInTiles) { this._startY = this.heightInTiles - this._maxY; } // Finally get the offset to avoid the blocky movement this._dx = dx; this._dy = dy; this._dx += -(camera.worldView.x - (this._startX * this.tileWidth)); this._dy += -(camera.worldView.y - (this._startY * this.tileHeight)); this._tx = this._dx; this._ty = this._dy; // Apply camera difference /* if (this.scrollFactor.x !== 1.0 || this.scrollFactor.y !== 1.0) { this._dx -= (camera.worldView.x * this.scrollFactor.x); this._dy -= (camera.worldView.y * this.scrollFactor.y); } */ // Alpha if(this.alpha !== 1) { var globalAlpha = this._game.stage.context.globalAlpha; this._game.stage.context.globalAlpha = this.alpha; } for(var row = this._startY; row < this._startY + this._maxY; row++) { this._columnData = this.mapData[row]; for(var tile = this._startX; tile < this._startX + this._maxX; tile++) { if(this._tileOffsets[this._columnData[tile]]) { this._game.stage.context.drawImage(this._texture, // Source Image this._tileOffsets[this._columnData[tile]].x, // Source X (location within the source image) this._tileOffsets[this._columnData[tile]].y, // Source Y this.tileWidth, // Source Width this.tileHeight, // Source Height this._tx, // Destination X (where on the canvas it'll be drawn) this._ty, // Destination Y this.tileWidth, // Destination Width (always same as Source Width unless scaled) this.tileHeight); // Destination Height (always same as Source Height unless scaled) } this._tx += this.tileWidth; } this._tx = this._dx; this._ty += this.tileHeight; } if(globalAlpha > -1) { this._game.stage.context.globalAlpha = globalAlpha; } return true; }; return TilemapLayer; })(); Phaser.TilemapLayer = TilemapLayer; })(Phaser || (Phaser = {})); /// /** * Phaser - Tile * * A Tile is a single representation of a tile within a Tilemap */ var Phaser; (function (Phaser) { var Tile = (function () { function Tile(game, tilemap, index, width, height) { this.mass = 1.0; this.collideLeft = false; this.collideRight = false; this.collideUp = false; this.collideDown = false; this._game = game; this.tilemap = tilemap; this.index = index; this.width = width; this.height = height; this.allowCollisions = Phaser.Collision.NONE; } Tile.prototype.destroy = /** * Clean up memory. */ function () { this.tilemap = null; }; Tile.prototype.setCollision = function (collision, resetCollisions) { if(resetCollisions) { this.resetCollision(); } this.allowCollisions = collision; if(collision & Phaser.Collision.ANY) { this.collideLeft = true; this.collideRight = true; this.collideUp = true; this.collideDown = true; return; } if(collision & Phaser.Collision.LEFT || collision & Phaser.Collision.WALL) { this.collideLeft = true; } if(collision & Phaser.Collision.RIGHT || collision & Phaser.Collision.WALL) { this.collideRight = true; } if(collision & Phaser.Collision.UP || collision & Phaser.Collision.CEILING) { this.collideUp = true; } if(collision & Phaser.Collision.DOWN || collision & Phaser.Collision.CEILING) { this.collideDown = true; } }; Tile.prototype.resetCollision = function () { this.allowCollisions = Phaser.Collision.NONE; this.collideLeft = false; this.collideRight = false; this.collideUp = false; this.collideDown = false; }; Tile.prototype.toString = /** * Returns a string representation of this object. * @method toString * @return {string} a string representation of the object. **/ function () { return "[{Tiled (index=" + this.index + " collisions=" + this.allowCollisions + " width=" + this.width + " height=" + this.height + ")}]"; }; return Tile; })(); Phaser.Tile = Tile; })(Phaser || (Phaser = {})); /// /// /// /// /** * Phaser - Tilemap * * This GameObject allows for the display of a tilemap within the game world. Tile maps consist of an image, tile data and a size. * Internally it creates a TilemapLayer for each layer in the tilemap. */ var Phaser; (function (Phaser) { var Tilemap = (function (_super) { __extends(Tilemap, _super); function Tilemap(game, key, mapData, format, resizeWorld, tileWidth, tileHeight) { if (typeof resizeWorld === "undefined") { resizeWorld = true; } if (typeof tileWidth === "undefined") { tileWidth = 0; } if (typeof tileHeight === "undefined") { tileHeight = 0; } _super.call(this, game); this.isGroup = false; this.tiles = []; this.layers = []; this.mapFormat = format; switch(format) { case Tilemap.FORMAT_CSV: this.parseCSV(game.cache.getText(mapData), key, tileWidth, tileHeight); break; case Tilemap.FORMAT_TILED_JSON: this.parseTiledJSON(game.cache.getText(mapData), key); break; } if(this.currentLayer && resizeWorld) { this._game.world.setSize(this.currentLayer.widthInPixels, this.currentLayer.heightInPixels, true); } } Tilemap.FORMAT_CSV = 0; Tilemap.FORMAT_TILED_JSON = 1; Tilemap.prototype.update = function () { }; Tilemap.prototype.render = function (camera, cameraOffsetX, cameraOffsetY) { if(this.cameraBlacklist.indexOf(camera.ID) == -1) { // Loop through the layers for(var i = 0; i < this.layers.length; i++) { this.layers[i].render(camera, cameraOffsetX, cameraOffsetY); } } }; Tilemap.prototype.parseCSV = function (data, key, tileWidth, tileHeight) { var layer = new Phaser.TilemapLayer(this._game, this, key, Tilemap.FORMAT_CSV, 'TileLayerCSV' + this.layers.length.toString(), tileWidth, tileHeight); // Trim any rogue whitespace from the data data = data.trim(); var rows = data.split("\n"); for(var i = 0; i < rows.length; i++) { var column = rows[i].split(","); if(column.length > 0) { layer.addColumn(column); } } layer.updateBounds(); var tileQuantity = layer.parseTileOffsets(); this.currentLayer = layer; this.collisionLayer = layer; this.layers.push(layer); this.generateTiles(tileQuantity); }; Tilemap.prototype.parseTiledJSON = function (data, key) { // Trim any rogue whitespace from the data data = data.trim(); var json = JSON.parse(data); for(var i = 0; i < json.layers.length; i++) { var layer = new Phaser.TilemapLayer(this._game, this, key, Tilemap.FORMAT_TILED_JSON, json.layers[i].name, json.tilewidth, json.tileheight); layer.alpha = json.layers[i].opacity; layer.visible = json.layers[i].visible; layer.tileMargin = json.tilesets[0].margin; layer.tileSpacing = json.tilesets[0].spacing; var c = 0; var row; for(var t = 0; t < json.layers[i].data.length; t++) { if(c == 0) { row = []; } row.push(json.layers[i].data[t]); c++; if(c == json.layers[i].width) { layer.addColumn(row); c = 0; } } layer.updateBounds(); var tileQuantity = layer.parseTileOffsets(); this.currentLayer = layer; this.collisionLayer = layer; this.layers.push(layer); } this.generateTiles(tileQuantity); }; Tilemap.prototype.generateTiles = function (qty) { for(var i = 0; i < qty; i++) { this.tiles.push(new Phaser.Tile(this._game, this, i, this.currentLayer.tileWidth, this.currentLayer.tileHeight)); } }; Object.defineProperty(Tilemap.prototype, "widthInPixels", { get: function () { return this.currentLayer.widthInPixels; }, enumerable: true, configurable: true }); Object.defineProperty(Tilemap.prototype, "heightInPixels", { get: function () { return this.currentLayer.heightInPixels; }, enumerable: true, configurable: true }); Tilemap.prototype.setCollisionRange = // Tile Collision function (start, end, collision, resetCollisions) { if (typeof collision === "undefined") { collision = Phaser.Collision.ANY; } if (typeof resetCollisions === "undefined") { resetCollisions = false; } for(var i = start; i < end; i++) { this.tiles[i].setCollision(collision, resetCollisions); } }; Tilemap.prototype.setCollisionByIndex = function (values, collision, resetCollisions) { if (typeof collision === "undefined") { collision = Phaser.Collision.ANY; } if (typeof resetCollisions === "undefined") { resetCollisions = false; } for(var i = 0; i < values.length; i++) { this.tiles[values[i]].setCollision(collision, resetCollisions); } }; Tilemap.prototype.getTile = // Tile Management function (x, y, layer) { if (typeof layer === "undefined") { layer = 0; } return this.tiles[this.layers[layer].getTileIndex(x, y)]; }; Tilemap.prototype.getTileFromWorldXY = function (x, y, layer) { if (typeof layer === "undefined") { layer = 0; } return this.tiles[this.layers[layer].getTileFromWorldXY(x, y)]; }; Tilemap.prototype.getTileFromInputXY = function (layer) { if (typeof layer === "undefined") { layer = 0; } return this.tiles[this.layers[layer].getTileFromWorldXY(this._game.input.worldX, this._game.input.worldY)]; }; Tilemap.prototype.getTileOverlaps = function (object) { return this.currentLayer.getTileOverlaps(object); }; Tilemap.prototype.collide = // COLLIDE function (objectOrGroup, callback) { if (typeof objectOrGroup === "undefined") { objectOrGroup = null; } if (typeof callback === "undefined") { callback = null; } if(objectOrGroup == null) { objectOrGroup = this._game.world.group; } // Group? if(objectOrGroup.isGroup == false) { return this.collideGameObject(objectOrGroup); } else { objectOrGroup.forEachAlive(this, this.collideGameObject, true); } return true; }; Tilemap.prototype.collideGameObject = function (object) { if(object == this) { return false; } if(object.immovable == false && object.exists == true && object.allowCollisions != Phaser.Collision.NONE) { return this.collisionLayer.getTileOverlaps(object); } else { return false; } }; return Tilemap; })(Phaser.GameObject); Phaser.Tilemap = Tilemap; // Set current layer // Set layer order? // Get block of tiles // Swap tiles around // Delete tiles of certain type // Erase tiles })(Phaser || (Phaser = {})); /// /// /// /// /// /// /// /// /// /// /// /// /// /// /// /// /// /// /// /// /// /// /// /// /// /// /// /// /// /// /// /** * Phaser - Game * * This is where the magic happens. The Game object is the heart of your game, * providing quick access to common functions and handling the boot process. * * "Hell, there are no rules here - we're trying to accomplish something." * Thomas A. Edison */ var Phaser; (function (Phaser) { var Game = (function () { function Game(callbackContext, parent, width, height, initCallback, createCallback, updateCallback, renderCallback) { if (typeof parent === "undefined") { parent = ''; } if (typeof width === "undefined") { width = 800; } if (typeof height === "undefined") { height = 600; } if (typeof initCallback === "undefined") { initCallback = null; } if (typeof createCallback === "undefined") { createCallback = null; } if (typeof updateCallback === "undefined") { updateCallback = null; } if (typeof renderCallback === "undefined") { renderCallback = null; } var _this = this; this._maxAccumulation = 32; this._accumulator = 0; this._step = 0; this._loadComplete = false; this._paused = false; this._pendingState = null; this.onInitCallback = null; this.onCreateCallback = null; this.onUpdateCallback = null; this.onRenderCallback = null; this.onPausedCallback = null; this.isBooted = false; this.callbackContext = callbackContext; this.onInitCallback = initCallback; this.onCreateCallback = createCallback; this.onUpdateCallback = updateCallback; this.onRenderCallback = renderCallback; if(document.readyState === 'complete' || document.readyState === 'interactive') { setTimeout(function () { return _this.boot(parent, width, height); }); } else { document.addEventListener('DOMContentLoaded', function () { return _this.boot(parent, width, height); }, false); window.addEventListener('load', function () { return _this.boot(parent, width, height); }, false); } } Game.prototype.boot = function (parent, width, height) { var _this = this; if(this.isBooted == true) { return; } if(!document.body) { window.setTimeout(function () { return _this.boot(parent, width, height); }, 13); } else { this.device = new Phaser.Device(); this.motion = new Phaser.Motion(this); this.math = new Phaser.GameMath(this); this.stage = new Phaser.Stage(this, parent, width, height); this.world = new Phaser.World(this, width, height); this.sound = new Phaser.SoundManager(this); this.cache = new Phaser.Cache(this); this.collision = new Phaser.Collision(this); this.loader = new Phaser.Loader(this, this.loadComplete); this.time = new Phaser.Time(this); this.tweens = new Phaser.TweenManager(this); this.input = new Phaser.Input(this); this.rnd = new Phaser.RandomDataGenerator([ (Date.now() * Math.random()).toString() ]); this.framerate = 60; // Display the default game screen? if(this.onInitCallback == null && this.onCreateCallback == null && this.onUpdateCallback == null && this.onRenderCallback == null && this._pendingState == null) { this.isBooted = false; this.stage.drawInitScreen(); } else { this.isBooted = true; this._loadComplete = false; this._raf = new Phaser.RequestAnimationFrame(this.loop, this); if(this._pendingState) { this.switchState(this._pendingState, false, false); } else { this.startState(); } } } }; Game.prototype.loadComplete = function () { // Called when the loader has finished after init was run this._loadComplete = true; }; Game.prototype.loop = function () { this.time.update(); this.tweens.update(); if(this._paused == true) { if(this.onPausedCallback !== null) { this.onPausedCallback.call(this.callbackContext); } return; } this.input.update(); this.stage.update(); this._accumulator += this.time.delta; if(this._accumulator > this._maxAccumulation) { this._accumulator = this._maxAccumulation; } while(this._accumulator >= this._step) { this.time.elapsed = this.time.timeScale * (this._step / 1000); this.world.update(); this._accumulator = this._accumulator - this._step; } if(this._loadComplete && this.onUpdateCallback) { this.onUpdateCallback.call(this.callbackContext); } this.world.render(); if(this._loadComplete && this.onRenderCallback) { this.onRenderCallback.call(this.callbackContext); } }; Game.prototype.startState = function () { if(this.onInitCallback !== null) { this.loader.reset(); this.onInitCallback.call(this.callbackContext); // Is the loader empty? if(this.loader.queueSize == 0) { if(this.onCreateCallback !== null) { this.onCreateCallback.call(this.callbackContext); } this._loadComplete = true; } } else { // No init? Then there was nothing to load either if(this.onCreateCallback !== null) { this.onCreateCallback.call(this.callbackContext); } this._loadComplete = true; } }; Game.prototype.setCallbacks = function (initCallback, createCallback, updateCallback, renderCallback) { if (typeof initCallback === "undefined") { initCallback = null; } if (typeof createCallback === "undefined") { createCallback = null; } if (typeof updateCallback === "undefined") { updateCallback = null; } if (typeof renderCallback === "undefined") { renderCallback = null; } this.onInitCallback = initCallback; this.onCreateCallback = createCallback; this.onUpdateCallback = updateCallback; this.onRenderCallback = renderCallback; }; Game.prototype.switchState = function (state, clearWorld, clearCache) { if (typeof clearWorld === "undefined") { clearWorld = true; } if (typeof clearCache === "undefined") { clearCache = false; } if(this.isBooted == false) { this._pendingState = state; return; } // Prototype? if(typeof state === 'function') { state = new state(this); } // Ok, have we got the right functions? if(state['create'] || state['update']) { this.callbackContext = state; this.onInitCallback = null; this.onCreateCallback = null; this.onUpdateCallback = null; this.onRenderCallback = null; this.onPausedCallback = null; // Bingo, let's set them up if(state['init']) { this.onInitCallback = state['init']; } if(state['create']) { this.onCreateCallback = state['create']; } if(state['update']) { this.onUpdateCallback = state['update']; } if(state['render']) { this.onRenderCallback = state['render']; } if(state['paused']) { this.onPausedCallback = state['paused']; } if(clearWorld) { this.world.destroy(); if(clearCache == true) { this.cache.destroy(); } } this._loadComplete = false; this.startState(); } else { throw new Error("Invalid State object given. Must contain at least a create or update function."); } }; Game.prototype.destroy = // Nuke the whole game from orbit function () { this.callbackContext = null; this.onInitCallback = null; this.onCreateCallback = null; this.onUpdateCallback = null; this.onRenderCallback = null; this.onPausedCallback = null; this.cache = null; this.input = null; this.loader = null; this.sound = null; this.stage = null; this.time = null; this.world = null; this.isBooted = false; }; Object.defineProperty(Game.prototype, "paused", { get: function () { return this._paused; }, set: function (value) { if(value == true && this._paused == false) { this._paused = true; } else if(value == false && this._paused == true) { this._paused = false; this.time.time = Date.now(); this.input.reset(); } }, enumerable: true, configurable: true }); Object.defineProperty(Game.prototype, "framerate", { get: function () { return 1000 / this._step; }, set: function (value) { this._step = 1000 / value; if(this._maxAccumulation < this._step) { this._maxAccumulation = this._step; } }, enumerable: true, configurable: true }); Game.prototype.createCamera = // Handy Proxy methods function (x, y, width, height) { return this.world.createCamera(x, y, width, height); }; Game.prototype.createGeomSprite = function (x, y) { return this.world.createGeomSprite(x, y); }; Game.prototype.createSprite = function (x, y, key) { if (typeof key === "undefined") { key = ''; } return this.world.createSprite(x, y, key); }; Game.prototype.createDynamicTexture = function (width, height) { return this.world.createDynamicTexture(width, height); }; Game.prototype.createGroup = function (MaxSize) { if (typeof MaxSize === "undefined") { MaxSize = 0; } return this.world.createGroup(MaxSize); }; Game.prototype.createParticle = function () { return this.world.createParticle(); }; Game.prototype.createEmitter = function (x, y, size) { if (typeof x === "undefined") { x = 0; } if (typeof y === "undefined") { y = 0; } if (typeof size === "undefined") { size = 0; } return this.world.createEmitter(x, y, size); }; Game.prototype.createScrollZone = function (key, x, y, width, height) { if (typeof x === "undefined") { x = 0; } if (typeof y === "undefined") { y = 0; } if (typeof width === "undefined") { width = 0; } if (typeof height === "undefined") { height = 0; } return this.world.createScrollZone(key, x, y, width, height); }; Game.prototype.createTilemap = function (key, mapData, format, resizeWorld, tileWidth, tileHeight) { if (typeof resizeWorld === "undefined") { resizeWorld = true; } if (typeof tileWidth === "undefined") { tileWidth = 0; } if (typeof tileHeight === "undefined") { tileHeight = 0; } return this.world.createTilemap(key, mapData, format, resizeWorld, tileWidth, tileHeight); }; Game.prototype.createTween = function (obj) { return this.tweens.create(obj); }; Game.prototype.collide = function (objectOrGroup1, objectOrGroup2, notifyCallback) { if (typeof objectOrGroup1 === "undefined") { objectOrGroup1 = null; } if (typeof objectOrGroup2 === "undefined") { objectOrGroup2 = null; } if (typeof notifyCallback === "undefined") { notifyCallback = null; } return this.collision.overlap(objectOrGroup1, objectOrGroup2, notifyCallback, Phaser.Collision.separate); }; Object.defineProperty(Game.prototype, "camera", { get: function () { return this.world.cameras.current; }, enumerable: true, configurable: true }); return Game; })(); Phaser.Game = Game; })(Phaser || (Phaser = {})); /// /// /** * Phaser - ScrollRegion * * Creates a scrolling region within a ScrollZone. * It is scrolled via the scrollSpeed.x/y properties. */ var Phaser; (function (Phaser) { var ScrollRegion = (function () { function ScrollRegion(x, y, width, height, speedX, speedY) { this._anchorWidth = 0; this._anchorHeight = 0; this._inverseWidth = 0; this._inverseHeight = 0; this.visible = true; // Our seamless scrolling quads this._A = new Phaser.Quad(x, y, width, height); this._B = new Phaser.Quad(x, y, width, height); this._C = new Phaser.Quad(x, y, width, height); this._D = new Phaser.Quad(x, y, width, height); this._scroll = new Phaser.MicroPoint(); this._bounds = new Phaser.Quad(x, y, width, height); this.scrollSpeed = new Phaser.MicroPoint(speedX, speedY); } ScrollRegion.prototype.update = function (delta) { this._scroll.x += this.scrollSpeed.x; this._scroll.y += this.scrollSpeed.y; if(this._scroll.x > this._bounds.right) { this._scroll.x = this._bounds.x; } if(this._scroll.x < this._bounds.x) { this._scroll.x = this._bounds.right; } if(this._scroll.y > this._bounds.bottom) { this._scroll.y = this._bounds.y; } if(this._scroll.y < this._bounds.y) { this._scroll.y = this._bounds.bottom; } // Anchor Dimensions this._anchorWidth = (this._bounds.width - this._scroll.x) + this._bounds.x; this._anchorHeight = (this._bounds.height - this._scroll.y) + this._bounds.y; if(this._anchorWidth > this._bounds.width) { this._anchorWidth = this._bounds.width; } if(this._anchorHeight > this._bounds.height) { this._anchorHeight = this._bounds.height; } this._inverseWidth = this._bounds.width - this._anchorWidth; this._inverseHeight = this._bounds.height - this._anchorHeight; // Quad A this._A.setTo(this._scroll.x, this._scroll.y, this._anchorWidth, this._anchorHeight); // Quad B this._B.y = this._scroll.y; this._B.width = this._inverseWidth; this._B.height = this._anchorHeight; // Quad C this._C.x = this._scroll.x; this._C.width = this._anchorWidth; this._C.height = this._inverseHeight; // Quad D this._D.width = this._inverseWidth; this._D.height = this._inverseHeight; }; ScrollRegion.prototype.render = function (context, texture, dx, dy, dw, dh) { if(this.visible == false) { return; } // dx/dy are the world coordinates to render the FULL ScrollZone into. // This ScrollRegion may be smaller than that and offset from the dx/dy coordinates. this.crop(context, texture, this._A.x, this._A.y, this._A.width, this._A.height, dx, dy, dw, dh, 0, 0); this.crop(context, texture, this._B.x, this._B.y, this._B.width, this._B.height, dx, dy, dw, dh, this._A.width, 0); this.crop(context, texture, this._C.x, this._C.y, this._C.width, this._C.height, dx, dy, dw, dh, 0, this._A.height); this.crop(context, texture, this._D.x, this._D.y, this._D.width, this._D.height, dx, dy, dw, dh, this._C.width, this._A.height); //context.fillStyle = 'rgb(255,255,255)'; //context.font = '18px Arial'; //context.fillText('QuadA: ' + this._A.toString(), 32, 450); //context.fillText('QuadB: ' + this._B.toString(), 32, 480); //context.fillText('QuadC: ' + this._C.toString(), 32, 510); //context.fillText('QuadD: ' + this._D.toString(), 32, 540); }; ScrollRegion.prototype.crop = function (context, texture, srcX, srcY, srcW, srcH, destX, destY, destW, destH, offsetX, offsetY) { offsetX += destX; offsetY += destY; if(srcW > (destX + destW) - offsetX) { srcW = (destX + destW) - offsetX; } if(srcH > (destY + destH) - offsetY) { srcH = (destY + destH) - offsetY; } srcX = Math.floor(srcX); srcY = Math.floor(srcY); srcW = Math.floor(srcW); srcH = Math.floor(srcH); offsetX = Math.floor(offsetX + this._bounds.x); offsetY = Math.floor(offsetY + this._bounds.y); if(srcW > 0 && srcH > 0) { context.drawImage(texture, srcX, srcY, srcW, srcH, offsetX, offsetY, srcW, srcH); } }; return ScrollRegion; })(); Phaser.ScrollRegion = ScrollRegion; })(Phaser || (Phaser = {})); /// /// /// /** * Phaser - ScrollZone * * Creates a scrolling region of the given width and height from an image in the cache. * The ScrollZone can be positioned anywhere in-world like a normal game object, re-act to physics, collision, etc. * The image within it is scrolled via ScrollRegions and their scrollSpeed.x/y properties. * If you create a scroll zone larger than the given source image it will create a DynamicTexture and fill it with a pattern of the source image. */ var Phaser; (function (Phaser) { var ScrollZone = (function (_super) { __extends(ScrollZone, _super); function ScrollZone(game, key, x, y, width, height) { if (typeof x === "undefined") { x = 0; } if (typeof y === "undefined") { y = 0; } if (typeof width === "undefined") { width = 0; } if (typeof height === "undefined") { height = 0; } _super.call(this, game, x, y, width, height); this._dynamicTexture = null; // local rendering related temp vars to help avoid gc spikes this._dx = 0; this._dy = 0; this._dw = 0; this._dh = 0; this.flipped = false; this.regions = []; if(this._game.cache.getImage(key)) { this._texture = this._game.cache.getImage(key); this.width = this._texture.width; this.height = this._texture.height; if(width > this._texture.width || height > this._texture.height) { // Create our repeating texture (as the source image wasn't large enough for the requested size) this.createRepeatingTexture(width, height); this.width = width; this.height = height; } // Create a default ScrollRegion at the requested size this.addRegion(0, 0, this.width, this.height); // If the zone is smaller than the image itself then shrink the bounds if((width < this._texture.width || height < this._texture.height) && width !== 0 && height !== 0) { this.width = width; this.height = height; } } } ScrollZone.prototype.addRegion = function (x, y, width, height, speedX, speedY) { if (typeof speedX === "undefined") { speedX = 0; } if (typeof speedY === "undefined") { speedY = 0; } if(x > this.width || y > this.height || x < 0 || y < 0 || (x + width) > this.width || (y + height) > this.height) { throw Error('Invalid ScrollRegion defined. Cannot be larger than parent ScrollZone'); return; } this.currentRegion = new Phaser.ScrollRegion(x, y, width, height, speedX, speedY); this.regions.push(this.currentRegion); return this.currentRegion; }; ScrollZone.prototype.setSpeed = function (x, y) { if(this.currentRegion) { this.currentRegion.scrollSpeed.setTo(x, y); } return this; }; ScrollZone.prototype.update = function () { for(var i = 0; i < this.regions.length; i++) { this.regions[i].update(this._game.time.delta); } }; ScrollZone.prototype.inCamera = function (camera) { if(this.scrollFactor.x !== 1.0 || this.scrollFactor.y !== 1.0) { this._dx = this.bounds.x - (camera.x * this.scrollFactor.x); this._dy = this.bounds.y - (camera.y * this.scrollFactor.x); this._dw = this.bounds.width * this.scale.x; this._dh = this.bounds.height * this.scale.y; return (camera.right > this._dx) && (camera.x < this._dx + this._dw) && (camera.bottom > this._dy) && (camera.y < this._dy + this._dh); } else { return camera.intersects(this.bounds, this.bounds.length); } }; ScrollZone.prototype.render = function (camera, cameraOffsetX, cameraOffsetY) { // Render checks if(this.visible == false || this.scale.x == 0 || this.scale.y == 0 || this.alpha < 0.1 || this.cameraBlacklist.indexOf(camera.ID) !== -1 || this.inCamera(camera.worldView) == false) { return false; } // Alpha if(this.alpha !== 1) { var globalAlpha = this._game.stage.context.globalAlpha; this._game.stage.context.globalAlpha = this.alpha; } this._dx = cameraOffsetX + (this.bounds.topLeft.x - camera.worldView.x); this._dy = cameraOffsetY + (this.bounds.topLeft.y - camera.worldView.y); this._dw = this.bounds.width * this.scale.x; this._dh = this.bounds.height * this.scale.y; // Apply camera difference if(this.scrollFactor.x !== 1.0 || this.scrollFactor.y !== 1.0) { this._dx -= (camera.worldView.x * this.scrollFactor.x); this._dy -= (camera.worldView.y * this.scrollFactor.y); } // Rotation - needs to work from origin point really, but for now from center if(this.angle !== 0 || this.flipped == true) { this._game.stage.context.save(); this._game.stage.context.translate(this._dx + (this._dw / 2), this._dy + (this._dh / 2)); if(this.angle !== 0) { this._game.stage.context.rotate(this.angle * (Math.PI / 180)); } this._dx = -(this._dw / 2); this._dy = -(this._dh / 2); if(this.flipped == true) { this._game.stage.context.scale(-1, 1); } } this._dx = Math.round(this._dx); this._dy = Math.round(this._dy); this._dw = Math.round(this._dw); this._dh = Math.round(this._dh); for(var i = 0; i < this.regions.length; i++) { if(this._dynamicTexture) { this.regions[i].render(this._game.stage.context, this._dynamicTexture.canvas, this._dx, this._dy, this._dw, this._dh); } else { this.regions[i].render(this._game.stage.context, this._texture, this._dx, this._dy, this._dw, this._dh); } } if(globalAlpha > -1) { this._game.stage.context.globalAlpha = globalAlpha; } return true; }; ScrollZone.prototype.createRepeatingTexture = function (regionWidth, regionHeight) { // Work out how many we'll need of the source image to make it tile properly var tileWidth = Math.ceil(this._texture.width / regionWidth) * regionWidth; var tileHeight = Math.ceil(this._texture.height / regionHeight) * regionHeight; this._dynamicTexture = new Phaser.DynamicTexture(this._game, tileWidth, tileHeight); this._dynamicTexture.context.rect(0, 0, tileWidth, tileHeight); this._dynamicTexture.context.fillStyle = this._dynamicTexture.context.createPattern(this._texture, "repeat"); this._dynamicTexture.context.fill(); }; return ScrollZone; })(Phaser.GameObject); Phaser.ScrollZone = ScrollZone; })(Phaser || (Phaser = {})); /// /** * Phaser - State * * This is a base State class which can be extended if you are creating your game using TypeScript. */ var Phaser; (function (Phaser) { var State = (function () { function State(game) { this.game = game; this.camera = game.camera; this.cache = game.cache; this.collision = game.collision; this.input = game.input; this.loader = game.loader; this.math = game.math; this.motion = game.motion; this.sound = game.sound; this.stage = game.stage; this.time = game.time; this.tweens = game.tweens; this.world = game.world; } State.prototype.init = // Overload these in your own States function () { }; State.prototype.create = function () { }; State.prototype.update = function () { }; State.prototype.render = function () { }; State.prototype.paused = function () { }; State.prototype.createCamera = // Handy Proxy methods function (x, y, width, height) { return this.game.world.createCamera(x, y, width, height); }; State.prototype.createGeomSprite = function (x, y) { return this.world.createGeomSprite(x, y); }; State.prototype.createSprite = function (x, y, key) { if (typeof key === "undefined") { key = ''; } return this.game.world.createSprite(x, y, key); }; State.prototype.createDynamicTexture = function (width, height) { return this.game.world.createDynamicTexture(width, height); }; State.prototype.createGroup = function (MaxSize) { if (typeof MaxSize === "undefined") { MaxSize = 0; } return this.game.world.createGroup(MaxSize); }; State.prototype.createParticle = function () { return this.game.world.createParticle(); }; State.prototype.createEmitter = function (x, y, size) { if (typeof x === "undefined") { x = 0; } if (typeof y === "undefined") { y = 0; } if (typeof size === "undefined") { size = 0; } return this.game.world.createEmitter(x, y, size); }; State.prototype.createScrollZone = function (key, x, y, width, height) { if (typeof x === "undefined") { x = 0; } if (typeof y === "undefined") { y = 0; } if (typeof width === "undefined") { width = 0; } if (typeof height === "undefined") { height = 0; } return this.game.world.createScrollZone(key, x, y, width, height); }; State.prototype.createTilemap = function (key, mapData, format, resizeWorld, tileWidth, tileHeight) { if (typeof resizeWorld === "undefined") { resizeWorld = true; } if (typeof tileWidth === "undefined") { tileWidth = 0; } if (typeof tileHeight === "undefined") { tileHeight = 0; } return this.game.world.createTilemap(key, mapData, format, resizeWorld, tileWidth, tileHeight); }; State.prototype.createTween = function (obj) { return this.game.tweens.create(obj); }; State.prototype.collide = function (ObjectOrGroup1, ObjectOrGroup2, NotifyCallback) { if (typeof ObjectOrGroup1 === "undefined") { ObjectOrGroup1 = null; } if (typeof ObjectOrGroup2 === "undefined") { ObjectOrGroup2 = null; } if (typeof NotifyCallback === "undefined") { NotifyCallback = null; } return this.collision.overlap(ObjectOrGroup1, ObjectOrGroup2, NotifyCallback, Phaser.Collision.separate); }; return State; })(); Phaser.State = State; })(Phaser || (Phaser = {}));